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•., {. Hee, 2oi2 -o» 3 7I9 o 5t,✓ Seteid f 5 • 7650 S. W. Beveland St. TM RIPPEY Tigard, Oregon 97223 Fax: Phone: (503) 443 -3900 CONSULTING ENGINEERS ` Fax: (503) 443 -3700 STRUCTURAL CALCULATIONS PROJECT: McCORMACK MECHANICAL UNITS LOCATION: TIGARD, OREGON CLIENT: McCORMACK PROPERTIES DATE: AUGUST 8, 2012 PROJECT NUMBER: 12302 TABLE OF CONTENTS: ITEM SHEET NUMBER GENERAL NOTES N1 -N2 BUILDING PLAN SK1 ROOF FRAMING PLAN SK2 PARTIAL FRAMING PLAN SK3 SECTION THROUGH CURB SK4 SECTION THROUGH TRIPPLE JOIST SK5 DETAIL FOR (E) CUTTING JOIST SK6 CALCULATIONS Cl -C12 GINF )1111":" •. 1' GENERAL STRUCTURAL NOTES CODE REQUIREMENTS: CONFORM TO THE 2009 INTERNATIONAL BUILDING CODE AS AMENDED BY THE 2010 OREGON STRUCTURAL SPECIALTY CODE, REFERENCED HEREAFTER AS IBC. DESIGN CRITERIA: DESIGN WAS BASED ON THE STRENGTH AND DEFLECTION CRITERIA OF THE IBC. IN ADDITION TO THE DEAD LOADS, THE FOLLOWING LOADS WERE USED FOR DESIGN, WITH LIVE LOADS REDUCED PER IBC: ROOF SNOW LOAD: 25 PSF BASIC WIND SPEED (3 -SEC GUST): 100 MPH WIND EXPOSURE: B SEISMIC SITE CLASS: D SDS = 0.706 EXISTING CONDITIONS: THE CONTRACTOR SHALL FIELD VERIFY ALL EXISTING CONDITIONS, DIMENSIONS AND ELEVATIONS. THE CONTRACTOR SHALL NOTIFY THE ARCHITECT/ENGINEER OF ANY DISCREPANCIES FROM CONDITIONS SHOWN ON THE DRAWINGS PRIOR TO THE START OF THE WORK. TEMPORARY CONDITIONS: THE CONTRACTOR SHALL BE RESPONSIBLE FOR STRUCTURAL STABILITY OF THE NEW AND EXISTING STRUCTURES -AND WALL -S - DURING -CONSTRUCTION —TIC STRUC 'PURE SHOWN - ON- THE - DRAWINGS-HAS- BEEN - -- DESIGNED FOR STABILITY UNDER THE FINAL CONFIGURATION ONLY. CARPENTRY: SAWN LUMBER DESIGN IS BASED ON THE NATIONAL DESIGN SPECIFICATION, LATEST EDITION. SAWN LU4.4BER SHALL CONFORM TO WEST COAST LUMBER INSPECTION BUREAU OR WESTERN WOOD PRODUCTS ASSOCIATION GRADING RULES. UNLESS NOTED OTHERWISE ALL LUMBER SHALL HAVE A MAXIMUM MOISTURE CONTENT OF 19% AT TIME OF FABRICATION. ALL WOOD IN PERMANENT CONTACT WITH CONCRETE OR CMU SHALL BE PRESSURE TREATED UNLESS AN APPROVED BARRIER IS PROVIDED. GRADES SHALL BE AS FOLLOWS UNLESS NOTED OTHERWISE ON THE PLANS: FRAMING ACCESSORIES AND STRUCTURAL FASTENERS SHALL BE MANUFACTURED BY SIMPSON STRONG -TIE COMPANY (OR ENGINEER APPROVED EQUAL) AND OF THE SIZE AND TYPE SHOWN ON THE DRAWINGS AND ATTACHED PER MANUFACTURER'S REQUIREMENTS AND RECOMMENDATIONS UNLESS NOTED OTHERWISE. HANGERS NOT SHOWN SHALL BE SIMPSON HU OF SIZE RECOMMENDED FOR MEMBER. ALL FRAMING NAILS SHALL BE COMMON NAILS. NO BOX NAILS ALLOWED. ALL FASTENERS IN CONTACT WITH FIRE RETARDENT LUMBER MUST BE HOT - DIPPED GALVANIZED. NAIL CALLOUTS SHALL BE. INTERPRETED AS FOLLOWS: NAIL TYPE LENGTH DIAMETER 8d 2 -1/2" 0.131" 10d 3" 0.148" 16d 3 -1/2" 0.162" ALL ROOF SHEATHING AND SUB - FLOORING SHALL BE INSTALLED WITH FACE GRAIN PERPENDICULAR TO SUPPORTS, EXCEPT AS INDICATED ON THE DRAWINGS. ROOF SHEATHING SHALL EITHER BE BLOCKED, TONGUE - AND - GROOVE, OR HAVE EDGES SUPPORTED BY PLYCLIPS. SHEAR WALL SHEATHING SHALL BE BLOCKED WITH 2X FRAMING AT ALL PANEL EDGES. NAILING NOT SPECIFICALLY IDENTIFIED ON THE DRAWINGS SHALL CONFORM TO IBC TABLE 2304.9.1. K TM RIPPEY M (c)tZnn ►c-L� f �II�,�t� N n,l �1�� - X12 Consulting Engineers By: I. t Date: 7650 SW Beveland Street Chk By: Date: Suite 100 Tigard, Oregon 97223 Job #: 12 'Sv Phone: (503) 443 -3900 Sheet: N Or • L PREMANUFACTURED PARALLAM BEAMS SHALL BE OF THE SIZE AND TYPE SHOWN ON THE DRAWINGS, MANUFACTURED BY THE TRUS JOIST COMPANY, RED BUILT OR AN ENGINEER APPROVED EQUAL. MECHANICAL: THE CONTRACTOR SHALL COORDINATE SEISMIC RESTRAINTS OF ELECTRICAL EQUIPMENT, MECHANICAL, PLUMBING, FIRE SPRINKLER, MACHINERY, AND ASSOCIATED PIPING WITH THE STRUCTURE. ANY CONNECTIONS TO STRUCTURE NOT CONFORMING TO SHEET METAL AND AIR CONDITIONING CONTRACTORS NATIONAL ASSOCIATION (SMACNA), OR SPECIFICALLY DETAILED ON THE MECHANICAL ENGINEER'S DRAWINGS, SHALL BE DESIGNED IN ACCORDANCE OF THESE GENERAL NOTES, BY AN ENGINEER REGISTERED IN THE STATE OF OREGON, AND SHALL BE SUBMITTED TO THE ARCHITECT/ENGINEER PRIOR TO FABRICATION. . • FLASHING AND WATERPROOFING: ALL FLASHING AND WATERPROOFING SHALL BE BY OTHERS UNLESS NOTED OTHERWISE ON THE PLANS. • • • IMK 1'M RIPPEY Mc LOct -t kt-Ir Y�� - -t N\ �►-� Consulting Engineers ' V \ ^ ` By: r` �ZI2 Date: • 7650 SW Beveland Street • ki'1 S Chk By: Date: Suite 100 Job #: I VA 0'z- Tigard, Oregon 97223 Phone: (503) 443 -3900 Sheet: N 2 Of : ' t , y 5 C - / f t { -'.:--,'';‘,,.....< i r i i ` ty L i f 3 !® mo d . a i r b I E 5 n • \ t s t c _ , ; ' x ,�,�` o`er _ Y u..r�r S L S � g �� '� ` �;.'i� + <i���g� s�. a v �: . , b s r ' , •i :ew •.,, y A' ; . 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Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET .Ac.; OF Mt f.l1- W t \t 1:11 ari( • V —L-- -1 \F ---------------------r - r----------- Gl !)2? /yam 41- "F-A 64 /ale -WAN-1AT a) -Grp'` (r)_P -c� rcty5f — d4firti , — — — .1 .' , if . (.1 PI t i \i.,,/ AN Itt o v ►lI ;. Hy. isux..r,►,I C, - I iELcA J GV 1Z \3 Or /CILII,' J t�R��� o� �EAIII AF�'2- Ir:.li>vtt. 1�5 r,.'TVJ :� rJ s�sTry -gyp 2x1�'s w/ . 1 A/p. Sins (.a). 2 r l O Dr.- -41 - "to C c) ' ZX Q mit_ r l.l. LI ,.� bs-tl -i- Milt I�' 104 MA L - Guy �.��« 1� � a) 2x �� kf I' 0" %- S`tt.6v -t� -� rP -c�kn `I x i�.cxa�trsc, LW s ?OP •5btj W " Mit T . OF Zl Jp StMi'�.. r� t.J L�IMa'�$ Aw 1zts ' f (s) /V d /41--;1‘... lrT at..., t5:rJD', . J'. 4 t OEII I_ F C.,n1n J.•I C. Z36%& i g r-= f rr-,) r.172,A 11otil ski / 1M K. TM 1UPPE� / L:•-4/Vitt-AN— / "(5�.ai I c �CL.� BY Pi (k DATE C ONSULTING ENGINEERS IAN N \ 1 L CHK BY DATE 7650 S.W. Beveland St, Suite 100 JOB NO I ' JOZ -. Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET 51 6 OF N 2- 1 1.A. �1 j �r J r- TI {a• a�� == 3C� �I _ 2 ►rn j;; G�• ;z ty kJ I 0 t " -ck ti 7 l_ x IU .bF / �1 r L1 04 X Y " Z 2 � -- 1 � fs��C�� -:ice. 1-� �r Wit -ate,,. W r � s � � r— ,, I ,�� I 20 PE- 11J f= I L'- 4"1- i � I u , I Siva wry ��- C�c Le__ h2 ToK (, -') z_(10 Ti.)1ST c - • RIPPEY MG( "512}✓\ k! /Y 1V!AA kik ,J\T S BY Kr - Ac DATE . CONSULTING ENGINEERS CHK BY DATE 7650 S.W. Beveland St, Suite 100 SOB NO /2 3O2 Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET l OF Title Block Line 1 Title : Job # You can changes this area Dsgnr: using the "Settings" menu item Project Desc.: and then using the °Printing & Title Block selection. Project Notes • Title Block Line 6 Printed 27JUL2012 3.32PM ::. . , Wood ',1!0.,"14111,11 ��.� :�: s ; � ; x:R :: R: � , r . � . . ' ; ' rr '; = � r� ;c : � : . � � .Y x � � � : x x �;� .�� . � a . �`: .. ` r�i6rc c" , irisi s a 3= 2 o i i.° s Luc :'KW 06002662 •, ``, +- , • t,, ;License a TM ,RIPPEY.CONSULTING;ENGINEERS Description : 2 x 10 roof joist Material Properties Calculations per NDS 2005, IBC 2009, CBC 2010, ASCE 7 - 06 Analysis Method : Allowable Stress Design Fb - Tension 900.0 psi E : Modulus of Elasticity Load Combination 2009 IBC & ASCE 7 -05 Fb - Compr 900.0 psi Ebend- xx 1,600.0 ksi Fc - Pill 1,350.0 psi Eminbend - xx 580.0 ksi Wood Species : Douglas Fir - Larch Fc - Pep 625.0 psi Wood Grade :No.2 Fv 180.0 psi Ft 575.0 psi Density 32.210pcf Beam Bracing : Beam is Fully Braced against lateral- torsion buckling D(0.084) D(0.02) S(0.033) i i i i ` y�y!� w Y >u• . K: `�' ,e a gyp . Ys i Fi'.0 iT .. -Y, ,„' P . YY ^..�� .E:....5'. -11 . 'S � S t+T 4 <i:Y-i:y, - i ` NNN 'L' f E x li.^•. a £ 1 ` ,3 �a'N�_ ' <.. 9� „ a � � . -. : a< a. -: � e'"' ', ,, c� R ' 04 ,v t I s i . ' ,? q . V . ,, , £ z '�% - i � :'� � _: >.' i T'"eaic?a i �a .�y . � � n � �;E � s � <'.,i' : > .� ‘ , . , r k ; • 2x10 • • Span = 16.330 ft Ser vice loads entered. Load Factors will be a . �APPIied . loads ��:.:. •• �. :• • -.• . .. • . applied for calculations. . Uniform Load : D = 0.020, S = 0.0330 , Tributary Width =1.0 ft Point Load: D = 0.0840 k @ 4.0 ft • ;. 'D,,..SIGJV_SUIHMARY . :: . '; . ' ':;::, ... : _ : ... : _.... : .._ :: .:._. : - _.._.__.__...._.._ Desi•n`OK . Maximum Bending Stress Ratio = 0.955 1 Maximum Shear Stress Ratio = 0.239: 1 Section used for this span 2x10 Section used for this span 2x10 fb : Actual = 1,087.58 psi fv : Actual = 49.43 psi FB : Allowable = 1,138.50psi Fv : Allowable = 207.00 psi Load Combination +D +S +H Load Combination +0+541 Location of maximum on span = 7.757ft Location of maximum on span = 0.000 ft Span # where maximum occurs = Span # 1 Span # where maximum occurs = Span # 1 Maximum Deflection Max Downward L +Lr +S Deflection 0.336 in Ratio = 582 Max Upward L +Lr +S Deflection 0.000 in Ratio = 0 <360 Max Downward Total Deflection 0.597 in Ratio = 328 . Max Upward Total Deflection 0.000 in Ratio = 0 <180 . Maximum Forces S&.Stresses,for Loyd; Coinbinations . Load Combination Max Stress Ratios Summary of Moment Values Summary of Shear Values Segment Length Span # M V C d C FN C r C m C t Mactual lb-design Fb -allow Vactual fv.design Fv -allow +0 1.100 1.000 1.000 1.000 Length = 16.330 fl 1 0.479 0.127 1.000 1.100 1.000 1.000 1.000 0.85 474.18 990.00 0.21 22.92 180.00 +D+S +H 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.955 0.239 1.150 1.100 1.000 1.000 1.000 1.94 1,087.58 1,138.50 0.46 49.43 207.00 +D +0.750L+0.750S +H 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.943 0.238 1.000 1.100 1.000 1.000 1.000 1.66 933.71 990.00 0.40 42.80 180.00 • +D +0.750L+0.7505+0.750W +H 1.100 1.000 1.000 1.000 Length = 16.330 fl 1 0.943 0.238 1.000 1.100 1.000 1.000 1.000 166 933.71 990.00 0.40 42.80 180.00 +D+0.750L+0.750S+0.5250E +H 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.943 0.238 1.000 1.100 1.000 1.000 1.000 1.66 933.71 990.00 0.40 42.80 180.00 .Overall iiml mfDeflectirihs:.:Unfactored Loads:..:. . Load Combination Span Max. ' -' Defl Location in Span Load Combination Max. ' +' Defl Location in Span D +S 1 0.5969 8.083 0.0000 0.000 G Tri le Block Line 1 Title : Job # You can changes this area Dsgnr: using the °Settings " menu item Project Desc.: and then using the °Printing & Project Notes: Title Block" selection. • Title Block Line 6 Printed 27 JUL 2012 3:32PM Wood Beam ‘. ;,-.> • . ,••• >, • Lic.#-: KW-06002662 2, ,"""' ',Licensee : TM RIPPEY CONSULTING ENGINEERS,' • Description : 2 x 10 roof joist Vertical Reactions UrifaCtoreil Support notation : Far left is #1 Values in KIPS . . . . . Load Combination Support 1 Support 2 Overall MAXimum 0.496 0.453 D Only 0.227 0.184 S Only 0.269 0.269 D+S 0.496 0.453 • • • S VLw 1_I •- 1 r.-J Iz Tv\ CH ) r - 1 - r :�.� t ' i u i. -- - 1•0 1 -t.:r t U -.-.... - . 1 ...-:"'.:.. fl,F-- sk- 71' a:�V\ Inl r " . "' ' ..7 1-1 1t — — - �x�l �FZ »t- - 2x10 ;:e a '? .� (9 i ,. y , ./ 6. "t 'AnI +; - ?- ...::.L. t. c. +,a! 1 t_, rls It, '.