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Specifications • ./me 20 1C o /05& 5 s t/✓ c s %-vie Goa J • RECEIVED • .7- FEB 2 2011 STRUCTURAL DETAILS AND CALCULATIONS • • vITYOF I ;C ; BUILDONC DiVi6iON For The (N) RTU on (E) Roof Structure of the Scholls Business Center Building • Tigard, OR For Perlo Construction Walker Structural Engineering, LLC # .vpUCT Ug q! ,0:04 PROF d i 5 32PE k . // REGO a 0 ✓ 10 er 13 S q, OH L WAY !EXPIRES: 8/30/ 1a• I • January 31, 2011 Job # 11010 • Walker 4.4 • • h y V • 2863 NW Crossing Drive ' Suite 201 Bend, Oregon 97701 541.330.6869 / Fax: 541.330.2656 • . . • . . ' - 2863 NW Crossing Drive • Suite zoi office 541-330-6869 Bend, Oregon 97701 fax 541-330-2656 Wali B cpr - . . • Project By Sheet 0 * •••4 tk0 LLC r____ 1_,.. S CHOU3L__80.S_ cg_Riv. zr 'i ; 4., I Location 1 Revised Job if t) .,_____c> Client . Date ' i q L 1 1 . , - , Nor: co..)Te i Te. VE:eify (E) 241-0s 1 T.044. • c.rionI., AND cc).)•C"ez . • i %. • eNcriao..tEe. 1.F 01..sckeP"Alcie..) 1 . _r_. esi kri ..11 • . Ark ..F. . . Z 1 ? ' 1 ,- I , Ark . 1 - IZIV . • ( 4 • . r .1 t" I \23'-3 1/.2 i . __ T 0.F. 1 . , I T.O.F. 12 IM.g ‘. - . ..2, i ! i _L. • i . _ - e i 1 . 22 3/4"1 I . I , • NoTe.: (IV RTU rioNsi 3 c • ' • . 1 . 1 . Loco...rep gwy oF Ttlet sTti; PuRt.tms ca. ,,s 5 {4r....b . "3 : • . I . • I I Est e 1 I : (N) RTU itl c>"Ttt ekS4t i . 1 1 0 -6 1 4 iith ' 2> .--. ( • " 21'-9" I .. T.O.F. • ' .iligh■ I . (IRO. VW . . . I • I . SEE Pt c.iieD . 1 Den L5- . . • I . . . • 1 I I , . . I • . 0 ci RI D. ' • • ) 0 CI RID. I ' . 1 ; ' • ; t : , . . : . 1 . : , % I Alak PiNfo ) ROOF .FicAtAIL21( - PL A■1■) - L-NL(N) RTU . I , 1 ": II-0f. . . L_____ _:_.2..______.___[_..._ 4._ L. . . - . . • 2863 NW. Crossing Drive • Suite zor office 541-33o-6869 . ,.. , I)Ti11Ker Bend, Oregon 97701 fax 541-33o-2656 r • , i Project By Sheet U *•••••% (:)40LLC i t • ' Se–MoLL5 Sosir.e.s5 1 IZTJ • 1 Locah or. Revised Job # •. 1 — I •Z 8)0 . , Gent i Date P ERt.c.) con 5T. 1 tiz7/11 i_ cl) Loc.p<rG - to ce.sxre..-K ( k.)f•Jii - gr....),N) Pue.upts 1 1/ - t LW) - ry ey o TqE.c,5 1 _-_-.,-,_ i 0 . /z7 ) ____ R _:.? FL- . .,. , - RTJ M T ouNTINIC-1 Cug.6 PE R . . : >•<.1, . M c\ r F. INN, ... FiNsTE.-A--) Tc, LEv alEifk ' . r cLocx „, 1,4,, lc 3" L.Ac . . e... IZ" 0. C. . I Li ( L\4-LL E,Z 13 LoCK 1....i/ . 1/2." 4 X 4, " Li).<4 $ f C-2c_v4.5 -- lippr . e Igo O. c.c.s...TER S I t%) bc. . . P$ RC-_-C b- STAC7C-.4CZ., L.J/ .... . C_..,Re Sc-4E1.--1.5 . . i - . . .,., • i 6,u11.21 - P • 2 J''1 e e . 1 i ---.4" -.6F:ill • in ,. , 1 ' . • ( 1 1 ) Z I (Fic‘ Su0- p,....rz,L. % r.i.5 R_ 1 t - vi r, O. c. 1 • 1 ('4) Li x 9 61--Ic 'cl ge.L0 c_u R Ci k.---% / • 1-1..P-19 Hc- I (C.") oPE. L3 els STEEL 1 • : I i 1 • I t I . 1 , • • ■ . 1 1 • 1 . . .• I . I • i ,. • • 1 i - N ); KT U : e p - ERR E N‘ D 1 CO i 'L.".K S 615 T.S. . ____ --• __ _ • • • • • - ! , • . • 1 - • . • --I • 2863 NW Crossing Drive • Suite 201 office 541 -330 -6869 Bend, Oregon 97701 fax 54 -26 a 1 er - r (� • • Project By _ f Sheet it I ti bJ LLC Sc- gotl5_ Bust '• C TR IZ . -- J I _ _ . __ -- 1 N r r — - --- r z i Location Revised ` Job i � 1. Client i Date i h • (iv) RTU ' Cy oTit�R,S - ? _ �{, u RTv •+'1v_0iJ - rt tJ ` { U C JR� PEA / FrN,STLr■ To LCVELLQR • ,131 -Oct. U/ ' /ti.` QS x 3 LF j - ` • :SC €ws e. 3" o. c. • ) B° - UP 1 NC-1. . • REr" ovE @ BLocic . . \ I 4 x LEV tLt-C.R t Loc_K cam/ • -. . • _, t 1 8' V• �+ cauni�ER SINK • ' Al �s R Ec 2' V. 5TPcc -7yEQ _ J/ � _ .C_%.) 9, Z sc_¢E-%S i . I + I \` _• - °-_. .... ~ =_�— - - --- - - ,- '- -_-- \ I-- _�'= L -'u_: I I �a:; "_ 1- . _ --- - - -- .ews-- .., • ro b, • • (N)9x 13LK•C7 6eto•. CL & Q I8 o. c - AT PPS LtcL CvrC�� R� CoN TInjVOJ. $ELOw PE I Cu '�� 1{44 HAN - sisTE2 (N) Zx6 To (g.) Z7c6 suB- PulZ�lw • Ci / :cu Ri3 LocATIONS g..-1/ .3.) 16 of C. 16" 0 -c. FULL LE-m - f-4 ( E) STEEL C7IRDE I • • • - 1 i • • { • (N) RTU %517S; ::: 0%51 - S; • . - • 1 • • • • Project: Scholls Bus. Ctr RTU Proj. Engr: 1F Location: Tigard, OR Job It 11010 1 Client: Perlo Construction Date: 1/31/2011 `L DESIGN CRITERIA oa General: Building Department Washington County, OR Building Code' 2006 IBC / 2010 OSSC / 2008 ORSC` Building Importance Category II Roof Loads: Ground Snow Load (Pg) 25 psf Snow Exposure Factor ;Ce) 1.0 • Snow Importance Factor (Is) 1.0 • Thermal Factor (Ct) 1.0 Roof Snow Load : , 25 psf Roof Slope FLAT Roof Deflection Limitation L/240 Special Snow/Live Load Requirements Drifting /Sliding Per ASCE 7, Sect. 7 Wind Load: Basic Wind Speed, 3 -sec Gust 105 mph K 1.0 Basic Wind Speed, Fastest Mile 70 mph Exposure B Wind Importance Factor 1.0 Special Wind Load Requirements None Seismic Load: per 2010 O.S.S.C. "(based on ASCE 7 -05) Site Class D Sds 0.706 Seismic Design Category D Scope of Work: The Following Items Were Designed /Analyzed: * (N) RTU to (E) Roof - Analysis of (E) roof framing system for (N) RTU loads for all gravity load combinations. - Analysis of (E) building for (N) lateral loads of RTU. - Design and detail curb attachment to (E) roof for wind and seismic loading. .. . . , . . . 2863 NW Crossing Drive • office 54t-33o--6869 • .. r Walker Bend, Oregon mot Suite 201 . fax 541-330-2656 . - Project By - 1 Sheet* •■•••1 t LLC Scit_c4,.,t_s ;,.. . : Z Location [ Revised I Job* . t % . — 1. 1.1,21L._ . —..., - Client ' i t Date 13E FR.a■r 1 r.)67 DEc i c_-)N) 1 t-t (g) FI z-A sMt ^ Jel 1 .-V CN I ) RTL) • • Ins rnsl ... . C.-P‘L.L.-jc.)L3T .S.- Pc\r\)/ L.c,Abl•LIC-z7 : b,/ L (PL u. J. 0.) 1 ' 4 \ 1 t‘L 17, EQ . i.). SECI . . . , R. u LID ?» . . . lzs f` • . • I 1! L (c.,51 cop.,,,,GA kos.,41:3 .) • . . . . 0 = 25 Rye S, i 2, fs e Dt. $UB.- puLLI 10 iv (CL • I3 7 d 2..% 6 OF- L. 4 ( L e , i 0 . 2-7q, e 2-4" ) C.) 1 I 1 1 . 1 z vc.,v... t s• t r 8 • ( - . r • KTId kt (L1ol5 . LOA INsicrarfekKIT- 1 % r. "LAI Z Lb., ( Pelt, 2.0 Ica G.S3 C.. 1 pLiaLt...? . P i 1■•■ = c1137 U- P0060 i 7112117:41.1IA. 411■115111FMCW iv = ci x I ( 0 u 0 Z. 57, PA k..0 / Al x _ j — Z ...--i ■ r LI R.Lt r-3 rd \ t ,) z Zt12 ( i '' )4 "1/ (C0141.) • ft1 () Lsetls = azd ) / .„.4e.,,x,8: tit.ite. u,-f' , . • ClitZ.DEqs (N.0 Le. iND i AJ.St (7101 fl C Art .ty ani,Seec. • * Mg- •010 bSSC 3401.3 . . (1_■.6 /(e) LoPo LA s 7, . . • • . . . • . . , • • . • . . — - . . . . . . . ,. . . . . . : . • • . • . . , . • . . L._ ! , i • i . • . • ) COMPANY PROJECT \_ ® Walker Structural Engineering, LLC Scholls Bus. Ctr. RTU 2863 NW Crossing Dr. Tigard, OR '1 =� - r } ® VI/o r ks Suite 201 Perlo Construction SOF?WA/4<FOA WOCOI* ICN Bend, OR 97701 11010 • Jan. 27, 2011 15:26 Sub Purim w RTU Load Design Check Calculation Sheet Sizer 2004a LOADS ( lbs, psf, or plf ) Load Type Distribution Magnitude Location [ft) Pat - Start End Start End tern Loadl Dead Full Area 8.00 (24.0)* No Load2 Snow Full Area 25.00 (24.0)* No Load3 Dead Point 137 1.00 No Load4 Dead Point 116 7.00 No *Tributary Width (in) MAXIMUM REACTIONS (Ibs) and BEARING LENGTHS (In) : 0 6 , Dead 206 190 Live 200 200 Total 406 390 Bearing: LC number 2 2 Length 1.00 1.00 Lumber -soft, D.Fir -L, No.2, 2x6" Spaced at 24" c/c; Self Weight of 1.96 plf automatically Included in loads; Lateral support: top= full, bottom= at supports; Repetitive factor: applied where permitted (refer to online help): Load combinations: ICC - IBC, Analysis vs. Allowable Stress (psi) and Deflection (in) using NDS 2001 : Criterion Analysis Value Design Value Analysis /Design Shear fv = 68 Fv' = 207 fv /Fv' = 0.33 Bending(*) fb = 1063 Fb' = 1547 fb /Fb' = 0.69 Live Defl'n 0.14 = L/693 0.40 = L/240 0.35 Total Defl'n 0.29 = L/330 0.53 = L /180 0.54 ADDITIONAL DATA: FACTORS: F CD CM Ct CL CF Cfu Cr Cfrt Ci Cn LC# Fb'+ 900 1.15 1.00 1.00 1.000 1.300 1.00 1.15 1.00 1.00 - 2 Ev' 180 1.15 1.00 1.00 - - - - 1.00 1.00 1.00 2 Fcp' 625 - 1.00 1.00 - - - - 1.00 1.00 - - E' 1.6 million 1.00 1.00 - - - - 1.00 1.00 - 2 Bending( +): LCf 2 = D +S, M = 670 lbs - ft ' Shear : LC#.2 = D +S, V = 406, V design = 375 lbs Deflection: LC$ 2 = D +S EI= 33e06 lb -in2 Total Deflection = 1.50(Dead Load Deflection) + Live Load Deflection. (D =dead L =live S =snow W =wind I= impact C= construction CLd= concentrated) (All LC's are listed in the Analysis output) DESIGN NOTES: 1. Please verify that the default deflection limits are appropriate for your application. 2. Sawn lumber bending members shall be laterally supported according to the provisions of NDS Clause 4.4.1. • . - - - COMPANY PROJECT Walker Structural Engineering, LLC Scholls Bus. CV. RTU ®® Wo r ks ® 2863 NW Crossing Dr. Suite 201 Tigard, OR Yrt l . Perlo Construction SOFTWAAET6A'WOOD OTS70R. Bend, OR 97701 11010 Jan. 27, 2011 15:26 Sub Purlin w RTU Load 2. - Design Check •Calculation Sheet Sizer 2004a LOADS ( lbs, psf, or plf ) Load Type Distribution Magnitude Location [ft] Pat- Start End Start End tern Loadl Dead Full Area 8.00 (24.0)'' No Load2 Snow Full Area 25.00 (24.0)* No Load3 Dead Point 137 4.00 No *Tributary Width (in) MAXIMUM REACTIONS (Ibs) and BEARING LENGTHS (in) : 0' 8' Dead 140 140 Live 200 200 Total 340 340 Bearing: LC number 2 2 Length 1.00 1.00 Lumber -soft, D.Fir -L, No.2, 2x6" Spaced at 24" c/c; Self Weight of 1.96 plf automatically included in loads; Lateral support: top = full, bottom= at supports; Repetitive factor applied where permitted (refer to online help); Load combinations: ICC -IBC; Analysis vs. Allowable Stress (psi) and Deflection (in) using NDS 2001 : Criterion Analysis Value Design Value Analysis /Design Shear fv = 56 Fv' = 207 fv /Fv' = 0.27 Bending( +) fb = 1297 Fb' = 1547 fb /Fb' = 0.84 Live Defl'n 0.14 = L/693 0.40 = L/240 0.35 Total Defl'n 0.33 = L/293 0.`_3 = L /180 0.61 ADDITIONAL DATA: FACTORS: F CD CM Ct CL CF Cfu Cr Cfrt Ci Cn LCI) Fb'+ 900 1.15 1.00 1.00 1.000 1.300 1.00 1.15 1.00 1.00 - 2 Fv' 180 1.15 1.00 1.00 - - - - 1.00 1.00 1.00 2 Fcp' 625 - 1.00 1.00 - - - - 1.00 1.00 - - E' 1.6 million 1.00 1.00 - - - - 1.00 1.00 - 2 Bending( +): LCIF 2 = D +S, M = 818 lbs -ft Shear : LC$ 2 = D +S, V = 340, V design = 309 lbs - Deflection: LCIi 2 = D +S EI= 33e06 lb -in2 Total Deflection = 1.50(Dead Load Deflection) + Live Load Deflection. (D =dead L =live S =snow W =wind I= impact C =construc = ion CLd= concentrated) (All LC's are listed in the Analysis output) DESIGN NOTES: 1. Please verify that the default deflection limits are appropriate for your application. 2. Sawn lumber bending members shall be laterally supported according to the provisions of NDS Clause 4.4.1. • • 2863 NW Crossing Drive • Suite zo1 office 54 - 33 0 -686 • ' Bend, Oregon 9710! fax 541 -330 -2656 Noliker Project I By i Sheet # bQ LLC S C 4‘4.0 F CTR 2� 1� - - S F I i L et Location Revised Job # I k..) y i Client II 1 Date i - I �Ee�o Co�S1 . L 7/ l p — - L- - - - •. i- - - - -- - - -- - o LA? ERAI, LC>■DI1'1C' GNI RT -) = • • SElgrA V `' � V = F (Plat. i\ScE -0.5 I S.3 -1) — .:1� C^) kT Fp = O. Li 0. s \IJ / (R / xp) ` (I t Z Z / � n h) c = z_ P II (�) Liu,. >r = L. o S = O. C l S = b• 7 a4 - F µ ins 9. 5 r o• 4 SE•SMIL' Cc> € FIC , C v..1 T5 pe rt CC s. A = I•I Z3 2 = I. c) W = 9 $3 !Ss o F - o - 3S3 w • = 17 O lbs. F y 46.. 1 C.1 Cf A, f. . I &t : o. c o ZS G k k 1/ 1 j - 17 - s Psi' • V= IS Mp8 . K o.9 K = o• • K c I. o T. = I. • CI = n•5 . C = 1 -3 Nt ` 7 S x 33 / I .., = I7 L ffL L U .,�� 3 3 e tbs. C aMr/34 E (N) LANTEIZ■L L(> w/ (L-) (E) aiu No' A = 1 vo' >t I ' k I a•2- PsC = 8, 59 US /Lft ieratl LI AJE (NJ) 1(E) I ra b = 1.% P / 1 �l I = I. K. C ct I K t t I, Z-61° os5 C 16 -34 ) I (t )5e15 MI <- Mtk-55 '( IS PsC x WC,' Xtoo ) t (7$ Ps it 7' 'c Z. --')= LSs000 lbs 1 (N) •61:r+1!C M0 _ O 7. '4, -- ( N) Lo■TEP -ptl . Lv , ,tib 1 cia1 FICPrvT ' 'ry (E) ST12..x'i., t2C PER 201 o55L 3ya3. E�•I ^7 «lD% VOK • • 1_________L — - -- - -- - - - - - - - -- — - - - -- ---I Project Name = Scholls RTU 11010 Conterminous 48 States 2003 NEHRP Seismic Design Provisions Zip Code = 97281 Spectral Response Accelerations Ss and S1 Ss and S1 = Mapped Spectral Acceleration Values Data are based on a 0.05000000074505806 deg grid spacing Period Centroid Sa • (sec) (g) 0.2 0.942 (Ss) 1.0 0.339 (S1) Period Maximum Sa (sec) (g) 0.2 0.942 (Ss) 1.0 0.339 (S1) Period Minimum Sa (sec) (g) 0.2 0.942 (Ss) 1.0 0.339 (S1) Conterminous 48 States 2003 NEHRP Seismic Design Provisions Zip Code = 97281 Spectral Response Accelerations SMs and SM1 SMs = FaxSsand SM1 =FvxS1 Site Class D Period Centroid Sa (sec) (g) 0.2 1.058 (SMs, Fa = 1.123) 1.0 0.583 (SM1, Fv = 1.723) • Period Maximum Sa (sec) (g) 0.2 1.058 (SMs, Fa = 1.123) 1.0 0.583 (SM1, Fv = 1.723) Period Minimum Sa . 0.2 1.058 (SMs, Fa = 1.123) 1.0 0.583 (SM1, Fv = 1.723) Conterminous 48 States 2003 NEHRP Seismic Design Provisions Zip Code = 97281 Spectral Response Accelerations SDs and SDI SDs = 2/3 x SMs and SD1 = 2/3 x SM1 Site Class D Period Centroid Sa (sec) (g) 0.2 0.706 (SDs) 1.0 0.389 (SD1) Period Maximum Sa (sec) (g) 0.2 0.706 (SDs) 1.0 0.389 (SD1) Period Minimum Sa (sec) (g) 0.2 0.706 (SDs) 1.0 0.389 (SDI) • .- 714E620/,o— 0-0 .Ca 3T Gas Pack Project: TSE 01/24/2011 • Prepared By: 04:10PM 3T Gas Pack Tag Cover Sheet Unit Report Certified Drawing Performance .Report Spec Sheet Unit Feature Sheet • Packaged Rooftop Builder 1.28 Page.1 of 7 • • • Unit Report For 3T Gas Pack _ Project: TSE 01/24/2011 _ Prepared By: 04:10PM Unit Parameters Dimensions (ft. in.) & Weight (lb.) Unit Model: 48TCEA04A2A6 -1 A0A0 Unit Length: 6' 2:375" Unit Size: 04 (3 Tons) Unit Width • 3' 8" Volts- Phase -Hertz: 460 -3 -60 Unit Height• • 2' 9.375" Heating Type: Gas Base Unit Weight' 483 lb Duct Cfg• Vertical Supply / Vertical Return •'• Weights and Dimensions are approximate. Weight does not include roof Heating Capacity: curbs; unit packaging, field installed accessories or factory Medium Heat installed options. Approximate dimensions are provided primarily for shipping purposes. For exact dimensions and weights, refer to appropriate product data catalog. • Unit Configuration- Medium'Static,Option • • 'Al /Cu - Al /Cu PremierLink Controller • Standard Packaging Warranty Information - 1 -Year parts(std.) 5 -Year compressor parts(std.) • 10 -Year heat exchanger - Aluminized(std.) No optional warranties were selected. NOTE: Please see Warranty Catalog 500 -089 for explanation of policies and ordering methods. • • Ordering Information Part Number Description Quantity 48TCEA04A2A6 -1 A0A0 Rooftop Unit 1 Base Unit Medium Static Option Al /Cu - Al /Cu PremierLink Controller - Standard Packaging • Accessories 0537 - 014A Standard 14" Knocked Down Roof Curb 1 0406 -0100 HVAC Hold Down Brackets 1 0723 -0100 Manual 0 -25% OSA Damper with Hood 1 • Packaged Rooftop Builder 1.28 Page 2 of 7 • • Certified Drawing for 3T Gas Pack • Project: TSE 01/24/2011 • Prepared By: - 04:10PM NOTES AU, BAITED I O 601 4109 Illf • 198 11011.11 tl [9.11111 fn... .1111.OI 11111 0..1101 01 ml0lllf T[CIINOIOG ICS 9.99mLL, .1 J ! 810159 0019 lII IfR[t 081511lq 1X,11 IN f p G[f 401 f01f111011 INI IIUR991f II • 1 DIMENSIONS ARE IN INCHES , S Will 1 K CHRRIEI 0,111 Ca 1 11.1 wl 11 OIUC 1 Gt0 n 91101111m1 0.11111 9min.rl a m.11.n 19 I 1 ARE IA NILLINEIIHS CBI[ -01 JJ 1/8 SI LounmD.f 1111111 14.1111 7 CE91ER or 0140111 18171 1 1711 R ROTC - -OS 31384317 11 I/8 35 1NE F IE LD SIZES 18111 11111 A 1 118' DIA 1351 FIELD PONiR SUPPLY NOL[ 1 DIFECIION Of AIR FLOW 413I[ -06 35 3/R 11 119 1041 11111 B i' 13D1 DIA POOR SUPPLY Cx0[AOUI /81C--07 Al 3/6 11 I/e 13-148 110511 11711 18481 C 1 111• DIA 1511 (LOLL ACCESS PLUG • D 1/6 DIA 1111 FIELD CONTROL MIRING HOLE E I /1• -14 OPT CONDENSATE DRAIN F 1/2• -14 NPT GAS CONNECTION '--1 0 2 1/2 • DIA 1641 P09ER SUPPLY NACU-OUT ECO/ONI/El HOOD . 104,110.11 16 • • • 14061 .111(9 ACCL SS PANEL THOU THE WOOL CHART (DISPOSABLE FILTERS) CON? THE SC BOLES 900 0 FOR USE ACCESS CONDl 95CR — CRRINPNR90IA01, 2801. 1401. 4001 • PANEL COIL .4.--. ••—r, • -• • • • 1 /2' ACC 11116' 177 DI �E � 1 117• 248 11110' 171 2) ACCESS 10470 PANEL I , � - 3/4 1001.0011 POWER. 1 1 /8 128 41 1 114 1002,0011 POACR. I ILA• 144 41 D I ii SZ i 10 10911 112• FT? GAS 1 Ill• 111 81 f 1 \ I I 1117 PLI100 ID011 1 /1' FIP 007 1 518' 111 SI � ` \ ® .�)/ ' - .. SEA EITHER -�y--T-- 1 I } FOR POWER, DEPENDING ON WIRE 517E 1.5 /8 —1 111171 BACK 1611 ✓ E ALI. I r CONDLx5I 71-1 /8 TIP _ , DRAIN OPENING N6 11111 m o p 810TH 1 IN OASCPAY 11.314 26-I/O SUPPLY 1 16 -1/8 ET 1 16131 AIR 14111 SF( INN 111( 18 -1 /e 11.111 17.111 • BASE CHART. 14591 I 13611 11121 I • 6.111 - 1 f 1 0 If 1 •• 1511 25 — I I 3 -1 /6 --. 12.1/8 16361 I 1851 32-111 17071 I IBIB1 TOP „— 19.117 10 -111 11 RO1 12651 4-5/8 11181 CONDENSER ELECTRICAL CONTROL BON INDOOR BLOWER f SID COIL = DISCONNECT ACCESS PANEL ACCESS CONDENSATE I A• LOCATION 1 DRAIN G • — -- — I 16381 I OUTSIDE — •O. 19.1/7 • — I f� I II AIR SEE — 0 III -- !��I 1/911 12891 11771 I l � J 1— %lTJ /I___I 15191 • l 6-I /R — 1 6.519 -. _ _ _ _ �� - —• 1 11681 .j00 I I I I. : 00E 11551 �___ l 8:.— = :� p — 10 -Ile . 6 - 5/8 1 6 4 11611 11681 Ln11 11521 16.3/1 - 8 -11e 111811 12131 — 26.3/4 — .� II -3 /e 16811 BRAOAEle1C 148881 31 -1/4 -- RELIEF LEFT SUPPL I 17931 FLOW it FRONT AIR AIRURN SCALE 1 3 RIGHT 91111 906 Fulalllt 48TC 04-07 SINGLE ZONE ELECTRICAL Ill 48TM500993 1 Of 2 1 - 10 -07 - COOLING WITH GAS HEAT 2. 0 SCALE 18 Packaged Rooftop Builder 1.28 Page 3 of 7 • Certified Drawing for 3T Gas Pack Project: TSE 01/24/2011 Prepared By: 04:10PM UNI ICD r o 004 410111x11 eansn rs n rrasrrr or .ulrs c040 *lra sur rssra ar r nr ea I n a oocwrt n 610 UNIT CORNER CORNER CORNER CORNER TECHNOLOGIES 4,144* n 44 4RUS :iu 4 Frai Real c WiD 01 (n to Tura mu .ol i6 oii r[1ra..es 4 T 3) WEIGHT ICl WEIGHT (Dl C 0 HEIGHT CARRIER srri COIMIlo4 S nlslr. coas[n UNIT HEIGHT WEIGHT (A) WEIGHT ( .cc[rl..r[ar Il u.n LAS KG LOS 06 LOS 60 LAS KG LAS KG K 7 ! ....0.481C--04 183 219 III 50 125 57 131 S1 116 53 39 19911 23 15841 16 318 14161 48IC - -05 531 211 121 56 139 63 145 66 129 59 39 19911 23 15841 17 14121 481C - -06 569 258 131 59 Ili 61 154 70 137 62 39 19911 23 15841 17 ((4 14381 481C - -01 657 296 150 68 169 16 176 80 157 71 39 19911 23 15841 20 1I8 (Sill CORNER A CORNER B 0 • I f II'U�l� ^ ��\ , �) • CORNER D I4' ] CORNER C — • TOP • .1 :: .. �: ° • 000 BACK SCALE S 32 SIM em 4X1[1[60(1 48TC 04 -07 SINGLE ZONE ELECTRICAL III 2 or2 1 -10-01 - COOLING WITH GAS HEAT 48TM500993 2 0 Packaged Rooftop Builder 1.28 - Page 4 of 7 Performance Summary For 3T Gas Pack Project: TSE • 01/24/2011 Prepared By: 04:10PM Part Number:48TCEA04A2A6 -1 A0A0 ARI SEER 13.00 Base Unit Weight 483 lb Base Unit Dimensions Unit Length• 74.4 in Unit Width 44.0 in Unit Height' 33.4 in Unit Voltage-Phase-Hertz 460 -3 -60 Air Discharge* Vertical Fan Drive Type Belt Actual Airflow 1200 CFM Site Altitude: 0 ft Cooling Performance Condenser Entering Air DB: 95.0 F Evaporator Entering Air DB: 80.0 F Evaporator Entering Air WB: 67.0 F Entering Air Enthalpy 31.44 BTU/lb Evaporator Leaving Air DB: 59.7 F Evaporator Leaving Air WB: 57.7 F Evaporator Leaving Air Enthalpy: 24.84 BTU /lb Gross Cooling Capacity 35.65 MBH Gross Sensible Capacity: 26.25 MBH Compressor Power Input 2.48 kW Coil Bypass Factor: 0.186 Heating Performance Heating Airflow: 1200 CFM Entering Air Temp: 70.0 F • Leaving Air Temp: 141.8 F Gas Input Capacity 82.0 / 115.0 MBH • Gas Heating Capacity 93.00 MBH Temperature Rise 71.8 F NOTE: Second Stage Supply Fan External Static Pressure' 0.50 in wg Fan RPM: 826 Fan Power: 0.42 BHP NOTE: Standard Static Fan Option Electrical Data Minimum Voltage 414 Maximum Voltage 506 Compressor RLA• 5.8 Compressor LRA• 38 Outdoor Fan Motor Qty 1 Outdoor Fan FLA (ea): 0.8 Indoor Fan Motor Type: MED Indoor Fan Motor FLA: 2.1 Combustion Fan Motor FLA (ea)• 0.24 Power Supply MCA: 10.2 Power Supply MOCP (Fuse or HACK): 15 Min. Unit Disconnect FLA: 10 Min. Unit Disconnect LRA• 46 _ Electrical Convenience Outlet: None Packaged Rooftop Builder 1.28 Page 5 of 7 • Performance Summary For 3T Gas Pack Project: TSE 01/24/2011 - Prepared By: • 04:10PM • Acoustics - Sound Power Levels, db re 10E -12 Watts Discharge Inlet Outdoor 63 Hz 83.3 85.4 90.6 • 125 Hz 76.0 73.2 80.9 250 Hz 65.6 58.8 80.2 • 500 Hz 62.3 58.6 76.0 1000 Hz 59.0 58.3 74.6 2000 Hz • 53.4 52.3 71.3 4000 Hz 54.4 47.2 68.5 8000 Hz 48.6 38.7 63.9 A- Weighted 66.3 64.4 80.0 • Fan Curve 2.0 _ 1 RPM 1300 RPM �• 1500 RPM 1.8 k , 4, 1.6 Maillommommir,0 BHP 1.4 900 RPM -11111111=111111111E .11111111.11M MEM y 1.0 - 700 RPM _11111101,-.■" 0.8 lalgip 2 00 B 0.6 - SOORPM `�NI` EUIM 0.4 50 BH 0.2 _� I��a 1 00 BH 0.0 - _ -� - - -�.. 0.50 MIIMI 0.0 0.3 0.6 0.9 1.2 - 1.5 1.8 2.1 2.4 Airflow (CFM - thousands) RPM = 826 BHP = 0.42 Maximum RPM = 1175 Maximum HP = 2.40 Note: Please contact application engineering for selections outside the shaded region. SC - System Curve RP - Rated Point Packaged Rooftop Builder 1.28 Page 6 of 7 Unit Feature Sheet for 3T Gas Pack Project: TSE 01/24/2011 • Prepared By: 04:10PM Carrie* 0 e eatherMakerc — 48TC PACKAGED ROOFTOP GAS HEATINGIELECTRIC CODLING UNITS $4, 5,6,7AB.10.12.5.15TONS STANDARD FEATURES Mi LIKIE_ . • PsPusan L tit-41U4 I WC reb n t __. . • ASH RAE 50.1 =Want '" " I • Gaon oaaprenasat]h. terns' Rte avast a!t tr ertoxd maim • Gro cooing comely mrircl en C4-12 rendes • Tso -stage molng capacity cabal co 6}1S models j a` - 'i • SEER! aD in 13 e 0. EE Rs s to 11.1 and t 4 W m R 114 .i • Aadmt"' rddg�l metering a)slem 1"""' . -. - __ • E]Ldnshe notainn lace h condo• Rml m accordance v.191 - . • : • ASHR/hE c 62 sloping died= side a oaten drab j * Sten:lard owing cderatto up m t15'F (46 *C) aril dawn to 4 TF (4•C) d snob to S F ( 4 t l r a w i r r a r e r It • • Pie-parited eilerlar oa'eh and ort". ercah d nano Tested to !t I min rt spray platsen 6 • Fdy Misdated satinet . om • Exclusive hOC sold -std conb�ot far on-board Magmata lath LEO • ` tear des>Jna alas lwmer =drat ogle and energy =dig 7tdoor �. • Lam Mx models that meet ColfanrIs AU Melly Mmnpm•rent Optional Tau.arcedH il GuardShawn • Induced daft gas heatcdntaathn deirgn • Ret hrdal gas salves 'AM rpm tun stages of heaths, • loo pressure and rdpn mean runes prated ASNSAE MAINTENANCE FEATURES: • Access panels ugh easy grip bads i1 • Innovate easy 1w. rostrto sor os on tart access onsets 11 • • • Ywv -hrh dtsposhle rehnm al Item aril Teraina toter access doer Co mPU N T., * Bel dam evecaratiHan actor and oulermrtdthlathra • hear ?errand board fad:LaM stripe safely o1aX[ trelete4rcctro and *raged WEATHERMAKER SERIES • E7a MC �� d t an deanostts Mb LEO M1�tlL2lIL�tPl 48TC IIIJib are one-piece electric cmz lade de r aOan. tomerasndnd logic and energy aar4ng Indoor { ) one iece tar minor decay. c dung was Cent are pre -1Mred and Waged wttt Ram (W 410) reStgerat lltey are racaly tested In bath healing and INSTALLATION FEATURES: cola ,gr mottles. and rated In accordance part AHRI Standards * atmix - ban was entry ram SW 2181230 (04-06 tom) and 340t3E0 07 -14 & s). * Era manger ant drat oanergo Weablecklaber twits are designed Sr accentartoe win UL • FLII perFF_elsDae ran with t oft to Marna ampler' and amt arts Standard 1995, and aced by 1Re LAfden3Laes' LabmaOnes. • Am c mmittta lawn vetted to hateartal afdlom far stab rtxtadng. 16 see respites Ott l a el ed imply duct Cora. STANDARD WARRANTY: Approved and Care • 1ainar hued eadlmtss - t5-sear stantow :feet Maas COM • -yew • �3Im parts on Rosette where tte Condenser cods - whe aralable iii. Llfiiii�•.r• * Marry also widget _uti'i.JCJ. C ( US r.a)a5:.•.e ONIONS INCLUDE BUT ARE NOT UNITED TOE pm. °""°'•t" • PremertJri• and RTU Gpafstnn tsromml00C CmdneGupmry and •w.ars■r.....: P.,9.7 Regan AkSmote Detertora, high stalk motes 9. 9.71-97. • Wintered emrdensercon ids • Enanmtzer, demnnectred mmnntence odt et %bo a • Starless Steel teal ess t arcer apthn • C orrmhn rest:Mad cad . • Efrw Ne adarthedetaard acobsn mien mailable Certified to ISO 9001 x101.141f0dm -Motu ester Immwmrsemed Foc a compete ter of wdora anal acess/Me i rear b the Product Gab Gang farms Lint Packaged Rooftop Builder 1.28 Page 7 of 7 SUBMI � ®� Knocked -down Roofcurbs for - Part Number: TTAL Carrier 48/50 TF, TFQ, HJQ, TJ, HJ, TJQ, TM 0537 Series FORM NO. 1174-19P DATE: 1/02 004 - 007 units • SUBMITTED TO - COMPANY• `,i .'0537Series. Specifications (iriinches) DRAWN BY A.L.L. MicroMetl Part No. Carrier Part No. I A JOB NAME 0537 -O08A N/A - 8 EQUIPMENT: 0537-011A N/A II NOTES- 0537 - 0I4A CRRFCURBOOIA00 14 0537 -024A I CRRFCURB002A00 I 24 FEATURES 'Roofcurb sides and ends are 16ga. Opening for thru the ' galvanized steel. (.058 min.) bottom electrical connections •Gasketing package provided. (4) insulated 'Full perimeter wood nailer. deck pans 1 3/4" Alt. drain hole ...001.1111111111 • ' Blocked top • NOTES: corners 1.) Adjustable pitched /adjustable height /` curbs and taller curbs are available, 13 7/8" 0 -1/4::...... \ Ai � ' .2„ tp 2.) Attach ductwork to roofcurb. Flanges /`� 5/' i� o of duct rest on top of curb. f-- Supply air 32 1116" • ,3.) Roofcurbs are marked with the Carrier A Return air • part number. � ".... � // 67 3/8" 4.) The standard MicroMetl curbs do not I I I �., ,/ have service plate holes. If they are s Corner Detail required, you must specify on the order. 37 3/16" 0 NOTE: If using through- the -side of the curb gas or electrical connections, you must' specify servrce 1 \ =- = holes are required. Optional service plates: 0815 -0537. I® A 4_ CROSS SECTION l OFCURB l • I 2" k THIS DOCUMENT IS THE PROPERTY OF MICROMETL CORPORATION AND IS DELIVERED UPON THE EXPRESS CONDITION THAT THE CONTENTS WILL NOT BE DISCLOSED OR USED WITHOUT MICROMETL'S WRITTEN CONSENT MICROMETL CORP. • 3035 NORTH SHADELAND AVENUE, SUITE 300 • INDIANAPOLIS, IN 46226 • 1 -800-662 -4822 ••• MICROMETL SPARKS • 202 SOUTH 18TH ST. • SPARKS, NV 89431 • 1-800-884-4662 Part Number: • zt �IUIICro MICRO -HOLD for .� °` ' "'",1 48t50 HJ HE TJ QJ HJQ GJ 3 -12.5 TON UNITS 0406 -0100 FORM N0. 4250-1P DATE: 110l.1D ' ' ' ' ' SUBMITTED TO COMPANY: DRAWN BY: M. MILLIKEN JOB NAME: EQUIPMENT: NOTES: • FEATURES: 1) Manufactured from 16 gauge galvanized steel. 2) MICRO -HOLD Package includes: • (4) Hold -Downs • (32) 10" x 1/2" TEK screws P PP. (S screws per Hold -Down) 3) Some units may require additional Hold- Downs. m �QRtr LP • x.1 687 ,1 `i•-. plies 6 - 30 - 01 - t OF CAt14 i THIS DOCUMENT IS THE PROPERTY OF MICRO METL CORPORATION AND IS DELIVERED UPON THE EXPRESS CONDITION THAT THE CONTENTS W ILL NOT BE DISCLOSED OR USED WITHOUT MICRO NEIL'S WRITTEN CONSENT. MICROMETL CORPORATION • 3419 ROOSEVELT AVENUE • INDIANAPOLIS, IN. 46218 •1800. 882-4822 -• MICROMETL WEST • 202 SOUTH 18TH ST. • SPARKS, NV 89431.1.800.880 -4882 • S UBMITTAL M icroMetl Manual and 2 Position Hoods for Part Number: 48/50 TF, TFQ, TM, HJ, 004 -014, 48 HJQ 004 -014, 0723,0724 Series FORM NO.1877 -9P DATE:1 / 07 50 HJQ 004 -012 and 48/50HE 003 -006 SUBMITTED TO FEATURES: COMPANY• DRAWN BY: M. Hargis • Color coordinated, baked -on paint finish. JOB NAME • Insulated cover panel EQUIPMENT: • Attachment hardware package provided. NOTES: DOWN DISCHARGE APPLICATION Outside Air Intake Hoods Specifications (in inches) Carrier Units MicroMeti Description A B Part No. 0723 -0100 Manual O.A. Hood O Cover panel is not used in 003 -007 11 15/16 26 13/16 0724 -0101 2 Position O.A. Hood horizontal application. 48/50 TM, TF - 0723 -0200 Manual O.A. Hood .