- t1"1- -- - ELI „ — - / ��.,i - - I 6 .,1_ .` I:� / - R (), ,; 36, ..; - I lit rfLyL k e. L,.. 4-- } T� 1_ r...17 ,A. 7 C-) 2- x 10 5v1S s - FO ATM. ,+1 --K (v 4 0A c�LVn)nl l P = 0 ..5 r;F # 2a P (LZ.Hxg,t / 3H1 /' ” ?Z4' t 631 r.� • 5o x',IS x , `'1S I y ' c c� c- 1 v _ , 2- , -/ Fs/ 7 al 6 ' ` 23 Li Cr2) K a'L Cc-1-1A M -0 01,A-. TM RIPPEY AA ( (..01 - Mutt- - Ml BY k lc. DATE CONSULTING ENGINEERS CHK BY DATE 7650 S.W. Beveland St, Suite 100 SOB NO 12 `�c Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET e L k OF Title Block Line 1 Title : Job # You can changes this area Dsgnr: using the "Settings" menu item Project Desc.: and then using the "Printing & Project Notes : Title Block" selection. • Title Block Line 6 Pitted 2 AUG 2012, 8:29AM ... ,...._ t <-,. ,._,. , ,:.. // `x • Uaits %STRUCTIIKALICALCS112302:ec6 ` • Vhoo earn .....:..: . .:x x -- -;-; . , :x : :Y x. 1:. x r `fiNERC71lc; IhfQ =2o1f" Lic ## .iKIN- 06002662 . � ` Licensee TM RIPPEY,CONSULTING ENGINEERS, ' Description : 2 x 10 roof joist (4 Ton) Material Properties Calculations per NDS 2005, IBC 2009, CBC 2010, ASCE 7 -05 Analysis Method : Allowable Stress Design Fb - Tension 900.0 psi E : Modulus of Elasticity Load Combination 2009 IBC & ASCE 7 -05 Fb - Compr 900.0 psi Ebend- xx 1,600.0ksi Fc - PrIl 1,350.0 psl Eminbend - xx 580.0 ksi Wood Species : Douglas Fir - Larch Fc - Perp 625.0 psi Wood Grade : No.2 Fv 180.0 psi Ft 575.0 psi Density 32.210pcf Beam Bracing : Beam is Fully Braced against lateral- torsion buckling t( /' L ",�p 1 'M M r e - D(0.1) D(0.02) S(0.033) i i i i t ,. l s 2`1-t f. f <E f -�<. K�QNE3<l' ' 4 < , y1 ,, 2 .. 3 . : . . < DaL - 3��. s> C?iCacn;�> c} � ._ sr.>, : s- '�..... > acz`1: ..�e �.,. •�� ��` . i? • 2x10 • Span = 16.330 ft :-*Applied Loads .. , ... -. _ - , . . Service loads entered. Load Factors will be applied for calculations. _ Uniform Load : D = 0.020, S = 0.0330 , Tributary Width = 1.0 ft Point Load: D= 0.10k ©4.Oft .DESIGN SOM. I tY_ ... • - ., -- - _ -- - - - -- . . Design 'OK . Maximum Bending Stress Ratio = 0.972 1 Maximum Shear Stress Ratio - 0.245: 1 Section used for this span 2x10 Section used for this span 2x10 fb : Actual = 1,106.46psi fv : Actual = 50.74 psi FB : Allowable = 1,138.50psi Fv : Allowable = 207.00 psi Load Combination +D +S+H Load Combination +D +S +H Location of maximum on span = 7.675ft Location of maximum on span = 0.000 ft Span # where maximum occurs = Span # 1 Span # where maximum occurs = Span # 1 Maximum Deflection Max Downward L +Lr +S Deflection 0.336 in Ratio = • 582 Max Upward L +Lr +S Deflection 0.000 in Ratio = 0 <360 Max Downward Total Deflection 0.608 in Ratio = 322 Max Upward Total Deflection 0.000 in Ratio = 0 <180 :Maziniurn :Force & .Stresses for Load Combinations: Load Combination Max Stress Ratios Summary of Moment Values Summary of Shear Values Segment Length Span # M V C d C FN C r C m C t Mactual lb-design Fb-allow Vactual fv-design Fv -allow 40 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.500 0.135 1.000 1.100 1.000 1.000 1.000 0.88 494.61 990.00 0.22 24.23 180.00 +D +S +H 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.972 0.245 1.150 1.100 1.000 1.000 1.000 1.97 1,106.46 1,138.50 0.47 50.74 207.00 +D +0.750L+0.7505+H 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.962 0.245 1.000 1.100 1.000 1.000 1.000 1.70 952.77 990.00 0.41 44.11 180.00 • +D +0.750L+0.7505+0.750W +H 1.100 1.000 1.000 1.000 Length = 16.330 fi 1 0.962 0.245 1.000 1.100 1.000 1.000 1.000 1.70 952.77 990.00 0.41 44.11 180.00 40+0.750L+0.7505+0.5250E +H 1.100 1.000 1.000 1.000 Length = 16.330 ft 1 0.962 0.245 1.000 1.100 1.000 1.000 1.000 1.70 952.77 990.00 0.41 44.11 180.00 Overall: Maximum - Deflections .:Unfactored :Loads: •: • Load Combination Span Max. " - -' Dell Location in Span Load Combination Max. ' +' Dell Location in Span D +S 1 0.6077 8.083 0.0000 0.000 S Title Block Line 1 Title : Job # You can changes this area Dsgnr: using the °Settings" menu item Project Desc.: and then using the "Printing & Title Block" selection. Project Notes Title Block Line 6 Printed: 2AUG 2012, 8 29N t . {Fikep:12012 Proiects, 112302=: Mc' �biniedr. NlechaiieaLUpits1STALICTURACICALCS112302 :6116,• „ ;: :.1Nao:d <>Beam::rxh. rz x % xRx %. h ,n yx.x x rrxs;rx:::xx : x ,.Ver:ti•1Lii °�,k- >: „iric; ssa3.2ot1; �a:s.�t Lic #; .KIN '> ;,Licensee :,TM RIPPEY CONSULTING ENGINEERS Description : 2 x 10 roof joist (4 Ton) R13actions�- 'Unfacto • `' ' t•etl ���” � Support notation : Far left is #1 Values in KIPS :Vertical � � . ::. � �:�: �� :�.: :� Load Combination Support 1 Support 2 Overall MAXimum 0.508 0.457 D Only 0.239 0.188 S Only 0.269 0.269 D +S 0.508 0.457 • cr. • I\�r:J �I -- io ) - ern 6r &1.I,Jr. W 2 v v -- n-/ z_ tc �b \5} S4'1 >..I IS .\ .3 �• Lac i ( - 1--) , 1��v. lr.J cz. 1 c• \.1 ?0-Na ( I _�+`(✓�,.1t �> l• • t `:�f,fir t: :. 7 .ryrF01 (may 4 e 'T(C] 1,._) O N`.51 4N-1. Lbf rJ • Z 4\-c2-11.- W ?v Af II\ \ 6: ;'. St1 e tfc— (^) 5L -p T 5F > /S, 1 ' SZ8 ri-F Wp� = �6'S't / ro,t1 7 o n 2, = I, 1 1//,1 k AsTN a- . F 1 = ?Pr,/ lac 'NS" 2,215 = - Sew ‘" f, L/1671116-, !/� r P• 1 S 1i/ 1 0S • TM REPIPEY BY /1 DATE .6 \ 1G / . I L CONSULTING ENGINEERS CHIC BY DATE 7650 S.W. Beveland St, Suite 100 JOB NO / 234, Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET C.Z OF N r-Q L( .- 'fot.1 1 -1 (4) t 7 • t oc k11t.3 t -.1 'S k. -r--i ? r et e_.-7-1 = 15 'S\` 14 =• I t'S1 X 15 p) Fa ! ! cl) 2x10 1 I Y A t I I I I I ,.- .��O.% Y -1W WT = �a 61-111 I I I C- a-05w1 .- i c - )c� 1 1 3' ■ -f- ,, I 1 i ��� t1 1 I 1 I N/ 6.'31 j1. 3 ._ .. 10 9 (F 1 4-41 - "I ' ' _ ` 5 rsp- X ZZ, 4 F) S 4 5 _ I S �N Nu. % / ' - - lot — t:Vl X13 4- L o tcp l l.! e, C7F i C -u„ 1,16, R, GI p. a al, ,n R 1 = 2-0 PLF x 11 -1' I = //G " i- ; / 5 9 * 2 " /A= /5 x 2 Z1 o PLF % 2' ^6'• Z- W 8 V = i *A_ 1 2-1 x2'-e :' LI'Sy 7 V rz__ wklo b r`'Z- 1MA TM R IPPE /(L ( 2- ).t\h 1----... 1146,4-1-1- IA mIT5 BY KV�� DATE YssY CONSULTING ENGINEERS CHK BY DATE 7650 S.W. Beveland St, Suite 100 IOB NO ii:Se.Y(--- Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET GYM OF ,1; '. , c? 4/ I . / ( 7.\-- Ill, `�,_ V '' /_o Ft -r n li / = 4O 'I- 14 ‘?1` \V \A r ∎.1 C 3�RPx y��z= ( -r- C . I 1 i ) KS / Y - Io� / �t i,�0 x - ~ € ' 3�3 #I- i1 .035> , I IO`Y x 0, Cpl ' = - 7 1 -i CP ( .1-tip' l,.e.,rt� F12e)rn fl i" 14- 13.< -s ;c. a,.I B T 2\ t3 4 l -4 41 -____,a_r_. 6„,, p IZA NIT (AO '. K W Lam) 2h\ o 1 =.V° . '" 1. ‘ - ? St r-C D • Tv c art r"‘- C ILA A .L�(l TNI RIPPED' M (.CA7 - 1� C_ 1-%__. �1-� IAA 1 BY Il) DATE CONSULTING ENGINEERS CHK BY DATE 7650 S.W. Beveland St, Suite 100 JOB NO 123b'L Tigard, Oregon 97223 Phone (503) 443 -3900 SHEET61 OF ' ' Title Block Line 1 Title : Job # You can changes this area Dsgnr: using the 'Settings' menu item Project Desc.: and then using the °Printing & Title Block" selection. Project Notes . Title Block Line 6 Printed 15 AUG 2012, 8 27AM ' 11 . 401'd , , , B6 i i, < .: �Fib'p:12012 PIq cts112302 MMCormeck l�AedienicetUnitstSTRUCTURALICALCS112302 ,eo6;: . , . .. , x �,' ' . . -.� - " x B ki:61.6 :10Verfi.114:;• • Lk :ft ; °KW= 0 • • -, . z , " "Licensee':-- 883 -201 ui 1 . 1 , 1 • CALC,i1NC 1 • Description : (3) 2 x 10 joists - (2) 4 Ton units) Material Properties Calculations per NDS 2005, IBC 2009, CBC 2010, ASCE 7 -05 Analysis Method : Allowable Stress Design Fb - Tension 900.0 psi E : Modulus of Elasticity Load Combination 2009 IBC & ASCE 7 -05 Fb - Compr 900.0 psi Ebend- xx 1,600.0 ksi Fc - Prll 1,350.0 psi Eminbend - xx 580.0 ksi Wood Species : Douglas Fir - Larch Fc - Perp 625.0 psi Wood Grade : No.2 Fv 180.0 psi Ft 575.0 psi Density 32.210pcf Beam Bracing : Beam is Fully Braced against lateral- torsion buckling . ." c.)F 11?-111j •D1 1v c-. 1 I , / DI~ t D(0.199) S(0.208) D(0.237) S(0.2 S(0.033) + i l � i i i 1 1 S . t ;.• :.,; --:§ ; �s , t' �� � r, s � �s. su f ks ' ' � r .� :s fir e�t��`?i� c� .' £ s .= is .: o ... s, r *, , y �+� .. �' ; .. , l " a'`�°1 ;;` ia;, a. ;.:s; • /' • .. 3 -2x10 • • - .•�� :' ; Pi 1S _ �' t jH Span = 18.583 ft Applied .Loads > ;~. ; - Service loads entered. Load Factors will be applied for calculations. Point Load: D= 0.2370, S= 0.2710 k @ 7.0 ft Point Load: D = 0.1990, S = 0.2080 k @ 4.0 ft Uniform Load : D = 0.020, S = 0.0330 , Tributary Width = 1.0 ft :: DESIGN SUMMARY_ : : - _ . : . _ ._. _ ._ -:• - _.. _ - _:__ ..._ __._... - -- . Design OK _ • Maximum Bending Stress Ratio = 0.882 1 Maximum Shear Stress Ratio = 0.190 : 1 Section used for this span 3 -2x10 Section used for this span 3 -2x10 fb : Actual = 1,004.21 psi fv : Actual = 39.25 psi FB : Allowable = 1,138.50psi Fv : Allowable = 207.00 psi Load Combination +D +S +H Load Combination +D+S +H Location of maximum on span = 7.062ft Location of maximum on span 0.000 ft Span # where maximum occurs = Span # 1 Span # where maximum occurs = Span # 1 Maximum Deflection = Max Downward L +Lr +S Deflection 0.373 in Ratio 598 Max Upward L +Lr +S Deflection 0.000 in Ratio = 0 <360 . Max Downward Total Deflection 0.653 in Ratio = 341 Max Upward Total Deflection 0.000 in Ratio = 0 <180 ::Maximum Forces &Stresses-for'Load Combinations Load Combination Max Stress Ratios Summary of Moment Values Summary of Shear Values Segment Length Span # M V C d C FN C r C m C t Mactual Ib- design Fb -allow Vactual fv-design Fv -allow +D 1.100 1.000 1.000 1.000 Length = 18 583 fl 1 0.441 0.095 1.000 1.100 1.000 1.000 1000 2.34 436.89 990.00 0.47 17.11 180.00 +D +S +H 1.100 1 000 1.000 1.000 Length =18 583 ft 1 0.882 0.190 1.150 1.100 1.000 1.000 1 000 5 37 1,004.21 1,138.50 1.09 39.25 207.00 - +D+0.750L+0.750S +H 1.100 1.000 1.000 1.000 . Length = 18.583 fl 1 0 871 0.187 1.000 1.100 1.000 1.000 1.000 4.61 86235 990.00 0.94 33.71 180.00 +D+0.750L +0 750S+0.750W +H 1.100 1000 1.000 1.000 Length = 18.583 ft 1 0.871 0.187 1.000 1 100 1.000 1000 1.000 4.61 862.35 990.00 0.94 33.71 180.00 +D+0.750L +0.750S +0 5250E +H 1.100 1.000 1.000 1.000 • Length = 18 583 ft 1 0.871 0.187 1.000 1.100 1.000 1.000 1000 4.61 862.35 990.00 0.94 33.71 180.00 Ove Maximum Deflections - - Ufifactore d .Loads:: .i • - Load Combination Span Max. "-° Den Location in Span Load Combination Max. ' +' Defl Location in Span D +S 1 0.6532 8.920 0.0000 0 000 6 la / • • •Tit le Block Line 1 Title : Job # You can changes this area Dsgnr: using the "settings" menu item Project Dnon: and then using the "Printing & TiUeB|oo�ao�x�m. Project Title Block Line 0 _,� ., , /_.. ,�, , _ Printed: -^ 2012, 817AA4 �� ' • _-. ii' . =,~. -——,_^=-, • Description : QV2x1O joists ';q Ton units) �'��, !��_����,� Support notation : Far left is #1 Vatues in KIPS Load Combinatio Support 1 Support 2 Overall MAXimum 1.128 0.77 D Only 0.490 0.318 S Only 0.639 0.453 D+S 1.128 0.771 - - -- - '' - - - '---' - '------ • • 1 � Wind and Seismic Loads on Mechanical Unit Worksheet Calculates the wind and seismic forces for a rooftop mounted mechanical unit based on the ASCE 7-05 or the 1998 UBC OSSC, using the more conservative value. Hold down forces are calculated based on 0.6D + (W or 0.7E) load cases. Wind and Seismic Loads on Mechanical Unit Windspeed := 100mph Exposure := "B" Fastest Mile :_ no (Windspeed is a fastest mile value ?) Seismic Parameters SDS := 0.706 ap : = 2.5 R : = 6 IE := 1.0 Building Dimensions Category := "II" Roof Elevation := 23ft • Mechanical Unit Dimensions Displacement :_ "Mech Unit" - - - - -- Weight 6371b - — — -- UnitHeight := 33in Width := 46in Length := 74in Curb := 14in SUMMARY Method_Used = "ASCE 7 -05 - Analytical Procedure 6.5" D = 637 lb Displacement = "Mech Unit" • E ASD = 157 lb ° �-e` w S h seismic = 2.542 ft E— W = 431 lb 1 1 (#/ wa 7 4IC 1 11 VvJ -S X131 # /jN'► 2 9 sW S h d = 1.958 ft X = 3.503 ft TWind = 50 lb ' v SztiZSa i, Notes: 1 seismic = —77 lb 1. Positive sign convention shown. Negative values indicate opposite direction 2. X equals the width of the unit minus 4' I Sy y 1 NSV CT tel.+ T C71Z • GIB ARROW MECHANICAL CONTRACTORS, INC. 10330 S.W. TUALATIN RD. /, TUALATIN, OREGON 97062 , //4 e_ � cD / Z — d O T 3 6 PHONE: (503) 692 -1565 FAX: (503) 691 -1879 7 R 0 ‘S I Sc.--.0(12.4-vii . • DESIGN OF HVAC BASE UNITS CONNECTION TO MANUFACTURED ROOF CURB DESIGN CRITERIA: • SEISMIC USE GROUP: I OR II • SEISMIC DESIGN CATEGORY: D,E, OR F • HEAVIEST UNIT TOTAL WEIGHT: WP = 1600# TOTAL LATERAL FORCE (USING ASCE 7 -02 9.6.1.3) 0.4 ap SDS WP IP z Fp = 1 + 2— RP(1.4) h ap =1-0� -- -- SDS = 1.0 (max) WP =1600# • IP =1.0 RP= 2.5 z = UNIT ATTACHMENT POINT IN STRUCTURE ABOVE BASE h = ROOF HEIGHT ABOVE BASE z =1.0 FOR ROOF TOP HVAC UNITS Fp (0 .4)(1 .0)(1 .0)(1600)(1.0) ( + 2(1.0)) 2.5 (1.4) Fp =549# CHECK, Fpm = 0.3 SDS WPIP Fpi = (0.3)(1 .0) (1600) (1.0) = 343# < 549# OK. USE 549# _ .. ARROW MECHANICAL CONTRACTORS, INC. 10330 S.W. TUALATIN RD. TUALATIN, OREGON 97062 PHONE: (503) 692 -1565 FAX: (503) 691 -1879 OVERTURNING ON UNITS: 3.5' 1.5' MIN. MIN. •• = 16001# Fp =549# G.C. 2.0' MAX. • A END VIEWHVAC UNIT DIMENSION REQUIREMENTS MOT = (Fp) (Vert. Dist. to Center of Gravity) = (549)(2.0)=1098 FT - LBS • MR = (Wp) (Reduction for Load Combination) (Least Horiz. Dist. to Center of Gravity) = (1600)(0.9X1.5) = 2160 FT - LE MR >Mor TENSION AND UPLIFT CONNECTION NOT REQUIRED DESIGN FOR SHEAR ONLY. (4) #10 SCREWS BASE UNIT (20 GA) r „r AT LOCATIONS SHOWN.. • ' A A • r r. • r - (4) #10 SCREWS • • �r 4 r ii; AREA, CONDENSER COIL END . . • PLAN VIEW DETAIL A -A • - SCREW DESIGN: • • 549 ``� , D - ?pi ▪ V (ACTUAL) = =137# / SCREW I CJ b y G i 4 SCREWS L,r e 4T �fl • <" V (ALLOWABLE) =177# / SCREW IN 20 GA MATERIAL (RI F : ER 49438) k p ,G017 177#> 137# OK ��i rs, �9t • t -_... �? USE (4) #10 SCREWS CHAM�� • REQUIRED OUTDOOR VENTILATION AIR IN ACCORDANCE WITH TABLE 403.3 2010 OMSC UNIT AREA SQUARE . PEOPLE NUMBER OF O.S.A. CFM PER MIN. SERVED FOOTAGE PER 1000 SQ -FT PEOPLE CFM / SQFT PERSON O.S.A. CFM ' GP -8 Office 623 5 3 -- 5 16 TOTAL -- 623 -- 3 -- -- 16 REQUIRED OUTDOOR VENTILATION AIR IN ACCORDANCE WITH TABLE 403.3 2010 OMSC UNIT AREA SQUARE PEOPLE NUMBER OF O.S.A. CFM PER MIN. SERVED FOOTAGE PER 1000 SQ -FT PEOPLE CFM / SQFT PERSON O.S.A. CFM GP -9 Office 1214 5 6 -- 5 30 GP -10 Office 1332 5 7 -- 5 33 Confrence Room 265 50 13 -- 5 66 TOTAL -- 2811 -- 26 -- -- 130 p 1 GAS PIPE CALCULATIONS Based on 2010 OMSC Table C402.4(3) Schedule 40 Metallic Pipe, 2.0 PSI Inlet Pressure GAS INPUT DELIVERY EQUIPMENT BTU PRESSURE GP -6 115,000 2 PSI GP -7 115,000 2 PSI GP -8 60,000 2 PSI TOTAL LOAD 290,000 2 PSI LONGEST RUN 205' GAS PIPE SIZING BASED ON 2 PSI DELIVERY AT 300' SIZE MAX. CAPACITY 1" 449,000 3/4" 232,000 • • • l 1 GAS_ PIPE CALCULATIONS Based on 2010 OMSC Table C402.4(3) Schedule 40 Metallic Pipe, 2.0 PSI Inlet Pressure GAS INPUT DELIVERY EQUIPMENT BTU PRESSURE GP -9 115,000 2 PSI GP -10 115,000 2 PSI TOTAL LOAD 230,000 2 PSI LONGEST RUN 175' GAS PIPE SIZING BASED ON 2 PSI DELIVERY AT 200' SIZE MAX. CAPACITY 1" 566,000 3/4" 293,000 • 0 (0 )a , - C17 ac g:: i. e-P -6 -I ' c « / . / . ; " : 48N .T NMT NET NHT AND NVT 018 -060 HEATING 8 CD WW 1 Packaged Heating /Cooling Units - Installation, Start -Up and Service Instructions CONTENTS . - •• Page - . ,.•.:: ::: x: 1: >:•::- • ': • : J.. _:• ` SAFETY CONSIDERATIONS 1 '` • ` '"- General I . : " - - - Job Data 1 RECEIVING AND INSTALLATION 1 ' , Step 1 — Check Equipment 1 Y .. • IDENTIFY MACHINE , , • INSPECT SHIPMENT ' ?:':: • Step 2 — Provide Unit Support 4 M . l � � � `\ � • , h �K ,. : : : . • ROOF CURB -: : o r: • SLAB MOUNT , , f • Step 3 — Provide Clearances 4 1 e'•` Step 4 — Rig and Place Unit 4 '' ' Step 5 — Connect Condensate Drain 5 . • - : - Step 6 — Install Venting 6 Step 7 — Install Gas Piping 6 Step 8 — Install Duct Connections 7 Fig. 1 — Model 48NLT, NMT, NET, NHT and NVT Step 9 — Install Electrical Connections 8 • HIGH VOLTAGE CONNECTIONS • SPECIAL PROCEDURES FOR 208 -V OPERATION • CONTROL VOLTAGE CONNECTIONS • HEAT ANTICIPATOR SETTING 4► WARNING • TRANSFORMER CIRCUIT PROTECTION Before performing service or maintenance operations PRE - START -UP 10,11 on unit, turn off unit main power switch. Electrical shock START -UP 11 -20 could cause personal injury. MAINTENANCE 20-26 General — The 48NLT, NMT, NET, NHT and NVT • NOTE TO INSTALLER — Before the installation, READ units are fully self - contained, combination gas heating/ THESE INSTRUCTIONS CAREFULLY AND COM- cooling units designed for outdoor installation. See Fig. 1. PLETELY. Also, make sure the User's Manual and Re- The units are shipped in a vertical configuration and may placement Guide are left with the unit after installation. be installed either on a rooftop or converted to horizontal configuration when placed on a ground -level cement slab. SAFETY CONSIDERATIONS Job Data — Necessary information consists of: Installation and servicing of air conditioning equipment machine location drawings, piping drawings, field wiring can be hazardous due to system pressure and electrical corn- diagrams and rigging guide. ponents. Only trained and qualified personnel should in- stall, repair or service air conditioning equipment. Untrained personnel can perform basic maintenance func- RECEIVING AND INSTALLATION Lions of cleaning coils and filters. All other operations should be performed by trained service personnel. When working Step 1 — Check Equipment on air conditioning equipment, observe precautions in the IDENTIFY MACHINE — The machine model number and literature, tags and labels attached to the unit and other safety serial number are stamped on machine identification plate. precautions that may apply. Check this information against shipping papers and job data. Follow all safety codes. Wear safety glasses and work INSPECT SHIPMENT — Inspect for shipping damage while gloves. Use quenching cloth for unbrazing operations. Have fire extinguisher available for all brazing operations. machine is still on shipping pallet. If machine appears to be damaged or is torn loose from its anchorage, have it exam- . A WARNING ined by transportation inspectors before removal. Forward claim papers directly to transportation company. Manufac- Improper installation, adjustment, alteration, service, main- turer is not responsible for any damage incurred in transit. tenance or use can cause carbon monoxide poisoning, fire Check all items against shipping list. Immediately notify or an explosion which can result in personal injury or the nearest Carrier Air Conditioning office if any item is • unit damage. Consult a qualified installer, service agency missing. or gas supplier for information or assistance. The quali- fled installer or agency must use only factory- authorized To prevent loss or damage, leave all parts in original pack - kits or accessories when modifying this aroduct. ages until installation. Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without Incurring obligations. Book11 14 PC 111 Catalog No 564 -920 Printed In U.S.A. Form 48NT -2051 Pg 1 11.91 Replaces: 48NT -19SI Tab to la r , t 0 l I) V i4, 4 7 To 3g P..El o f n t i ° n &' t f 7 Table 1 — Physical Data (cont) UNIT SIZE 48 042 1 � 1�1 �1� �I�I Wf�f�l� NOMINAL CAPACITY (ton) 314 4 5 i OPERATING WEIGHT (lb) 496 I 500 I 500 I 550 I 556 CIP 1 680 T 586 f 586 604 I 610 I 616 I 616 QMSSORS Reciprocating Hermetic, 3500 Rpm REFRIGERANT' R -22 REFRIGERANT METERING DEVICE AocuRater• Piston CONDENSER COIL Rowe 2 Flnafln. 20 CONDENSER FAN Nominal Airflow (Cfm) 2500 3000 I 3500 20 minal Motoor Hp sfngfe.p ahsse 1 3'i 11 1 (three-phase) 'h I Wi 1 EVAPORATOR COIL Rows 3 4 Finsltn. 14 14 EVAPORATOR FAN Nominal Speed (Rpm) 1400 I 1100 1600 2000 I 3450 Diameter x Motor Hp - Width ( 10 x /0 ) )) 14 3 1 FURNACE SECTION Sumer OriSes No. 3 44 4. 44 4 42 5 44 6 44 3 44 4 44 5 44 6 42 3 44 4 44 5 44 6 42 Bunp�i�eyr O l� )) Plahrrel Gas B Or Ortflfl su er ) Pa Propane 355 465 454 5 55 6. 55 3 .55 455 6 55 B 54 3 66 4 56 555 654 P I . .drill size) Natural Gas 018 77 n� r (In.) 009 Propene RETURN-AIR s FILTERS (eq In.)t 720 816 960 Cleanable 480 [ 544 I 640 'Operating charge Is Dated on unit nameplate tRe e disposable uir 0 d type ied Tilt r areas f� based on the larger of the ARI -rated (Air Conditioning & Refrigeration Institute) cooing airflow or the heating airflow at a velocity of 300 ff/rrdn for high - capacity type. Air filter pressure dr must not exceed 0 08 In wg ® Step 5 — Connect Condensate Drain prevent the pan from overflowing. Prime the trap with water. NOTE When installing condensate drain connection be sure If the installation requires draining the condensate water to comply with local codes and restrictions. away from the unit, connect a drain tube using a minimum The unit disposes of condensate water through a' /4 -in. of 7 /6 -in. OD copper tubing,' /4 -in. galvanized pipe or 3 /4 -in. NPT drain fitting. See Fig. 2 and 3 for location. plastic pipe. Do not undersize the tube. Pitch the drain tube Install a 2 -in. trap at the drain fitting to ensure proper downward at a slope of at least one inch in every 10 ft of drainage. See Fig. 5. Make sure the outlet of the trap is at horizontal run. Be sure to check the drain tube for leaks. least one -in. lower than the unit drain pan connection to UNIT CORNER WT (LB) A B C 0 ?ILT024 100 RIM 100 2-0' p NHT024 101 101 ` ��,` ✓ /..• L -..:. 1lK c� 103 4 r. � ilk � � NLT038 107 IIEMIIEIIII 107 1 , : `� fl r Nfir 1 1'? 