- 008 -009 48/50 HJ, 13 5/8 34 3/4 HJQ 008 0724 -0201 2 Position O.A. Hood A 48/50 HJ, HJQ 0723 -0300 Manual O.A. Hood hie,/ ° 009 48/50 TM, TF, 13 5/8 37 1/2 O HJ 012 -014 0724 -0301 2 Position O.A. Hood O ° O ° HORIZONTALAPPLICATION ur 0. \ \ \ In the horizontal application, the hood and screen \ B ° '' ' section must be secured over a field cut opening A in the side of the field supplied return air duct. \ ° \ • Manually adjusted or 2 position motorized hood. O O r' ° ° \ \ \ — i ic�i N i O - /, J \ :U \ Return duct (field supplied) I \ Screen section to be For position tton hood: Note: Hood is snipped -out when used in shipped unattached to NOTE: Unit transformers must have an additional horizontal application. cover panel. 10V.A. If not, then an optional transformer must be used. THIS DOCUMENT IS THE PROPERTY OF MICROMETL CORPORATION AND IS DELIVERED UPON THE EXPRESS CONDITION THAT THE CONTENTS WILL NOT BE DISCLOSED OR USED WITHOUT MICROMETL'S WRITTEN CONSENT MMC INDIANAPOLIS - 3035 NORTH SHADELAND AVENUE. SUITE 300 INDIANAPOLIS. IN 46226 1 -800. 662.4822 / MMC WEST 202 SOUTH 18TH ST SPARKS, NV 89431 1-800-884-4662 r I 3 Ton Split System Project: TSE 01/24/2011 • Prepared By: 04:11 PM 3 Ton Split System Tag Cover Sheet Unit Report. Performance Report Acoustic'Summary Certified Drawing'. . Unit Feature Sheet • • Residential Carrier Products Bldr 1.16 Page 1 of 10 Unit Report For 3 Ton Split System Project: TSE 01/24/2011 Prepared By: 04:11 PM - I N , . 1 I Outdoor Unit Parameters Indoor Unit Parameters Unit Quantity' 1 Unit Quantity' 1 Unit Model: 24ABB Unit Model: FB4C Unit Size 3 Tons Unit Size: 36,000 Btuh Voltage: 208/230 -1 -60 V -Ph -Hz Cabinet Insulation:Single -piece cabinet with 1 -in. super thick insulation Voltage: 208/230 -1 -60 V -Ph -Hz System Parameter System Quantity: 1 Heating Size: 10kw Nominal Outdoor Unit Dimensions and Weight Indoor Unit Dimensions and Weight Unit Length 2' 3.0" Unit Length: 1' 10.1" Unit Width 2' 6.0" Unit Width' 1' 9.0" Unit Height 3' Unit Height 4' 1.0" Unit Shipping Weight' 170 lb Unit Shipping Weight: 122 lb Note:Outdoor unit dimensions may vary depending on the minor series sent from the factory. Warranty Information Indoor FB4C First Year - Parts Only (Standard) Warranty Information Outdoor 24ABB First Year - Parts Only (Standard) Ordering Information Part Number Description Quantity Base Unit - Outdoor 24ABB336A003 24ABB Base Air Conditioner with Puron Refrigerant 3 Tons Cooling 1 Base Unit 13 SEER @ ARI Conditions 1 Dense Grille 1 Accessories KSALA0301410 Low- Ambient Pressure Switch 1 KAACH1401AAA Crankcase Heater 1 KAALPO401 PUR Low Pressure Switch 1 KAAHI0501 PUR High Pressure Switch 1 - KSAHS1701 AAA Start Assist - Capacitor and Relay 1 KAAWS0101AAA Winter Start Control 1 KAAFT0101 AAA Evaporator Freeze Thermostat 1 Base Unit - Indoor FB4CNF036000 FB4C Base Series Fan Coil with Puron 36000 BTU Cooling 1 Residential Carrier Products Bldr 1.16 Page 2 of 10 • Unit Report For 3 Ton Split System - Project: TSE 01/24/2011 • Prepared By: 04:11 PM Base Unit Single -piece cabinet with 1 -in. super thick insulation 1 Standard 1 Accessories KSATX0301 PUR Thermostatic Expansion Valve (Hard Shutoff) 1 KFCEH2601 C10 10 kW Electric Heater with Circuit Breaker 1 • • • • , Residential Carrier Products Bldr 1.16 • Page 3 of 10 • • • Performance' Summary For 3 Ton .Split System Project: TSE 01/24/2011 Prepared By: 04:11 PM System: 24ABB /FB4C System Quantity: 1 . Altitude: ' 0.0 ft • Linear Pipe Length: 0.0 ft • Actual SEER • 13.0 - EER @ ARI Conditions: 11.0 Outdoor Unit Parameters Indoor Unit Parameters Unit Quantity 1 Unit Quantity 1 Unit Model: 24ABB336A003 Unit Model: FB4CNF036000 Unit Size (Nominal)• 3 Tons Unit Size (Nominal)• 36,000 Btuh Voltage: 208/230 -1 -60 V -Ph -Hz Voltage: ' 208/230 -1 -60 V -Ph -Hz Clg Ent Air Ambient: 95.0 °F Actual Airflow 1176.0 CFM Standard Airflow: 1176.0 CFM • Total Net Clg Capacity 32.37 MBH Net Sensible Clg Capacity 24.63 MBH Ent Air DB• 80.00 °F Ent Air WB• 67.00 °F Ent Enthalpy: 31.44 BTU /lb Lvg Air DB: 60.61 °F Lvg Air WB: 58.45 °F Lvg Enthalpy 25.32 BTU /lb Heating Size (Nominal) No Heat Indoor Unit External Static 0.50 in wg Total System Power: 2.97 kW • Outdoor Electrical Data Indoor Electrical Data: Unit Voltage 208/230 -1 -60 V -Ph -Hz Unit Voltage' • 208/230 -1 -60 V -Ph -Hz Fan Motor FLA:. 1.40 Amps (Single point power for unit WITH electric heaters) MCA: 20.5 Amps EH Part Number: KFCEH2601 C10 Max Fuse 30 Amps Electric Heater kW 10.0 kW Operating Range Min: 197 V EH MCA: 53.8/58.5 Amps Operating Range Max: 253 V EH MOCP• 60/60 Amps Compressor RLA• 14.1 Amps Heater Amps: 36.2/40.0 Amps • Compressor LRA: 77.0 Amps Motor HP: 1/3 HP Min Wire Size @ 60C: 12 Min Wire Size @ 75C: 12 Max Length Wire Size @ 60C: 61 ft Max Length Wire Size @ 75C: 58 ft Acoustics Sound Power Levels, db re 10E -12 Watts • • Outdoor Unit (dB) Indoor Unit (dB) DBA Level 75.0 NA 63Hz - NA 67.8 • 125Hz 59.5 63.8 250Hz 63.0 59.8 500Hz . 68.8 .56.8 1000Hz 70.0 54.8 2000Hz 65.5 52.8 4000Hz 61.5 .48.8 8000Hz 53.5 NA Sound Message - Residential Carrier Products Bldr 1.16 Page 4 of 10 Acoustic Summary For 3 Ton Split System Project: TSE 01/24/2011 Prepared By: 04:11 PM • Outdoor Unit Parameters: Tag Name' - 3 Ton Split System Unit Model: 24ABB Unit Size: 3 Tons Variations: Dense Grille Octave Band Center Frequency, Hz 63 125 250 500 1k 2k 4k 8k dBA Sound Power,dB 0.0 59.5 63.0 68.8 70.0 65.5 61.5 53.5 A- Weighted Sound Power, dBA 75.0 Indoor Unit Parameters: Tag Name: 3 Ton Split System Unit Model: FB4C Unit Size: 36,000 Btuh Cabinet Insulation: Single -piece cabinet with 1 -in. super thick insulation Octave Band Center Frequency, Hz 63 125 250. 500 1k 2k -4k 8k dBA Sound Power,dB 67.8 63.8 59.8 •56:8 54.8 52.8 48.8 0.0 A- Weighted Sound Power, dBA 0.0 • Residential Carrier Products Bldr 1.16 Page - 5 of 10 • • Certified Drawing for 3 Ton Split System Project: TSE 01/24/2011 Prepared By: 04:11 PM - y .- - ?9AHH3 , 1 • • DIMENSIONS -- ENGLISH (SIZES18 - -36' & 48 --60) • ELECTRICAL MT SEJ ES CNARACTEWSTICS I A B C 0 E I F G I K L N N P WN GFIT I I OQENSIONS IL N � W )C1/211 34499316 1 1 0 0 I 0 2 1 Ill' Its 5 /11' 3 550 1/4' 4 3 /11• 11 1/36' 7 13116'1 S 13116• 112 II 1/2• IV IV 101 3* 0t III 1 t7 3 /e 3 55 3419181 I I 1 0 I 0 I 0 23 I/O' 25 S/.6 3 SIV 1 /I • 1 1 /11' 11 1 /10' 17 131169 2 13/11• 1 IV 11 113• IS• 15' 110 114 24 1/4• 127 3/e• 3 33 In' 241//330 1 1 0 1 0 0 23 1 / 3 ' 26 I1/11' 1 3/V !IV 1 3/16• 16 In6 17 131111 t 1 3 / 1 6 ' I / 2 ' I I 1 / 7 ' I S • 1 4 ' III 131 141/4' 1 27 3 /5 1 371/2' 4 244653361 I 1 0 I 0 I 0 t0 0,1 132 5/16 17 113• 7,0 4 1131' 21 311• 16 III• I t IS /11• 3/5• 14 1/4' 10 In' IV 141 I70 21 I /5 6 33 1139' 133 13111' 24/93343 I 0 I 0. 0 31 1116• 35 Jn' 13 3/6' Ill' 1 3 /I6• 14 11 /11• 1 Ile• 13 IS /10• 516' 11 1 /e• 151/6' 15 1 /1• 166 I 221 32 l /6' 2 15 I/O' 1 31 115' 1//53310 I 1 1 0 0 0 31 llll• 135 tll• 13 lll' 710' 1 1111• 11 11/16' I III I 1 11115• 5l5• II 1 /6' 15 3/0' II 5 /0 1 130 1 576 32 3/■• 1 15 111 1 32 I/11• 55 .004 ppp , ��Iippp C} 40555. 8 n A o- P I AM W tem. tem. 00* s 1r u ry mar, .3 1/ A Iz1 2 1191rOv rir rE9L1 00 +163EI1 10 C001.100 i 140E [s srr, 1 It r l 1!1 3[3 11 11511101 33 1r( 213x 61313351 OF THE 0x *0351. 110631 1 316129 Or 4143310 S 1 ILL 01156310141 465 36 •lx0x[l• 40,133 401[0 1 0 N 41114 d Ill 3:01x4105 I ISC111162 / G \ / 1 1 B 31211.! 5!5 46 C041201 � /?/' i ' . . ...,. , • e �x l l 1.:6 3115 TTT ` � � 1 I F 11213 POWE1 3101±7 c 1 1 r 1 , \11 /� o III• xalE rI1X hIL I�- I� �� \ �� N ale. 41401641x[CON P � \ \L � /� 1� C 3 413. ...1 n�.1r _. 3 0 , `�. ) � " � E i [ 1 150'1001 LINE Ca. I L 5111 K r— 1IN IN NNNW UNT S� 610 JITIG PAD 7113 3233081 +6/(.1002 DNGH5IONS 111 01.4153 13.54.50 i 53 Ill' 1 231/V1 I 51 16 1 26• 4160 31 1/2 131 113• • I 35' 3 35• I ■ Residential Carrier Products Bldr 1.16 Page 6 of 10 • Certified Drawing for 3 Ton Split System Project: TSE 01/24/2011 Prepared By: 04:11 PM DIMENSIONS (cont.) V NOIES 1 CDNOENSAIE PAY DRAIN CAPS x07 SHOWN FOR CLARITY ; I L - ,r, [I . AU GINFh0!OAC ARE ID ':ACS' =: OUST NOTED 11161108 2 JI16• TIP — —I 1116' TIP I 11 PLAC751• 4:61106 12 PLACES). 1 Ill• r. • -• � G PIINAR, JR41 ' I 11. i1P 12 PLACESI• 111A' —j r- SECONDARY OAAI SECOIDPAI OAAI I I PRINAR1 ORAT II 1 1 I 2 ue , ,y ill__i_ 1• lYP 1/11• TIP ' �4 - _ 12 P1ACES1• IA PLACES). I:_) DOWNFLOW 2 3116• 3 118• 2 Rn6 I � fi[ (FIELD 11'E ) ED) 12 PL AC E51• >,• UPFLOW F,.,P: P91NAR1 DRAT (d) SI77 -t�D) - -" SECONDARY DRAT 5116' RY • , PRIMA 06 OAAI —{ 1 13116 (— SECONDARY OR AI TIP ill Ii7p I 1 51!' I ®' 1 ipplt `� � 1 114' . l! i�� . I i r � I I "1 _l' - • 111' I ';',,_I_ 1 �.' I liP • 2 116' 1 Il4• TIP • ^•I 7 /3' L 1 17/16' -y 1 - TYP • TIP • 1 516' YIP C HORIZ RIGHT —' `7/8' 3 7/6• liP • HORIZ LEFT 5' (FIELD TNVER - ED) ( ShPFEDI • HORIZONTAL 1407x1 LOCATIONS • 0181115 PROVIDED 14 TOP PANEL, A-COII 441 n1C: OF 71 1ENET. I'. CA'11IE7 .7Or2l; !W✓; PROVIDED 136' DIA HORIZONTAL HANOINO HARDWARE 10 6E FIELD SUPPLIED PRINAHI TT. I IJll6' SEOIDARY DT,P• AIRFLOW r 2 Jl lfi fYP I — 7116' ITP I I 12 PLAEE51• I 1 e O AIRFLOW 14 PLACES) 1 112 f ■- i,P• 1 112' J 1 - 5 7 /6• _ 511.• — — .- � We I 1116'•1 TIP I — LI• i/P • O 0 We 7 11 e• 12 PLACES) F 4 314• J4-22 G HORIZ. LEFT Li 3 1/16• l ' SECOVARI 01814 SCCO40.41 0:4:. (A) SIIPP:D) PIINABI:IA1 4 1 „k4 MAR/ DRAIN i 2 '7W: 1712 I r I1P SI11' • E.iIDA•I :. '.A /3 0 Q I• I1P CD P �� I O Or n- r 12 PL ACES,, • O O ; r L+ � , , 1 • O I. ve 11r L 7116' TIP, RT E-1— I I MI 3 Iltl II PLACES)• Z IIll6' S 711• 2 3T1P• - A 314• DOWNFLOW -I I , 7/6• 1 3116• I YP2 . ] (FIELD CONVERTED) 1 1, 16 I- i PLACES) • TIP HORIZ RIGHT T1----1 TP °; U PFLOW (FIELD CONVERTED) (AS SHIPPED) A10006 Fig. 2 -- FB4CNF -- English . 5 Residential Carrier Products Bldr 1.16 Page 7 of 10 Certified Drawing for 3 Ton-Split System Project: TSE 01/24/2011 Prepared By: 04:11 PM DIMENSIONS 4 • UNT A B C 0 C F 6 H ] Ncna•iAn4, SHIPPING (IBS/ WT SHIPPING Wt ILB51 SLOPE A. 4011 T1N•C3A1E0 11N•C0417) F4AC0076 42 lllll' IA 5/11• 12 7/14' 12 $111' 10 7/I1' 16 Il8• 16 5/8' - 12• 1 - 112 112 FOACYFO1A Al II/11• IA 5/11• I2 7/16' 12 5116' 10 7/16• 16 ll8• 18 5l7' • 11' 1 - 117 112 . FRACN10J0 A/ 5l0• IT 5l8 15 3 /4' 15 5/8' 15 3l8• 23 118• 21 5 /8' - 17' 1 122 122 " FAACAF516 44 5/8• 17 378' 15 374' 1$ 5/8• 15 3l8• 73 1 /8' 21 311• • 17• 1 • 122 122 FBACNF3A2 49 5/6' 21 1/8' 19 Ill' 19 118' IS 11116' 21 7116' 23 178• • • - - 1 157 157 F6AC.YFA4S Al 5/8' 21 1/8' 19 Ill 19 1l8• IS 11/16• 21 1116• 21 118• - • • 5 157 157 FBA01F060 53 1111• 21 116• 19 IIA' 19 118• 19 Ill' 21 1IA• 26 13041' - • • 1 175 175 'Ott Salt Al1 2• Fib 114,1 I. SCIIE! 67SIBNAIIO 71 lIt IAN 9041114, PS lO 15047 • O: 4,11 •100KI .6X46 6 All 014,5314,1 in II •171141• Uu136 WO ' ' WIT COOEC'1A'.1: SI2ES SUCTION 018 A 02A - 5l5 1 2 SWEAT 22 Ill6' . 030 8 036 • 3/4 1 0 SWEAI 012 THOU 060 • 118 1 0 SWEAT 10 Jlli' H 1/6• 1I0U7D 3 /8' I D.'SWEAT I X' ^, C)NOO45ATE 1 -/.' FPT 1 � 2 ll6' I I ' OUTLET AIR F' ]IR •, , ,,. _ ALTERNATE � ) , 1/8'.1 1 /52',2•DIA A 0 'S NOTE NODULAR 1 FOR NIGH VOLTAGE UNITS WILL NAVE ALTERNATE PCIER WIRING A TWO-PIECE - 716'8IA 6 0 OPPOSITE SIDE CABINET FOR 104 VOLTAGE 776• 1 IT'S • CONTROL WIRING 2' DIA A 0 'S OPTIONAL FIELD CONVERIE) FOR HIGH 0011AGE RIGHT SIDE RETURN OPENING (SLOPE COIL UNITS ONL11 /IULi?I8G A 1/8•316. K 0 1 1/2• 1 118' FOR 704 VOLTAGE 'CONTROL *18140 Ill 1 15116' 1' 1 3 /e' TOP VIEW liti711 1 3/16' J H 4AX FOR I B NODULAR UNITS 15 /16' .i C — I ■ I ISCOTNECT OR 1 116• �I CIRCUIT BREAKER { LOCATION ® :LOWER, CONTROL. — t F -'t L 1 ELECTRIC HEATER ACCESS PANEL I 1 /4• IOPINING 9 11116' 2 II:' RIGHT SIDE VIEW INLET AIR . OIL ACCESS • _AO PANEL -r- INLET .16 2 5/6" . .....--... I 111 • A 11/16' •IT11 MID LINE CONNECTION PANEL SUCTION LIRE 2011142 FIO.Y 10310 LINE lOUID LINE CONNECTION J I /IB' CONNECTION 0 ,:.. • 10 Inc �'- • SUCTIOr LINE o• 1 CONNECTION �� 6 1 /16' 9 112' Y Y O • ti 0 1/1• a • FMS• I FIL l[8 ACCESS 6 I . OT PANEL I. ^'71 D SLOPE COIL DETAILS el'CtS5 •1Y CTNIG SC/A • INLET AIR CONNECTION LOCATIONS SNOWY SLOPE COILS FOR UPFLOI OR 00111 00681106 09 HCR12 FRONT VIEW LEFT APPLICATIONS RIGHT A ?PL SHOWY WITH 'A' COIL DETAILS CONNECTION 'A" COILS LOCATIONS FOR UPFLOV OR $0711 APPLICATIONS 001.4110V AP ?LICAT104i A10005 Fig. 1 •• FB4CNF •• English 4 Residential Carrier Products Bldr 1.16 Page 8 of 10 24ABB3 Base' 13 Air Conditioner Carder with Purone Refrigerant Turn to the Experts Product Data INDUSTRY LEADING FEATURES / BENEFITS ' : Efficiency • 13.0 - 13.2 SEERi10.8- 11.0 EER (based on tested combinations) - • bef icrotabe Tecinoloey ` reateerar'on system • Indoor air quality accessories acatiab!e Sound • Sonnd level as low as 75 dBA • Sound level as low as 74 dBA with accessary sound blanket Comfort • System supports Edge' Thernidistat" or standard thernastvt consols Reliability I ..- • ?lion" •-a refrige : - environmentally sound, won't deplete the ozone layer and low li service cm:. • Scroll compressor Puron • Internal pressure relief valve ,.,. �,•.� �,�,. • ln:emal thermal overload • Filter drier Carrier's Air Condironers with Purone refrigerant provide a collection of features unmatched by any other family of • Balanced reingerrion system for maximum reliability equipment. The 24ABB has been designed untiring Cadet's Durability Puron refrigerant. The environmentally sound refrigerant allows weather Armor" rotection package: you to make a responsible decision in the protection of the earth's P- ozone Layer. • Solid, durable sheet metal conssucnon As an Energy Stars Partner, Carver Corporanon has determined • Dense wire coil guard available that this product near the Energy Stare guidelines for energy (3 -phase amts come standard with dense wire coil efficiency. Re to the combination ratings in the Product Data guard) for system combinations that mee: Energy Stare guidelines. Baked -on complete outer coverage, powder paint • NOTE: Ratings contained in this document are subject to Applications change at any time. Always refer to the AHR1 directory • Long -line - up to 250 feet (76.20 m) total equivalent twww.ahridirectory.org) for the most up -to -date ratings length, up to 200 feet (6036 m) condenser above inforntaritm. evaporator, or up to 80 ft. (24.38 m) evaporator above condenser iSee Longline Guide for more information:[ • Law ambient (down to -- 20`F/- 289 with accessory lit Residential Carrier Products Bldr 1.16 Page 9 of 10 FB4C Base Series Fan Coil Carrier Sizes 018 thru 060 turn to the expert Product Data AIR IL-1NDLER TECHNOLOGY AT ITS FLNEST The FB4C fan coil combines the proven technology of Carrier fan coil units with Puront. the environmentally sound refrigerant. and are loaded with popular features. The design features contoured condensate pans with rugged drain connections. ensuring that little water is left in the unit at the end of the cooling duty cycle. The lack of standing condensate and corrosion free pans improves IAQ and product life. features homeowners appreciate. Standard features include grooved copper tubing and louvered aluminum fms. Coil circuiting has also been updated to make the most of all Carrier heat pumps and air conditioners. Units come with solid state fan controls. 1 -inch (25mm) thick insulation with R- value of 4.2. multi -speed motors. and fully - wettable coils. Units can accommodate factory- andlor field - installed heaters from 3 to 30 kW. It also should be noted that the unique cabinet design of these fan coils meet new stringent regulations for cabinet air leakage - a requirement of 2 SC cabinet leakage rate when tested at 1.0 inches of static pressure. o The FB4C fan coil design is loaded with popular features. These fan coils utilize the latest in electronic commutation motor (ECM) technology through the use of high efficiency. X -13. blower • motors, allowing reliable air delivery with increased static pressure. It comes in a pre - painted (taupe metallic) galvanized steel casing and a factory - supplied power plug for ease of installation. ArntorCoat' provides a tin plating of the indoor coil's copper hairpins. This creates a barrier between the corrosion- causing MO[92 elements and the coil. AU FB4C units are equipped with a piston meter device. Residential Carrier Products Bldr 1.16 Page 10 of 10 I Print Form Split System Submittal Data SAIPJP/O System: 24KLS72 Indoor /Outdoor: KS2472/CL2472 Wall Mounted Low Ambient Air Conditioner Building Life. Job Name: TSE Approval: Location: Date: 1/24/201 1 Engineer: Construction: Submitted to: HVAC, Inc Unit #: Submitted by: Airefco - Larry Goodroe Drawing #: Reference: General Data )at 230/208V) - Power V /PH /Hz 230/208/1/60 _— _ ___ _ —. _ ' , Circuit Ampacity (A) 20 — - 1� j. Fuse Size, Max (A) 20 Refrigerant R410A Compressor DC Rotary Inverter Lbs - R410a (outdoor unit) 4 30 No. used 1 Control Electric Expansion Valve A.L. Amps - L.R. (A) 9 6/10 9 - 17.5 Connection Flare Crankcase Heater (W) 20 Line Length, Max 131 Lift Difference, Max 50 Outdoor Unit Line Size (in 0 D Discharge) 1/4" Fan type Propeller Line Size (in. 0.0 Suction) 5/8" Dia. (in.) - No Speeds 18 - 1/8 - 1 Type Drive - No. Speeds DC Motor Dimensions (in ) H x W x D No Poles (RPM) 8 - 850 Indoor Unit (Uncrated) 11 -23/32 x 41 -15/16 x 8 -19/32 No. Motors (W) 90 - 1 (Crated) 11 -3/8 x 44 -7/8 x 14 -29/32 CFM (High) 600 Outdoor Unit ( Uncrated) 29 -1/8 x 35 -7/16 x 12 -19/32 F.L. Amps (A) 0.7 (Crated) 33 -27/32 x 40 -5/8 x 16 -1/4 Coil Type Aluminum Fin & Copper Pipe Weight Indoor Outdoor Fin Type - Pipe Type Corrugated Plate - Inner Riffled Net (Ibs) 26 5 119 Rows - FPI. 2 - 18 1 Shipping (lbs) 33 1 127 9 Face Area ( sq.ft) 6 4 Tube Size (in ) 3/8" Indoor Outdoor Shipping Volume (cu.ft.) 4.23 12 71 Indoor Unit Fan type Cross Flow Performance Data @ ARI Standard Conditions (230V) Dia. & Length (in ) - No. Speeds 3 -11/16 33 -9/32 - 1 Cooling No. Speeds 3 & Auto Total Capacity (BTU /H) 24,200 (4,100- 24,200) No. Poles (RPM, High) 8 - 1250 Sensible Capacity (BTU /H) 14,800 No. Motors (W) 30 -1 Latent Capacity (BTU /H) 9,400 CFM (HI /Med /Lo) 600/541/482 SEER 17 Indoor Sound Rating (Hi) (dB -A) 47 Dehumidification (Pints /H) 4 89 F.L. Amps (A) 0.5 Amps (A) 10.8/12.1(1.3 -12.1) Power Inputs (W) 2,355/2,355 1280-2,355) Coil Type Aluminum Plate Fin & Copper Tube Outdoor Sound Rating (dB -A) 55 Fin Type - Pipe Type Slit Plate - Inner Riffled Rows - FP.I. 2 -19.5 Face Area (sq ft ) 3 07 Tube Size (in.) 9/32" Drain Connection Size (in.) 23/32" Dimensions Feature Option Controls Microprocessor Refrigerant Line Set Available Remote Controller LCD Wireless Type, Temp. Sensor Built In Fresh Air Intake N/A . Temperature Control IC Thermostat Airduct Extension N/A Timer 24 Hr Program, 1 Hr Off Indoor Frame Extension N/A Night Setback Built -In Condensate Drain Pump Available Air Louver (Horizontal) Manual Non - Removeable Remo -con Bracket Available (Vertical) Automatic Power Failure Automatic Restart Built -In Operating Range Heating /Cooling Automatic Changeover N/A Indoor Air Intake Temp Outdoor Air Intake Temp. Self- Diagnosis Built -In Cooling Maximum 95F DB/71F WB 115F DB Quiet Operation Built -In Minimum 67F DB /57F WB OF DB Air Filter Washable, Anti -Mold Ion Generator Equipped Air Clean Apatite Filer Standard zr..E �h 91rs1-1 z0 -1s1e s -n.32 gl il ii 117/32 1 ^� v - I I / '.2 I ..: • ; .4 1 _b_ _ _ _ _ _?._ _ _ __ _.../ _ _ _. . 7 d S h - t, R rvc., 2 i ' 1 — - - — ) . Now tbe servk _ - *�� ir,o 35.7.E1900) 2.1 we lute service alve 1 a Ii� I dm 5:8' (15 88) i ' ■ 9110'1: i - r -t • / iti ZF/EZ - - " — I &E Z pzcs / /� , r =e=-• I- _ y = - -_--= I ?° i r 1 1 l m 0/1•.1 -. =� = ' ' r — . _f _ �. a l too ZfIEZ-ll ZfJl6`l -;_{ `i- f -- -� 1 � B I �� -_ - +_ - sue � I °� i `� � �' l � � - f I R ,' i I �` yI 4 1 r.,- I ( 1121,32 2 -tr3' 412 • =I I ry � I I2.7 II O. WW1 I jl . �1 • of Unit inch(mm) SA0 i 0 Sanyo Commercial Solutions A Division of SANYO North America A��i: ^ 1300 Michael Drive ,v S P a Wood Dale, IL 60191 USA `� wwwsanyohvac corn • k ", 'tip "` ix - n '� r 'r «OG° MARK: EF -1 6 moon • 1 1 `, 1 t. a r v , PROJECT: TSE . c 0 us DATE: 1/27 /2011 ACRD °'! Upblast Centrifugal Exhaust Ventilator B Roof Mounted /Belt Drive MIIIIIIIIM STANDARD CONSTRUCTION FEATURES: t All aluminum housing - Backward inclined all aluminum wheel - Two — "�j a II piece top cap with stainless steel quick release latches - One piece ■ ! bottom spinning - Welded curb cap corners - Birdscreen - Vibration I _ isolators - Lifting Lugs - Permanently lubricated ball bearing motors -- I I M- c Oil and heat resistant, static conducting belts - Adjustable pitch drives '�, e 7 —. through 5 hp motor - Corrosion resistant fasteners - Regreasable a � �� bearings in a cast iron pillow block housing, rated at 200,000 hours _1i1 Ii average life - All fans factory adjusted to specified fan RPM - Transit II I d tested packaging. Standard motors ship factory installed. II I G I T Sq. -1 } Performance ( *Bhp includes 15% dnve loss) Dimensions (inches) Catalog Flow SP Fan Power* A 19 -1/16 Qty Number (CFM) (inwc) RPM (HP) B 30 -3/16 • 1 135R4B 1250 .750 1250 .291 C 28 -5/8 G 2 Altitude (ft): 39 Temperature (F): 70 . Motor Information T Sq 20 Roof Open. Sq.* 15 -1/2 HP RPM Volts /Ph /Hz Enclosure Mounted TOL NOTE Accessories may affect dimensions shown 1/3 1725 115/1/60 ODP -SE Yes Yes 'Shipping Weight(Ibs) * ** 104 I Roof opening size for cuts supplied by Cook only "'Includes fan, motor 8 accessones Sound Data Inlet Sound Power by Octave Band 1 2 3 4 5 6 7 8 LwA dBA Sones 77 81 78 66 62 60 55 51 72 61 11.3 Fan Curve Accessories: 1.50 .334 STD DISCONNECT .._ / BD -14 DAMPER / ROOF CURB RCG 18 -9.5 H BELT TENSIONR- ROTARY 1.20 \ .267 / 1 i k "C 0.90 - .200 0 c il -1 ,. a ` 2 CO 0.60 / ,' .134 0 / I Fan Curve Legend 0.30 7 - .067 CFM vs SP (1250) - - -77 MaxRPM( 1574) MinRPM(740) _ - CFM vs HP 0.00 0.00 0 500 1000 1500 2000 2500 Point vs of HP 0 System Curve - Flow (CFM) v5 8 76 11329 M \CookwareUOBS keithh\2011\ f `' % ' PROJECT: TSE A y ` ' • • DATE: 1/27/2011 BD Gravity Backdraft Damper STANDARD CONSTRUCTION FEATURES: .02 blades - .06 aluminum frame - Aluminum hinge pins - Nylon bushings. Note: ' Sizes 36 thru 60 are shipped as 2 panels. Air Sizes 66 and 78'are shipped as 6 panels. ` • ' ' Flow These may require assembly. • . ' 7 B o : o o I 1- C Sq. • Dimensions (inches) Mark Qty Description A Max. B C Sq. # Panels EF -1 1 BD -14 DAMPER 5 -3/16 1 -7/8 13 -3/4 1 v5 8 76 11329 M \Cookware'JOBSViceithh120111 • .PROJECT: TSE u+ 1110-3 • • • DATE: 1/27/2011 RCG Galvanized Steel Roof Curb STANDARD CONSTRUCTION FEATURES: 18 gauge galvanized steel - 1 -1/2 ", 7 Wood Nailer 3 lbs. density thermal and acoustical V Sq. insulation - Continuously welded corners - I F Sq. j + Wood nailer. A 7 Options:(As noted below* ) 1) No wood nailer (deduct 1 -1/2" Ht. for actual height). 0 2) Damper tray. A , F^— W Sq. Insulation Roof Opening Optional Damper Tray Dimensions (inches) Mark Qty Descriptio Ht Options* A F Sq. V Sq. W Sq. Roof n Opening EF -1 1 RCG 18 9.5 - 1 -1/2 18 -1/2 22 -1/2 11 -3/4 15 -1/2 v5 8 76 11329 M \Cookware\JOBS\kelthh\2011\ ' MARK: EF -2 • 1 Fdt y g er PROJECT: TSE c ® us • DATE: 1/27/2011 • AC RU -H P . Upblast Centrifugal - , Exhaust Ventilator B • Roof Mounted /Belt Drive STANDARD CONSTRUCTION FEATURES: • \ _ All aluminum housing - Backward inclined all aluminum wheel - Two — " ir piece top cap with stainless steel quick release latches - One piece a bottom spinning = Welded curb cap corners - Birdscreen - Vibration III isolators - Lifting Lugs - Permanently lubricated ball bearing motors - AIM ' NM Oil and heat resistant, static conducting belts - Adjustable pitch drives � ! m __• A through 5 hp motor - Corrosion resistant fasteners - Regreasable a ;ME — bearings in a cast iron pillow block housing, rated at 200,000 hours _ average life - All fans factory adjusted to specified fan RPM - Transit I tested packaging. Standard motors ship factory installed. G I-- T Sq. -I f Performance ('Bhp includes 14% drive loss) Dimensions (Inches) Catalog Flow SP Fan Power* A 20 - 15/16 Qty Number (CFM) (inwc) RPM (HP) B 34 - 11/16 1 150RH5B 1000 1.00 1517 .412 C 27 -1/2 Altitude (ft): 39 Temperature (F): 70 G 2 T Sq. 24 . Motor Information • Roof Open. Sq.' 19 - 1/2 HP RPM Volts /Ph /Hz Enclosure Mounted TOL NOTE Accessones may affect dimensions shown 1/2 1725 115/1/60 ODP -SE Yes Yes !Shipping Weight(Ibs)' 124 I Roof opening size for curbs supplied by Cook only. "'Includes fan, motor 8 accessones. Sound Data Inlet Sound Power by Octave Band 1 2 3 4 5 6 7 8 LwA !IBA Sones 83 74 71 66 64 68 62 56 73 61 11.8 . Fan Curve Accessories: 3.00 .500 STD DISCONNECT BD -18 DAMPER ROOF CURB RCG 22 -9.5 H `BELT TENSIONR- ROTARY 2.40 ,.;. .400 I , 3 1.80 , 1 .300 p N 1.20 ... , ��• , .200 i Fan Curve Legend 0.60 ....1111 uui .100 ' CFM vs SP (1517) Mill,111■•„■, M RPM( 1952) 0.00 ��,�■•,- 0.00 Min inRPM(880) CFM vs HP 0 400 800 1200 1600 2000 Point of Operation O Flow (CFM) System Curve v5 8 76 11329 M 1Cookware\JOBS\keithh\2011\ • PROJECT: TSE ^` 1 �� 5 R f rC { • 1 �`�. ; .� ` 9 ; DATE: 1/27/2011 BD Gravity Backdraft Damper STANDARD CONSTRUCTION FEATURES: .02 Aluminum blades - .06 aluminum frame - Aluminum hinge pins - Nylon bushings. Note: Sizes 36 thru 60 are shipped as 2 panels. :.:r Sizes 66 and 78 are shipped as 6 panels. '••' fi Flow c These may require assembly. B O-- : O O a �!� 1 - C Sq. -.I Dimensions (inches) Mark Qty Description A Max. B C Sq. # Panels EF -2 1 BD -18 DAMPER 5 -3/16 1 -7/8 17 -3/4 1 • . v5 8 76.11329 M 1Cookware1JOBS keithh120111 14 PROJECT: `# ;Ce s. . .- • , DATE: 1/27/2011 RCG v Galvanized Steel • Roof Curb - - STANDARD CONSTRUCTION FEATURES: 18 gauge galvanized steel - 1-1/2", 7 Wood Nailer 3 lbs. density thermal and acoustical - V Sq. insulation - Continuously welded corners - f F Sq. j i Wood nailer. , . ` \ 0 A • Options:(As noted below *) � _ ' 1) No wood nailer (deduct 1 -1/2" Ht. ____0°A, for actual height). 0 2) Damper tray. Si a W Sq ' Optional Damper Tray Insulation Roof Opening Dimensions (inches) Mark Qty Descriptio Ht Options* A F Sq. V Sq. W Sq. Roof n • Opening EF -2 1 RCG 22 9.5 - 1 -1/2 22 -1/2 26 -1/2 15 -3/4` 19 -1/2 • v5 8 76 11329 M \CookwarellOBS\kelthh12011\ JANUARY 2007VIP == F antec h- , 411111 ` .. ?. '" 1k. ' _ . • THE INDUSTRY STANDARD FOR INLINE DUCT FANS 4- ' ' JUST GOT BETTER! " I ` The company that invented the circular duct fan more ' than thirty years ago, now introduces new improved ‘•.. % c CL us inline fans that are virtually airtight. :: :... e).. New production processes eliminate manufacturing variances 1 :. . z to ensure tight tolerances for optimal performance of every fan, Va�_ r -i%' Galvanized steel housings meet code requirements for both "s "`. applications. High quality ebm -papst rl ''`'u residential and commercial a PP 9 q Lock for te Energy Star motors ensure long life and dependable performance. Razed hlodelsinPerlornarte r ...t. Data Chart on back page Simplified Installation: &I. The FG Series features new longer duct connections for easier rb- kx rrz.. rs - -, installation. Fans are prewired and include bracket for mounting WE'VE SET NEW a , :0 y t 9 - , to wall or ceiling. STANDARDS FOR: ;Cen- ra N, to rec. ni Straight-through airflow allows fans to be installed at an any • Performance • Air Tightness L� - n, � angle at any point along the ductwork. r:_, ,t I, • Efficiency • Ease of rb�. • Reliability Installation :den•- FC Vibration NV Isolating Clamps Nre Suspension —0- CERTIFlED ryI . / r r Ly m � , 111111111101101.1111=120,12e:11011.0 -,------ . ' . Eif soft nix, Also Available: $ FGC SERIES Duct Same fans pre wired with _ ��_ Fantech Inline Duct Fan six foot cord and plug. HARD WORKING. LONG LASTING. HERE'S WHY: • Airtight galvanized steel housing — perfect for commercial 12 MODELS TO CHOOSE FROM: code applications • 4" to 12" duct diameters • Powered by ebm -papst external rotor motorized impeller • 135 to 940 CFM for excellent heat dissipation, even at low RPM • Backward curved impeller • 100% speed controllable • Permanently lubricated • Rated for airstream temperatures up to 140° F • sealed ball bearings _ _ , ± • Five -year factory warranty • for maintenance- ` g '`i • UL Listed; CSA Certified free operation _ , (! �. • Automatic reset thermal overload I / rt. protection —' Fantech external rotor motor I M P R O V I N G I N D O O R A I R Q U A L I T Y T H R O U G H B E T T E R V E N T I L A T I O N www.fantech.net FROM RESIDENTIAL TO COMMERCIAL . x X . . ,..,, ,:-' : ,i 1 4 • ..t ,4 4,,,e :A4 '•-# ,•,; .1 -; l it - ' ve p t '. 