1111111r411111 11111 09 o se 1 1 ;8 or NMT042 110 140 140 110 ,1•11,97-_- ' 2 110 110 /' A NHT042 117 117 SPREADER BAR `, •" ; , NVT042 124 125 (BOTH SIDES) /y/ NL - .Tr 128 9 129 � �- `• — . 130 1 • 1:. 131 4' -0• NHT048 131 161 162 132 B / NT0 131 161 162 132 I II NLT080 80 136 165 5 166 137 NMT080 138 166 167 139 NHT060 139 168 169 140 NVT060 139 168 169 140 Fig. 4 — Suggested Rigging 5 ��,_ -- S 4. UNIT YYT CORNER WT LBIKd UNIT ELECTRICAL CHARACTERISTICS LB KG A B ' C 0 48NFTT038 2 011160. 208/230/3/60. 460 /3/60 ' 530 241 117/53 147/87 148/87 118/54 48NVT036 208/230/180, 208230/3/60. 460/3/60 538 243 119/54 148187 149/68 120/54 48NHT042 201 ,230 /1/60.208/23013 /60.460/3180 550 249 122/55 152169 153/69 123/58 46NViO42 206/ 130 /1180, 208d230080.480/3160 556 252 124/56 153/89 154770 125/57 'IL• f' 208230/1/60, 208/230/3,60, 46013/60 574 261 128/58 158172 159/72 129/59 48NMITT048 208290 11/60.208/230/3160, 460/3/80 580 263 130/59 159/72 160/73 131/59 8"-. ... a y4 48NHT048 208/230/1/60, 208/230/3/60.460 /3/60 586 r 265 131/59 161/73 162/73 132160 2293.8 94.6 48NVT048 2081230/1/60. 208/230/3/60. 460/380. 566 265 131/59 ' 161/73 162/73 132/60 l B e = i C 48NLT080 208 /230/180.20823013 /60.460/3180 ' 604 274 136/82 165/75 166/75 137/82 t 48NMT060 208/230/180, 208230/3160, 46013/60 610 277 13883 166/75 167/76 139/83 u in• 48NHT060 208230!1/60, 208230/3160.46013/6 ' 616 280 139/63 168/76 169/77 140/64 MIT CAP 7 --f � i '` 1 48NVT' 060 2061230/1/60, 20823013/60. 4608/60 , 616 280 139/63 168/76 .169/77 140/64 • aide r NOTE. Clearances must be maintained to prevent recirculation of air from r . : ,.. condenser-fan discharge. :" . REQUIRED CLEARANCES TO COMBUSTIBLE MATERIAL - In. (mm) - Maximum Extension of Overhang 48 (1219.2 e • ce ar es 9 Unit Top 36 (914. J' eeu•- ra s7r.e sae o rie' a ,ro•' a nr ....715 , .7 Duct Side of Unit .. . 6 Min. (152.4 Min. G+ ur.o i .e m Side Opp Ducts . 30 (762.0 ? F 1 : RETURN Side of Unit, 0 t' . 1 1 1,_ AIR w nn ewvt r I REQUIRED CLEARANCES FOR SERVICING - In. (mm) l e• Blower Access Panel Side . .. . 30 (762.0) AIR rt+ELU� I � e Control Box Access Side 30 (762.0) V` I i I I I I W A a - ** o � . � `.3 OPENI G D 30.8 01.. 100.0 TOP VId. r i 014. OM Sine) t , we DIA. 1(7(711/70. EOM MOM ACC159 RAIN SHIELD , O•TIW01 SIWI.r OPTION. NOINI 019C0I0B1 MERE Sax AIR 0719010 Am WENim \ 0001 * * It It V I 1 I „ ,�. a H =it 1ii " 1 ik , � r2 3/4' 1 1111�1�_ t 8 419/18"+► �► L,n 114 v i i Ili It Sr o 115.4 6 tzv 1 914 2' MI s i.0 S 0. DXIR ACC® I« 120.8 IH -1.111/111. h .��~ M4 , m e' e9o.a 50.6 19.0 1950 2 se in - 141 03 CaNCrnW oM,N aunlr pow vtFOr LEFT SIDE VIEW Ats1rt SIDE VIEW Maxim Fig. 3 - 48 Dimensional Drawing, Sizes NHT038 - NVT080 6 6 i 7 ci + 1 0 48TC Gas Heat/Electric Cooling C Packaged Rooftop • turn to the exper 3 to 15 Nominal Tons Product Data 0 WeatherMakee _ ...naili • , . .• . a' IThri , ... - J.- : . , •tr.,...-1-.,- ; ....„-- ..:,-... ---: • „ , . .. --..,:-.-f..ff - i . .. ! 3 luuth.,..suker or - 1gFe ----::-, = ....;7 ;kt:. Awl ; , - it tr ii= , --__,--, : _.,-- ..,-k; - • • . .....___y-. ; -.----!-:„----- -.---_----.! • ------"-- - • e ut..„. . ..:.-- -- i , -IT: -,-- . , . . ...• ..•_ ... ;'4 . ----- - - ,., :. 1 :-._..._!,,,__- _,-, ._, .,..c ...•.-.), •....... _.__ .. _ _. 1 ._------ C08813 . _ ... & IISNRAE Puron. • ComPLIAN the ernAlonirrotaly nom] rotrkpaara I 6 P 6;' -1-10 Table 2 - AHRI COOLING RATING TABLE COOLING NOM. NET COOLING TOTAL POWER UNIT STAGES CAPACITY CAPACITY ( SEER EER IEER (TONS) (MBH) A04 1 3 34.6 3.1 13.0 11.00 N/A L (A05 ) 1 4 45.0 4.0 3.0 11.00 N/A A06 1 5 59.0 5.5 13.0 10.75 N/A A07 1 6 70.0 6.4 N/A 11.00 11.2 A08 1 7.5 88.0 8.0 N/A 11.00 11.2 A09 1 8.5 97.0 8.8 N/A 11.00 11.2 • Al2 1 10 117.0 10.6 N/A 11.00 11.2 COOLING NOM. NET COOLING TOTAL POWER UNIT STAGES CAPACITY CAPACITY ( SEER EER IEER (TONS) (MBH) 008 2 7.5 83.0 7.5 N/A 11.00 11.7 D09 2 8.5 99.0 9.0 N/A 11.00 11.7 V D12 2 10 114.0 10.3 N/A 11.10 11.8 F-- D14 2 12.5 140.0 12.9 N/A 10.80 11.0 co D16 2 15 174.0 16.1 N/A 10.80 11.7 LEGEND NOTES: AHRI - Air Conditioning, Heating and Refrigeration 1. Rated in accordance with AHRI Standard 210/240 or Institute Test Standard 340/360, as appropriate. ASHRAE - American Society of Heating, Refrigerating 2. Ratings are based on: and Air Conditioning, Inc. Cooling Standard: 80 °F (27 °C) db, 67 °F (19 °C) wb EER - Energy Efficiency Ratio indoor air temp and 95 °F (35 °C) db outdoor air temp. IEER - Integrated Energy Efficiency Ratio IEER Standard: A measure that expresses cooling SEER - Seasonal Energy Efficiency Ratio part-load EER efficiency for commercial unitary air conditioning and heat pump equipment on the basis of weighted operation at various load capacities. U ASHRAE 3. All 48TC units comply with ASHRAE 90.1 Energy Standard for minimum SEER and EER requirements. C �. 4. 48TC units comply with US Energy Policy Act (2005). O �� COMPLIANT To evaluate code compliance requirements, refer to state and local codes. r ui...s CERTIFIED_ Use at the AHRI Wiled TM Mat kdralas e nmrAeWaa/s PaneOmm In the program Far win:alba a<aeMUam tr aablal w ahlmtlay.a� 8 t,-P - C'; ` 1 -t- J o Table 7 - PHYSICAL DATA (COOLING) 3 - 6 TONS 48TC *A04 48TC *A0� 48TC *A08 48TC *A07 Refrigeration System # Circuits / # Comp. / Type 1 / 1 / Scroll 1 / 1 / Scroll 1 / 1 / Scroll 1 / 1 / Scroll Puronerefrig. (R -410A) (lbs-oz) 5 -10 8 -8 10 -11 . 14 -2 Humidi -MiZer Purone refrig. charge NB (lbs - oz) 8 -11 14 -13 16 -0 22 -5 Metering Device Acutrol Acutrol Acutrol Acutrol High - press. Trip / Reset (psig) 630 / 505 630 / 505 630 / 505 630 / 505 Low-press. Trip / Reset (prig) 54 / 117 54 / 117 - - 54 / 117 - 54 / 117 - Compressor Capacity Staging ( %) 100% 100% 100% 100% Evap. Coll • Material (Tube /Fin) Cu/A1 Cu/AI Cu /AI Cu / Al Coil type 3 /8 -in RTPF 3 /8 -in RTPF 3 /8 -in RTPF 3 /8 -in RTPF Rows /FPI 2/15 2/15 4/15 4/15 Total Face Area (ft 5.5 5.5 5.5 7.3 Condensate Drain Conn. Size 3 /4 -in 3 /4 -in 3 /4 -in 3 /4 -in Evap. Fan and Motor O Motor Qty / Drive Type 1 / Belt 1 / Belt 1 / Belt - I- .0 H Max B 1.2 1.2 1.2 - a v r RPM Range 560 -854 560 -854 770 -1175 - v a Motor Frame Size 48 48 48 - g Fan Qty / Type 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal - Fan Diameter (in) 10 x 10 10 x 10 10 x 10 - Motor Qty / Drive Type 1 / Belt 1 / Belt Belt - A m Max BHP 1.2 1.2 1.5 L RPM Range 770 -1175 770 -1175 1035 -1466 - 7 a Motor Frame Size 48 48 56 - m Fan Qty / Type 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal - 2 Fan Diameter (in) 10 x 10 10 x 10 10 x 10 - O Motor Qty / Drive Type 1 / Belt 1 / Belt 1 / Belt 1 / Belt ` Max BHP 1.2 1.2 1.5 2.4 ✓ m RPM Range 560 -854 560 -854 770 -1175 1073 -1457 . v a Motor Frame Size 48 48 48 56 S °' Fan Qty / Type 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal Fan Diameter (in) 10x 10 10 x 10 10 x 10 10 x 10 V Motor Qty / Drive Type 1 / Belt 1 / Beft 1 / Belt 1 / Beft 7 o Max BHP 1.2 1.2 2.4 2.9* n as RPM Range 770 -1175 770 -1175 1035 -1466 1173 -1518 z a. Motor Frame Size 48 48 56 56 • 0) Fan Qty / Type 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal FanDiameter(in) 10x10 10x10 10x10 10x10 Motor Qty / Drive Type 1 / Belt 1 / Belt 1 / Belt 1 / Belt • m Max BHP 2.4 2.4 2.9 3.7 rs a g RPM Range 1035 -1466 1035 -1466 1303 -1687 1474 -1788 lie a. a. Frame Size 56 56 56 56 el Fan Oty / Type 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal 1 / Centrifugal Fan Diameter (in) 10 x 10 10 x 10 10 x 10 10 x 10 Cond. Coll Material (Tube /Fin) Cu/A1 Cu/A1 Cu/A1 Cu/AI Coil type 3/8-in RTPF 3 /8 -in RTPF 3 /8 -in RTPF 3 /8 -in RTPF Rows /FPI 1/17 2/ 2/17 2/17 Total Face Area (ft 14.6 18.5 16.5 21.3 Humid) - MiZer Coil Material (Tube /Fin) Cu / Al Cu / Al Cu / Al Cu / AI Rows..Finsfin. 1/17 2/17 2/ 2/17 Total Face Area (ft 3.9 3.9 3.9 5.2 Cond. fan / motor Qty / Motor Drive Type 1/ Direct 1/ Direct 1/ Direct 1/ Direct • Motor HP / RPM 1/4 / 1100 1/4 / 1100 1/4 / 1100 1/4 / 1100 Fan diameter (in) 22 22 22 22 Filters RAFIlter # /Size(in) 2/16x25x2 2/16x25x2 2/16x25x2 4/16x16x2 OA inlet screen # /Size(in) 1 /20x24x1 1 /20x24x1 1 /20x24x1 1 /20x24x1 NOTE: Humidi -MiZer is not available with Novation condenser coil models, only Round Tube / Plate Fin (RTPF). * 575V motor utilizes 3.7 BHP. 12 1 L Cr+ `Ld 7 et - t1 Ci CURBS & WEIGHTS DIMENSIONS — 48TC 04 -07 RO1ES ��(• -- -- 31-3/8 I I [8181 1 DIMENSIONS ARE IN INCHES. DIMENSIONS IN I I ARE IN MILLIMETERS 2 flio CENTER Of GRAVITY 32.1/1 ECONOMIZER HOOD [8181 1O2TI0'AL1 16 3 E. DIRECTION OF AIR FL0R (4061 . t • ��� /� / / \ 1 25 -5 /8 1011/8 II II � \V` RETURN 17711 /4 X1 , � ® RETURN AIR RETURN 411111 \ l — J IB AIR ' � E Ali rW • CONDENSATE • 11.3/4 • I DRAIN OPENING 44511 • 1 IN BASEPAX SUPPL' 76-117 29-3/8 18-118 1 �" AIR 16i)] [Tail SUPPLY , 14591 J/ AIR 1 6-1 /B 14.1/4 11- �__:, + . V 1 4111 [363] 13121 1 SEE THRU THEN 6 -I/4 I-- i i 1 l BASE CHART x [157 1 - - - -` - - 176 f -- 3 -3/8 - • 12 -118 4-- (851 25 —^ LUE 13011 - (6361 (1701 HOOD ..---- 18.1/2 TOP (4(01 10-1/2 1•I /1 (2653 (321 . . • — * p K ((181 E STD. ILTER LECTRICAL CONDENSATE • DRAIN I ° - j DISCONNECT _ _ / •i 25-1/8 _ _ I I LOCATION [6381 CONDENSER — • 16 -314 RETURN AIR COIL I COIL === — B• . IL [28918 I SUPPL 11A1R AIR I I / 2I-1/4 OPTIONAL • 0 L _ J 15391 FACTORY TORT , I 1 6.1/8 ������ I INSTALLED - = i-- 04941 11557 C 6 -5/8 1 OUTLET 11687 11111 (1521 I - - -- 'I 6 -5 /8 . 26-3/4 8•,4. 4• 8 11681 16811 BAROMETRIC 31 -1/4 RELIEF 3-3/4 17931 FLOW (951 46.3/4 SUPPLT [11811 AIR r� AIRURN RIGHT LEFT r•-- .. 1 CONTROL 801 • INDOOR BLOWER FILTER ACCESS PANEL (TOOL SSI COMP • ACCESS PANEL ACCESS ACCESS CONDENSER • ® • PANEL I COIL • INDOOR COIL DISCONNECT OPTIOWAL I . HANDLE ACCESS PANEL - __ —_— • FACTORY - -L�_ �jf j00 ' II: : 00 .1 2-5/8 HANDLE - 8-3/8 BACK (611 30 -1/8 (2131 TOP (1641 CURB + (4.3/8 WIDTH (18881 FRONT - 1HRU-THE-BASE CHART UNIT 1 6 THESE HOLES REOUIRED FOR USE 33 3/8 18 5/8 CONNECTION SIZES CRBTNPWR001A01. 003601 48TC-A04 (8411 14121 A 13/8' (351 DIA FIELD POWER SUPPLY HOLE THREADED WIRE REO•D HOLE 4872 f84 t/8 1(3711 B 2' (501 DIA POWER SUPPLY KNOCKOUT CONDUIT SIZE USE SIZES MI.) 33 ■ 1/2' ACC 7/8' 122 21 48TC -A06 184/3/8 841 1 (31 1 11 C 1 3/4' 1511 DIA GAUGE ACCESS PLUG 1 112' 240 7/8' 122.21 48TC-A0/ 41 3/8 14 1/8 • D 7/8• 1211 DIA FIELD CONTROL WIRING HOLE 9 • 3 /4' (001,0031 POWER I 1 /8' 118 41 110513 13171 E 3/4' -I4 HPT CONDENSATE DRAIN _244 10031 1/2' FPT GAS 1 3/16' (30 OI E 1/2' -14 WEPT GAS CONNECTION FOR 'THRU- THE-BASEPAN' FACTORY OPTION. G 7 1/2 • (641 DIA POWER SUPPER KNOCK-OUT FITTINGS FOR ONLY I, O, d 7 ARE PROVIDED 4 SELECT EITHER 3/4 OR 1/2' FOR POWER, DEPENDING ON WIRE SIZE (001) PROVIDES 3/4• (PT THRU CURB 44 FLANGE d FITTING • A10484 Fig. 1 - Dimensions 48TC 04 -07 18 , 6- f'. -- , 7, 1 r 1 c CURBS & WEIGHTS DIMENSIONS - 48TC 04 -07 (cont.) STD UNIT CORNER CORNER CORNER CORNER C G HEIGHT UNIT WEIGHT WEIGHT (A) WEIGHT (B) WEIGHT (C) WEIGHT (0) LES KG LBS KG LBS. KG LBS KG LBS KG I P 1 48TC -AC4 483 219 111 50 125 51 131 59 116 53 39 [ 23 (5841 16 3/8 [4161 (48TC -AC5 531 2L4 124 56 139 63 145 66 129 59 39 [9911 23 [584) 17 [4321 48 -A 258 131 59 _IC/ 61 154 10 131 6? 39 [991] 23 [5841 17 1/4 [4381 48TC -A01 652 296 150 68 169 76 176 80 151 71 39 [9911 23 [5841 20 1/8 [5111 *STANDARD UNIT WEIGHT I WITH LOW HEAT A WITHOUT PACKAGING FOR OPTIONS & ACCESSORIES, REFER TO THE PRODUCT DATA CATALOG CORNER A CORNER B r , - 4 0 • co . illid n. goo oo _. CORNER D I - -- CORNER C FRONT ' TOP A10485A Fig. 2 - Dimensions 48TC 04 -07 \ \` I . C08337 Fig. 3 - Service Clearance LOC DIMENSION CONDITION 48 —in (1219 mm) Unit disconnect is mounted on panel A 18 —in (457 mm) No disconnect, convenience outlet option 18 —in (457 mm) Recommended service clearance 12 —in (305 mm) Minimum clearance 42 —in (1067 mm) Surface behind servicer is grounded (e.g., metal, masonry wall) B 36 —in (914 mm) Surface behind servicer is electrically non — conductive (e.g., wood, fiberglass) Special Check for sources of flue products within 10 —ft of unit fresh air intake hood C 36 —in (914 mm) Side condensate drain is used 18 —in (457 mm) Minimum clearance 48 —in (1219 mm) No flue discharge accessory installed, surface is combustible material D 42 —in (1067 mm) Surface behind servicer is grounded (e.g., metal, masonry wall, another unit) 36 —in (914 mm) Surface behind servicer is electrically non — conductive (e.g., wood, fiberglass) Special Check for adjacent units or building fresh air intakes within 10 —ft of this unit's flue outlet 19 48ES —A Comfort"" 13 SEER Single— Packaged Air Conditioner and Gas Furnace System with Puron® (R -410A) Carrier Refrigerant Single and Three Phase turn to the experts 2 to 5 Nominal Tons (Sizes 24 -60) Prod Data Innovative Unit Base Design On the inside a high -tech composite material will not rust and incorporates a sloped drain pan which improves drainage and helps rP P P P g P inhibit mold, algae and bacterial growth. On the outside metal base 1111 111rails provide added stability as well as easier handling and rigging. �1;1; 1� Convertible duct configuration Unit is designed for use in either downflow or horizontal al Ng applications. Each unit is converted from horizontal to downflow and includes horizontal duct covers. Downflow operation is provided in the field to allow vertical ductwork connections. The I I basepan seals on the bottom openings to ensure a positive seal in the vertical airflow mode. Efficient operation High - efficiency design offers SEER (Seasonal Energy Efficiency Ratios) of up to 13.5 and AFUE (Annual Fuel Utilization Efficiency) ratings as high as 80.4 %. Energy - saving, direct spark ignition saves gas by operating only when the room thermostat calls for heating. Standard units are O furnished with natural gas controls. A low -cost field installed kit for propane conversion is available for all units. A09034 48ESN units are dedicated Low NOx units designed for Fig. 1 - Unit 48ES -A California installations. These models meet the California maximum oxides of nitrogen (NOx) emissions requirement of 40 nanograms/joule or less as shipped from the factory and MUST be Single- Packaged Products with Energy- Saving Features and installed in California Air Quality Management Districts and Puron® refrigerant. wherever a Low NOx rule exists. • Up to 13.5 SEER Durable, dependable components Compressors are designed • Up to 80.4% AFUE for high efficiency. Each compressor is hermetically sealed against • Factory- Installed TXV contamination to help promote longer life and dependable • ECM Motor - Standard operation. Each compressor also has vibration isolation to provide • Direct Spark Ignition quieter operation. All compressors have internal high pressure and overcurrent protection. • Low Sound Levels Monoport inshot burners produce precise air -to -gas mixture, • Dehumidification Feature which provides for clean and efficient combustion. The large FEATURESBENEFITS monoport on the inshot (or injection type) burners seldom, if ever, One -piece heating and cooling units with low sound levels, easy requires cleaning. All gas furnace components are accessible in one installation, low maintenance, and dependable performance. compartment. Puron Environmentally Sound Refrigerant is Carrier's unique Turbo- tubular' heat exchangers are constructed of aluminized refrigerant designed to help protect the environment. Puron is an steel for corrosion resistance and optimum heat transfer for l FC refrigerant which does not contain chlorine that can harm the improved efficiency. The tubular design permits hot gases to make ozone layer. Puron refrigerant is in service in millions of systems, multiple passes across the path of the supply air. proving highly reliable, environmentally sound performance. In addition, dimples located on the heat exchanger walls force the Easy Installation hot gases to stay in close contact with the walls, improving heat • Factory- assembled package is a compact, fully self- contained, transfer. combination gas heating/electric cooling unit that is prewired, ECM Motor is standard on all 48ES -A models. pre - piped, and pre- charged for minimum installation expense. Direct -drive PSC (Permanent Split Capacitor) condenser -fan These units are available in a variety of standard and optional motors are designed to help reduce energy consumption and heating/ cooling size combinations with voltage options to meet provide for cooing operation down to 40 °F (4.4 °C) outdoor residential and light commercial requirements. Units are temperature. Motomrastere II low ambient kit is available as a lightweight and install easily on a rooftop or at ground level. The field - installed accessory. high tech composite base eliminates rust problems associated with Thermostatic Expansion Valve - A hard shutoff, balance port ground level applications. TXV maintains a constant superheat at the evaporator exit (cooling cycle) resulting in higher overall system efficiency. 1 . . &-f--e AHRI* CAPACITIES Cooling Capacities and Efficiencies UNIT 48ES -A NOMINAL TONS STANDARD CFM NET COOLING EER" SEERt CAPACITIES (Btuh) (2 2 800 23,000 11.0 2-1/2 1000 28,400 11.2 13.5 - -- 36 - - - - -3- - - - 1200 -- - 34:400 -- - - - - -- 11.0 - - -- - -- - 13.0 - - -- 42 3 -1/2 1400 40,500 11.2 13.2 48 4 1600 46,500 11.2 13.2 60 5 1750 57,000 11.0 13.4 LEGEND Notes: dB -Sound Levels (decibels) 1. Ratings are net values, reflecting the effects of circulating fan heat. db-Dry Bulb Ratings are based on: SEER - Seasonal Energy Efficiency Ratio Cooling Standard: 80 °F (26.7 °C) db, 67 °F wb (19.4 °C) indoor entering -air wb-Wet Bulb temperature and 95 °F db (35 °C) outdoor entering -air temperature. COP - Coefficient of Performance 2. Before purchasing this appliance, read important energy cost and effi- • Air Conditioning, Heating & Refrigeration Institute. ciency information available from your retailer. < **At "A" conditions -80 °F (26.7 °C) indoor db /67 °F (19.4 °C) indoor wb & l 95 °F (35 °C) outdoor db. U) t Rated in accordance with U.S. Government DOE Department of Energy) LU c0 test procedures and/or AHRI Standards 210/240. ao c1 Gas Heating Capacities and Efficiencies UNIT 48ES -A HEATING INPUT (Btuh) OUTPUT CAPACITY TEMPERATURE RISE AFUE ( %) • (Btuh) RANGE °F ( °C) 3 2 0040 40,000 32 (16.7 -33.3) 80.0 24060 48,000 80.0 30060 48.000 25 -55 80.0 36060 60,000 (13.9 -30.6) 80.0 42060 47,000 78.5 36090 72,000 79.3 42090 90 000 73,000 35 -65 80.4 48090 73,000 (19.4 -36.1) 80.4 60090 73,000 80.4 48115 30-60 60115 115,000 93,000 (16.7-33.3) 80.3 60130 130,000 103,000 (19.4-36.1) 78.9 LEGEND AFUE - Annual Fuel Utilization Efficiency NOTE: Before purchasing this appliance, read important energy cost and efficiency information available from your retailer. A- Weighted Sound Power Level (dBA) UNIT 48ES -A STANDARD TYPICAL OCTAVE BAND SPECTRUM (dBA without tone adjustment) RATING dBA 125 250 500 1000 2000 4000 8000 24 - - -30 76 66.0 66.0 70.5 71.5 67.5 62.5 58.5 30 -- -30/50 75 66.0 63.5 68.0 68.5 67.5 61.5 55.0 36 - -- 30/50/60 75 64.0 83.5 68.0 70.5 64.5 61.0 81.0 42 - -- 30/50/60 77 67.0 67.0 69.5 70.5 68.0 65.5 61.0 48 - -- 30/50/60 78 71.5 - 66.5 73.0 71.5 68.0 84.0 57.0 60--- 30/50/60 78 74.5 66.5 70.0 70.0 66.5 64.0 57.0 Tested in accordance with AHRI Standard 270 (not listed in)J1RI). r 4 PHYSICAL DATA UNIT SIZE 24040 2406111) 30040 30060 36060 36090 42060 42090 • NOMINAL COOLING CAPACITY (ton) 2 2 2 -1/2 2 -1/2 3 3 3 -1/2 3 -1/2 NOMINAL HEATING INPUT (Btu/hr) 40,000 60,000 40,000 60,000 60,000 90,000 60,000 90,000 SHIPPING WEIGHT** lb. • 311 311 316 316 326 326 420 420 SHIPPING WEIGHT** (kg) 141 141 143 143 148 148 191 191 COMPRESSORS Scroll Quantity 1 REFRIGERANT (R -410A) Quantity lb. 4.8 4.8 6.2 6.2 6.4 6.4 6.1 6.1 Quantity (kg) 2.2 2.2 2.8 2 8 2.9 2 9 2.7 2.7 REFRIGERANT METERING DEVICE TXV OUTDOOR COIL Rows...Fins/m. 1..21 1.. 21 1.. 21 1...21 1...21 1...21 1...21 1...21 Face Area (sq ft) 10.2 10.2 11.9 11.9 15.4 15.4 13.6 13.6 OUTDOOR FAN Nominal CFM 2800 2800 3000 3000 3200 3200 3600 3600 Diameter in. 24 24 24 24 24 24 26 26 Diameter (mm) 609.6 609.6 609.6 609.6 609.6 609.6 660.4 660.4 Motor Hp (Rpm) 1/5 (810) 1/5 (810) 1/5 (810) 1/5 (810) 1/5 (810) 1/5 (810) 1/5 (810 1/5 (810) Q INDOOR COIL I Rows...Fins/in. 2...17 2..17 3...17 3...17 3...17 3..17 3...17 3...17 f/) Face Area (sq ft) 3 7 3.7 3.7 3.7 3.7 3.7 4.7 4.7 W INDOOR BLOWER CO ct Nominal Cooling Airflow (Cfm) 800 800 1000 1000 1200 1200 1400 1400 Size in. 10x10 10x10 10x10 10x10 11x10 11x10 11x10 11x10 Size (mm.) 254x254 254x254 254x254 254x254 279.4x254 279.4x254 279.4x254 279.4x254 Motor HP (RPM) 1/2 (1050) 1/2 (1050) 1/2 (1050) 1/2 (1050) 3/4 (1000) 3/4 (1000) 3/4 (1075) 3/4 (1075) FURNACE SECTION* Burner Orifice No. (Qty...Drill Size) Natural Gas Factory Installed 2...44 2...38 2...44 2..38 2...38 3..38 2...38 3...38 Propane Gas 2...55 2...53 2...55 2...53 2...53 3...53 2...53 3...53 HIGH - PRESSURE SWITCH 650 +/- 15 (paig) Cut -out Reset (Auto) 420 +/- 25 LOSS -OF- CHARGE / LOW - PRESSURE 20 +/_ 5 SWITCH (Liquid Une) (psig) cut -out Reset 45 +!