'X t rt•(. e .0 . 1 p - ,, , - FG4 FG10 DIMENSIONAL DATA r -33/4.- i AIR PERFORMANCE GRAPHS E _ F �1 r 350 300 r .�. _ FG I2 1 }} = 251 FG 10 I r 1,90 A ( &) r e ea_ea e tob se me , bra m, AMU Seal th tango em: deed 7n L•J eV m+ I FG9 ceeoteo in cana rh MICA 1 8 nm..acTni NA canto \ FG6 \ 1 • R d• reelmxmo at Oa . P Cne °m a irco o cor, .,. to l 7e*mum w 0 050 a II-rearm eon 0 FG 4, ,,, FG 5 fM.wae,m w eo rm D C "nom° = e c� e ° 0° 0 m0 200 300 400 500 600 700 BOO 900 1000 :mass laemmai Flow Rate ICFM) leall- Model to C D E F 350 FG 4 4 83'4 • 6'/2 1 1 NV 30° FG 4xt 4 9 6' 1 1 FG 5 5 8 51/2 1 '/e C (MI US = 25° FG 5m. 5 9 5' 1 1 o. FG 6 6 11 6 1 1 .a 2 w � ,` 12x11 FG 6xL 6 131 6% 1 1 S P9 6 15° ` FG 8 8 13% 6 1'/s 1/a ... � � FG 10 I • � s 1 I FG 8xt 8 13% 6 1 11/2 ti FG 10 10 13% 4h /,6 11/2 1 �° ° FG 6xt FG 10x1 10 13% 5% 1% 1 El1Ef16vSnr11I 1 FG Sn FG 12 12 16 8Y4 1'As 13/16 Letk far the Eneryv 000 Star RatedMcde'e 0 100 200 300 400 500 600 700 800 900 1000 FG 12x1 12 16 8 1'As 13/16 in Perfcrnarce Flow Rate (CFM) Data Gars PERFORMANCE DATA Fan Energy Rated Max. Static Pressure in Inches W.G. Max. Duct Model Star RPM Voltage Watts Amps 0" 0.1" 0 2" 0.4" 0 6" 0 8" 1 0" 1 25" 1 5" 2 0" 2 5" Ps Dia. FG 4 ✓ 3000 120 20 0 19 135 123 110 83 55 25 - - - - - 0.94 4" FG 4xt - 2750 120 71 0.66 170 160 150 134 119 103 86 63 40 - - 1.98 4" FG 5 ✓ 3000 120 20 0.19 - 156 143 130 99 66 . 33 - - - - - 0.99 5" FG 5xt - 2700 120 73 0 68 220 205 190 160 135 112 91 66 41 - - 1.89 5" FG 6 ✓ 2700 120 72 0.68 303 287 270 232 196 164 134 97 58 - - 1 88 6" re,,,,- LOOM IPM 1 :0 1 10 100 IMO Ice IMO 003 0E3 LOO P10 t01 100 L.I. 3 I L FG 8 61 2550 120 119 1.14 461 435 410 351 295 243 191 143 97 - - 211 8" • FG 10 ✓ 3000 120 138 1 43 513 497 480 444 407 366 324 269 216 89 - 2 36 10" • FG 10xt ✓ 3100 120 196 1.96 589 574 560 531 503 472 441 400 355 257 137 302 10" • FG 12 ✓ 2600 120 181 1.87 741 711 680 601 515 434 363 290 236 146 72 2 99 12" FG 1290 ✓ 2900 120 301 3.01 940 910 880 819 746 670 596 505 425 259 80 2 74 12" Performance certified is for installation type D - Ducted inlet, Ducted outlet Speed (RPM) shown is nominal Performance is based on actual speed of test Performance ratings do not include the effects of appurtenances (accessories) = _ — Fa n to C h United States 1712 Northgate Blvd • Sarasota, FL. 34234.1 800 747 1762 • www fantech net Item # 450286 Canada 50 Kanalflakt Way • Bauctouche. NB E4S 3M5 • 1 800 565 3548 • www fantech ca Rev Date 071207 Fantech, reserves the right to modify, at any time and without notice, any or all of its products' features, designs, components and specifications to maintain their technological leadership position A4 Ee2:01- 0 - era' ea 5 5 Single Duct Air Terminal Zone Controller ��, ez core -, ' , VAV Fan Terminal Zone Controller . ® Secondary Terminal Zone Controller - r I Installation Start -Up and Configuration Instructions Part Numbers 33ZCFANTRM, 33ZCVAVTRM, 33ZCSECTRM CONTENTS Service Configuration Selection Screen 37 Page • AIRFLOW SERVICE CONFIGURATION SCREEN SAFETY CONSIDERATIONS 1 • TERMINAL SERVICE CONFIGURATION SCREEN GENERAL 2 • OPTIONS SERVICE CONFIGURATION SCREEN • SECONDARY DAMPER SERVICE INSTALLATION 2 -29 CONFIGURATION SCREEN General 2 Maintenance Table Menu Screen 43 Zone Controller Hardware 2 • LINKAGE MAINTENANCE TABLE Field Supplied Hardware 2 • OCCUPANCY MAINTENANCE TABLE • SPACE TEMPERATURE SENSOR • ZONE AIR BALANCE /COMMISSIONING TABLE • PRIMARY AIR TEMPERATURE SENSOR • ZONE MAINTENANCE TABLE • SUPPLY AIR TEMPERATURE (SAT) SENSOR - • RELATIVE HUMIDITY SENSOR SAFETY CONSIDERATIONS • INDOOR AIR QUALITY (CO2) SENSOR Mount Zone Controller 4 SAFETY NOTE • LOCATION Air- handling equipment will provide safe and reliable • MOUNTING Connect the Power Transformer 7 service when operated within design specifications. The Connect Airflow. Pickups • - 7 equipment should be operated and serviced only - by Install Sensors 19 authorized personnel who have a thorough knowledge • SPACE TEMPERATURE SENSOR INSTALLATION of system operation, safety devices and emergency • PRIMARY AIR TEMPERATURE SENSOR procedures. INSTALLATION Good judgement should be used in applying any manu- • SUPPLY AIR TEMPERATURE (SAT) SENSOR facturer's instructions to avoid injury to personnel or dam - INSTALLATION age to equipment and property. • INDOOR AIR QUALITY SENSOR INSTALLATION • HUMIDITY SENSOR (WALL - MOUNTED) INSTALLATION Remote Occupancy Contact 26 4 p Y ��' " °, ^ ; �O yWARNING � :�� \ ,, Connect the Outputs 26 ,2 _ . :} Modulating Baseboard Hydronic Heating 26 Disconnect all power to the unit before performing matnte- Connect the CCN Communication Bus 26 nance or service. Unit may automatically start if power is • COMMUNICATION BUS WIRE SPECIFICATIONS not disconnected. Electrical shock and personal injury • CONNECTION TO THE COMMUNICATION BUS ' could result. START-UP 29 - 31 Perform System Check -Out 29 • Network Addressing 30 . WARNING ' Initial Operation and Test 30 � ^` Airflow Check 30 If it is necessary to remove and dispose of mercury contac- _, , , Fan and Heat Configuration and Test 30 tors in electric heat section, follow all local, state, and fed - 7. CONFIGURATION 31 -50 eral laws regarding disposal of equipment containing Points Display Screen 31 hazardous materials. I • Modify Controller Configuration 32 `? • ALARM LIMIT CONFIGURATION SCREEN i • CONTROLLER IDENTIFICATION SCREEN • HOLIDAY CONFIGURATION SCREENS • LINKAGE COORDINATOR CONFIGURATION SCREEN • • OCCUPANCY CONFIGURATION SCREEN • SET POINT SCREEN Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations. Book 1 4 PC 111 Catalog No. 533 -355 Printed in U.S.A. Form 33ZC -1SI . Pg 1 303 11 -99 Replaces: New Tab 1 11 a 13a • I • . GENERAL the SPT sensor. The Network Service Tool can be used to ad- just set points, set operating parameters, and fully configure the The zone controller is a single duct, fan powered, Variable zone controller or any device on the system. Air Volume (VAV) terminal control with a factory- integrated 1 controller and actuator. The zone controller maintains precise Zone Controller Hardware — The zone controller temperature control in the space by operating the terminal fan consists of the following hardware: and regulating the flow of conditioned air into the space. Build- • terminal control module ings with diverse loading conditions can be supported by con- • torque - limiting damper actuator trolling reheat or supplemental heat. • . airflow transducer (velocity sensor) ' The VAV Fan Terminal Zone. Controller (33ZCFANTRM) • plastic enclosure provides dedicated control functions for series fan or• parallel • one no. 8 x. I /2 -in. sheet metal screw (to prevent zone fan powered terminals, single duct terminals with 3 stages of controller rotation) heat, or as a primary controller for dual duct or zone pressure NOTE: A is not provided for the airflow transducer. control applications. For installations on systems with a high degree of impuri- The Single Duct Air .Terminal Zone Controller ties, an air filter can be purchased and installed on the trans - (33ZCVAVTRM) provides dedicated control functions for sin- ducer high pressure pickup. gle duct terminals with modulating heat or up to 2 stages of Figure 2 shows the zone controller physical details. heat. - Figures 3 -5 show the 3 different types of zone controllers. When the VAV Fan Terminal Zone Controller is used in Field Hardware — Each zone controller re- conjunction with a secondary terminal and the 33ZCSECTRM pP secondary terminal zone controller, either dual duct or zone quires the following field - supplied components to complete its pressurization applications can be supported. installation: Carrier's Linkage system is an integrated combination of • air terminal unit Carrier Comfort Network (CCN) controllers for use with Sin- • space temperature sensor gle Duct air terminals and VAV Fan Powered terminals. The • transformer — 24 vac, 40 va . Single Duct air terminal and VAV Fan terminal zone control- • two no. 10 x 1 /2-in. sheet metal screws (to secure SAT lers are part of the Carrier ComfortiD system. sensor to duct, if required) • Devices manufactured by Carrier which have Product Inte- two no. 6-32 x 5 /s-in. screws (to mount SPT sensor base grated Controls on the same communication bus as the zone to electrical box) • controller, air handlers (such as the 39L,T), or large rooftop contactors (if required for fan or electric heat) • units do not require an external controller to function as part of supply air temperature sensor (required for terminal with a Carrier linkage system. These air handlers or large rooftop ducted heat) • units feature factory- installed Product Integrated Control (PIC) indoor air quality sensor (if required) controllers that are directly compatible with the system. Con- • relative humidity sensor (if required) • sult your local Carrier representative for the complete list of one SPST (for each stage of electric heat, not required compatible air handlers. The Comfort System AirManager for Carrier fan terminals) • (CSAM) or the CC6400 supports linkage for non - Carrier de- valve and actuator for hot water heat (if required) • vices or air handlers. Figure 1 shows an example of a Carrier delta pressure airflow pickup linkage system. NOTE: When selecting an airflow pickup, it is the designer's responsibility to select a sensor that provides the INSTALLATION desired output at the design airflow. . • wire General — The zone controller is a microprocessor -based • polyethylene tubing (for pressure pickup) direct digital control (DDC) controller for variable air volume • bushings (required when mounting SAT sensor in a duct (VAV) air terminals. It can be retrofitted on units manufactured 6 -in. or less in diameter) by Carrier or other manufacturers to provide pressure- • primary air temperature sensor (if required) independent VAV control. SPACE TEMPERATURE SENSOR — Each zone control - Each zone controller has the ability to function as a linkage ler requires a field- supplied Carrier space temperature sensor. coordinator for systems with up to 128 zones. As a linkage co- There are two sensors available for this application: ordinator, a zone controller will retrieve and provide system in- • 33ZCT55SPT, Space Temperature Sensor with Override formation to the air handling equipment and other zone con- Button irollers. A zone controller can function as a stand alone device • 33ZCT56SPT, Space Temperature Sensor with Override by installing a primary supply air sensor. Button and Set Point Adjustment The zone controller monitors differential pressure from an PRIMARY AIR TEMPERATURE SENSOR — A field- r airflow pickup (or a pair of pickups) mounted on the terminal supplied, primary air temperature .(PAT) sensor (part number box. It compares the resulting signal to an airflow set point in 33ZCSENPAT) is used on a zone controller which is function - order to provide pressure independent control of the air passing ing as a Linkage Coordinator for a non CCN/Linkage compati- 1 through the terminal. ble air source. The zone controller is connected to a wall - mounted, field- +, SUPPLY AIR TEMPERATURE (SAT) SENSOR — On supplied, space temperature sensor (SF!) in order to monitor stand -alone applications or applications with ducted heat, the zone temperature changes and satisfy zone demand. zone controller must be connected to a field- supplied supply air On stand -alone applications or applications with heat, the temperature (SAT) sensor (part number 33ZCSENSAT) to zone controller must be connected to a field - supplied supply air monitor the temperature of the air delivered by the air terminal. temperature (SAT) sensor to monitor the temperature of the air The zone controller will maintain the air temperature below the delivered by the air terminal. maximum air temperature in ducted heating applications. Carrier's Network Service Tool can be connected to the sys- , tem at the SPT sensor if CCN communication wiring is run to 2 • • c • 1 4# CCN SYSTEM 000 CCN PRIMARY BUS (BUS 0) MONITORING O/ SOFTWARE FULLY CC6400 OR CSAM COMPATIBLE EQUIPPED AIR HANDLER NON -CCN AIR HANDLER 04; \� BRIDGE (RECOMMENDED) V COMFORTID EQUIPPED AIR TERMINAL SECONDARY BUS (1 OF UP TO 128) ADDRESSED SEQUENTIALLY • DATA COLLECTION OPTION II II II II 11 •' LEGEND CCN — Carrier Comfort Network CSAM — Comfort System AirManager Fig. 1 — Typical Carrier Linkage System 3 DAMPER ACTUATOR LOW PRESSURE SHAFT CLAMP TUBING ROUTING ASSEMBLY � • o ® e I � - I Cc - F AN A szca GND MECHANICAL ®'O ® # 1 SAT STOP �� 'I ? G 24VAC o " TN ® i GROMMET N � �L�V NEAT3 GND aND L`, PAT .%1, 11 - } 4. 4) 1 - RE 8� mf r5�rtm GND IMTE gapt C % HF23BJ042 Ca rrleY 4 - tee - -� ZONE Controller - - _ a (/-�) \J w s.....m..e� 11..44(4,.,4 o. — ''_ � "/J • 4,1144 m2 COM . z . 14 e San Number 33ZCFANTRM w COW U + m (7 " 00 ®0 sl• © I siN . -9' g 7 ui:0 ,— Beer ROTAA TION E 'mow` ,e � TAB Cva 2v/ ' 0 4 8 6 ' ® B ACTUATOR wow MEM a ® RELEASE MOM CMG@ — • I J NOTE: Actuator clamp accepts dampers -.) `-..,,, HIGH shafts with the following characteristics: PRESSURE Round — 1 /4 -in. to 5 /8-In. TUBING (6 to 16 mm) ROUTING Square — to 7 /l6-in. (6 to 11 mm) Damper shaft must be a minimum of 1.5 -in. (38 mm) long. - Fig. 2 — Zone Controller Physical Details (33ZCFANTRM Shown) RELATIVE HUMIDITY SENSOR — The 3. Press the release button on the actuator and rotate the 33AMSENRHS000 relative humidity sensor is required for clamp in the same direction that was required to close zone humidity control (dehumidification). the damper in Step 2. NOTE: The relative humidity sensor and CO2 sensor cannot 4. Press the release button on the actuator and rotate the be used on the same zone controller. actuator back one position graduation. Release the but - INDOOR AIR QUALITY (CO2) SENSOR — An indoor air ton and lock the actuator in this position. quality sensor is required for optional demand control ventila- 5. Mount the zone controller to the terminal by sliding tion. The CGCDXSEN002A00 CO2 Sensor is an indoor, the damper shaft through the actuator clamp assembly. wall mounted sensor with an LED display. The Secure the zone controller to the duct by installing CGCDXSEN003A00 CO2 Sensor is an indoor, wall mounted the screw provided through the grommet in the anti - sensor without display. rotation tab. Be sure the floating grommet is in the NOTE: The relative humidity sensor and CO2 sensor cannot center of the slot. Failure to center the grommet may be used on the same zone controller. cause the actuator to stick or bind. Mount Zone Controller 6 Tighten• the actuator clamp assembly to the damper shaft. Secure by tightening the two 10 -mm nuts. LOCATION — The zone controller must be mounted on the 7. If the damper has less than 90 degrees of travel air terminal's damper actuator shaft. For service access, there between' the fully open and fully closed positions, then should be at least 12 in. of clearance between the front of the a mechanical stop must be set on the actuator. The zone controller and adjacent surfaces. Refer to Fig. 6. mechanical stop prevents the damper from opening MOUNTING — Perform the following steps to mount the past the maximum damper position. To set the zone controller: mechanical stop, perform the following procedure: 1. Visually inspect the damper and determine the direc- a. Press the actuator release button and rotate the tion in which the damper shaft moves to open the damper to the fully open position. damper — clockwise (CW) or counterclockwise b. Using a Phillips screwdriver, loosen the appropri- (CCW). Refer to Fig. 7. ate stop clamp screw. J . If the damper rotates CCW to open, it does not require c. Move the stop clamp screw so that it contacts the any configuration changes. edge of the cam on the actuator. Secure the stop If the damper rotates CW to open, then the damper clamp screw in this position by tightening the actuator logic must be reversed. This is done in the : screw. software when performing system start-up and damper 8. Verify that the damper opens and closes. Press the calibration test. Do not attempt to change damper rota- actuator release button and rotate the damper. Verify tion by changing wiring. This will upset the damper that the damper does not rotate past the fully open position feedback potentiometer readings. position. Release the button and lock the damper in the 2. Rotate the damper shaft to the fully closed position. fully open position. Note direction of rotation. 801 4 • illlll , L • . o�`` p � .. ^ m 111 • • \- O C US N RHAAO *2" _ ^ SPT B I O GND O OA I / / m F AN AC SECFLOW SAD ® 1 ` C r I O ® � • ^ L.; 2dVAC OMPPO TS e ® Ir� 1 �� 1 wA L 1 H EAT3 GND GND ; Ifir: r l ' P AT CM C. fi Spin. ONO REMOTE FA J HF23BJ042 CaYKler°1 � • srz..., �® I ZONE Controller ^ ._ . , B , Brou.okeonew .5 BO. (ia M CW Z w + r LP p_ mo COM COW s °C I Pan Number 33ZCFANTRM 1' C ' V La U + m 0 " ®6 ■` ■ ■ ■ ■■ 196 �• ® � Bus ". '+ � S/N• t'1 N N ' I� I'' ®O ®01 r— n ' e p Q I Elementin m l c . 9..0 UnRA• G j , C E 24VACIC CO C 50,60 HS J6 2VA 2W I = FUF U C 3 .1 03 x w ow > + ®6 30200 1 = 1 80Ueux 6 n r c7 e 0 - mum l \ - - - / ®a J )---I . - Fig. 3 — VAV Fan Terminal Zone Controller �- �a e g I � I 0 AM US RHAAO � ;: : r i IL „ ii r 1 i , r -, ' TEST PAT I 74, 40 i 40 Comfort Spun. GND REMOTE BI ' HF23BJ042 Carrier, �� ZONE Controller ^ h d:� w w ^ 'r LL "� 1 11h32(. Nm) ( LII 80 - 1103 2 dill Z + '2' + � in® ' 1PMM ® 6 I =� Pan Number 33ZCVAVTRM 3 C7 m a G 0 SAr ® � I SIN• N I ll' ®° ® 6 � u Bsh II e6 � j Elements' csrxsr Un its m 2 , L U C C s ,VA J C J6 N 1)71.1 : O r 5K JVA 2W I = FUF ^ 0 f ®00 0 1 0 3 u Ae u A 6 .- > c. vnP n 0 AGo 0 Nu v. 1210© -' - L 2 ' �w -. �. ) ----- j . -* Fig. 4 — Single Duct Air Terminal Zone Controller 5 801 .Q --- ---_ ir . O \ o 9141 . _ 0 _ CUS ` C E OUT Q ® �� o e — — — �� t u finSpn"r COM o ea . r-- — �W HF23BJ042 _ i • CQ ZONE r� I Controller � _ � �o 35 Io-m (5 Nm) y 90 110A I I . SP Sat Number 33ZCSECTRM • , I B4f' • O I S • i RI oe r amr Unit* 7�VACIOL .. � C E . - 5O,eCNa J2 1E) ll� 7VA 7W 2 COM /1 !� I• : c).3.....= t 2 3 t: ,...x. :e • I 12E20 MENU bM '" vm ` \\ L I IN \ . V • — 1 1 ---------____ _________—_________..." . Fig. 5 — Secondary Terminal Zone Controller ALLOW 12" CLEARANCE FOR SERVICE ACCESS TO CONTROL BOX 3" REF. • \ ►I - / 0 h ZONE _ CONTROLLER , END VIEW INLET Fig. 6 — Service Clearance for Zone Controller Mounting • 6 • , NOTE: Do not run sensor or communication wiring in the ,' same conduit with line - voltage wiring. NOTE: An accessory conduit box (part no. 33ZCCONBOX) is • AIR p. , available for conduit wiring connections to the zone controller. • FLOW .'•r , • Perform the following steps to connect the power , transformer. • .. , ' 1. Install the field - supplied transformer in an electrical ' enclosure that conforms to NEC and local codes. CW TO OPEN, CCW TO CLOSE 2. Connect 24 vac from the transformer as shown in the applicable wiring diagram (Fig. 8A -J). Connect Airflow Pickups — The zone controller de- termines velocity pressure by obtaining the difference between .. high and low duct pressure from two airflow pickups. The INNO. AIR � pickups are connected to barb fittings on the zone controller FLOW with 1 /4 -in. polyethylene tubing. All piping for this purpose must conform to local codes. . Figure 9 indicates thepositions of the two barb fittings. `� Perform the following steps to install and connect the air- ' flow pickups: CCW TO OPEN, CW TO CLOSE 1. Select a location on the air handler's supply air duct . Fig. 7 — Damper Configuration where the airflow pickups will be installed. The loca- tion should be one where there are at least three duct • Connect the Power Transformer — An individual, diameters of straight duct upstream of the pickups. If this requirement is not met, stable airflow measure field- supplied, 24 vac power transformer is recommended for each zone controller. If multiple zone controllers are powered ments may not be possible. from one power transformer (100 v.a maximum for UL [Under- 2. Mount the field- supplied airflow pickup(s) in the duct, writers' Laboratories] Class 2 conformance), maintain polarity ' following the manufacturer's directions. Two individ- on the power input terminals. All transformer secondaries are ual pickups may be used, one for high pressure airflow required to be grounded. Use only stranded copper conductors and one for low pressure airflow. A dual pickup, which for all wiring to the zone controller. Wiring connections must combines the two functions, may also be used. When be made in accordance with NEC (National Electrical Code) using individual pickups, make sure that the one for and local codes. Ground the transformer at the transformer lo- high pressure airflow faces upstream, in the direction cation. Provide an 18 -gage, green, chassis ground wire at the the air is coming from, and the one for low pressure terminal airflow faces downstream, in the direction the air is The power supply is 24 vac ± 10% at 40 va (50/60 Hz). going to. For 33ZCVAVTRM zone controllers, the power require- 3. Use field- supplied 1 /4 -in. tubing (rated for the applica- to ment sizing allows for accessory water valves .and for electric bofitt on) t n the high pressure• aucer. At t heat contactor(s). Water valves are limited to 15 va on both controller, ing gn P PI o n•the pressure g io transducer. thhe e z zone e two-position and modulating hot water. The electric heat'con- insstalledtalled: Be e careful fitting s on the side witth h the filter tactor(s) are limited to 10 va (holding) each. - cful to avoid sharp bends in the tubing, because malfunctions may occur if the tubing is bent For 33ZCFANTRM zone controllers, the power require- too sharply. Use at least '2 ft .of tubing for reading ment sizing allows for accessory water valves 'and for the fan stability. contactor. Water valves are limited to 8 va on both two- position 4. Use field - supplied 1 /4 -in. tubing (rated for the applica- and modulating hot water. The fan contactor is limited to tion) to connect the low pressure airflow pickup to 11 va (holding). barb fitting P2 on the pressure transducer. Be careful to NOTE: If a water valve or electric heat contactor exceeds avoid sharp bends in the tubing, because malfunctions these limits, or external contactors are required for electric may occur if the tubing is bent too sharply. Use at least heat, then it is recommended a 60 va transformer be used. 2 feet of tubing for stability. The maximum rating for any output is 20 va. 7 W O IN ' . R k .± s SPT SE Low T56 L._ C G A I S \� Par - • AL U G REMOTE � (J HF23BJ042 'C • Made In Switzerland O By Bei mo Automation 35 in- Ib(4Nm) • • 80...110s 0 0 CU tit C R C GN f� U yy O - - -------. 47- 7 - \ . 7 () G 0 � - Not used • 24VAC /DC 50 /60Hz CCN comunications oo 3VA 2W HI ( I- r - t cam r" CCN comunications • o- W B 24 VA II Line Voltage R HEAT? 24VAC HEAT2 �u, Yel Blu Ora Blk Red Wht 0 0 0 0 0 0 o- TRAN . • o- I TRANSFORMER I I / / /. GROUND TERMINAL • GROUND LEGEND • CCN — Carrier Comfort Network • SAT — Supply -Air Temperature Sensor • SPT — Space Temperature Sensor TRAN — Transformer • • — — — — Field Wiring _ • Factory Wiring - Fig. 8A — Zone Controller Wiring — Single Duct Air Terminal, Cooling Only • . ' LEGEND ' / . . CCN — Carrier Comfort Network . . _ HWV -- Hot Water Valve . . SAT -- Sensor . ' • SPT -- Space Temperature Senso . . . . TRAN --Transformer - - - - Field Wiring • — Factory Wiring �� / . open mnonnun owoou,a*omay ' • ' """°°". . . . / - / . . / . . / �� . p�� . . �� l SAT | Low ' ~ Y �' — ' ' . �� . ��^ / -- �� / Or ' .// �\ ' — �� . « . . "o8Ts . . 382/ . m HF23BJ042 Made in Switzerland - °_��.`^ . . By mm�wwm . / U --- ' 80...110s ^~ || ' w0 " || ' C . . / . W 0 oO "o \_ Not 24vauuc umoo*z ' CCN comunications Hi / ,_ vm"u uo�n 3VA 2W / / • r ucwvmn"nicmoonx | � ~ uom \ / / \ / 0 O ^{- w o n i *�»m"�*m� ^ ..3 ' u*.°^ Line Voltage Yel Blu Ora a� �Red W� 0 0 0 |' {) �� ~~�~ —�_ TRAN 0 . TRANSFORMER I GROUND Fr7 U � TERMINAL GROUND -+ Fig. 8B-- Zone Controller Wiring -- Single Duct Air Tmrnmimm|.Tmo9pm�ixnHot Water Heat W ° LEGEND ' I CCN — Carrier Comfort Network I I HWV — Hot Water Valve I I SAT — Supply -Air Temperature Sensor I ' ' I SPT — Space Temperature Sensor I I ' ' I TRAN — Transformer ' ' ' ' ' . — — — — Field Wiring EBB I I Factory Wiring I I ® I I I 'Required for some spring return modulating valves. ► • • I I I I I I I I I I I I � I a26V I R HOP'G I I U s 4 SPT , _ // I I " . D - - - . 1 I SEC 8.0W -- • = i SAT • ir Low I ' O s T I I .. V ///�� 1 I 1' • �b I ' BI •� I I 1 I Or GND I / \ \ I PAT � o 0 1 I I V RE GTE ' GNU I I I O o HF23BJ042 I ' Carrier.; I Made in Switzerland "' ' ""'"� I 1 By Be11mo Automation I o ' I 35 In- Ib(4Nm) 80...110s i 0 C I I I I I I ('IO R Q� • ' I I I I I (GN[� w I I u I I (•) B ''.....\ I I 0 0 - 24VAC /DC U Not used I • I 1 50/60Hz I ' 3VA 2W HI I I CCN comunications i L I I I • I I . I I CCN comunications ' . t com -. I ' / I I W B R I HEAT1 24VAC HEAT2 I i /O 24 VAA i Line Voltage Yel Blu Ora Blk Red Wht O O O 1 -0 6 0-1 cx- _ TRAN . 0— ' TRANSFORMER I GROUND I i 1 TE NAL GROUND —> Fig. BC — Zone Controller Wiring — Single Duct Air Terminal, Modulating Hot Water Heat t , r I • LEGEND I I CCN — Carrier Comfort Network I I I I H — Heater Relay I I I I I • HWV — Hot Water Valve I I I I I • SAT — Supply -Air Temperature Sensor I I I SPT — Space Temperature Sensor I T H2 T I I I TRAN — Transformer I I I I • - - -- Field Wiring I l I I I Factory Wiring I I I 1 I I I 1 *24V I I RFAO O -- -- ---------- seer O =1SPTI I I - I 1 I • y 0 OCe} °- SAT 4. Low I I S -- - - 1101 \ \ Or I I I GN° • HF23BJ042 ( / Carrier.. : : I (� Made m LI I 35 In- Ib(4Nm) Switzerland • By Bolimo 80...110s I I 0 I I I Automation I I _ M O A I I I I (G , w I I f I (-)o B O ::t:ed 50 /60H DC I I I 50 /60Hz I I 3VA 2W Hi I I L comunications I I I I CCN sue\ com comunlcatlons I 1 ' I W B A I HEAT1 24VAC HEAT2 I ' o- 24 VAC Line � Voltage Yel Blu Ora Blk Red Wht 0 0 0 - - 0 d 0 - I TRAA N o- TRANSFORMER 47 GROUND TERMINAL GROUND - Fig. 8D — Zone Controller Wiring — Single Duct Air Terminal, Staged Electric Heat (2 Stages) 00 0 r,wl C ' `'' ' LEGEND 1 1 I I I CCN — Carrier Comfort Network ' I 1 I I I, I H — Heater Relay I , 1 I I I SAT — Supply -Air Temperature Sensor 1 1 l 1 I I SPT — Space Temperature Sensor 3 T H2 T H I I I TRAN — Transformer I I ' I ' - _ – _ Field Wiring , I ' I ' Factor Wirin , I , I , , / , I L ♦ \ I I I I , 1 NOTE: The VAV fan terminal zone controller is used on single duct air I I 1 terminals with 3 stages of electric heat. I I I I I I I , , - - I ' I I I .2,4v - 11116., � i c�O (C� SPT c�LOw 4 se SAT 1 .1011 1111 I 1 S T Low I • 8 „ I I ' FAf�AC T(5}6 _. _ _ I (, IYYVJ `" _____...