- 10 (auto) RETURN -AIR FILTERSt# Throwaway Size in. 20x20x1 20x24x1 24x30x1 (mm) 508x508x25 508x610x25 610x782x25 5 z ELERIIGL - UNIT 01. ,OMIT BEIOXT 10 /NM clx1U OF 01111111 1x/101 ii OMIT ex1RAeT1116TIta x0 •A• I T 2 1" 48E81-41)A14(040/060120 2001210 -1.10 104 +101.0 40.1/6 1011 22.13/16 155/14 /66.1 15.11116 110.5 • 'u• 1.151+0 21- 11 1 9.15111 16(61 - /450301015/005)(313)5 206/210 -1. 206/110.3•40 140.0 42.116 1070 22.13/11 311.4 15.5/11 345.9 15.15118 411,4 ry [252.41 1615.71 [252.41 48161.411/5364060/0001(343/17 2001230 -1. 201/210-6 -60 511 140.6 46.116 1172 22.13114 519.4 15.5114 588.1 14 -510 422.9 �j 3-7118 48E61•/1)A66(010/0901/0 480-1-61 , 333 130.9 44.1/0 1172 22.13116 311.4 13.5/11 _ 308.1 14.510 422.t 20711 Uatrs 110Lr1/[ coNxtN e1owT 18 /I9 FIEOUIRED CLEARANCES TO COe�USTIBtg 6110E [���qy Z • 1ei3i11 01100$ al, SUPPLY © 48011.46)/241040/010130 2081130 63.1 00.6 27.4 11.1 41.4106.3, 10.5 TOP tF WET Uw [ �6] I� SKID 42 161./111/30104140811(1570 108/230 41.0 31.1 11.0 20.0 12.0 11.1 100.T 19.1 SIB O l 2 D 0lI{$ I u 1353.11 , - -- - 1 4018(- /x11361010 /0901(31570 008/231141.0 21.1 93.8 28.1 13,0 43.4111.0 50.1 10TT011 q 0517 0 10.11 W 00ALI � � ( O'TIOa1t t 1513(- 4114311010 /000110 460 47.8 21.7 20.1,04.(41.5116.6 52.9 FLUE P 36 1111.11 'z t NI - _�� \ -. 6WPlT /� : � � ' NEC. MOUSED C LEARANCES j C/) 15-13/11 0 AIN �.,, _ _� p [10/.61 Wpia6 / "' :: ',; :, \ ' ,' , p110 EMI AL TAILS 9ATA AELEVALT FOR ALL FACTORY INSTALLED ICES (611 1512[011 UN1T1013. FOIEA 0TOY IIOE I1 [+066.11 1 ��� l�, l 1 i ,; 1� �\ �' OPTIONS Y'[11 LCOeONIIp T 1x0 13/61001 S RFACES PC1[R [NTH SIX [913.01 IER O Ill '' - . ll, �`' ...... ;! hII Ili 10 �- 3-3111 11 1660U10ED 6$13 ACAS, PORN (NTRS � . 42 [1061.81 O eo6 A F: \ [61.01 �1a1 ® OPERATION CIEAAANCE OPERATION AND SERVICING 0015001 COIL j'' . ' - (YAP. COIL ACCESS 6101 INC 13 [1114.01 ril •1 ' * ti �•... -- PM 11115 601E 1 T' (INCEPT FOR ICY 1153011212110) OxIT TOP 02 1+021.03 /e 1124..11 110E OPPOSITE DUCTS 16 1114.01 in glr © -1 DUCT PANEL . 12 7301.01• 110002 COIL t1 12.11 401/0100 OI3IAOC(S:IF O1(T LS PLACED LESS 111111 I1 1301.61 IRON BALL W TCP WEN • ,, •R COIL TSTD,TI 1T3TEN PLRFOA1A10E NAVEL CODA00I$EI CT DIIE13I(IN3 11 CI A0E IN 61 * 31.7/10 [716.31 (n5.4)1 � .3191.81 ' [ll� 1 al C !Illillllllill • • L2e.n ILO. glllllllllllll! 718• (22.21 DIA. IDLE li y - A � L1a COmOL 04111 ` - _ [16.01 I 0AS • . I 6 /0 = • ---ice • I ` • I i. /e ` . D r [103.!1 OPENI • - r 3.3/0 ihs /H • • • 2306 11 .11/ I 1 1 /12.11 - - - - - - 2 503 . s1 t 6 R. 1110•an1 IL 11 , • - T` r:-) 0 111 O (••_, O O i I 1210.01 i �-_ O• (11113 (0 O r - 1 1 r--1 O Di 1 + 1 i 1 1//• [4.0) a.P - 12.13110 ^ �MPAetl LAZIER 1 -13/16 ' 1/2. 7 12.n1.P.T. 17/8• [22.0 1013.11 ....-./.--.... ....-./.--.... 1051 ACC P 11151. ENTIT 5.7.03 55.9 -- 0 32-7/ ■ 2 -I /t5 3/14 • 4.7.17 33-1/ 1 1310. 65.3/+1 [52.41 (4.53 1 (:1221.01 .1/0 m.----- 219./8 1 [230.01 2.0.8 '^• 4 -13/19 01 [3/9.a1� LIFT 8 E VIN FRS �� nr2.23 FEW SEE VtN FEAR VEfI I 48ES5O0214 13701 g I . 48ES -A B RO N SPECIFICATION SHEET , MODEL 684 fi CEILING/WALL FAN Dependable, high performance bathroom TYPICAL SPECIFICATION ventilation. Ventilator shall be Broan Model 684. FEATURES Unit shall have galvanized steel housing with dual GRILLE: integral mounting brackets. It shall be ducted to a roof • Attractive grille conceals interior or wall cap. • Matte white polymeric — blends well with any decor • Torsion spring grille mounting — no tools required Blower assembly shall be removable and have a • White, metal grille kit available (purchase sepa- centrifugal blower wheel and permanently lubricated rately) motor. BLOWER: Air delivery shall be no less and sound level no • Plug -in, permanently lubricated motor greater than valves listed in the °Performance Ratings" • Centrifugal blower wheel charts on this sheet. Air and sound ratings shall be certified by HVI and AMCA licensed. HOUSING: • Rugged, 26 -gage galvanized steel construction Unit shall be U.L. Listed for use over bathtubs and • Sturdy key -holed mounting brackets for quick, showers when connected to a GFCI protected branch accurate installation circuit. • Tapered, polymeric duct fitting with built -in backdraft damper for easy, positive arnca Broan- NuTone LLC certifies that the duct connection and no metallic clatter CERTIFIED models shown herein are licensed to RRTIflG$ bear the AMCA Seal. The ratings Model 2687H & 3687H: Rough-in housings for 2684F shown are based ntestsandproce- 9 9 AMID dures performed i n accordance with finish assemblies (packed 4 per carton). 3687H ru AMCA Publication 211 and AMCA housings include slide channels and mounting "°°°°°° Publication 311 and comply with the 1110 requirements of the AMCA Certified brackets. NCOMM O Ratings Program. °SS SSOCIFIIOII, inc U.L. Listed for use over tubs and showers when — - connected to a GFCI protected branch circuit 2100 HVI (2) CERTIFIED Broan - NuTone LLC, 926 West State Street, Hartford, WI 53027 (1- 800 -637 -1453) REFERENCE QTY. REMARKS Project Location Architect • Engineer Contractor Submitted by Date 50G 990429210 PERFORMANCE RATINGS - MODEL 684 AMCA LICENSED PERFORMANCE Model Static Pressure (in. wg Ps) Total Nominal Duct No. 0.0 0.1 .125 .250 .375 Volts Watts RPM Size 684 CFM 89 89 87 77 59 120 48 1280 4" Round Sones 2.7 3.2 3.3 3.6 3.9 . The performance ratings include the effects of inlet grille and backdraft damper in the airstream. Speed (RPM) shown is nominal. Performance is based on actual speed of test The sound ratings are loudness values in fan sones at 5' (1.5m) in a hemispherical free field calculated per AMCA Std. 301. Values shown are for Installation Type B: Free inlet fan sone levels. Air performance shown is for Installation Type B Free inlet, Ducted outlet. SONES AMPS amca Broan-NuTone LLC certifies that the CERTigtfl models shown herein are licensed to Model HVI Sones AMCA Sones MODEL RRTUt S bear the AMCA Seal. The ratings 0.1" * �� Ps* NUMBER AMPS shown are based on tests and pro - Number A 0.1 PS @0.0 PS cedures performed in accordance 684 2.5 2.7 684 0.5 with AMCA Publication 211 and ' AMCA Publication 311 and comply • There is difference between sone values certified by HVI for residential use ° m o „d„N with the requirements of the AMCA and by AMCA for commerciaVindustrial use. Exact comparison of these R +roOCIRI a M Certified Ratings Program. values is not possible. This difference is mainly due to procedures used to ........ convert measured sound to perceived sound. ANSI S3.4, used by both HVI and AMCA, specifies a procedure for calculating loudness as perceived by a typical listener under specific conditions. HVI establishes values at a 0.50 ' - ' distance of 5 feet from the fan in a ''spherical free field'; AMCA establishes values at a distance of 5 feet in a'hemispherical free field'. HVI and AMCA 0.45 have different rules for rounding sone values. 0.40 HVI PERFORMANCE z 0.35 v MODEL NUMBER SONES CFM @0.1" Ps W 0.30 684 2.5 80 0 CO 0.25 HVI -2100 CERTIFIED RATINGS comply with new t) - ® testing technologies and procedures prescnbed by W 2 1 00 1111,, the Home Ventilating Institute, for off- the -shelf ce 0.20 N V I products, as they are available to consumers. Product performance is rated at 0.1 in. static CL pressure, based on tests conducted in AMCA's 0 0.15 state-of -the-art test laboratory. Sones area measure l— CE RTIFIED of humanly - perceived loudness, based on laboratory measurements. H 0.10 Cl) WEIGHT 8 $ 0.05 4 0.00 ' - - I MOD6 EL NO. I SHIPP8 1b WT. I 0 10 20 30 40 50 60 70 80 90 100 . 11 , ` AIR FLOW RATE (CFM) 61 111 Qg I ® L I s �% • BR N ® Broan - NuTone LLC, 926 West State Street, Hartford, WI 53027 (1- 800 -637 -1453) /14 e. 2 a l 2 - ©o L-13 g COMcheck Software Version 3.8.2 Mechanical Compliance Cert RECEIVED Oregon Energy Efficiency Specialty Code AUG 2 1 2012 CITYOFTIGARD Section 1: Project Information BUILDINGDNISION Project Type: Alteration Project Title : McCormack Properties Construction Site: Owner /Agent: Designer /Contractor: 719f) SW candhurq St. Arrow Mechanical C6P -9 & 10 Garden Level ) 10330 SW Tualatin Rd Tigard, OR 97223 Tualatin, OR 97062 503 -692 -1565 Section 2: General Information Building Location (for weather data): Tigard, Oregon Climate Zone: 4c Section 3: Mechanical Systems List Quantity System Type & Description 2 GP -9 & 10 (Single Zone) : Heating: 1 each - Central Furnace, Gas, Capacity = 115 kBtu/h, Efficiency = 81.00% Et Cooling: 1 each - Rooftop Package Unit, Capacity = 40 kBtu/h, Efficiency = 13.00 SEER, Air- Cooled Condenser Section 4: Requirements Checklist In the following requirements, the relevant code section reference is shown in [1. ' +' denotes that more details exist in the specified code section. Requirements Specific To: GP -9 & 10 : d1. [503.2.3 +j Equipment meets minimum efficiency: Central Furnace (Gas): 80.0 % Et (or 78% AFUE) Le `. [503.2.3 +] Equipment meets minimum efficiency: Rooftop Package Unit: 13.0 SEER Generic Requirements: Must be met by all systems to which the requirement is applicable: Eli. [503.2.1 +] Calculation of heating and cooling loads. Design loads are determined in accordance with the procedures described in the ASHRAE/ACCA Standard 183. Alternatively, design loads have been determined by an approved equivalent computation procedure. ❑ 2. [503.2.1.1 +] Packaged Electric Equipment. Specified packaged electrical equipment has a heat pump as the primary heating source. ❑ Exception: Unstaffed equipment shelters or cabinets used solely for personal wireless service facilities. Location In plans/specs where compliance can be Identified (enter NA if not applicable)" M JA a o. [503.3.1 +] Cooling equipment economizers: The total capacity of all cooling equipment without economizers must be less than 240 kBtu/h. This project lists 80 kBtu/h capacity without economizers. That portion of the equipment serving dwelling units and guest rooms is not included in determining the total capacity of units without economizers. 1 / J p Location in plans/specs where compliance can be identified (enter NA if not applicable)" GO, f6 / Pi �,,..:f Pi TA d4 . [503.2.2 +] Equipment and system sizing. Heating and cooling equipment and systems capacity do not exceed the loads calculated in accordance with Section 503.2.1. ❑ Exception: Required standby equipment and systems provided with controls and devices that allow such systems or equipment to operate automatically only when the primary equipment is not operating. ❑ Exception: Multiple units of the same equipment type with combined capacities exceeding the design load and provided with controls that have the capability to sequence the operation of each unit based on load. Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 1 of 5 r r Location in plans/specs where compliance can be identified (enter NA if not applicable) u1/5. (503.2.3 +] HVAC Equipment Performance Requirements. Reported efficiencies have been tested and rated in accordance with the applicable test procedure. The efficiency has been verified through certification under an approved certification program or, if no 5( certification program exists, the equipment efficiency ratings are supported by data furnished by the manufacturer. 6. [503.2.4.1 +] Thermostatic Controls. The supply of heating and cooling energy to each zone is controlled by individual thermostatic controls that respond to temperature within the zone. Location in plans/specs where compliance can be identified (enter NA If not applicable). 7. [503.2.4.1.1] Heat pump supplementary heat. Heat pumps having supplementary electric resistance heat have controls that, except during defrost, prevent supplementary heat operation when the heat pump can meet the heating load. Location In plans/specs where compliance can be identified (enter NA if not applicable)_ M /A • 5(8. [503.2.4.2] Set point overlap restriction. Where used to control both heating and cooling, zone thermostatic controls provide a temperature range or deadband of at least 5 °F (2.8 °C) within which the supply of heating and cooling energy to the zone is capable of being shut off or reduced to a minimum. O Exception: Thermostats requiring manual change over between heating and cooling modes. Location in plans/specs where compliance can be Identified (enter NA if not applicable) 1 9. [503.2.4.3] Optimum Start Controls. Each HVAC system has controls that vary the start-up time of the system to just meet the temperature set point at time of occupancy. Location In plans/specs where compliance can be identified (enter NA If not applicable) [1 10. [503.2.4.4 +] Off-hour controls. Each zone is provided with thermostatic setback controls that are controlled by either an automatic time clock or programmable control system. O Exception: Zones that will be operated continuously. O Exception: Zones with a full HVAC load demand not exceeding 6,800 Btu/h (2 kW) and having a readily accessible manual shutoff switch. Location in plans/specs where compliance can be identified (enter NA if not applicable): 11. [503.2.4.5 +] Shutoff damper controls. Both outdoor air supply and exhaust are equipped with not less than Class I motorized dampers. O Exception: Gravity dampers shall be permitted for outside air intake or exhaust airflows of 300 cfm or less. Location in plans/specs where compliance can be identified (enter NA if not applicable) 1 O 12. [503.2.4.6 +] Freeze Protection and Snow melt system controls. Freeze protection systems, such as heat tracing of outdoor piping and heat exchangers, including self - regulating heat tracing, include automatic controls capable of shutting off the systems when outdoor air temperatures meet code criteria. M Location In plans/specs where compliance can be identified (enter NA If not applicable)* 1 O 13. [503.2.4.8] Separate air distribution systems. Zones with special process temperature requirements and /or humidity requirements are served by separate air distribution systems from those serving zones requiring only comfort conditions; or shall indude supplementary control provisions so that the primary systems may be specifically controlled for comfort purposes only. Exception: [503.2.4.8 +] Zones requiring only comfort heating or comfort cooling that are served by a system primarily used for process temperature and humidity control. *� Location in plans/specs where compliance can be identified (enter NA If not applicable). IA 0 14. [503.2.4.9] Humidity control. If a system is equipped with a means to add or remove moisture to maintain specific humidity levels in a zone or zones, a humidity control device is provided. p o Q Location in plans/specs where compliance can be Identified (enter NA if not applicable): • 15. [503.2.4.9.1] Humidity control. Where a humidity control device exists it is set to prevent the use of fossil fuel or electricity to produce relative humidity in excess of 30 percent. Where a humidity control device is used for dehumidification, it is set to prevent the use of fossil fuel or electricity to reduce relative humidity below 60 percent. O Exception: Hospitals, process needs, archives, museums, critical equipment, and other non- comfort situations with specific humidity requirements outside this range. p� Location in plans/specs where compliance can be identified (enter NA If not applicable)_ 0 16. [503.2.4.9.2] Humidity control. Where a humidity control device exists it is set to maintain a deadband of at least 10% relative humidity where no active humidification or dehumidification takes place. O Exception: Heating for dehumidification is provided with heat recovery or heat pumping and the mechanical cooling system efficiency is 10 percent higher than required in section 503.2.3, HVAC equipment performance requirements. Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck • Page 2 of 5 Location in plans/specs where compliance can be identified (enter NA if not applicable) 5 (17. [503.2.5] Ventilation. Ventilation, either natural or mechanical, is provided in accordance with Chapter 4 of the International Mechanical Code. Where mechanical ventilation is provided, the system has the capability to reduce the outdoor air supply to the minimum required by Chapter 4 of the International Mechanical Code. Location in plans/specs where compliance can be identified (enter NA if not applicable)• ❑ 18. [503.2.5.1 +] Demand controlled ventilation (DCV). DCV is required for spaces larger than 500 ft2 for simple systems and spaces larger than 150_ft2 for_multiple zone systems._ ❑ Exception: Systems with energy recovery complying with Section 503.2.6 ❑ Exception: Spaces less than 750 ft2 (69.7 m2) where an occupancy sensor turns the fan off, closes the ventilation damper, or doses the zone damper when the space is unoccupied. Q • Location in plans/specs where compliance can be Identified (enter NA If not applicable) `'fir JA ❑ 19. [503.2.5.2 +] Kitchen hoods. Kitchen makeup is provided as required by the Oregon Mechanical Specialty Code. ❑ Exception: Where hoods are used to exhaust ventilation air that would otherwise be exhausted by other fan systems. ❑ Exception: Kitchen exhaust systems that include exhaust air energy recovery complying with section 503.2.6. Location in plans /specs where compliance can be identified (enter NA if not applicable)• 11/% ❑ 20. [503.2.5.3 +] Enclosed parking garage ventilation controls. In Group S-2, enclosed parking garages used for storing or handling automobiles employs automatic carbon monoxide sensing devices. Location in plans/specs whore compliance can be identified (enter NA if not applicable) 14/A ❑ 21. [503.2.6 +] Energy recovery ventilation systems. Individual fan systems that have both a design supply air capacity of 5,000 cfm or greater and a minimum outside air supply of 70 percent or greater of the design supply air quantity have an energy recovery system. ❑ Exception: Where energy recovery systems are prohibited by the International Mechanical Code. ❑ Exception: Systems serving spaces that are not cooled and are heated to less than 60 °F. ❑ Exception: Where more than 60 percent of the outdoor heating energy is provided from site - recovered or site solar energy. ❑ Exception: Type 1 kitchen exhaust hoods. ❑ Exception: Cooling systems in climates with a 1- percent cooling design wet -bulb temperature less than 64 °F (18 °C). ❑ Exception: Systems requiring dehumidification that employ series -style energy recovery coils wrapped around the cooling coil when the evaporative coil is located upstream of the exhaust air stream. ❑ Exception: Systems exhausting toxic, flammable, paint exhaust, corrosive fumes, or dust. ❑ Exception: Laboratory fume hood systems that include qualifying features. IQ Location in plans/specs where compliance can be identified (enter NA if not applicable) ci22. [503.2.7 +] Duct and plenum insulation and sealing. All supply and return air ducts and plenums are insulated with the specified insulation. When located within a building envelope assembly, the duct or plenum is separated from the building exterior or unconditioned or exempt spaces by a minimum of R-8 insulation. All ducts, air handlers and filter boxes are sealed. Joints and seams comply with Section 603.9 of the International Mechanical Code. ❑ Exception: When located within equipment ❑ Exception: When the design temperature difference between the interior and exterior of the duct or plenum does not exceed 15 °F (8 °C). W 23. [503.2.7.1.1 +t Low - pressure duct systems. All longitudinal and transverse joints, seams and connections of low- pressure supply and return ducts are securely fastened and sealed with welds, gaskets, mastics (adhesives), mastic -plus- embedded -fabric systems or tapes installed in accordance with the manufacturer's installation instructions. ❑ Exception: Continuously welded and locking -type longitudinal joints and seams on ducts operating at static pressures less than 2 inches w.g. pressure classification. Location in plans/specs where compliance can be identified (enter NA if not applicabte)• ❑ 24. [503.2.7.1.2 +] Medium - pressure duct systems. All ducts and plenums designed to operate medium - pressure are insulated and sealed in accordance with Section 503.2.7. Pressure classifications specific to the duct system are dearly indicated on the construction documents. 