„ \\ I uB1 �^ / � ' . FAN t', -7 w I , I V 1 0 1 1 I 24 VAC —- I REMOTE ' I I (, I 0 U I I I HF23BJ042 i,Ca%rier. P1e1J�5ed n,, Made in Switzerland `+° " I , I I � I By Behmo Automation 35 in- Ib(4Nm) I 1 I _ – 1 5t • 80...110s 11 0 C I I R 0 R 0 I , 24VAC /DC 7 Second C 8 M B 0' B 0 • Damper Not used , I , c8w I I 50 /60Hz ' 1 I CCN comunications 3VA 2W Hi ' I I L 11 I I I I- CCN comunications 1 com I W B R , HEAT1 24VAC HEAT2 � `'� 24 VAC Line Voltage 1 Yel Blu Ora Blk Red Wht Q 0 0 I —0 d o- -I a = = = _L TRAN 1 o-- - - -, — t , TRANSFORMER • I I TERMINAL GROUND GROUND --j Fig. 8E — Zone Controller Wiring - Single Duct Air Terminals, Staged Electric Heat (3- Stage) • V • LEGEND CCN — Carrier Comfort Network I Fan I SPT — Space Temperature Sensor I Contactor TRAN — Transformer 0 - - - - Field Wiring 0 l Factory Wiring I I • I I I Fan Motor I I I I I I • Line Voltage I I I I I I I I 1 I I R G D __ I o s - 1 SPTI I ki- SEC�OW I '. = L ow SST y.� 750 I AC 1 0- — ..1 ue1lr•N�,�.` - - � — V 0y p T I // Or 0 1 24 6C I � RTTE - O I w HF23BJ042 :C r i c rl 1 Het //11 I I UeoW I 1 Made In Switzerland Hens ' = I By Bekaa Automation 351n Ib(4Nm) 0 I I 80...110s I 0 1 all • 1 ( +)O R 0 I I 1 0 w0 .4 • 1 ( _0 B Damper C t '' B 1 omvOr I ( — ) 0 Not Used 24VAC/DC °c'" I 1 50 /60Hz Hi O I CCN 3VA 2W 1_ comunications I 4 — CCN } comunicatlons I com Cr - - -' W 8 R HEATI 24VAC HEAT2 24 � VAC 1 Line 1 Voltage Yel Blu Ora Blk . Red Wht 0 0 0 0 0 0 TRAN o- 1 TRANSFORMER GROUND I I I rt7 TERMINAL GROUND ---> Fig. 8F — Zone Controller Wiring — Fan Powered Terminals, Cooling Only 00 0 CO LEGEND r \ � � — CCN — Carrier Comfort Network , HWV — Hot Water Valve , SAT — Supply -Air Temperature Sensor I Fan Contactor • i SPT — Space Temperature Sensor I . TRAN — Transformer I — I I — — — — Field Wiring I Factory Wiring I I I I ® I Fan Motor • I I I I I • I I i I Line I I Voltage I I I I I I I I I I I '. . I I • I I .z RF 1 I O s . .. :::::::::: .::: SPT l I j I I O GND .j i i SATI IoW i I FA C y*CY —1 2, 6 7 I I i i O FP o- u— n75 3■Ie I — — �N 0''� yA �j \\ I 24 VAC I f'1�A 0 0 i REMOTE GND U HF23BJ042 =C arri e r. I N°' sod ' ° • I l6 I ' I I I Made In Swe ndand 35 in- Ib(4Nm) I Haan i D o By Belimo Automation 80...110s I I CH C I I I (s) R 0 0 I i I I �,�V Second C8M I S v 24VAC /DC I c�w (-1 0 e 0 Not Used I CCN 50/60Hz 2W Hi l I comunications • r -CCN 1 Corn I I comunicatl W e R I HEAT1 24VAC HEAT2 24 VAC �E Line Voltage . Yel Blu Ora Blk Red Wht O O O -- 0 6 O - - - - - - T IRAN • _ 1 o- TRANSFORMER I GROUND I (Ti TERMINAL GROUND –> Fig. 8G — Zone Controller Wiring — Fan Powered Terminals, Two-Position Hot Water Heat LEGEND \ / CCN — Carrier Comfort Network I � ' HWV — Hot Water Valve i PAT — Primary Air Temperature Sensor 1 - SAT — Supply-Air Temperature Sensor i I Fan Contactor �� SPT — Space Temperature Sensor I — I I TRAN — Transformer I I i r I I — — — — Field Wiring I I it I Fan Motor Factory Wiring II it I I i I I 1 ii I i - 1 . , ii I i Line II I I Voltage I I 1 'Required only on Linkage master if on a non - compatible air source. I I I ' I II I I II ' I I t i i ,22V 4 ' i I - R D GyD 951- -- - - ----- - - ---- SPT I / / Ii I 1 -- . II I I SECELOW 5 I Y - - - i SAT '. Low II - 0 ® __. I I ` • It ' I FC- - ' DMP OS Ell . It FA g // \ \ \\ I - - 'V N I orO P— G V T � --- - 1 PAT` 0 1 It 24y II REF1OTE I �J II 9 D O is _ i 1 HF23BJ042 Currier , t I us �O i' Made in Switzerland , I H oBt3 1 1 7 By Bellmo Automation 35 in-lb(4Nm) II O 1 1 80...1105 it it = • C ll ii { II II I II (ri jo�� R0 • I i O cw � I (GNIJ) w D It i I t Second CQM I I ( -) B ------:*- T' \-- /f� I I I Damper C � i O O Not Used 24VAC /DC �/ I I C � w I i CCN I 3VA 2W Hi ti I I L comunications I II 4 II I II f CCN • t ;1 Com II 1 '' comunications r li i I 1 II HEAT1 24VAC HEAT2 I o- Line W B R I I I 24 VAI g Yel Blu Ora Blk Red Wht 0 0 0 I - 0 Q 0- _ _ _ _ -_ _ _ Voltage TRAN (} - - - - - I TRANSFORMER . 1 i GROUND I ' TERMINAL • GROUND o — ) Fig. 8H — Zone Controller Wiring — Fan Powered Terminals, Modulating Hot Water Heat 00 1 1 o , � I r I \ Fan Contactor I ' 1 I ' I ' I I , — I I I I I 1 3 2 1 H I 1 1 Fan Motor T T ' II I ' 1 �� L , . I I I I ' • I I I Line I i i Voltage I I I I I *24V 1 I I ' OND O _ _ • I S T U . � j ' CF GNU _ _, _ I SECFLOW CJ ` SAT 44 = Low — — — — -— 0 ST ' I I I I ye t nv I / / ////��` I I 1 FA A C C T O 1 1/B F'YOb V u I I I Ny p I / \\\\ ' I ' I - - FAN I OG0° - 6T - - - - 4 PAT' I • �J[ PLT 0 1 I I I I 24VAC - V RE 1 I I I ( N ( J HF23BJ042 .C ar ri er -. I I ; ' Nated O — In Swia � � I I Made adond 1 - -0 Q I By Be limo Automation 35 in- Ib(4Nm) i I , - I I I 80...110s 1 I I ' = I CH I I I I I I I 1 ( +) O R O I I I I 3 i IGND) w O , I - O '� I Dampe CQM (-) 0 9 O Not Used I Damper 24VAC /DC 7 ' ' I c15w ' 50 /60Hz ' I CCN 3VA 2W Hi i i I i I L comunications I I I 1 r I I I CCN I t / 0 " COM , L - - - comunications - I w a A I HEAT1 24VAC HEAT2 ` -, \o- 24 VAC Line L Voltage Yel Blu Ora Blk Red Wht O 0 0 L- O b a -' c:: T TRAN o- I TRANSFORMER _ • 1 I GROUND LEGEND I r77 CCN — Carrier Comfort Network f G R OU ND L H — Heater Relay PAT - — Primary Air Temperature Sensor SAT — Supply -Air Temperature Sensor SPT — Space Temperature Sensor 'Required only on Linkage master if on a non-compatible air source. TRAN — Transformer - - - - Field Wiring -3 Fig. 81 — Zone Controller Wiring — Fan Powered Terminals, Staged Electric Heat Factory Wiring PRIMARY DAMPER — 33ZCFANTRM n2aV ' RE D s s / j I - S:7.1:: W . Low - - 56 • ^ FAN AC I 1 II �- O III ".. O"' I BI •— F I G D 0 1 O• A I N • 0 \\ 24 VAC I 1 I O RE OTE O 1 liND HF23BJ042 / Car >"i - Not ed III 0 Made in Switzerland Heat3 III — I I By Bellmo Automation 35 in- Ib(4Nm) I 80...110s l i _ I I CH I Second I I Damper 1 1I HO R 0 7CC7�� W I i I - - - Z.J I I I (GO) w0 111 f\ C M I 1 ------ \ T /1 1— — I 11 ' I " 0 e 0 Not Used 24VAC /DC V ccw 1 1 50 /60Hz I 1 - -0 III 1 CCN 3VA 2W Hi l I 1 I L- comunications 1 111 I • . I 111 1 I- CCN corn 1 I I i I I- comunications • • 1 1 11 I W B R HEAT1 24VAC HEAT2 I i I 1 - -0- 24 VAC LINE Yel Blu Ora Bik Red Wht 0 0 0 0 0 0 ' I1 I _ _ � VOLTAGE I I I II I TRAN • I I 11 I 1 I TRANSFORMER 1' I GROUND I T m 1 I 1 I I l iD SHIELD TERMINAL I GROUND 1 I I LEGEND I I ' I CCN — Carrier Comfort Network l I I SHIELDED (CCN -TYPE) CABLE SPT — Space Temperature Sensor 1 I : `-- TRAN — Transformer - - - - Field Wiring Factory Wiring –> Fig. 8J — Zone Controller Wiring — Dual Duct Applications w • o - - w . • SECONDARY DAMPER — 33ZCSECTRM 1 1 • 1 1 I Iii 1 1 Iii 1 I Iii I I Iii I 1 1 Iii I 1 1 III 1 1 `y 1 I 111 .)(7 i 1 1 - • 11' • I III 1 1 I III G� / I i I I I rl r GRID I II SECC LOW —IL— LOW 1 I -1 (J 1 I .1 9.6D CJ I I Gy I CCW — O HF23BJ042 Carrier . • Made In Switzerland By Behmo Automation 35 in- Ib(4Nm) °O 80...110s 24VAC /DC 7 .. . 50 /60Hz 3VA 2W Hi cam , W B R V BI' Or Yel Blu Ora Blk Red Wht 0 0 0 0 0 0 , . - 11 -- LEGEND CCN — Carrier Comfort Network SPT — Space Temperature Sensor TRAN — Transformer • - - - - Field Wiring • Factory Wiring Fig. 8J — Zone Controller Wiring — Dual Duct Applications (cont) • • • • Install Sensors 3. Connect the sensor cable as follows: - SPACE TEMPERATURE SENSOR INSTALLATION — a. Connect . one wire from. the cable • (RED) to the ; A space temperature sensor must be installed for each zone SPT terminal on the controller. Connect the - other controller. There -are three types of SPT sensors available from end of the wire to the left terminal on the SEN. ter- , Carver: the 33ZCT55SPT space temperature sensor with - timed minal block of the sensor. • override button, the 33ZCT56SPT space temperature sensor b. Connect another wire from the cable (BLACK) to with timed override button and set point adjustment and the the GND terminal on the controller. Connect the 33ZCT58SPT with liquid crystal display. See Fig. 10. other end of the wire to the remaining open termi- The space temperature sensor is used to measure the build- nal on the SEN terminal block. ing interior temperature and should be located on an interior c. On 33ZCT56SPT thermostats, connect the re- building wall. The sensor wall plate accommodates the NEMA maining wire (WHITE /CLR) to the T56 terminal standard 2 x 4 junction box. The sensor can be mounted direct- on the controller. Connect the other end of the ly on the wall surface if accpectable by local codes. wire to the right most terminal on the SET termi- Do not mount the sensor in drafty locations such as near air nal block. conditioining or heating ducts, over heat sources such as base- d. In the control box, install a No. 6 ring type crimp board heaters, radiators, or directly above wall mounted light- lug on the shield drain wire. Install this lug under ing dimmers. Do not mount the sensor near a window which the mounting screw in the upper right corner of may be opened, near a wall corner, or a door. Sensors mounted the controller (just above terminal T1). in these areas will have inaccurate and erratic sensor readings. e. On 33ZCT56SPT thermostats install a jumper The sensor should be mounted approximately 5 ft from the between the two center terminals (right SEN and floor, in an area representing the average temperature in the left SET). space. Allow at least 4 ft between the sensor and any corner —> Wiring the Space Temperature Sensor (33ZCT58SPT) — The and mount the sensor at least 2 ft from an open doorway. T58 space temperature sensor is wired differently than other Install the sensor as follows (see Fig. 11): conventional sensors. The T58 sends all its sensor information 1. Locate the two Allen type screws at the bottom of the through the CCN bus to the zone controller that is is associated sensor. with. The SPT sensor wiring connections are not used. The T58 2. Turn the two screws clockwise to release the cover sensor does not need to be directly wired to the zone controller. from the sensor wall mounting plate. The T58 sensor may be powered by a separate 24 -VAC pow - 3. Lift the cover from the bottom and then release it from er supply or may connected to the J1 24 power termi- the top fasteners. nals on the zone, controller. Be sure that the polarity of the power 4. Feed the wires from the electrical box through the supply connections are consistent. For multiple devices wired to g the same power supply, all positive ( +) and negative ( —) termi- opening in the center of the sensor mounting plate. nals should be wired in the same polarity. 5. Using two no. 6 -32 x 1 mounting screws (provided Wire the T58 sensor to the CCN. Connect the CCN + termi- with the sensor), secure the sensor to the electrical box. nal to the RED signal wire (CCN +). Connect the CCN — termi- 6. Use 20 gage wire to connect the sensor to the control- nal to the BLACK signal wire (CCN —). Connect the GND ler. The wire is suitable for distances of up to 500 ft. terminal to the WHITE /CLEAR signal wire (Ground). Refer to Use a three- conductor shielded cable for the .sensor the T58 sensor Installation Instructions for more information and set point adjustment connections. The standard on installing and wiring the sensor. CCN. communication cable may be used. If the set - point: adjustment- (slidebar) is not required, then an . IMPORTANT: The T58 sensor must be configured with unshielded, 18 or 20 gage, two- conductor, twisted pair the bus address and device type, of the zone controller cable may be used. before it will broadcast temperature to the zone control - The CCN network service jack requires a separate, • ler. Refer to the T58 sensor Installation Instructions for shielded CCN communication cable. Always use sepa- rate cables for CCN communication and sensor wir- • - ing. (Refer to Fig. 12 for wire terminations.) Wiring the CCN Network Communication Service Jack — 7. Replace the cover by inserting the cover at the top of See Fig. 12, 13, and 14. To wire the service jack, perform the the mounting plate first, then swing the cover down following: over the lower portion. Rotate the two Allen head 1. Strip back the jacket from the CCN communication screws counterclockwise until the cover is secured to cable(s) for at least 3 inches. Strip I /4 -in. of insulation the mounting plate and locked in position. from each conductor. Remove the shield and separate 8. For more sensor information, see Table 1 for ther- the drain wire from the cable. Twist together all the mistor resistance vs temperature values. shield drain wires and fasten them together using an NOTE: Clean sensor with damp cloth only. Do not use closed end crimp lug or a wire nut. Tape off any solvents. exposed bare wire to prevent shorting. Wiring the Space Temperature Sensor (33ZCT55SPT and 2. Connect the CCN + signal wire(s) (RED) to 33ZCT56SPT) — To wire the sensor, perform the following Terminal 5. (see Fig. 12 and 13): 3. Connect the CCN — signal wire(s) (BLACK) to 1. Identify which cable is for the sensor wiring. Terminal 2. 2. Strip back the jacket from the cables for at least 4. Connect the CCN GND signal wire(s) (WHITE /CLR) 3- inches. Strip 1 /4 -in. of insulation from each conduc to Terminal 4. tor. Cut the shield and drain wire from the sensor end of the cable. 19 801 LOW PRESSURE f • , .. TUBING • . • , st .. . 4` ., : :. z .?.., l r ®❑ • r'1 Ise "' .. , I // . . \i . 0 -- - - •.. . . . . ..: . .. • . . . • . _ ti.,....r, i _. . . • . . • `� HIGH PRESSURE TUBING NOTE: Minimum length of tubing-is 2 ft. . Fig. 9 — Airflow Pickup Installation HOLES (2) #8 MOUNTING FOR i____________ SCREWS ON CENTERLINE ::: 1 00 • i • i I 4.50 3 28 , ,CarriC t i • // Cool ,t Warm . .50j o- Fig. 10 — Space Temperature' Sensor NOTE: Dimensions are in inches. (P/N 33ZCT56SPT Shown) Fig. 11 — Space Temperature Sensor and Wall _ Mounted Humidity Sensor Mounting 20 \ \ 7 / \ \ /•/ T I ii ,en .. ®m ® ® ® ®® m ® ® ®� i 2 3 ' ° RED( +), ' ' ' ' ' RED(.. +)_„ _ , _ L , ,_ g �) ,` WHT(GND)l, , CCN COM \ . -g WHT(GND) ,; CCN COM - _ , SEN SEN SET = SW ®® I-1SN, ®lo ®l® wHT ' \ (T56) ,T -. ‘\ ELK SGNDJ . , SENSOR WIRING ‘� _ _BLKSGND� �; SENSOR WIRING RED(SPT) ; - REDI DT)2,; JUMPER TERMINALS O ©,© l l it a 1I 11 AS SHOWN 0 ❑, n I❑ ❑, I /,/ `\ / / Cool Warm \ \ , Li \.> Fig. 12 — Space Temperature Sensor Wiring Fig. 13 — Space Temperature Sensor Wiring (33ZCT55SPT) (33ZCT56SPT) Table 1 — Thermistor Resistance vs Temperature Values for Space Temperature Sensor, Return -Air Temperature Sensor, and Supply -Air Temperature Sensor TEMP TEMP RESISTANCE (C) (F) (Ohms) -40 -40 335;651 - 35 -31 242,195 - 30 -22 176,683 - 25 -13 130;243 - 20 -4 96,974 -15 5 72,895 - 10 14 55,298 -5 23 42,315 0 32 32,651 5 41 25,395 10 50 19,903 15 59 15,714 20 68 12,494 25 77 10,000 30 86 8,056 35 95 6,530 40 104 5,325 45 113 4,367 50 122 3,601 55 131 2,985 60 140 2,487 65 149 2,082 70 158 1,752 • 21 Wiring when distance between zone controller and space temperature sensor is 100 feet or less CCN COMM BUS 100 FT MAXIMUM • 3 COND COMM CABLE (TYP) • 2 COND TWISTED CABLE OR 3 COND CABLE (TEMP 0• SENSOR WIRING) (TYP) ° i 0 4, ♦ 0 ♦ 0 AIR TERMINAL ZONE UNIT CONTROLLER NIT (TYP) p (TYP) L • — ^ SPACE TEMPERATURE SENSOR Wiring when distance between zone controller and space temperature sensor is greater than 100 feet CCN COMM BUS DISTANCE GREATER THAN 100 FT. • 1 2 COND TWISTED CABLE OR 3 COND CABLE (TEMP ° SENSOR WIRING) (TYP) ° • o 11-1111 0 ♦ O ♦ O AIR TERMINAL ZONE CONTROLLER s UNIT (TYP) CONTROLLER SPACE TEMPERATURE SENSOR Fig. 14 — Communication Bus Wiring to Zone Controller Before wiring the CCN connection, refer to the Connect to The other end of the communication bus cable must be con- • the CCN Communication Bus section on page 26, for commu- nected to the remainder of the CCN communication bus. If the nication bus wiring and cable selection. The cable selected cable is installed as a T -tap into the bus, the cable length cannot - must be identical to the CCN communication bus wire used for exceed 100 ft. Wire the CCN service jack of the sensor in a the entire network. daisy chain arrangement with other equipment. Refer to the Connect to the CCN Communication Bus section, page 26, for more details. 22 • PRIMARY AIR TEMPERATURE SENSOR INSTALLA- If the unit is equipped with electric reheat, ensure that the TION — A primary air temperature (PAT) sensor is used on a sensor is installed at least 2 ft downstream of the electric heater. zone controller which is functioning as a Linkage Coordinator See Fig. 17 for the sensor location in this application: ' • r for a non CCN/Linkage compatible air source. The part nurn If the unit has an octopus connected directly at the dis- ber is 33ZCSENPAT. See Fig. 15. charge, install the sensor in the octopus. If•the unit has an elec- When used on a zone controller, try to select a zone control- tric heater, the two foot minimum distance between the sensor ler which will allow installation of the PAT sensor in the main and the heater must be maintained. See Fig. 17 for the sensor ,, trunk, as close to the air source as possible. See Fig. 16. location in this application. SUPPLY AIR TEMPERATURE (SAT) SENSOR INSTAL LATION — On terminals with heat, the SAT sensor is re- ° ':' ' ' ' quired. The SAT must be installed in the duct downstream -. � -2;4'. }� :, ;� A WARNI ;; - � ,; from the air terminal. The SAT sensor is also sometimes called Disconnect electrical power before wiring the zone control - a duct temperature (DT) sensor. The part number is ler. Electrical shock, personal injury, or damage to the zone 33ZCSENSAT. controller can result. The SAT sensor probe is 6 inches in length. The tip of the probe must not touch the inside of the duct. Use field- supplied Do not run sensor or relay wires in the same conduit or race - bushings as spacers when mounting the probe in a duct that is way with Class 1 AC or DC service wiring. Do not abrade, cut, 6 in. or less in diameter. or nick the outer jacket of the cable. Do not pull or draw cable If the unit is a cooling only unit, the SAT is not required. with a force that may harm the physical or electrical properties. Avoid splices in any control wiring. Perform the following steps to connect the SAT sensor to N• the zone controller: I. Locate the opening in the control box. Pass the sensor probe through the hole. 2. Drill or punch a 1 /4 -in. hole in the duct downstream of the unit, at a location that conforms to the require- ments shown in Fig. 17. 3. Use two field- supplied, self - drilling screws to secure the sensor probe to the duct. Use field supplied bush- ings as spacers when installing the sensor probe in a duct 6 in. or less in diameter. ® Perform the following steps if state or local code requires the use of conduit, or if your installation requires a cable length of more, than 8 ft: 1. Remove the center knockout from a field- supplied 4 x 2 -in. junction box and secure the junction box to the duct at the location selected for the sensor probe. ® 2. Drill a 1 /2 -in. hole in the duct through the opening in the junction box. 3. Connect a 1 /2 -in. nominal field - supplied conduit between the zone controller enclosure and the junction box. Fig. 15 — Primary Air Temperature Sensor 4. Pass the sensor probe wires through the conduit and (Part Number 33ZCSENPAT) insert the probe' in the duct. Use field- supplied bush- ings as spacers when installing the sensor probe in a duct 6 in. or less in diameter. 5. Secure the probe to the duct with two field- supplied self - drilling screws. 6. If you are extending cable length beyond 8 ft, use ple- num rated, 20 AWG, twisted pair wire. 7. Connect the sensor leads to the zone controller's wir- ing harness terminal board at the terminals labeled . SAT and GND. 8. Neatly bundle and secure excess wire. - INDOOR AIR QUALITY SENSOR INSTALLATION — The indoor air quality (IAQ) sensor accessory monitors carbon dioxide levels. This information is used to modify the position . Ill a of the outdoor air dampers to admit more outdoor air as required to provide the desired ventilation rate. Two types of sensors are supplied. The wall sensor can be used to monitor the conditioned air space; the duct sensor monitors the return air duct. Both wall and duct sensors use infrared technology to 0 measure the levels of CO2 present in the air. The wall sensor is available with or without an LCD readout to display the CO2 level in ppm. See Fig. 18. The sensor part number is 33ZCSENCO2. To mount the Fig. 16 — Primary Air Temperature Sensor sensor, refer to the installation instructions shipped with the ac- Installation (Unit Discharge Location) cessory kit. 23 800 L UNIT WITH ELECTRIC REHEAT ' riFT MIN. • • ti AIR ti PRIMARY n 4 * I , • AIR INLET TERMINAL • UNIT I ZC IHEATI kg UNIT WITH OCTOPUS r 2 FT. MIN. • • 4 4 • AIR AIR INLET TERMINAL OCTOPUS UNIT I ZC I HEAT I ♦ ® j ZC - Zone Controller -4 Fig. 17 — Supply Air Temperature Probe (Part No. 33ZCSENSAT) Locations The CO2 sensors (33ZCSENCO2) factory set for a range of To convert the CO2 sensor into a duct - mounted CO2 sensor, 0 to 2000 ppm and a linear voltage output of 0 to .10 vdc. the duct - mounted aspirator (33ZCASPCO2) will need to be Figure 19 shows ventilation rates for various CO2 set points purchased. when outside air with a typical CO2 level of 350 ppm is used. To accurately monitor the quality of the air in the condi- Refer to the instructions supplied with the CO2 sensor for elec- tioned air space, locate the sensor near the return air grille so it trical requirements and terminal locations. The zone controller senses the concentration of CO2 leaving the space. The sensor requires 24 vac 25 va transformer to provide power to the should be mounted in a location to avoid direct breath contact. sensor. Do not mount the space sensor in drafty areas such as near • 0 0 0 Q 0 0 - supply ducts, open windows, fans, or over heat sources. Allow • U U _ a at least 3 ft between the sensor and any corner. Avoid mounting 0 0 0 0 0 0 0 0 0 0 0 - _ =� the sensor where it is influenced by the supply air; the sensor 0 0 0 0 0 - -- gives inaccurate readings if the supply air is blown directly 0 p■ MINN 0 0 0 _ 0 0 - onto the sensor or if the supply air does not have a chance to 0 ••• == mix with the room air before it is drawn into the return air stream. To accurately monitor the quality of the air in the return air' 5.625 5 duct, locate the sensor at least 6 in. upstream or 15 in. down - (14.3) (12.7) stream of a 90 degree turn in the duct. The downstream loca- tion is preferred. Mount the sensor in the center of the duct. . IMPORTANT: If the sensor is mounted in the return air . - duct, readjust the mixed -air dampers to allow a small - amount of air to flow past the return air damper when- ever the mixing box is fully open to the outside air. If the I . I I II damper is not properly adjusted to provide this mini- .. 3.25 ' 1 1.125 I 00.25 mum airflow, the sensor may not detect the indoor -air (8.3) (2.$) 'I I II (a8) mum during the economizer cycle. Fig. 18 — Indoor Air Quality (CO2) Sensor - (33ZCSENCO2) 303 24 ao The sensor must be mounted vertically on the wall. The - Z Carrier logo should be oriented correctly when the sensor is . : . o properly mounted. ca M 60 a 0 DO NOT mount the sensor in drafty areas such as near heat- o rr � _ ing or air- conditioning ducts, open windows, fans, or over heat ii w 20 CFFM/PERSON sources such as baseboard heaters, radiators, or wall - mounted o �°—, - / 5 CFM /PERSON light dimmers. Sensors mounted in those areas will produce in- LL D \ accurate readings. a 0 t I I i i L r r Avoid corner locations. Allow at least 4 ft between the sen- s oo 700 900 1100 1300 1500 1700 1900 2100 2300 2500 sor and any corner. Airflow near corners tends to be reduced, CO2 CONCENTRATION (PPM) resulting in erratic sensor readings. Fig. 19 — Ventilation Rated Based on Sensor shou vertically m ounted approximate 5 ft up 9• from the floor, beside th s temperature se nsor . CO2 Set Point For distances up to 500 feet, use a 3- conductor, 18 or 20 AWG cable. A CCN communication cable can be used, Indoor Air Quality Sensor Wiring — To wire the sensors although the shield is not required. The shield must be removed after they are mounted in the conditioned air space and return from the sensor end of the cable if this cable is used. See air duct, see Fig. 20 and the instructions shipped with the sen- Fig. 22 for wiring details. sors. For each sensor, use two 2- conductor 18 AWG twisted The power for the sensor is provided by the control board. pair cables (unshielded) to connect the separate isolated 24 vac The board provides 24 vdc for the sensor. No additional power power source to the sensor and to connect the sensor to the con- source is required. trol board terminals. To connect the sensor to the control board, identify the positive ( +) PIN -8 and ground (GND) PIN -7 termi- To wire the sensor, perform the following: nals on the sensor and connect the positive terminal to terminal 1. At the sensor, remove 4 -in. of jacket from the cable. RH/IAQ and connect the ground terminal to terminal GND. Strip 1 /4-in. of insulation from each conductor. Route HUMIDITY SENSOR (WALL - MOUNTED) INSTALL the 'cable through the wire - clearance opening in the TION — The accessory space humidity sensor is installed on center of the sensor. See Fig. 22. an interior wall to measure the relative humidity of the air with- 2. Connect the RED wire to the sensor screw terminal in the occupied space. See Fig. 21. marked ( +). The use of a standard 2- x 4 -in. electrical box to accommo 3. Install one lead from the resistor (supplied with the date the wiring is recommended for installation. The sensor can sensor) and the WHITE wire, into the sensor screw ter - be mounted directly on the wall, if acceptable by local codes. urinal marked ( —). After tightening the screw terminal, test the connection by pulling gently on the resistor If the sensor is installed directly on a wall surface, install the lead. humidity sensor using 2 screws and 2 hollow wall anchors 4. Connect the remaining lead from the resistor to the (field- supplied); do not overtighten screws. See Fig. 11. BLACK wire and secure using a closed end type crimp connector or wire nut. -- A CAUTION : , , '.1 5. Using electrical tape, insulate any exposed resistor - .= '4• -• r lead to prevent shorting. Do NOT clean or touch the sensing element with chemical 6. At the control box, remove the jacket from the cable solvents; they can permanently damage the sensor. and route the RED conductor over to the left side of . the control board. Route the. remaining conductors to the right side of the control board. • i A y, — t -- • o OQ lop* y y QO • 1 (,�� ® • Q GND . - _ - _ - _ - 1 1 ANC ®� , a ° ® ®o °�� I lam I o CJo ® ® ® ®� HF23 • rIBr ® ®y I ..._.._ w . o...; I . E ® NNE • _ �I • sP • 4 Ili ^ i " �— NN �: ° O LINE \ �_ // ® 0 0 ®• T ' 0 0a 24 VAC I: VOLTAGE SEPARATE • ��Q „V,nx a- y y a O ISOLATED E • • POWER 3VA 23. e, • ^ I • e�, c ' � ' •• eC REQUIRED • EM� CMo I .,Y Irat 4 if n ,� t y ' , • M e. / (24 VAC, 25 VA — J ! MINIMUM) \III" Existr4(ip 1_1- / N p � 'Do not connect to the same transformer that supplies power to the zone controller. - Fig. 20 — Indoor Air Quality Sensor Wiring 25 303 , Refer to the service configuration table and set the Heating , Loop parameters as follows: .. Proportional Gain = 20.0 Integral Gain = 0.5 Derivative Gain = 0.0 Start Value = 102.0 Also, set the Ducted Heat decision to YES and set the Max- . imum Duct Temperature decision equal to the design (maxi- - mum) boiler water' temperature minus 20 degrees, but not • . greater than 200 degrees F. - Connect the CCN Communication Bus — The i zone. controllers connect to the bus in a daisy chain arrange- ment. The zone controller may be installed on a primary CCN ' � i bus or on a secondary bus from the primary CCN bus. Con- . i necting to a secondary bus is recommended. At 9,600 baud, the number of controllers is limited to 128 • ct�; r zones maximum, with a limit of systems (Linkage Coordina for configured for at least 2 zones). Bus length may not. exceed — _ J 4000 -ft, with no more than 60 devices on any 1000 -ft section. �j \ Optically isolated RS-485 repeaters are required every 1000 ft. • At 19,200 and 38,400 baud, the number of controllers Fig. 21 — Wall Mounted - Relative Humidity Sensor is limited to 128 maximum, with no, limit on the number of (P/N 33AMSENRHS000) Linkage Coordinators. Bus length may not exceed 1000 ft. The first zone controller in a network connects directly to 7. Strip 1 /4 -in. of insulation from each conductor the bridge and the others are wired sequentially in a daisy chain and equip each with a 1 /4 -in. female quick connect fashion. Refer to.Fig. 25 for an illustration of CCN Communi- terminal. cation Bus wiring. 8. Connect the RED wire to terminal +24v on the control The CCN Communication Bus also connects to the zone board. controller space temperature sensor. Refer to the Install the 9. Connect the BLACK wire to terminal GND on the Sensors section for sensor wiring instructions. control board. 10. Connect the WHITE /CLEAR wire to terminal COMMUNICATION BUS WIRE SPECIFICATIONS — RH/IAQ on the control board. . The Carrier Comfort Network (CCN) Communication Bus 11. Connect shield to ground (if shielded wire is used). wiring is field- supplied and field - installed. It consists of shielded three- conductor cable with drain (ground) wire.. The - Remote Occupancy Contact — The remote occu- cable selected must be identical to the CCN Communication pancy input (J4 pin 2) has the capability to be connected to a Bus wire used for the entire network. Seel - able 2 for'recom- normally open or normally closed occupancy dry contact. Wire mended cable. . . . ' the dry contact as show in Fig. 23 between J4 Pin 2 and 24 VAC J1 Pin 1. The 24 VAC necessary to supply the Table 2 = Recommended Cables CornfortIDTm Controller remote occupancy contact input shall MANUFACTURER CABLE PART NO. be supplied using the existing ComfortID Controller. Alpha 2413 or 5463 Connect the Outputs — Wire the zone controller's American r3��2 A 772 outputs (fan, staged heat, valves) as shown in the applicable Colu wiring diagrams in Fig. 8A -J. Columbia bia 02525 NOTE: Conductors and drain wire must be at least 20 AWG Modulating Baseboard Hydronic — In- (American Wire Gage), stranded, and tinned copper. Individual con - stall the water valve on the leaving water end of the baseboad ductors must be insulated with PVC, PVC /nylon, vinyl, teflon, or g polyethylene. An aluminum/polyester 100% foil shield and an outer heater. See Fig. 24. Observe the fluid flow direction when jacket of PVC, PVC /nylon, chrome vinyl, or Teflon with a minimum mounting the valve. Be sure to properly heat sink the valve and operating temperature range of —20° C to 60° C is required. direct the flame away from,the actuator- and valve body when sweating the valve connections. Install the leaving water tem- CONNECTION TO THE COMMUNICATION BUS perature sensor (33ZCSENCHG) on the hydronic heating coil 1. Strip the ends of the red, white, and black conductors as shown. The sensor accommodates nominal copper pipe of the communication bus cable. from 1 /2 to 1 -in. (OD sizes from 5 /8 to 1.125 in.). It should be 2. Connect one end of the communication bus cable to - secured to the pipe with the clamp supplied. If piping is larger the bridge communication port labeled COMM2 (if than 1 -in. nominal size, a field - supplied clamp must be used. connecting on a secondary bus). Use fiberglass pipe insulation to insulate the sensor assembly. When connecting the communication bus cable, a Refer to Fig. 8C and 8H to wire the modulating water valve color code system for the entire network • is recom- - and the sensor to the zone controller. Connect the leaving water mended to simplify installation and checkout. See temperature sensor to the controller using the wiring connec- • Table 3 for the recommended color code. tions shown for the SAT sensor. (NOTE: The leaving water temperature sensor replaces the SAT sensor in this application.) Table 3 — Color Code Recommendations Use 18 or 20 AWG wire for all connections. The water valve SIGNAL TYPE CCN BUS WIRE PLUG PIN actuator housing may be used as a junction box if the leaving COLOR NUMBER water temperature sensor cable is not long enough and the sen- + Red 1 sor cable must be extended to reach the controller. Ground White 2 For modulating hydronic heating applications, the default - Black 3 configuration must be changed to properly control the valve. 801 26 3. Connect the other end of the communication bus cable NOTE: The communication bus drain wires (shield) must to the terminal block labeled CCN in the zone control- be tied together at each zone controller. If the •communica- • 1er of the first air terminal. Following the color code tion bus is entirely within one building, the resulting contin- in Table 3, connect the Red ( +) wire to Terminal 1. uous shield must be connected to ground at only one single . Connect the White (ground) wire to Terminal 2: Con- point. If the communication bus cable exits from one build nett the Black ( —) wire to Terminal 3. ing and enters' another building, connect the shields • to 4. Connect additional zone controllers in a daisy chain ground at a lightning suppressor in each building where the fashion, following the color coded wiring scheme in cable enters or exits (one point only). Table 3. Refer to Fig. 25. 3 CONDUCTOR 20 AWG CABLE RED r 1 I ® + I WHITE _ _ I I -� --(Si 1 I BLACK - // �- 1 I 499 I I I I RESISTOR I I 1 (SUPPLIED W /SENSOR) I I SHIELD I (IF USED) HUMIDITY SENSOR I 1 - I I I I I I I I I I I I I RHAAO I I I 1 I I I I I I I I I I I I I 1 ' I • I I I I I GND I I I I I I I I I I I I r I r °° � i e I ° $°, ^ + lJ I I ° ni nips . I ` e i �. _ +24V 1 I - ° ° O II i l l � o 7•I 0O 2 :r6 10 ® e �17® 1 ® 0. Kli ggg � 1. 0 / a 0 ii ®®® - ILL-., � I HF23BJ042 I - \ I C V 1 I . a nn � 9 0 § i H O 000 : �a ® - e �.o ❑ - ©r ICIIdI _ ` . ❑ 1� C E 24VACICC eae° I I �\ B'6 y'� y'y e4 •J CV O 2v8 2w i SI �J �� I.� i ,II i�� °0., e q O ee q 7y IN 101211:1:1 eN1 w.1 �.., - �O O . e '.—...- P \IITIr . --- 1111 1 1 1 1117 lEi li ,/ l Fig. 22 — Humidity Sensor Wiring 27 • w • 0 w a24V RHIIAO U S6T 4 irO — GNO (J O GRID SECELOW Y U O S& Low +�v T58 \ _ILL l o (gJ V U • // \ \ \ OG� P ®T FIELD - SUPPLIED ,,, DRY CONTACT SWITCH 0 1 GND �"- --' C o- • I HF23BJ042 Carrie U Made in Switzerland — By Belimo Automation 35 in-lb(4Nm) 80...110s I I I • C ll ( +) 0 R 0 . ,GN¢j � w ,�� Not used V � 7 (•) B 0 24VAC /DC Hi t_ CCN comunications 50/60Hz N.) 3VA 2W ' oo 4 I —C CCN comunications I COfT1 , W B R HEAT1 24VAC HEAT2 24 VAC Line Voltage Yel Blu Ora Blk Red• Wht - 0 0 0 0 0 0 0- 1 TRAN t o- I TRANSFORMER I GROUND I I . TERMINAL GROUND • • LEGEND CCN — Carrier Comfort Network SAT — Supply -Air Temperature Sensor SPT — Space Temperature Sensor TRAN — Transformer • — — — — Field Wiring . Factory Wiring , - Fig. 23 — Remote Occupancy Wiring . . 33ZCSENCHG (SENSOR) FLOW 1/2" TUBE 3/4' TUBE r TUBE • -* Fig. 24 — Typical Water Valve and Sensor Installation 4 1000 FT. MAXIMUM DRAIN WIRE (TYP) Q 7� BLK (TYP) 1 GND WHT (TYP) A RED (TYP) AIIIMIM 011 II I' LI II LI LI \I & - -' - - - -- I V �\� I v ECM � r v / 7_7... qO CCN CCN CCN CCN COMM 2 _ o• o• o• 4* . ZC . ° �P, 1. ° • � ° • • 4 ° ♦ O ♦ 0 ♦ O O I — Il AIR TERMINAL UNIT (TYP) BRIDGE (RECOMMENDED) I N LEGEND CCN — Carrier Comfort Network . • ZC — Zone Controller Fig. 25 — Communication Bus Wiring START - 3. Check that all air duct connections are tight. 4. At the air terminals, check fan and system controls for Use the Carrier network communication software to start up proper operation. Verify that actuator screws are prop - and configure the zone controller. erly tightened. All set -up and set point configurations are factory-set and 5. At the air terminals, check electrical system and con - field- adjustable. nections of any optional electric reheat coil. If hot Changes can be made using the ComfortWORKS® soft- water reheat is used, check piping and valves against ware, ComfortVIEWTM software, or Network Service Tool. job drawings. The Network Service Tool is a portable interface device that al- 6. At the air terminals, make sure that all balancing lows the user to change system set -up and set points from a dampers at box outlets are in the fully open position. zone sensor or terminal control module. During start-up, the 7 If using an air handler with field- installed controls, Carrier software can also be used to verify communication make sure controls and sensors have been installed and with each zone controller. wired per manufacturer installation instructions. • For specific operating instructions, refer to the literature 8. At air handlers, verify that the motor starter and, if provided with the software. applicable, the Hand/Off/Auto (HOA) switch are Perform System Check - Out installed and wired. 1. Check correctness and tightness of all power and corn- NOTE: The HOA switch must be in the Off position. munication connections. • 2. Check that all air terminals, ductwork, and zone con- trollers are properly installed and set according to installation instructions and job requirements. 29 800 9. Check to be sure the area around the air handler(s) is elliptical damper inlet is supplied, then enter the inlet clear of construction dirt and debris. size in square inches in the Inlet Area decision. 10. Check that final filters are installed in the air han- 5. If the terminal damper closes in the CW direction, then dler(s). Dust and debris can adversely affect system no adjustment is required. Otherwise, locate the operation. damper direction configuration decision (CW Rota - 11. Verify that the zone controller and the air handler con- tion) and toggle the value to OPEN by using the space trots are properly connected to the CCN bus. bar. This • configuration decision is also located on the Terminal Service Configuration screen. . - ` •` , , ':',r; %,. , :1 6. After entering the area and rotation direction verify • ` operation of the damper. From the service tool Diag- Before starting the air source fan, make sure that dampers nostic, Maintenance Screen, • select the Zone Air at the system's air terminals are not fully closed. Starting Balance /Commissioning Table and force the Commis - the fan with dampers closed will result in damage to the sioning Mode point to Enable. •Then - select the system ductwork. Damper /Transducer Cal point and force this point to . - Enable. The controller automatically tests the actuator 12. Remember to utilize good duct design and to provide by fully closing the damper. sufficient straight duct at the inlet of the box. A mini- It checks the fully closed position to determine if the mum of three times the inlet size is recommended. control was properly mounted. It then opens the Network Addressing — Use the following method damper. The control scales the actual actuator travel when all the zone controllers are installed and powered, and the range used to a 0 to 100% open value. Finally the con SPT sensors are wired and functioning properly. This method trot will close the damper, test, and zero the pressure can be used if no addresses have been set previously. The ad- transducer. When completed, the control automatically dress of an individual controller may be set by using the removes the force from the Damper /Transducer Cal address search function on the Service, Tool software when it is point. If a failure occurs at any point during the testing, directly connected to the service port of the zone controller and the Auto Calibration point at the bottom of the screen the CCN bus is disconnected. This is the standard method of will indicate ALARM and the test will be aborted. setting the address. 7. The actuator stroke has now been calibrated for the Addresses may also be set using the Service Tool Address proper rotation. • Search Function if the zone controller is isolated from the CCN Airflow Check — After the damper transducer calibration bus. has been performed, the terminal is ready for an airflow check. Each zone controller will default to an address of 0, 140 To perform airflow check, make sure'Terminal Type, Primary when its application software is initially loaded. Since multiple Inlet Size, and Probe Multiplier settings on the Terminal Ser- controllers.will be on the same bus, a unique address must be vice Configuration screen are configured. If all of the terminals assigned to each controller before the system can operate prop- were installed with the dampers open, it is acceptable to start erly. The assignment of controller addresses will be performed the fan at this time. If it becomes difficult for the air source to through software by using the Address Search function of the provide the necessary static pressure for airflow testing, it may Network Service Tool, as follows: be necessary to calibrate the damper transducer for a majority of terminals and check temperatures and set points to be sure 1. The software recognizes that the Zone Controller's ad- dress, stored in the zone controller memory, has not been most will be controlling to less than maximum CFM when the written yet (this will be true when the unit is first powered air source is started. up on the job, or after a jumper - initiated reset). When the system fan is running and the static pressure is 2. Press the override button on the SPT (terminals J4 -14 and fairly stable access the Zone Air Balance /Commissioning table J4-12 are shorted) for 1 to 10 seconds. and force the Commissioning Mode Point to Enable. The sys- 3. The zone controller address changes from 0, 140 to 239, tem is now ready to enable maximum CFM and check if the airflow controls correctly with the maximum CFM set point. 239 for a period of 15 minutes. Read the Zone Air Balance /Commissioning table section on –+ 4. Use Network Service Tool to change the address from page 47 which describes the Zone Air Balance /Commissioning 239, 239 to a valid system address within 15 minutes. table and what adjustments can be made from this screen. If the NOTE: If the address is not changed from 239, 239 to maximum airflow function is working properly, the user can a valid system address within 15 minutes, the control- stop here and leave the rest of the airflow calibration for the air ler will revert to address 0, 140 and use of the override balance contractor. - button will cause the address function to repeat. The If working with the air balance contractor; proceed with the operator MUST actively set the address even if the minimum airflow calibration at this time. If this terminal is fan final desired address is 0, 140. powered or the terminal was installed with heat, and the heat Initial Operation and Test — Perform the following configuration was already performed, continue with the fan - and heat test while the Zone Air Balance /Commissioning table procedure: is,still being displayed. 1. Apply 24 vac power to the control. 2. Connect the service tool to the phone jack service port Fan and Heat Configuration and Test — Per- - of the controller. form the following procedure to configure and test the fan and • heat: 3. Using the service tool, upload the controller from 1. Display the Terminal Service Configuration screen to address assigned in Network Addressing section make sure the proper Terminal Type and Heat Type are above. configured. See the Configuration section to answer 4. From the Terminal Service Configuration screen, questions about the individual configurations. properly configure the damper type and inlet size. If a 2. From the Diagnostics Maintenance Screen select the round inlet is used, then enter the size directly in the Zone Air Balance /Commissioning table. Inlet Diameter decision. If a square, rectangular, or 3. Force the Commissioning Mode to Enable. • 501 30 4. If the terminal is a parallel or series powered fan box, TERMINAL TYPE — Terminal .type is the confirmation of . force the Fan Override to Enable. If the damper is open the . terminal type configuration in the SERVCONF Service it may have to be repositioned to the proper position Config table. depending on the box type. Damper percent change Terminal Type: Display Units ASCII will be displayed.;After the damper is positioned cor- Default value SINGLDUCT rectly, the fan relay should energize and the fan should Display Range SINGLDUCT, PAR run fora few seconds. . FAN, SER FAN, DUALDUCT 5. Make sure the fan runs and the Fan Override decision Network Access Read only returns to disabled to ensure the fan is wired correctly - CONTROLLING SETPOINT — Controlling Setpoint will for proper operation. display either the heating master reference or the cooling mas- 6. Force the Heating Override to Enable. If the unit is a ter reference depending upon what mode the terminal is in. The single duct unit, this must be done with the primary display will default to the heating master reference and display terminal at reheat set point. The damper will modulate the last controlling master reference when in neither heating to maintain the terminal reheat CFM. The heat outputs nor cooling. will be commanded to provide . maximum heat. If the Controlling unit is a fan powered terminal, the fan must be on. Setpoint Display Units F (C) NOTE: The CFM settings can be found under service con- Default Value: –40 figuration in the table AIRFLOW. Display Range: –40 to 245 Network Access: Read only CONFIGURATION SPACE TEMPERATURE — Space temperature from 10 kfl The following sections describe the computer configuration thermistor (Type III) located in the space. screens which are used to configure the zone controller. The Space screens shown may be displayed differently when using differ- Temperature: Display Units F (C) ent Carrier software. . Default Value -40.0 • Display Range -40.0 to 245.0 Points Display Screen — The Points Display screen ' Network Access Read/Write allows the user to view the status of the air terminal controller PRIMARY AIRFLOW — Volume of primary air calculated points. See Table 4. for pressure reading from the velocity pressure pickup probe TERMINAL MODE — The terminal mode is determined by located in the input collar of the air terminal. the equipment mode as reported by linkage and space require - Primary Airflow: Display Units cfm . ments determined by space temperature and set points. The Default Value 0 ZEROCAL and COMMISS modes are the result of the activat- Display Range 0 to 9999 ing the commissioning maintenance table to perform terminal Network Access Read/Write testing and commissioning. PRIMARY DAMPER POSITION — Damper position per - Terminal Mode: Display Units ASCII cent range of rotation determined by the transducer calibration . Default Value COOL procedure. The zone controller is designed be used on dampers Display Range HEAT, COOL, VENT, with any range of rotation. FAN AND VENT, DEHUMID, WARM - UP, REHEAT, PRESSURE, EVAC, OFF, buy Damper ZEROCAL, COMMISS Position: Display Units % open Network Access Read only Default Value 0 Display Range 0 to 100 Network Access Read only . - Table 4 — Points Display Screen DESCRIPTION DEFAULT POINT NAME Terminal Mode COOL MODE Terminal Type SINGLDUCT TYPE Controlling Setpoint -40.0 F CNTSP Space Temperature -40.0 F SPT Primary Airflow 0 cfm PRIFLO Primary Damper Position 100 % DMPPOS Supply Air Temperature 0.0 F SAT Local Heating Capacity 0 % HCAP Terminal Fan Off FAN . Relative Humidity 0 % RH RH Air Quality (ppm) 0 ppm AO Secondary Airflow 0 cfm SECFLO Primary Air Temperature 0.0 F PATEMP Heat Dsable HEAT • 31 801 SUPPLY AIR TEMPERATURE — Temperature of the air Air Quality (ppm):Display units None shown (parts per leaving the zone controller downstream of any ducted heat . million source. Measured by a 10 kS2 thermistor (Type III). This tem- Default Value 0 perature is used to control the maximum discharge air to the - Display range 0 to 5000' space when local heat is active. The sensor is not required or Network Access Read/Write recommended for cooling only terminals. If supply air temper- SECONDARY AIRFLOW — Airflow reading from the sec - ature display is required by specification, on a cooling only ondary pressure transducer, supplied with the secondary actua- box, , a heat type other .than zero must be configured. This tor, intended for dual duct and pressure control applications. •- will have no adverse affect on the operation of a cooling only terminal. Secondary . . Airflow: Display Units cfm Supply Default Value 0 • Air Temperature: Display Units F (C) Display Range 0 to 9999 Default Value . 0.0 Network Access • Read/Write Display Range -40.0 to 245.0 PRIMARY AIR TEMPERATURE — Primary ai era- Network Access Read/Write �' r tempera- LOCAL HEATING CAPACITY — When local heat at the ture from sensor (10 k0., Type III), located in main trunk of percent of heat being d elivered is deter- ment: Used for supply nka ac provided by .the. air handling equip - terminal is enabled the P g ment: Used for linkage coordination. mined by the following•formula for modulating (floating point) • • type heat - Primary Air • Capacity [(SAT - SPT)/(Maximum Duct Tem SPT Temperature: Display Units F (C) Ca p ty - [( Temp – )A Default Value 0.0 The percent of heat delivered is determined' by the follow- Display Range -40.0 to 245.0 ing for two- position hot water or staged electric heat: - Network Access Read/Write % Output Capacity = (# of active stages/Total stages) * 100 HEAT ENABLE/DISABLE — Provides enable /disable Local Heating . function for local heat at the terminal. When enabled the Local Capacity: Display Units % output capacity heat capacity function will run to operate the terminal heat. Default Value 0 Heat Display: Display Units . Discrete ASCII Display range 0 to 100 Default Value Dsable Network Access Read only Display Range Dsabe/Enable TERMINAL FAN — The commanded output for the terminal Network Access Read/Write fan on a fan powered terminal. • Modify Controller Configuration — In Service Terminal Fan: Display Units Discrete ASCII Tool software, select the desired zone controller and access the Default Value Off Modify Controller Configuration Menu screen. This configura- . Display Range Off/On tion screen is also displayed under CONFIGURE when using Network Access Read/Write ComfortWORKS® and ComfortVIEWTM software." RELATIVE HUMIDITY — Space Relative Humidity read- The Modify Controller Configuration Menu screen is used ing from the optional relative humidity sensor. Used 'by Hu- to access the Alarm Limit Configuration screen, Controller . midity control function if configured. Identification screen, Holiday Configuration screen, Linkage Relative Coordinator Configuration screen, Occupancy Configuration Humidity: Display Units % RH screen, and Set Point screen. . Default Value 0 ALARM LIMIT CONFIGURATION SCREEN — The Display Range 0 to 100 Alarm Limit Configuration screen is used to configure the Network Access Read/Write alarm settings for the zone controller. See Table 5. AIR QUALITY — Indoor air quality reading from a CO2 sen- . sor installed in the space. Used by Air Quality control function if configured. — Table 5 — Alarm Limit Configuration Screen . DESCRIPTION -. DEFAULT POINT NAME • Alarm Routing Control 00000000 ROUTING Re -Alarm Time 0 - RETIME SPT Occupied Hysteresis 5.0 F SPTHYS _ Unoccupied SPT - . Low Limit 40 F LOWLIM High Limit 99 F HIGHLIM Occupied RH Low Limit 10 % LOWLIM High Limit 99 % HIGHLIM Unoccupied RH Low Limit 0 % LOWLIM High Limit . 100 % HIGHLIM Air Duality • Low Limit 250 ppm LOWLIM High limit 1200 ppm HIGHLIM High Velocity Pressure 1.2 in. wg HIGHVP 801 32 Alarm Routing Control — This decision indicates which - Unoccupied Humidity Low Limit — This configuration de= • CCN system software or devices will receive and process fines the lowest humidity that the unoccupied space can be alarms sent by the zone controller. This decision consists of before an alarm is generated. • eight digits each can be set to zero or one. A setting of 1 indi- Unoccupied . cates alarms should be sent to this device. A setting of zero dis- Humidity Low ables alarm processing for that device. Currently the corre- Limit: Units % humidity sponding digits are configured for the following devices: first Range 0 to 100% digit - user interface software; second digit - autodial gateway Default Value 0 or Telink; fourth digit - alarm printer interface module; digits 3, Unoccupied Humidity High Limit — This configuration de- and 5 through 8 - unused. fines the highest humidity that the unoccupied space can be Alarm Routing before an alarm is genenerated. Control: Range 00000000 to 11111111 Default Value 00000000 Unoccupied Humidity High Re -Alarm Time — This decision is used to configure the num- Limit: Units % humidity ber of minutes the zone controller will wait before an alarm Range 0 to 100% condition which has not been corrected will be re- transmitted Default Value 100 on the communications network. Re alarming of an alarm con- Indoor Air Quality Low Limit — This configuration defines dition will continue until the condition no longer exists. the lowest CO2 level that the occupied space can have before Alarm Re -Alarm an alarm is generated. Time: Units Minutes Range 0 to 1440 Indoor Air Quality Default Value 0 (Disabled) Low Limit: Units PPM (implied) Range 0 to 5000 Space Temperature Occupied Hysteresis — This configura- Default Value 250 • lion defines the range above the occupied high set point and be- Indoor Air Quality High Limit — This configuration defines low the occupied low set point that the space temperature must the highest CO2 level that the occupied space can have before exceed for an alarm condition to exist during occupied hours. Space Terrrperature an alarm is generated. Occupied Indoor Air Quality • • Hysteresis: Units delta F (delta C) High Limit: Units PPM Range 0.0 to 99.9 Range 0 to 5000 PPM Default Value 5.0 Default Value 1200 Unoccupied Space Temperature Low Limit — This configu High Velocity Pressure — This configuration defines the ration defines the lowest temperature that the unoccupied space maximum velocity pressure the zone controller should see at can be before an alarm is generated. the pickup mounted in the inlet of the terminal. This is also used by the zone controller to calculate the maximum CFM the Unoccupied Space terminal will be able to control to using the terminal inlet size Temperature configured in the service configuration table. Low Limit: Units F (C) Range 0 to 255 F High Velocity Default Value 40 Pressure: Units in. wg ied Space Temperature High Limit configu- Range 0.0 to 2.0 in. wg Unoccu P P P P� �- Default Value 1.2 ration defines the highest temperature that the unoccupied CONTROLLER IDENTIFICATION SCREEN — The con - space can be before an alarm is generated. troller identification screen displays the device information for Unoccupied Space the zone controller. Temperature HOLIDAY CONFIGURATION SCREENS — The zone High Limit: Units F (C) controller has configuration screens for up to 12 different holi- Range 0 to 255 F day schedules. Highlight the holiday name on the screen and Default Value 99 press enter to configure the holiday schedule. A separate screen Occupied Humidity Low Limit — This configuration defines is used to ENTER the Holiday schedule. the lowest humidity that the occupied space can be before an Start Month — The start month is the month in which the hol- alarm is generated. Occupied Humidity iday starts. Months are represented by numbers with 1 repre- P ty senting January, 2 February, up to 12. Low Limit: Units % humidity Range 0 to 100% Start Month: Range 1 to 12 Default Value 10 Default Value 1 Occupied Humidity High Limit — This configuration de- Start Day — The start day is the day on which the holiday will fines the highest humidity that the occupied space can be be- start. fore an alarm is generated. Start Day: Range 1 to 31 Occupied Humidity Default Value 1 High Limit: Units % humidity Duration — Length of time, in days, that the holiday will last. Range 0 to 100% Duration: Range 0 to 365 Default Value 99 Default Value 0 33 801 LINKAGE COORDINATOR CONFIGURATION Air Source Bus and Element Number — The Air Source Bus SCREEN — The Linkage Coordinator Configuration screen and Element Number configurations define the address of the allows the user to set the linkage coordinator configuration set - air source providing conditioned air to the zones controlled by tings. See Table 6. the linkage coordinator. If the address is left at zero, the Link - Linkage Master Zone — This decision defines if the zone age coordinator will look for a primary air sensor to determine controller will function as a Linkage Coordinator (Linkage the equipment mode. If no primary air sensor is installed, or the Master) for itself and other zones. sensor fails, the Linkage Coordinator will default the air source If the zone controller is to use a supply air sensor for stand- mode to Cooling. alone operation, this configuration must be configured to No Air Source and the number of Zones to 1. Bus Number: Range 0 to 240 If the zone controller will use its primary air sensor to deter- Default Value 0 mine the air handler mode for a number of zone controllers, Air Source configure this configuration to Yes, input the number of zones, Element Number. 0 to 240 and leave the air source decisions at the default values of zero. ' Default Value 0 If this zone controller will communicate linkage informa- Static Pressure Reset — Air systems designed with diversity tion with an air source, configure this configuration to Yes. The (airflow required with all zones at maximum cfm exceeds de- number of zones must be configured and the address of the air sign capacity of air handler) are capable of providing enough source entered. CFM to all zones on days when conditions meet the demand at Linkage design static. At other times, the air system does not require the Master Zone: - Range Yes/No design static to meet the load requirements. Default Value No Static pressure reset allows the static pressure set point on Number of Zones — This decision defines the number of zone the air source to be reset whenever the system load is reduced controllers (including itself) for the Linkage Coordinator to from the design maximum. The zone controller will then moni- scan and include as part of the average temperature, set points, tor damper positions. When the system dampers are modulat- and occupancy information to the air source. The address of the ing at lower damper positions due to the higher static, the static zone controller functioning as a Linkage Coordinator must be pressure will then be reset to a lower value allowing the damp - larger than the number of zones configured. The zone control- ers to open more. This allows the system to automatically make ler will scan addresses less than its own, including information adjustments to the static pressure and optimize performance of for as many zones as are configured. Other zone controller con - the fan which will reduce energy consumption. figured as linkage coordinators will also be included, so it is The linkage coordinator monitors the position of all damp - possible to have zones scanned by more than one linkage coor- ers in its system. When any zone's maximum damper position dinator. Therefore care must be taken in addressing to prevent reaches the Reset Maximum Damper Position, the linkage co- overlapping systems, unless overlapping systems is necessary. ordinator will reduce the value of the reset variable. In large buildings the use of bridges and multiple busses is rec- ommended to improve communication and provide system The Maximum Damper Position and Static Pressure Reset differentiation. values can be viewed on the Linkage maintenance screen. Number of NOTE: The static pressure set point configured in the air Zones: Range I to 128 source should be the desired maximum (zero reset) static Default Value 1 pressure. - Table 6 — Linkage Coordinator Configuration Screen DESCRIPTION I DEFAULT I POINT NAME Zone Linkage Linkage Master Zone No MZENA Number of Zones 1 NSYSTZ Air Source Bus Number 0 ASBUSN Air Source Element Number 0 ASELEMN Static Pressure Reset Reset Minimum Damper Position 50 % MINDP Reset Maximum Damper Position 80 % MAXDP Maximum Reset 0.0 in. wg SPMAX SP Reset Variable Name (blank) SPRVAR - CCN Linkage Data CCN Variable Name (blank) CCNVAR CCN Function Configuration 3 CCNFUNC _ Data Transfer Rate 10 minutes DATARATE CCN Output Point (blank) CCNOUTP Destination Bus Number 0 DESTBUSN Destination Element Number 0 DESTELEN Temperature Sensor Grouping Temperature Sensor Mode 1 BRD_RECV Temperature Sensor Configuration 1 SENSCFG Broadcast Device ID 1 BRDDEVID 801 34 Reset Minimum —> Temp Sensor Grouping— Each - ComfortIDTM controller.has Damper Position: Units % the capability to broadcast the associated space temperature Range 0 to 99 sensor's data or listen to another controller's sensor data over Default Value 50 the network. All controllers sharing the same sensor must be Reset Maximum installed on the same CCN bus. Damper Position: Units % There are three configuration decisions that must be config- Range 0 to 99 ured in order to share sensors. The Temp Sensor Mode is used , Default Value 80 to specify if a controller will use its own local sensor, broadcast Maximum Reset: Units in. wg its local sensor, or listed to another controller's sensor broad - Range 0.0 to 5.0 cast. The Temp Sensor Config is used to specify if the control - Default Value 0.0 ler is sharging the space temperature information only- or the space temperature and temperature offset slidebar information. Static Pressure Reset Static Name: Units ASCII (8 characters) The Broadcast Device ID decision is used to specify which Range A 9 controller number a zone will listen for when configured to R Value * receive another controller's broadcast. *To use Static Pressure Reset with a Comfort System Mod Sensor Mode: Units none A irManager, configure the variable name to SPRESET. Range 1 = Local Sensor, Currently, to make use of the static reset information, a cus- 2 = Broadcast, 3 = Listen tom program must be written in a Comfort Controller to read - Default Value I the reset value and change the set point of the static pressure Temp Sensor control in the air source. Use this configuration to create a van- Con fig: Units none able name (Static Pressure Reset Value). See the application Range 1 = SPT, 2 = SPT and manual for information about creating this custom program. offset The Comfort System AirManagerTM control has an internal Default Value 1 SPRESET variable which functions to accept the static pres- Broadcast sure reset value from the linkage coordinator (refer to the Air Device ID: Units None Manager manual for configuration setup). Range 1 -239 -4 CCN Linkage Data — A zone controller configured as a . Default Value 1 Linkage master has the ability to poll its slaves and collect the OCCUPANCY CONFIGURATION SCREEN — The Oc- high, low or average value of any variable within its slaves. cupancy Configuration screen is used to set the occupied Once the high, low or average is determined, the master can schedule. See Table 7. - then transfer that value to a configured bus number, element number and point name. Typically this feature is used to deter - Manual Override Hours — The Manual Override Hours deci- mine a system's highest indoor air quality reading. sion is used to command a timed override by entering the num- In order to utilize this feature the CCN Variable Name being ber of hours the override will be in effect collected from the slaves must be supplied. The data transfer If the occupancy schedule is occupied when this number is rate must be specified and whether the high, low, or average downloaded, the current occupancy period will be extended by value is being determined. After the value has been deter - the number of hours downloaded. mined, a valid point name and CCN address to transfer the If the current occupancy period is unoccupied when the oc- value to must be entered. cupancy override is initiated, the mode will change to occupied CCN Variable for the duration of the number of hours downloaded. Name: Units ASCII (8 Characters) If the occupancy override will end after the start of the next Range A -Z, 0 -9 occupancy period, the mode will transition from occupancy Default Value (blank) override to occupied without becoming unoccupied, and the CCN Function occupancy override timer will be reset. Config: Units none An active occupancy override or a pending occupancy over - Range 0 = none, 1 = average, ride may be canceled by downloading a zero to this configura- 2 = low, 3 = high tion. Once a number other than zero has been downloaded to Default Value 3 this configuration any subsequent downloads of any value oth- Data Transfer er than zero will be ignored by the zone controller. Rate: Units minutes Manual Override Range 1 -15 Hours: Units hours Default Value 10 Range 0 to 4 • CCN Output Default Value 0 Point: Units ASCII (8 Characters) Occupancy Scheduling — For flexibility of scheduling, the Range A -Z, 0 -9 occupancy programming is broken into eight separate periods. Default Value (blank) For each period the scheduling, the active days of the week, Destination Bus occupied start time, and occupied stop time needs to be Number: Units none configured. Range 0 -239 Day of Week — This configuration consists of eight fields Default Value 0 corresponding to the seven days of the week and a holiday Destination field in the following order: Monday, Tuesday, Wednesday, Element Number: Units none Thursday, Friday, Saturday, Sunday, Holiday. A separate con - Range 0 -239 (0 = disabled) figuration screen is used. Default Value 0 35 801 Table 7 = Occupancy Schedule Information Screen DESCRIPTION DEFAULT POINT NAME Manual Override Hours 0 OVRD Period 1: Day of Week 11111111 DOW1 . Period 1: Occupied From 00:00 OCC1 Period 1: Occupied To 24:00 UNOCC1 Period 2: Day of Week 00000000 DOW2 Period 2: Occupied From 00:00 OCC2 Period 2: Occupied To 24:00 UNOCC2 Period 3: Day of Week 00000000 DOW3 Period 3: Occupied From 00:00 OCC3 Period 3: Occupied To 24:00 UNOCC3 • Period 4: Day of Week 00000000 DOW4 Period 4: Occupied From 00:00 • OCC4 Period 4: Occupied To 24:00 UNOCC4 Period 5: Day of Week 00000000 , DOW5 Period 5: Occupied From 00:00 ' OCC5 Period 5: Occupied To 24:00 , •UNOCCS Period 6: Day of Week 00000000 DOW6 Period 6: Occupied From 00:00 OCC6 Period 6: Occupied To 24:00 UNOCC6 Period 7: Day of Week 00000000 DOW7 Period 7: Occupied From 00:00 OCC7 Period 7: Occupied To 24:00 UNOCC7 Period 8: Day of Week 00000000 DOW8 Period 8: Occupied From 00:00 ' OCC8 Period 8: Occupied To 24:00 UNOCC8 If a 1 is configured in the corresponding place for a certain Occupied Cool — The Occupied Cool set point is used to con - day of the week, the related "Occupied, from" and "Occupied figure the cooling set point for the zone controller during Occu- to" times for that period will take effect on that day of the pied mode. week. If a 1 is placed in the holiday field the related times will Occupied Cool: Units F (C) take effect on a day configuredas a holiday. A zero means the Range 45.0 to 99.9 schedule period will not apply to that day. Default Value 74.0 Period (1 -8): Unoccupied Heat — The Unoccupied Heat set point is used to Day of Week: Range 0 or 1 configure the heating set point for the zone controller during Default Values 11111111 for period 1, Unoccupied mode. 00000000 for periods 2 -8. Unoccupied Heat: Units F (C) Occupied From — This field is used to configure the hour and Range 40.0 to 90.0 minute, in military time, when the mode for the zone controller Default Value 55.0 becomes occupied. Unoccupied Cool — The Unoccupied Cool set point is used to Period (1 -8): configure the cooling set point for the zone controller during Occupied from: Units Hours: Minutes Unoccupied mode. Range 00:00 to 24:00 Unoccupied Cool: Units F (C) Default Value 00:00 Range 45.0 to 99.9 Occupied To — This field is used to configure the hour and Default Value 90.0 minute, in military time, when the occupied mode for the zone —> Occupied High Humidity — The Occupied High Humidity controller becomes unoccupied. set point is used to configure the humidity set point for the zone Period (1 -8): controller if optional zone humidity control (dehumidification) Occupied from: Units Hours: Minutes is used. Range 00:00 to 24:00 Occupied High Humidity: Units % Humidity Default Value 24:00 Range 0.0 to 100.0 SET POINT SCREEN — The Set Point screen is used to Default Value 60.0 modify the zone controller set points. See Table 8. —' Unoccupied High Humidity — The unoccupied high humidi- Occupied Heat — The Occupied Heat set point is used to con- ty set point is used to configure the unoccupied humidity set figure the heating set point for the zone controller during Occu- point for the zone controller if optional zone humidity control pied mode. (dehumidification) is used. • Occupied Heat: Units F (C) Unoccupied Range 40.0 to 90.0 High Humidity: Units % humidity Default Value 70.0 Range 0 to 100 Default Value 100 1001 36 ' Air Quality — The Air Quality set point is used to configure Cool Minimum (PI) — This configuration is the minimum ' ' the IAQ set point for the zone controller if optional controlled , airflow - the terminal will-control to•when the equipment is in - ventilation support is used. Cooling mode. (or Fan Only mode) or free cooling. The Air Quality Units none shown (ppm requirements for cooling must be at a minimum, or the terminal (ppm): implied) is a fan powered terminal and the space requirements are for Range 0 to 5000 heat. Default Value 850 Cool Minimum: Units CFM •• Delta Airflow — The Delta Airflow set point is used to con- Range 0 to 9999 (Limited by figure the Delta Airflow set point for the zone controller if the the High Velocity pressure limit alarm) zone pressure control option is used. If a negative pressure is Default Value 0 desired, configure the value as a positive delta. Cool Maximum (P11 — This configuration is the maximum Delta Airflow: Units cfm airflow the terminal will control to when the equipment is in Range -9999 to 9999 Cooling mode (or Fan Only mode) or free cooling and the Default Value 0 space requirements for cooling are at a maximum. Service Configuration Selection Screen — The Cool Maximum: Range CFM tion Selection screen is a menu of Service the High 0 to a limit (Limited by Service Configuration the High Velocity pressure limit alarm) screens which can be accessed by the user. The following Default Value 4000 screens are available: Airflow Service Configuration, Terminal Terminal Reheat (PI) — This configuration is for single duct Service Configuration, Option Service Configuration, and Sec- ondary Damper Service Configuration. units with ducted reheat. The desired airflow is configured at AIRFLOW SERVICE CONFIGURATION SCREEN -- which the reheat will provide optimum performance. This val.- The Airflow Service Configuration Table is used to cone ue is compared to the Minimum Cool value and the greater of the two values is used to determine the airflow set point. the pressure independent and backup pressure ,dependent set points. See Table 9. Terminal Reheat: Units CFM Independent — Pressure Independent set points Range 0 to e limit (Limited by Pressure Inde p p �n p the High Velocity pressure limit alarm) should be configured for pressure independent- operation ' Default Value 0 applications. - Table 8 — Set Point Screen DESCRIPTION I DEFAULT 1 POINT NAME Set Points Occupied Heat 70.0 F OHSP Occupied Cool 74.0 F OCSP Unoccupied Heat 55.0 F UHSP Unoccupied Cool 90.0 F UCSP Occupied High Humidity 60.0 %- ORHH Unoccupied High Humidity - 100 % URHH Air Quality (ppm) • 850 ppm AOSP Delta Airflow 0 cfm - • DCFM Table 9 — Airflow Service Configuration Screen ' DESCRIPTION I DEFAULT I POINT NAME Pressure Independent Cool Minimum 0 cfm COOLMIN Cool Maximum 4000 cfm COOLMAX Terminal Reheat 0 cfm REHEAT Heat Minimum 0 cfm HEATMIN . Heat Maximum 4000 cfm HEATMAX Parallel Fan On 0 cfm FNONCFM Dual Duct CV Airflow 4000 cfm DDCVFLOW Pressure Dependent Cool Minimum Position 0 % CMINPOS • Cool Maximum Position 100 % CMAXPOS Reheat Minimum Position 0 % REMINPOS Heat Minimum Positon 0 % HMINPOS Heat Maximum Position 100 % HMAXPOS Deadband Percent 12.5 % DB PCT 37 1001 Heat Minimum (PI) — This configuration is the minimum Reheat Minimum Position (PD) — This configuration is for airflow the terminal will control to when the equipment mode single duct units with ducted reheat. Configure the desired is Warm -Up or Heat. If the terminal is not configured for VAV damper position at which the reheat will provide optimum per - central heating this is the only airflow the terminal will control formance. This value is compared to the Minimum Cool value to for these equipment modes. and the greater of the two values is used to determine the Heat Minimum: Units CFM damper position. - Range 0 to 9999 (Limited by Reheat Minimum the High Velocity pressure limit alarm) Position: Units % • Default Value 0 Range . 0 to 100 Heat Maximum (PI) — This configuration is used to config- Default Value 0 ure'the maximum airflow at which the zone controller will op- Heat Minimum Position (PD) — This configuration is the erate if VAV central heat is configured to yes. If the equipment Minimum damper position the terminal will control to when mode is heat or. warm -up, and demand in the space is for the equipment mode is Warm -Up or Heat. If the terminal is not heat, the zone controller will calculate the proper airflow need- configured for VAV central heating this is the only position the ed to achieve space temperature set point (operating between terminal will control to for these equipment modes. • the Heat Min and Heat Max). Heat Minimum - Heat Maximum: - Units ' CFM Position: Units % Range - 0 to 9999 (Limited by Range 0 to 100 • the High Velocity pressure limit alarm) Default Value 0 Default Value 4000 Heat Maximum Position (PD) — This configuration is used Parallel Fan On (PI)•— .This configuration is used to define to configure the maximum damper position at which the zone the primary airflow setting below which a parallel fan terminal controller will operate if VAV central heat is configured to yes. should energize its fan. The setting should be used to allow a If the equipment mode is Heat or Warm -Up and the demand in low volume of primary airflow to be better diffused into the the space is for heat the zone controller will calculate the prop - space. er damper position needed to achieve space temperature set Parallel Fan On: Units CFM point, operating between the Heat Min and Heat Max. Range 0 to 9999 (Limited by Heat Maximum the High Velocity pressure limit alarm) Position: Units % Default Value 0 Range 0 to 100 Dual Duct CV Airflow (PI) — This configuration defines the Default Value 100 Dual Duct, constant volume, total airflow set point. Deadband Percent — This configuration is used to configure Dual Duct the Deadband Percent that the airflow will operate with. Airflow: Units - CFM Deadband Range 0 to 9999 (Limited by Percent: Units % the High Velocity pressure limit alarm) . Range 0.0 to 100.0 . Default Value 4000 Default Value 12.5 Pressure Dependent — Pressure Dependent (PD) set points TERMINAL SERVICE CONFIGURATION SCREEN — should be configured for backup pressure dependent operation, The Terminal Service Configuration screen lists the main con - if an operating problem with the pressure transducer occurs. figuration settings for the air terminalcontroller. See Table 10. Terminal Type — This configuration is used to indicate the IMPORTANT: Pressure dependent settings are terminal type that the zone controller is installed on. A 1 is for included for use only in the event of a pressure trans- Single Duct terminals, a 2 is for Parallel Fan terminals, a 3 is ducer failure. The inclusion of these configuration set- for Series Fan terminals, and a 4 is for Dual Duct applications. tings does not indicate that Canner is endorsing this Terminal Type: Range 1 to 4 product for pressure dependent operation. In the case Default Value 1 of a pressure sensor failure, the zone controller will broadcast a pressure sensor failure message on the Primary Inlet Size —The Primary Inlet Size configuration is CCN bus. These configurations may be used by a ser- used to input the inlet diameter of the terminal if used with a vice technician to put the terminal in pressure depen- round inlet. The Inlet Area configuration is used for oval or dent mode until the zone controller can be replaced. rectangular inlets. The zone controller will use the larger value for CFM calculations if both values are configured. Cool Minimum Position (PD) — This configuration is the NOTE: Carrier sizes 12, - 14, and 16 are oval. minimum damper position the terminal will control to when Primary Inlet Size the equipment mode is Cooling (or Fan Only), or free cooling (Inlet Diameter): Units Inches and the space requirements for cooling are at a minimum. Range 3.0 to 24.0 _ Cool Minimum Default Value 6.0 . Position: Units % Inlet Area — The Inlet Area configuration is used if the termi- Range . 0 to 100 nal has an oval or rectangular inlet. The Primary Inlet Size Default Value 0 • configuration is used for round inlets. The zone controller will Cool Maximum Position (PD) — This configuration is the use the larger value for CFM calculations if both values are maximum damper position the terminal will control to when configured. the equipment mode is cooling (or fan only), or free cooling Inlet Area: Units Square Inches and the space requirements for cooling are at a maximum. Range 0.0 to 500.0 Cool Maximum Default Value 0.0 Position: Units % Range 0 to 100 Default Value 100 38 • • Table 10 — Terminal Service Configuration Screen DESCRIPTION I DEFAULT . I POINT NAME .- COOLING . ., Terminal Type 1 ' TERMTYPE Primary Inlet Size Inlet Diameter 6.0 in. RNDSZ . Inlet 0.0 in. SQA Probe Multiplier 2.443 PMF Calibration Gain 1.000 CAL_GAIN Offset 0 cfm OFFSET Damper • Proportional Gain 30.0 KP Integral Gain 5.0 KI Derivative Gain 0.0 KD Starting Value 20 % STARTVAL CW Rotation Close DMPDIR Pressure Independent Yes PRESIND HEATING Heat Type 0 HEATTYPE VAV Central Heating Yes CENHEAT Heating Proportional Galn 8.0 KP Integral Gain 3.0 KI Derivative Gain 0 0 KD Starting Value 80 F STARTVAL Ducted Heat Yes DUCTHEAT Maximum Temperature 110 F MAXTEMP Number of Electric Heat Stages 1 STAGES Heat On Delay - 2 HONDEL Fan Off Delay • 2 FNOFFD 2- Position Heat Logic Normal HEATYPE SPT Trim 0 0 F SPTTRIM SAT Trim , 0 0 F SATTRIM Remote Contact Configuration Close . • RMTCFG –4 Probe Multiplier — This configuration is used to input a factor that gives an airflow value of 820 cfm at a velocity pressure for the velocity pressure probe installed in the terminal inlet. reading of 1 in. wg. To determine the PMF for the terminal: Most inlet probes will have some aerodynamic characteristics 1. Determine duct area. that will affect the differential pressure output from the probe. radius of duct = diameter of duct/2 The formula used by the Comfort[DTm controller for calculat- radius = 8- in. /2 -in. ing the airflow (cfm) is based on measuring velocity with a radius = 4 -in. Pitot tube probe. A PMF (Pitot measurement factor) is required Area of circular duct = fir in the calculation for different probes. Because various probe Area = 3.14159 x 4 characteristics are different, the PMF is used to determine the Area = 3.14159 x 16 correct airflow based on the type of probe installed. The PMF Area = 50.26 -in. will compensate for the difference between Pitot -type probes Area must be in ft and the actual probe installed. 50.26 -in. /(144 -ft = 0.34906 ft The, default PMF value of 2.273 is the correct value to use 2. Determine K factor. when the zone controller is used with a Carrier probe in a K factor = (820 cfm/0.34906 ft Carrier air terminal. For terminals and probes supplied by other K factor = 2349 fpm manufacturers, the PMF must be calculated and. entered into 3. Determine PMF. the zone controller configuration in order to correctly measure PMF = 4005 m fpm ) f 2 airflow. ( PMF = 2.907 To determine the correct PMF value, there are several meth Another way to determine the probe constant for a probe ods depending on the data supplied by the terminal manufac without documentation is to measure the velocity pressure with tuner: The manufacturer may supply . a "K factor" or may sup - �' P ply a chart of velocity pressure vs. airflow for the terminal. The a Magnahelic gage. Open the damper and adjust the static pres • K factor is the actual airflow velocity at a velocity pressure sure or open the damper until you have one inch of velocity reading of 1 in. wg for the probe. This value is in ft/min and pressure on the Magnahelic gage. Measure the total CFM of air • can be used to calculate the PMF. When the K factor is entered being delivered. The CFM just measured divided by the inlet • into the following equation, it is compared to the value of 4005, area in square feet should equal the K factor for the formula. which is the K factor for a Pitot tube probe: Now use the K factor that was empirically derived to determine the probe multiplier. PMF = (4005/K FACTOR)2 Probe Multiplier: Range 0.250 to 9.999 If a chart is supplied by the manufacturer instead of the K Default Value 2.443 factor, then the K factor can be calculated from the chart using Calibration Gain — Air terminal testing by industry standards the following formula: is done with straight duct, upstream of the terminal. Since some K FACTOR = (cfm at 1 -in. wg) /(duct area ft2) applications do not get installed in this manner, the actual air - As an example, an air terminal with an 8 -in. round inlet is flow from the terminal at balancing may not equal the reading used. The terminal manufacturer has provided an airflow chart from the zone controller. 39 303 The calibration gain is used for the fine tuning adjustments 'Start Value: Units % which might need to be made to the airflow calculation. This Range 0 to 100 number is calculated automatically by the zone controller after Default Value 20 input to the air balance maintenance screen, or it can be input Clockwise Rotation — This configuration is used to define manually at this screen. For ease of use it is recommended to what effect a clockwise rotation of the actuator will have on the use the Air Balance Maintenance screen to determine this num- damper. If the actuator rotates clockwise to closed position, the ber. The Air Balancing Maintenance screen will cause the val- configuration should be set to Close. If the actuator rotates ue to be updated during the balancing procedure. clockwise to open, the configuration should be set to open. If the Calibration Gain must be configured manually, it is This configuration is used to change the rotation of the actuator determined as a percentage up or down that the CFM indicated so that the damper transducer calibration will work properly. will be offset. A number of .95 will cause the maximum air- The actuator does not have to be re- installed nor any switches flow calculated to be reduced to 95% of the value. A Calibra- changed to reverse the action. tion Gain of 1.00 will cause no change. A number of 1.05 Clockwise would cause readings to become 5% higher. Rotation: Range Close/Open The Calibration Gain is adjusted on the Air Balance Mainte- . Default Value Close . nance screen when performing the Maximum Airflow calibra- Pressure Independent — This configuration defines if the ter - tion and will have the greatest effect on the airflow at maxi- minal will function in the pressure independent or pressure de- mum CFM. Any error in reading at minimum airflow is adjust- pendent mode. ed by calculating the Offset configuration value. After NOTE: Pressure dependent mode should only be used in an performing the air balance using the Air Balance Maintenance screen it is a good idea to upload and save the Calibration Gain emergency, if the pressure sensor is not functioning. • and Offset values. Pressure Calibration Gain: Range 0.000 to 9.999 Independent: Range No/Yes • . Default Value 1.000 Default Value Yes _ Offset — The Offset configuration is included for precision Heat Type — This configuration is used to define the type of applications where the minimum airflow is critical and not ze heat installed on the terminal. A 0 is equal to None. A 1 is ro. This configuration indicates the amount of CFM the trans- equal to Modulating/VAV. A 2 is equal to Two, Position. A 3 is ducer is off by, at minimum airflow, during the minimum air- equal to staged Electric. A 4 is equal to Modulating/CV. flow test on the air balance screen. This'configuration should Heat Type: Range 0 to 4 not be used to zero the airflow transducer since an auto zero Default Value 0 test is included on the air balance screen and is also automati- VAV Central Heating — The VAV Central Heating configura- cally performed each time the equipment fan is disabled (or tion is used if the air source has the ability to provide heat and every 72 hours for systems which run the fan continuously). the terminal is required to modulate, using the heat minimum After performing the air balance testing using the Air Balance and heat maximum airflows, when the air source is in the heat Maintenance screen it is a good. idea to upload and save the mode. If this variable is set to No, the terminal will use its Calibration gain and Offset values. The cfm will be offset by available local heat to heat the zone at all times. the value entered in the Minimum Cfm variable and will zero VAV Central at the value entered in the Maximum Cfm variable. There will Heating: Range No/Yes be a linear relationship between the two set points. Default Value Yes Offset: Units cfm Heating Loop Parameters — The heating loop gains and start Range -250 to 250 value define how the terminal will respond to deviations in Default Value 0 measured space temperature in order to control to the heat set Damper Loop Parameters — The loop gains and start value point. define how the terminal will respond to deviations in measured The Proportional Gain is calculated each time the space CFM in order to control to the airflow set point. temperature is compared to the heat set point. As the error The Proportional Gain is calculated each time the airflow is from set point goes to zero, the Proportional Gain will also go compared to the active airflow set' point. As the error from set to zero. . - point goes to zero, the proportional term will also go to zero. The Integral Gain is a running summation of all integral The Integral Gain is a running summation of all integral terms since the loop started. This has the affect of trimming off terms since the loop started. This has the effect of trimming off any offset from set point which might occur if only the Propor- any offset from the set point which might occur, if only the pro- tional Gain existed. Normally a proportional loop with no Inte- portional term existed. Normally a proportional loop with no - gral Gain would require 'frequent adjustments of the starting integral term would require frequent adjustments of the starting _ to eliminate the offset as loading conditions on the room value to eliminate the offset as static pressure and other condi change. tions change. The Derivative Gain is not needed. This term tends to nulli- The Derivative Gain is not needed. The Derivative Gain fy large changes in the Proportional Gain for dampened would tend to nullify large changes in the Proportional Gain for response. dampened response. These large changes in the Proportional Heating Loop Parameters Gain do not tend to happen for this type of control. Proportional Gain: Range 00.0 to 99.9 Damper Loop Parameters Default Value 8.0 Proportional Gain: Range 00.0 to 99.9 Default Value 30.0 Integral Gain: Range 00.0 to 99.0 Default Value 3.0 Integral Gain: Range 00.0 to 99.0 Default Value 5.0 Derivative Gain: Range 00.0 Default Value 0.0 Derivative Gain: Range 00.0 Default Value 0.0 801 40 ' .Start Value: Units F (C) _ Space Temperature Trim — This configuration is used to trim • Range 40 to 125 a space sensor which might• need calibration. For example, if ' Default Value 80 the temperature displayed is two degrees' above the value mea- Ducted Heat — The Ducted Heat configuration is used to con- sured with calibrated test equipment, input a value of -2:0. figure the terminal for ducted heat. If a local heat source is in Space Temperature . . the duct and requires airflow to provide heat, set the Ducted . Trim: . ". Units delta F (delta C) Heat configuration for yes. Range –9.9 to 9.9 . : Ducted Heat Range No/Yes : Default Value 0.0 . Default Value Yes Supply Air Temperature Trim — This configuration is used Maximum Duct Temperature — This configuration is used to to trim a supply air sensor which might need calibration. For configure the maximum supply -air temperature desirable for example, if the temperature displayed is two degrees above the heating the space. This will cause the heat to be modulated or value measured with calibrated test equipment, input a value of cycled using this value as the maximum temperature of the air –2.0. to be supplied. Supply Air Temperature Maximum Duct Trim: Units delta F (delta C) Temperature: Units F (C) Range –9.9 0.0 9 to 9.9 Range 40 to 200 Default Default Value 110 - Remote Contact Config — The remote timeclock contact in- Number of Electric Stages — This configuration is used to put can be configured as a normally open or normally closed define the number of stages of electric heat controlled by the contact. When the timeclock input is 'On' the zone will follow zone controller. it's local occupancy schedule. When the timeclock input is • Number of 'Off' the zone will be forced into unoccupied state. Electric Stages: Range 1 to 3 Remote Contact • Default Value 1 Config: Range Close /Open Default Value Close Heat On Delay — The Heat On Delay configuration is used to OPTIONS - SERVICE CONFIGURATION SCREEN — define a delay from the time a parallel terminal fan is started until the heat is activated. The Options Service Configuration screen is used to configure Heat On Delay: Units minutes the service options of the air terminal controller. See Table 11. Range 1 to 60' Occupancy Schedule Number — The Occupancy Schedule Default Value 2 Number defines what Occupancy schedule the zone controller Fan Off Delay — The Fan Off Delay configuration is used to will use. Occupancy Schedule 64 is a local schedule. Occupan- define a delay time. The delay time is from when the heat is de cy Schedules 65 to 99 are global schedules. activated (in a parallel terminal) until the parallel fan is deacti- Occupancy Schedule vated. This allows the fan to circulate air and remove the resid- Number: Range 64 to 99 ual heat from the heat source. - Default Value 64 Fan Off Delay: Units minutes Global Schedule Master - The Global Schedule Master con - Range 1 to 15 figuration allows the Occupancy Schedule to be used as a Glo- De fault Value 2 bal Schedule Master (Occupancy Schedules 65 -99). Two - Position Heat Logic — This configuration is used for Global Schedule controlling a normally closed or normally open valve for hot Master: Range No/Yes water. Use normal logic if the valve is normally closed. Use in- Default Value No verted logic,if the valve is normally open. Two Position - Heat Logic: Range Normal/Invert Default Value Normal Table 11 — Options Service Configuration Screen DESCRIPTION DEFAULT POINT NAME Occupancy Schedule Number 64 SCH Global Schedule Master No GSM Override 00:00 OVR Broadcast Acknowledge No BCACK Set Point Group Number 0 SETT Global Set Point Master No GSTM Maximum Offset Adjust 2 F LIMT Control Options 0 CTLOPT Humidity Proportional Gain 1.5 KP Integral Gain 0.30 KI Maximum Output Value 100.0 cfm MAXOUT Alr Quality Proportional Gain . 0.10 KP Integral Gain 0.03 KI Maximum Output Value 100.0 cfm MAXOUT AQ Low Voltage 0.0 AQINLO AQ High Voltage 10.0 AQINHI AQ Low Reference 0 ppm AQLO AQ High Reference 2000 ppm AQHI 41 801 - • Override — The Override parameter is used to configure the Integral Gain: Range 0.00 to 9.99 number of hours and minutes the override will be in effect. The Default Value 0.30 user initiates override by pressing the override button on the space temperature sensor. This will cause the schedule to enter Maximum Output into the Occupied mode. If global scheduling is used, all zones Value:. Range 0.0 to 100.0% (max cool ' using the global schedule will enter Occupied mode. Pushing cfin) . the override button,during Occupied mode will have no effect. Default Value 100.0 If the occupancy override is due to end after the start of the Indoor Air Quality Control — These configuration values de- - , next occupancy period, the mode will transition from occupan- fine the calculation parameters for determining the airflow cy override ,to occupied without becoming unoccupied, and the needed to correct a high incidence of air pollution contami- occupancy override timer will be reset. nants in the space, such as CO2. The Maximum Output Value is NOTE: If using the tenant billing function, the override measured in percentage of nominal terminal cfm. • • hours set point must be configured between 1 and 3 hours. Proportional Gain:Range 0.00 to 9.99 Override: Units , Hours: Minutes Default Value 0.10 Range 00:00 to 24:00 Integral Gain: Range 0.00 to 9.99 .: Default Value • . 00:00 Default Value 0.03 • ' ' Broadcast Acknowledger — This configuration defines if the zone controller will be used to acknowledge broadcast messag- Maximum Output es on the CCN bus: One broadcast acknowledger is required Value: Range 0.0 to 100.0% (max cool per bus, including secondary busses created by the use of a .. Default Value 100.0 bridge. Broadcast . • -) LAO Sensor Low Voltage — This configuration defines the • • Acknowledger: Range • No/Yes lowest voltage ,which should be read from the air quality Default Value No V sensor. . Set Point Group Number — The Set Point Group Number is IAQ Sensor used to define the current zone controller as a part of a group of Low Voltage: Range 00.0 to 10.0 zone controllers which share the same set points. All zone con- Default Value 0.0 trollers with the same Set Point Group Number will have the IAQ Sensor High Voltage — This configuration defines the same set points. The set points are broadcast to the group by the highest voltage which should be read from the air quality sen- zone controller defined by the Global Set Point Master config- sor. uration. A value of 0 is a local schedule. Values 1 to 16 are used IAQ Sensor for global scheduling. High Voltage: Range .00.0 to 10.0 . Set Point Default Value 10.0 Group Number: Range 0 to 16 IAO Low Reference — This configuration defines the value Default Value 0 in parts per million which correlate to the low voltage reading Global Set Point Master — This configuration defines if the from the air quality sensor. current zone controller will broadcast its set point values to the IAQ Low other zone controllers which are made part of the same group Reference: Units ppm (parts per million) by configuring the Set Point Group Number. Range 0 to 5000 Global Set Point Default Value 0 Master: Range No/Yes IAQ High Reference — This configuration defines the value Default Value No in parts per million which correlate to the high voltage reading Maximum Offset Adjustment — This configuration deter- from the air quality sensor. mines the maximum amount that the set point will be biased IAQ High (up or down), by adjusting the slide bar on the space tempera- Reference: Units ppm (parts per million) cure sensor (if installed). Range 0 to 5000 Maximum Offset Default Value 2000 Adjustment: Units delta F (delta C) . Range 0 to 15 . SECONDARY DAMPER SERVICE CONFIGURATION Default Value 2 SCREEN - The Secondary Damper Service Configuration Control Options — The Control Options configuration deter- screen is used to configure the secondary damper settings. See mines whether the zone controller will use a humidity sensor or Table 12: • an indoor air quality sensor. A configuration of 0 means no Zone Pressure Control — The Zone Pressure Control config- _ sensors are used. A configuration of 1 means a Humidity Sen- uration determines whether the primary and secondary control - sor is used. A configuration of 2 means an IAQ Sensor is used. lers will be configured for zone pressure control. Control Options: Range 0 to 2 Zone Pressure Default Value 0 Control: Range Dsable/Enable • Humidity Control — These configuration values define the Default Value Dsable calculation parameters for determining the airflow needed to Dual Duct Type — The Dual Duct Type setting configures the correct a high humidity problem in the space. The Maximum secondary controller for the correct dual duct type. A value of 0 Output Value is measured in percentage of nominal terminal configures the type to None. A value of 1 configures the type to . cam. Second Inlet (Hot Deck). A value of 2 configures the duct to Proportional . Total Probe (terminal outlet). Gain: Range 0.0 to 9.9 Dual Duct Type: Range 0 to 2 Default Value 1.5 Default Value 0 800 42 Table 12 — Secondary Damper Service Configuration Screen ' DESCRIPTION DEFAULT POINT NAME Zone Pressure Control Dsable ZPCNTL ,, Dual Duct Type 0 - • DDTYPE Secondary Duct Size . Inlet Diameter 6.0.in. . - SRNDSZ Inlet Area • 0.0 sq. in. SSQA Probe Multiplier - 2.443 . SPMF Calibration Gain 1.000 CAL_GAIN Offset . 0 cfm SOFFSET CW Rotation Close DMPDIR Secondary Duct Size — The Secondary Duct Size setting is will be offset. A number of .95 will cause the maximum air - used to input the inlet diameter of the terminal, if used with a flow calculated to be reduced to 95% of the value. A Calibra- round inlet. The Inlet Area. configuration is used for oval or tion Gain of 1.00 will cause no change. A number of 1.05 rectangular inlets. The zone controller will use the larger value would cause readings to become 5% higher. for CFM calculations if both values are configured. Any error in reading at minimum airflow is adjusted by cal - Secondary Duct Size culating the Offset configuration value. (Inlet Diameter): Units Inches Calibration Gain: Range 0.000 to 9.999 Range 3.0 to 24.0 Default Value 1.000 Default Value 6.0 Offset — The Offset configuration is included for precision Inlet Area -- The Inlet Area configuration is used if the termi- applications where the minimum airflow is critical and not nal has an oval or rectangular inlet. The Primary Inlet Size zero. The cfm will be offset by the value entered in the Mini - configuration is used for round inlets. The zone controller will mum Cfm variable and will zero at the value entered in the use the larger value for CFM calculations if both values are Maximum Cfm variable. There will be a linear relationship be- configured. • tween the two set, points. Inlet Area: Units Square Inches Range 0.0 to 500.0 , Offset: Units cfm Default Value 0.0 . Range —250 to 250 , Default Value 0 Probe Multiplier — This configuration is used to input a fac- tor for the velocity pressure probe characteristics installed in Clockwise Rotation — This configuration is used to define the inlet. All averaging probes will have some aerodynamic what effect a clockwise rotation of the actuator will have on the characteristics which will amplify the pressure difference read damper. If the actuator rotates clockwise to closed position, the at the inlet of the terminal. The default of 2.443 is the correct configuration should be set to Close. If the actuator rotates value to use if the probe is a Carrier probe in a 35 or 45 Series clockwise to open, the configuration should be set to open. terminal. This configuration is used to change the rotation of the actuator so that the damper transducer calibration will work properly. The formula for calculating velocity using an Ideal probe is: The actuator does not have to be reinstalled nor any switches Velocity = 4005* SQRT (Velocity Pressure) changed to reverse the action. Most manufactures will provide a probe constant for the Clockwise probe supplied. For example, Velocity = 2213 *SQRT(Velocity Rotation: Range , Close /Open Pressure). To calculate the number to input in this decision Default Value Close (Probe Multiplier) use the formula. (4005/2213) = 3.3. So you Maintenance Table Menu Screen — The Mainte- would use 3.3 in place of 2.443 for a probe with a probe con - Hance Table Menu screen allows the user to select one of 4 slant of 2213. available maintenance tables: the Linkage Maintenance Table, An easy way to determine the probe constant for a probe the Occupancy Maintenance Table, the Zone Air Balance without documentation is to measure the velocity pressure with Table, and the Zone Maintenance Table. a Magnahelic gage. Open the damper and adjust the static pres LINKAGE MAINTENANCE TABLE The Linkage sure until you have one inch of velocity pressure on the Magna- g helic gage. Measure the total CFM of air being produced. The Maintenance table is used to view the zone linkage variables. CFM just measured divided by the inlet area in feet should See Table 13. equal the probe constant for the formula. Velocity = (CFM just - Air Source Bus Number — This variable will display the bus measured/inlet area) * SQRT (1.0). Now use the constant that number of the air source that the zone controller will be com- was' empirically derived to determine the probe multiplier municating Linkage to, if this zone is the Linkage Master. (4005 /(CFM at 1.0 Inch/Inlet area))'- = Probe Multiplier. Air Source ' Probe Multiplier: Range 0.250 to 9.999 Bus Number: Range 0 to 239 Default Value 2.443 Default Value 0 Calibration Gain — Air terminal testing by industry standards Network Access None • is done with straight duct, upstream of the termmal. Since most —> Air Source Element Number — This variable will display the • applications do not get installed in this manner, the actual air- Element Address of the Air Source that the zone controller flow from the terminal at balancing may not equal the reading will be communicating Linkage to, if this zone is the Linkage from the zone controller. Master. The calibration gain is used for the fine tuning adjustments Air Source which might need to be made to the airflow calculation. Element Number: Display Range 1 to 239 If the Calibration Gain must be configured manually. It is Default Value 0 determined as a percentage up or down that the CFM indicated Network Access None • 43 501 Master Zone Element Number — This variable will display Average Unoccupied Cool Set Point — This variable dis- the element address of the zone which is the Linkage Master. plays the weighted average of the unoccupied cool set point, Master Zone calculated by the linkage coordinator, from the information re- Element Number: Display Range 1 to 239 ceived from polling its associated zones. The set points are Default Value 0 weighted by the maximum airflow capacities of the zone con - Network Access Read only trollers scanned by the linkage coordinator. Operating Mode — This variable will 'display the current op- Average Occupied erating mode of the air source, if Linkage is •available, or the Cool Set Point: Display Units F (C) mode determined by the Linkage Master using the primary air Display Range 0.0 to 99.9 sensor, if available. If the primary.air sensor has failed or was Default Value 0.0 not installed, the Linkage master will assume the default mode Network Access None of cooling. • . _ Average Zone Temperature — This variable displays the • Operating Mode: Display Range COOLING, HEATING, weighted average of the space temperatures, collected by the • WARM -UP, FREECOOL, PRESSURE, linkage, coordinator, from polling its associated zones. The EVAC, OFF temperatures are weighted by the maximum airflow capacities Default Value OFF of the zone controllers scanned by the linkage coordinator. • Network Access Read only Average Zone Air Source Supply Temperature — This variable displays the Temperature: Display Units F (C) • • supply temperature reading of the air source. Display Range 0.0 to 99.9 Default Value 0.0 Air Source Supply Network Access Read Only Temperature: Units F (C) • Average Occupied Zone Temperature — This variable dis- Display Range -40 to 245 plays the weighted average of the space temperatures of occu- • Default Value 0 • pied zones, collected by the linkage coordinator, from polling Network Access None its associated zones. The temperatures are weighted by the Start Bias Time — This variable displays the Start Bias Time, maximum airflow capacities of the zone controllers scanned by in minutes, calculated by the air source. The Start Bias Time is the linkage coordinator. . calculated to bring the temperature up or down to the set point Average Occupied under the optimum start routine. This value will be sent to all Zone Temperature:Display Units F (C) associated zones for optimum start of zone controllers. This Display Range 0.0 to 99.9 function is supported by all Carrier equipment which perform Default Value 0.0 linkage. _ Network Access Read Only Start Bias Time: Display Units minutes -+ Composite CCN Value — This variable displays the high, low Display range 0 to 185 • or average of the CCN variable collected from each zone as Default Value 0 configured in the Linkage Coordinator Configuration Screen. Network Access None' The value is sent to the CCN address and variable specified Average Occupied Heat Set Point — This variable displays within that configuration table. the weighted average of the occupied heat set point, calculated Composite by the linkage coordinator, from the information received from CCN Value: Display Range 0 -65535 polling its associated zones. The set points are weighted by the Default Value 0 maximum airflow capacities of the zone controllers scanned by Network Access Read Only the linkage coordinator. Average Occupied Occupancy Status — This variable displays a "1" when at Av A Set Point: Display Units F (C) least one of the associated zone controllers (that are being DisplayRange 0.0 to 99.9 scanned) is in the occupied mode. Default Value 0.0 Occupancy Status: Display Range 0 or 1 (1 = occupied) Network Access None Default Value 0 Average Occupied Cool Set Point — This.. variable displays Network Access Read only the weighted average of the occupied cool set point, calculated Next Occupied Day — This variable displays the .day when by the linkage coordinator, from the information received from the next associated zone is scheduled to change from unoccu- polling its associated zones. The set points are weighted by the pied to occupied mode.'This point is read in conjunction with maximum airflow capacities of the zone controllers scanned by the next occupied time to allow the user to know the next time the linkage coordinator. • V and day when a zone will become occupied. Average Occupied Next Occupied Cool Set Point: Display Units F (C) Day: - Display Range MON, TUE, WED, . Display Range 0.0 to 99.9 THU, FRI, SAT, SUN Default Value 0.0 , . Default Value No display (Blank) Network Access None Network Access None Average Unoccupied Heat Set Point —This variable displays Next Occupied Time — This variable displays the time of day ' the weighted average of the unoccupied heat set point, calculat- when the next associated zone is scheduled to change from un- ed by the linkage coordinator, from the information received occupied to occupied mode. This point is read in conjunction from polling its associated zones. The set points are weighted with the next occupied day to allow the user to know the next by the maximum airflow .capacities of the zone controllers time and day when a zone will become occupied. scanned by the linkage coordinator. Next Occupied Average Unoccupied Time: Display Range 00:00 to 24:00 Heat Set Point: Display Units F (C) Default Value 0:00 Display Range 0.0 to 99.9 Network Access None Default Value 0.0 Network Access None 801 44 - Table 13 — Linkage Maintenance Screen DESCRIPTION DEFAULT - . . POINT NAME Air Source Bus Number 0 ASBUSNUM t Air Source Element Number 0 - ASDEVADR . Master Zone Element Number 0 MZDEVADR Operating Mode OFF ASOPMODE Air Source Supply Temperature 0 F ASTEMP • Start Bias Time 0 minutes STRTBIAS Average Occupied Heat Set Point 0.0 F AOHS Average Occupied Cool Set Point 0.0 F AOCS Average Unoccupied Heat Set Point 0.0 F AUHS Average,Unoccupled Cool Set Point 0.0 F AUCS Average Zone Temperature 0.0 F AZT Average Occupied Zone Temperature 0.0 F AOZT Composite CCN Value 0 CCCNVAL Occupancy Status 0 OCCSTAT Next Occupied Day • (blank) NXTOCCD Next Occupied Time 00:00 NXTOCCT Next Unoccupied Day (blank) NXTUNOD Next Unoccupied Time 00:00 NXTUNOT Previous Unoccupied Day (blank) PREVUNOD Previous Unoccupied Time 00:00 PRVUNOT Maximum Damper Position 0.0 % MAXDMPOS Static Pressure Reset 0.0 in. wg PRESVAL Pressure Decrease Value 0.000 in. wg PRESDECR Pressure increase Value 0.000 in wg PRESINCR Next Unoccupied Day — This variable displays the day when Maximum Damper Position — This variable displays the the next associated zone is scheduled to change from occupied damper position of the zone controller in the system with the to unoccupied mode. This point is read in conjunction with the damper in the most open position. This is used by the linkage next unoccupied time to allow the user to know the next time coordinator to calculate the static pressure reset. and day when a zone will become unoccupied. Maximum Damper Next Unoccupied Position: Display Units - % (open) Day: Display Range MON, TUE, WED, Display Range 0.0 to 100.0 . THU, FRI, SAT, SUN Default Value 0.0 Default Value No display (Blank) Network Access Read/Write Network Access None Static Pressure Reset — This variable displays the current Next Unoccupied Time — This variable displays the time of static pressure reset calculated, using the maximum damper po- dgy when the next associated zone is scheduled to change from sition and the configuration information from the linkage con - occupied to unoccupied mode. This point is read in conjunction figuration table. with the next unoccupied day to allow the user to know the Static Pressure next time and day when a zone will become unoccupied. Reset: Display Units in. wg Next Unoccupied Display Range 0.0 to 5.0 Time: Display Range 00:00 to 24:00 Default Value 0.0 Default Value 0:00 Network Access Read/Write Network Access None Pressure Decrease Value — If the maximum damper position Previous Unoccupied Day — This variable displays the day in the system goes below the minimum configuration setting, when the last associated zone changed from occupied to unoc- the linkage coordinator will calculate an amount that the static cupied mode. This point is read in conjunction with the previ- pressure should be decreased. This is used to open the system ous unoccupied time to allow the user to know the last time and dampers more so that they will modulate between their mini - day when a zone became unoccupied. mum and maximum settings. Previous Unoccupied This number is rounded to the nearest tenth of an inch and ., Day: Display Range MON, TUE, WED, will be added to the static pressure reset value unless the static THU, FRI, SAT, SUN pressure reset value has reached maximum reset. Default Value No display (Blank) Pressure Decrease Network Access None Value: Display Units in. wg Previous Unoccupied Time — This variable displays the time Display Range 0.000 to 5.000 of day when the last associated zone changed from occupied to Default Value 0.000 unoccupied mode. This point is read in conjunction with the Network Access Read/Write previous unoccupied day to allow the user to know the last time Pressure Increase Value — If the maximum damper position and day when a zone became unoccupied. in the system goes above the maximum configuration setting, Previous Unoccupied the linkage coordinator will calculate an amount that the static Time: Display Range 00:00 to 24:00 pressure should be increased. This is used to close the system Default Value 0:00 dampers more so that they will modulate between their mini - Network Access None mum and maximum settings. 45 801 This number is rounded to the nearest tenth of an inch and Unoccupied Start Time — This variable displays the time that will be subtracted to the static pressure reset value unless the the current occupied mode will end (the beginning of the next static pressure reset value has reached zero. unoccupied mode). If the current mode is unoccupied or the Pressure Increase zone controller is following a global schedule, the value dis- Value: Display Units in. wg played by this point will be 0:00. '' Display Range 0.000 to 5.000 Unoccupied Start Default Value 0.000 Time: Display Range 00:00 to 24:00 Network Access Read/Write Default Value 0:00 OCCUPANCY MAINTENANCE TABLE — The Occu- Network Access None panty Maintenance table is used to view the occupancy set Next Occupied Day — This variable displays the day .when points. See Table 14. the next occupied period is scheduled to begin. This point is Mode — This variable displays the current occupied mode for read in conjunction with the next occupied time to allow the the zone controller. If the zone controller is following its own user to know the next time and day when the next occupied pe- local schedule, this is the result of the local schedule status. If riod will occur. If the zone controller is following a global the zone controller is 'configured to follow a global schedule, schedule this point will remain at default. . this point displays the mode last received from a global sched- NOTE: If the current mode is occupied, this point makes refer - ule broadcast. ence to the next occupied period and, in most cases, may not Mode: Display Range 0 or 1 (1 = occupied) be the same as the current occupied start time. ' Default Value 0 Next Occupied Network Access None Day: Display Range MON, TUE, WED, Current Occupied Period — 'If the zone controller is config- THU, FRI, SAT, SUN ured to determine occupancy locally, this variable will display Default Value No display (Blank) the current period determining occupancy. Network Access None Current Occupied - - Next Occupied Time — This variable displays the time of day Period: Display Range 1 to 8 when the next occupied period will occur. This point is read in Default Value 0 conjunction with the next occupied day to allow the user to Network Access None know the next time and day when the zone will become occu- pied. If the zone controller is following a global schedule this Override in Progress — If an occupancy override is in point will remain at default. progress, this variable will display a yes. Override In NOTE: If the current mode is occupied, this point makes Override Display Range Yes/No reference to the next occupied period and, in most cases, Default Value No may not be the same as the current occupied start time. Next Network Access None Occupied Timmee : Display Range 00:00 to 24:00 Override Duration — This variable displays the number of Default Value 0:00 minutes remaining for an occupancy override which is in Network Access None effect. If the number of override hours was downloaded, the - Next Unoccupied Day — This variable displays the day when value will be converted to minutes. the next unoccupied period is scheduled to begin. This point is Override read in conjunction with the next unoccupied time to allow the Duration: Display Units minutes user to know the next time and day when the zone will become Display Range 0 to 1440 unoccupied. If the zone controller is following a global sched- Default Value 0 ule this point will remain at default. Network Access None NOTE: If the current mode is unoccupied, this point makes Occupied Start Time — This variable displays the time that reference to the next unoccupied period and, in most cases, the current occupied mode began. If the current mode is unoc- may not be the same as the current unoccupied start time. cupied or the zone controller is following a global schedule, the Next Unoccupied value displayed by this point will be 0:00. Day: Display Range MON, TUE, WED, Occupied Start THU, FRI, SAT, SUN Time: Display Range 00:00 to 23:59 Default Value No display (Blank) Default Value 0:00 Network Access None Network Access None Table 14 — Occupancy Maintenance Screen DESCRIPTION DEFAULT POINT NAME Mode 0 MODE Current Occupied Period 0 PERIOD A Override In Progress No OVERLAST Override Duration 0 OVERDURA Occupied Start Time 00:00 OCCSTART Unoccupied Start Time 00:00 UNSTART Next Occupied Day (blank) NXTOCCD Next Occupied Time 00:00 NXTOCCT Next Unoccupied Day (blank) NXTUNOD Next Unoccupied Time 00:00 NXTUNOT Last Unoccupied Day (blank) PRVUNOD Last Unoccupied Time 00:00 PRVUNOT 501 46 • • -' Next Unoccupied Time — This variable displays the time 'of Maximum Cooling Airflow Calibration — By enabling the day when the next unoccupied period is scheduled to begin. Maximum Cooling Airflow Calibration, the Maximum Cool - This point is read in conjunction with the next unoccupied day ing Airflow from the set point schedule will be made the Air - to allow the user to know the next time and day when the zone flow CFM Set Point. The zone controller will modulate the will become unoccupied. If the zone controller is following a damper to control to this'set point. The actual airflow, damper global schedule this point will remain at default. position; and velocity pressure readings will be displayed. NOTE: If the current mode is unoccupied, this point makes If the' set point is not correct, it may be changed from this reference to the next unoccupied period and, in most cases, screen by forcing the airflow set point to the desired value. The may not be the same as the current unoccupied start time. value will be written to the set point schedule in the Maximum Next Unoccupied Cool CFM set point, and the zone controller will begin to con - Time: Display Range 00:00 to 24:00 trol to the new value. Default Value 0:00 The airflow can be measured using test and balance equip - Network Access None ment and compared to the actual reading on the screen. If the - Last Unoccupied Day — This variable displays the last day value measured requires adjustment to the value on the screen, when the zone changed from occupied to unoccupied mode. force the value on the screen to the value measured. The zone This point is read in conjunction with the last unoccupied time controller will take the value and calculate a new calibration to allow the user to know the last time and day when the zone gain which will be shown at the bottom of the screen. The new became unoccupied. If the zone controller is following a global value will be automatically loaded into the Service Configura- schedule this point will remain at default. tion table. Last Unoccupied Maximum Cooling Day: Display Range MON, TOE, WED, Airflow THU, FRI, SAT, SUN Calibration: Display Range Dsable/Enable Default Value No display (Blank) Default Value Dsable Network Access None Network Access Read /Write • —> Last Unoccupied Time — This variable displays the last time Minimum Cooling Airflow Calibration — Enabling the Min - of day when the zone changed from occupied to unoccupied imam Cooling Airflow Calibration will cause the airflow CFM mode. This point is read in conjunction with the last unoccu- set point to change to the Minimum Cooling set point. The ac- pied day to allow the user to know the last time and day when a tual airflow, damper position, and velocity pressure readings zone became unoccupied. If the zone controller is following a will be displayed. global schedule this point will remain at default. If the set point is not correct, it may be changed from this Last Unoccupied screen by forcing the Airflow set point to the desired value. Time: Display Range 00:00 to 24:00 The value will be written to the set point schedule in the Mini- Default Value 0:00 mum Cool CFM set point, and the zone controller will begin to Network Access None control to the new value. ZONE AIR BALANCE /COMMISSIONING TABLE — The airflow can be measured using test and balance equip - The Zone Air Balance /Commissioning Table is used to display ment and compared to the actual reading on the screen. If the the air balance variables. See Table 15. value measured requires adjustment to the value on the screen, Commissioning Mode — This variable is used to put the zone force the value on the screen to the value measured. The zone controller into the commissioning mode. Force this point to en- controller will take the value and calculate a new offset. able. The zone controller will be ready to accept a command to The Offset configuration is included for precision applica- perform the tests and functions onthis screen. tions where the minimum airflow is critical and not zero. The NOTE: Commissioning mode will automatically be dis Offset configuration should not be used to zero the airflow abled after one hour. transducer since an auto zero test is included in the normal function of the zone controller and is automatically performed Commissioning each time the equipment fan is disabled (or every 72 hours for Mode: Display Range Dsable/Enable systems which run the fan continuously). After performing air Default Value Dsable balance testing using the Air Balance Maintenance screen, it is Network Access Read /Write a good idea to upload and save the Airflow set points, Calibra- Damper Actuator/Transducer Calibration — The Damper tion Gain, and Offset values. Actuator Transducer calibration is the first calibration which Minimum Cooling should be performed on a newly installed actuator. The zone Airflow controller will command the actuator to close and read the Calibration: Display Range Dsable/Enable feedback potentiometer to determine the zero position of the Default Value Dsable damper. It will then command the damper to fully open. The Network Access Read /Write zone controller will read the potentiometer to determine the maximum open position. Damper positions from closed to Fan Override — This variable can be used to test the fan on se- maximum open will be scaled to read 0 to 100% for the damp- ries and parallel fan powered terminals. Enabling this point will er position. cause the terminal fan to run until this point is disabled or the • The zone controller will then close the damper and open it' commissioning mode is ended once more to zero calibrate the airflow sensor. The entire Fan Override: Display Range Dsable/Enable calibration procedure can take up to 3 minutes. If the damper Default Value Dsable fails the test or the airflow calibration is unable to be complet- Network Access Read /Write ed, the Auto- Calibration point will indicate an Alarm. Damper Actuator Transducer Calibration: Display Range Dsable/Enable Default Value Dsable Network Access Read /Write 47 501 —> Table 15 — Zone Air Balance /Commissioning Table DESCRIPTION DEFAULT - POINT NAME Commissioning Mode • Dsable CMODE Damper/Transducer Calibration Dsable CALIBRAT Maximum Cooling Dsable MAXCOOL Minimum Cooling Dsable MINCOOL Heating Override • Dsable HEATOVER Fan Override - Dsable FANOVER CFM Set Point 0 cfm COMCFM Actual Airflow 0 cfm AIRFLOW • Primary Damper Position 100 % DMPPOS Measured Velocity Pressure 0.000 in. wg MVP Supply Air Temperature , • 0.0 F SAT Auto-Calibration Normal CAL • Calibration Gain 1.000 CAL GAIN Heating Override — This variable can be used to test the heat Display Range 0.000 to 2.000 (Limited outputs. Enabling this variable will cause the heat to be modu- by velocity pressure transducer high alarm lated or staged to full heat until this point is disabled or the limit) force released. Ducted reheat operation will be controlled so as Default Value 0.000 not to exceed the configured maximum duct temperature. The Network Access Read Only supply -air temperature is included on this screen to verify that Supply -Air Temperature — This variable displays the supply - the heat is operating. air temperature for ease of verifying the heat operation during Heating Override: Display Range Dsable/Enable the heat test. Default Value Dsable Supply -Air Network Access Read /Write Temperature: Display Units F (C) Airflow CFM Set Point — This variable displays the current Display Range -40.0. to 245.0 airflow set point that the zone controller is controlling to. Dur- Default Value 0.0 ing the calibration tests this value can be forced, which will Network Access Read /Write . change the set point configuration for the value being tested. Auto - Calibration — This variable will display "Normal" if the Airflow CFM actuator and airflow transducer calibrations are successful. If Set Point: Display Units CFM damper or transducer calibration was not successful, this point Display Range 0 to 9999 (Limited by will display "Alarm" and the zone controller will broadcast the velocity pressure transducer high alarm appropriate alarm (if configured to transmit alarms). limit) Auto - Calibration: Display Range Normal/Alarm Default Value 0 Default Value Normal • Network Access Read /Write Network Access Read Only Actual Airflow Display — This variable shows the actual air Calibration Gain — Air terminal testing by industry standards flow being measured, based on the inlet size configured. Dur- is done with straight duct, upstream of the terminal. Since most ing the Maximum and Minimum Cooling Airflow calibration applications are not installed in this manner, the actual airflow tests this value can be forced, which will correct the multiplier from the terminal, at balancing, may not equal the reading from or offset used to calculate the airflow. the zone controller. Actual Airflow: Display Rang e 0 to 9999 (Limited by CFM Display Range The Calibration Gain is used for making fine tuning adjust- ments to the airflow calculation. This number is calculated au- velocity pressure .transducer high alarm tomatically by the zone controller after input to the air balance limit) maintenance screen. The Calibration Gain can also be entered Default Value 0 Network Access Read /Write manually in the service configuration CONFIG screen. Primary Damper Position — This variable displays the cur- A number of .95 entered into. the Calibration Gain variable rent damper. position. During CFM Balancing, this variable is will cause the maximum airflow to be reduced to 95/0 of the used to display the position of the damper. This value can calculated value. A number of 1.05 would cause readings to be used to see if the damper is fully open and the system air is become 5% higher. The Calibration Gain is adjusted on the Air sufficient. Balance maintenance screen when performing the Maximum Primary Damper Airflow Calibration and will have the greatest affect on the air - Position: Display Units % (open) flow at maximum CFM. • Display Range 0 to 100 After performing the air balance procedure using the air bal- ' Default Value 100 ance ,maintenance screen, it is recommended to upload and Network Access Read'Only save the Airflow Configuration, Calibration Gain, and Offset Measured Velocity Pressure — This variable displays the settings. measured velocity pressure, which is used to check accuracy Calibration Gain: Display Range 0.000 to 9.999 during test and balancing of the terminal. If the pressure Default Value 1.000 appears to be much different than that measured with a Magna- Network Access Read Only helic gage, the transducer can be forced to recalibrate its zero by enabling the Damperfrransducer Calibration. Measured Velocity Pressure: Display Units in. wg 501 48 r, - ZONE MAINTENANCE TABLE — The Zone Maintenance unoccupied mode. This variable will display any space temper - table is used to • display zone set points and variables. See attire sensor slidebar offset that is being applied. Table 16. Cool Master • • Occupied — This variable indicates if the zone controller is Reference: Display-Units F (C) operating in the occupied mode. Display Range 45.0 to 99.9 Occupied: Display Range . . No/Yes Default Value ' 90.0 Default Value . No Network Access Read/Write • 0 Network Access Read Only Primary Damper Airflow Reference — This variable dis- -4 Linkage Slave — This variable displays if air source linkage is plays the current controlling airflow set point. in effect. Primary Damper Linkage Slave: Display Range No/Yes Airflow Display Units CFM Default Value No Reference: Display Range 0 to 9999 (Limited by Network Access Read Only velocity pressure transducer high alarm Linkage Master — This variable displays if this zone control- De fa lima) ult Value 0 ler is functioning as a linkage master. Network Access Read /Write Linkage Master: Display Range No/Yes Primary Damper Position — This variable displays the cur - Default Value No rent damper position. p la y Network Access Read Only Timed Override in Effect — This variable indicates if a timed Primary Damper Position: override is in effect. Position: Display Units % (open) Display Range 0 to 100 Timed Override Default Value 100 in Effect: Display Range No/Yes Network Access Read/Write Default Value No Secondary Damper Airflow Reference — This variable dis- Network Access Read Only plays the current controlling airflow set point for the secondary Set Point Offset (T -56) — This variable displays the degrees damper. of offset when using a 33ZCT56SPT space temperature sensor Secondary Damper with set point adjustment. The slidebar on the sensor will adjust Airflow Display Units CFM the desired temperature in that zone, up or down, when, it is Reference: Display Range 0 to 9999 (Limited by moved. The Set Point Offset (T -56) variable can disable set velocity pressure transducer high alarm point offset (set to 0). limit) Set Point Default Value 0 Offset (T -56): Display Units delta F (delta C) Network Access Read /Write Display Range 0.0 to 15.0 Heat Enable — This variable displays the demand for heat in Default Value 0.0 the space. The space temperature must be below the appropri- Network Access Read Only ate heat set point. Cool Master Reference' — This variable displays the cooling Heat Enable: Display Range Dsable/Enable master reference from the set point schedule. This should be Default Value Dsable the occupied cool set point when the zone is in occupied Network Access ReadOnly mode or the unoccupied cool set point when the zone is in -> Table 16 — Zone Maintenance Table DESCRIPTION DEFAULT POINT NAME Occupied No ZONEOCC Linkage Slave No DAVCTL Linkage Master No LINKMAST Timed Override in Effect No TIMOV Set Point Offset (T56) 0.0 F T56OFF Cool Master Reference 90.0 F CCMR PI Primary Damper Reference 0 cfm PISMR PD Primary Damper Reference 100 % PDSMR Secondary Damper Reference 0 cfm SDSMR p, Heat Enable Dsable HEATENA Heat Master Reference 55.0 F HCMR Heat Submaster Reference 0 F HSMR Temperature Control Airflow 100 % TCA Relative Humidity Airflow 0 % RHA Air Quality Airflow 0 % AQA Cooling In Effect Yes COOLFLAG Heating In Effect No HEATFLAG RH in Effect No RHFLAG AO in Effect No AQFLAG Unoccupied Dehumidification No UNOCCDH Cooling Energy 0 Btu COOLBTUS Heating Energy 0 Btu HEATBTUS 49 801 • Heat Master Reference — This point displays the occupied Cooling in Effect — This variable displays if the air source is heat set point if occupied, or the unoccupied heat set point if in the Cooling mode and if the terminal is using the cooling air - unoccupied. This variable will display any space temperature flow set points. sensor slidebar offset that is being applied. Cooling In Effect: Display Range No/Yes Heat Master • Default Value Yes Reference: Display Units 'F (C) Network Access Read Only Display Range 40.0 to 90.0 Heating in Effect — This variable displays if the air source is Default Value ' 55.0 in the Heat mode and if the terminal is using the heating air- - Network Access Read/Write flow set points. Heat Submaster Reference — If heat is enabled, this variable Heating In Effect: Display Range No/Yes displays the desired supply air temperature calculated to heat Default Value No • the space. This is a result of the heatingPID loop calculation. - Network Access Read Only Heat Submaster Relative Humidity Control in Effect — This variable indi- Reference: Display Units F (C) cates if the relative humidity control is active. Display Range 0 to 240 - Default Value 0 Relative Humidity . Network Access Read/Write Control In Effect: Display Range No/Yes • • Default Value No Temperature Control Airflow — This variable displays the Network Access Read Only • airflow set point determined from the temperature loop calcula- Air Ouality Control in Effect — This variable indicates if the tion. The zone controller compares the Temperature, Relative Humidity, and Air Quality loop. The greatest of the three will air quality control is active. . become the primary damper airflow reference. Air Quality Temperature Control In Effect: Display Range No/Yes Control Airflow: Display Units % Default Value No Display -Range 0 to 100 Network Access Read Only • Default Value 100 - Unoccupied Dehumidification — This variable indicates if Network Access Read Only unoccupied dehumidification control is in effect. Relative Humidity Control Airflow — This variable dis- Unoccupied plays the airflow set point determined from the relative Dehumidification: Display Range Yes/No humidity loop calculation. The zone controller compares the Default Value No Temperature, Relative Humidity, and Air Quality loop. The Network Access Read Only . greatest of the three will become the primary damper airflow Cooling Energy — This variable displays the amount of pri- reference. mary air source cooling BTUs being provided to the space by Relative Humidity the terminal. A CCN compatible air source or PAT sensor on a Control Airflow: Display Units % linkage master is required. Display Range 0 to 100 Cooling Energy: Display Units • Btu Default Value 0 Display Range 0 to 999999 Network Access Read Only Default Value 0 Air Quality Control Airflow — This variable displays the air- Network Access Read Only . flow set point determined from the air quality loop calculation. Heating Energy — This point displays the amount of primary The zone controller compares the Temperature, Relative air source heating BTUs being provided to the space by the ter - Humidity, and Air Quality loop. The greatest of the three will minal. This value will not include zone level heating. A CCN become the primary damper airflow reference. compatible air source or PAT sensor on a linkage master is Air Quality required. ' Control Airflow: Display Units % Heating Energy: Display Units Btu Display Range 0 to.100' - Display Range 0 to 999999 Default Value - 0 Default Value 0 Network Access Read Only Network Access Read Only 801 50 a • • Copyright 1999 Carrier Corporation Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations. Book 11 4 PC 111 Catalog No. 533 -355 Printed In U.S.A. Form 33ZC -1SI Pg 52 303 11-99 Replaces: New Tab 11a 13a [Page Too Large for OCR Processing] [Page Too Large for OCR Processing] [Page Too Large for OCR Processing] [Page Too Large for OCR Processing] [Page Too Large for OCR Processing] [Page Too Large for OCR Processing]