1� Location In plans/specs where compliance can be identified (enter NA if not eppicable)• I ` ❑ 25. [503.2.7.1.3 +] High - pressure duct systems. Ducts designed to operate at high - pressure are insulated and sealed in accordance with Section 503.2.7. In addition, ducts and plenums are leak- tested in accordance with the SMACNA HVAC Air Duct Leakage Test Manual. Location In plans/specs where compliance can be identified (enter NA if not eppllrable)• A /• re Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 3 of 5 t' I t 26. [503.2.9.1 +] Air system balancing. Each supply air outlet and zone terminal device is equipped with means for air balancing in accordance with the requirements of IMC 603.17. Discharge dampers intended to modulate airflow are prohibited on constant volume fans and variable volume fans with motors 10 horsepower. Location in plans/specs where compliance can be identified (enter NA if not applicable) '27. [503.2.9.3 +] Manuals. The construction documents require that an operating and maintenance manual be provided to the building owner by the mechanical contractor. See long description for specifications. Location in plans/specs where compliance can be identified (enter NA if not applicable)" ❑ 28. [503.2.10 +] Air System Design and Control. Each HVAC system having a total fan system motor nameplate hp exceeding 5 hp meets the provisions of Sections 503.2.10.1 through 503.2.10.2. Location in plans/specs where compliance can be identified (enter NA if not applicable)" j . A ❑ 29. [503.2.10.1 +] Allowable fan floor horsepower. Each HVAC system at fan system design conditions does not exceed the allowable fan system motor nameplate hp (Option 1) or fan system bhp (Option 2) as shown and calulated in requirement details. ❑ Exception: Hospital and laboratory systems that utilize flow control devices on exhaust and /or return to maintain space pressure relationships necessary for occupant health and safety or environmental control shall be permitted to use variable volume fan power limitation. O Exception: Individual exhaust fans with motor nameplate horsepower of 1 hp or less. Location in plans/specs where compliance can be identified (enter NA if not applicable)" 1 JA ❑ 30. [503.2.10.2 +] Motor nameplate horsepower. For each fan, the selected fan motor is no larger than the first available motor size greater than the brake horsepower (bhp). ❑ Exception: For fans less than'6 bhp, where the first available motor larger than the brake horsepower has a nameplate rating within 50 percent of the bhp, selection of the next larger nameplate motor size is allowed. ❑ Exception: For fans 6 bhp and larger, where the first available motor larger than the bhp has a nameplate rating within 30 percent of the bhp, selection of the next larger nameplate motor size is allowed. A' Location in plans/specs where compliance can be identified (enter NA if not applicable)* ❑ 31. [503.2.10.3.1] Large Volume Fan Systems. Fan systems over 8,000 (7 m3/s) cfm without direct expansion cooling coils that serve single zones reduce airflow based on space thermostat heating and cooling demand. A two-speed motor or variable frequency drive reduces airflow to a maximum 60 percent of peak airflow or minimum ventilation air requirement as required by Chapter 4 of the International Mechanical Code, whichever is greater. ❑ Exception: Systems where the function of the supply air is for purposes other than temperature control, such as maintaining specific humidity levels or supplying an exhaust system. • Location in plans/specs where compliance can be Identified (enter NA if not applicable)* • ' /A • ❑ 32. [503.2.10.3.2 +] All air-conditioning equipment and air - handling units with direct expansion cooling and a cooling capacity at ARI conditions greater than or equal to 110,000 Btulh that serve single zones have their supply fan operation controlled according to code specific requirements. ❑ Exception: Systems where the function of the supply air is for purposes other than temperature control, such as maintaining specific humidity levels or supplying an exhaust system. Location In plans/specs where compliance can be identified (enter NA if not applicable)" 4 ❑ 33. [503.2.10.4] Series fan - powered terminal unit fan motors. Fan motors for series fan- powered terminal units are electronically- commutated motors and have a minimum motor efficiency of 70 percent when rated in accordance with NEMA Standard MG 1 -2006 at full load rating conditions. Location in plans/specs where compliance can be identified (enter NA if not applicable)" Ni/kA ❑ 34. [503.2.12] Hot Gas Bypass Limitation. For cooling systems <= 240 kBtu/h, maximum hot gas bypass capacity is no more than 50% total cooling capacity. l�y� Location in plans/specs where compliance can be identified (enter NA if not applicable) Section 5: Compliance Statement Compliance Statement: The proposed mechanical alteration project represented in this document is consistent with the building plans, specifications and other calculations submitted with this permit application. The proposed mechanical alteration project has been designed to meet the Oregon Energy Efficiency Specialty Code, Chapter 8, requirements in COMcheck Version 3.8.2 and to comply with the mandatory requirements in the Requirements Checklist. pv l2 Lb 'tee J f2 Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 4 of 5 t' t Name - Title Signature Date • Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 5 of 5 Mec_2dI2. oo'f3T COMcheck Software Version 3.8.2 Mechanical Compliance Certificate Oregon Energy Efficiency Specialty Code • Section 1: Project Information Project Type: Alteration Project Title : McCormack Properties Construction Site: Owner /Agent: Designer /Contractor: • 7190 SW Sandburq St. Arrow Mechanical (GP-6 & 7 First Floor Lev, 10330 SW Tualatin Rd Tigard, OFT972z3 Tualatin, OR 97062 503 -692 -1565 Section 2: General Information Building Location (for weather data): Tigard, Oregon Climate Zone: 4c Section 3: Mechanical Systems List Quantity System Type & Description 2 GP-6 & 7 (Single Zone) : Heating: 1 each - Central Furnace, Gas, Capacity = 115 kBtu/h, Efficiency = 81.00% Et Cooling: 1 each - Rooftop Package Unit, Capacity = 40 kBtu/h. Efficiency = 13.00 SEER, Air- Cooled Condenser • 1 GP-8 (Single Zone) : Heating: 1 each - Central Furnace, Gas, Capacity = 60 kBtu/h, Efficiency = 80.00% Et Cooling: 1 each - Rooftop Package Unit, Capacity = 21 kBtu/h, Efficiency = 13.20 SEER. Air - Cooled Condenser • Section 4: Requirements Checklist In the following requirements, the relevant code section reference is shown in [ ]. ' +' denotes that more details exist in the specified code section. Requirements Specific To: GP-6 8 7 : V1. [503.2.3 +] Equipment meets minimum efficiency: Central Furnace (Gas): 80.0 % Et (or 78% AFUE) d2. [503.2.3 +] Equipment meets minimum efficiency: Rooftop Package Unit: 13.0 SEER Requirements Specific To: GP-8 : �1 [503.2.3 +] Equipment meets minimum efficiency: Central Furnace (Gas): 80.0 % Et (or 78% AFUE) 2. [503.2.3 +] Equipment meets minimum efficiency: Rooftop Package Unit: 13.0 SEER Generic Requirements: Must be met by all systems to which the requirement is applicable: r y1. [503.2.1 +] Calculation of heating and cooling loads. Design loads are determined in accordance with the procedures described in the ASHRAE/ACCA Standard 183. Alternatively, design loads have been determined by an approved equivalent computation procedure. l] 2. [503.2.1.1 +] Packaged Electric Equipment. Specified packaged electrical equipment has a heat pump as the primary heating source. Exception: Unstaffed equipment shelters or cabinets used solely for personal wireless service facilities. Location In plans/specs where compliance can be Identified (enter NA if not applicable)* [ (i J. [503.3.1 +J Cooling equipment economizers: The total capacity of all cooling equipment without economizers must be less than 240 kBtu/h. This project lists 101 kBtu/h capacity without economisers. That portion of the equipment serving dwelling units and guest rooms is not included in determining the total capacity of units without economizers. r Location in plans/specs where compliance can be Identified (enter NA If not applicable)* ( & ScAt is -poYw / f ir2DU' -'T PRTA 1241. [503.2.2 +] Equipment and system sizing. Heating and cooling equipment and systems capacity do not exceed the loads calculated in accordance with Section 503.2.1. Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 1 of 5 t 1 ❑ Exception: Required standby equipment and systems provided with controls and devices that allow such systems or equipment to operate automatically only when the primary equipment is not operating. ❑ Exception: Multiple units of the same equipment type with combined capacities exceeding the design load and provided with controls that have the capability to sequence the operation of each unit based on load. Location in plans/specs where compliance can be identified (enter NA if not applicable)" [/5. [503.2.3 +] HVAC Equipment Performance Requirements. Reported efficiencies have been tested and rated in accordance with the applicable test procedure. The efficiency has been verified through certification under an approved certification program or, if no certification program exists, the equipment efficiency ratings are supported by data furnished by the manufacturer. 2/6. [503.2.4.1 +] Thermostatic Controls. The supply of heating and cooling energy to each zone is controlled by individual thermostatic controls that respond to temperature within the zone. • Location in plans/specs where compliance can be Identified (enter NA If not applicable) ❑ 7. [503.2.4.1.1] Heat pump supplementary heat. Heat pumps having supplementary electric resistance heat have controls that, except dunng defrost, prevent supplementary heat operation when the heat pump can meet the heating load. Location in plans/specs where compliance can be identified (enter NA if not applicable) /8. [503.2.4.2] Set point overlap restriction. Where used to control both heating and cooling, zone thermostatic controls provide a temperature range or deadband of at least 5 °F (2.8 °C) within which the supply of heating and cooling energy to the zone is capable of being shut off or reduced to a minimum. ❑ Exception: Thermostats requiring manual change over between heating and cooling modes. Location in plans/specs where compliance can be identified (enter NA if not applicable) - 0/9. [503.2.4.3] Optimum Start Controls. Each HVAC system has controls that vary the start-up time of the system to just meet the temperature set point at time of occupancy. Location in plans/specs where compliance can be identified (enter NA if not applicable)" d 1 0. [503.2.4.4 +] Off -hour controls. Each zone is provided with thermostatic setback controls that are controlled by either an automatic time clock or programmable control system. ❑ Exception: Zones that will be operated continuously. ❑ Exception: Zones with a full HVAC load demand not exceeding 6,800 Btu/h (2 kW) and having a readily accessible manual shutoff switch. Location in plans/specs where compliance can be Identified (enter NA if not applicable)" ❑ 11. [503.2.4.5 +] Shutoff damper controls. Both outdoor air supply and exhaust are equipped with not less than Class I motorized dampers. ❑ Exception: Gravity dampers shall be permitted for outside air intake or exhaust airflows of 300 cfm or less. Location in plans/specs where compliance can be identified (enter NA if not applicable): M1 /A ❑ 12. [503.2.4.6 +] Freeze Protection and Snow melt system controls. Freeze protection systems, such as heat tracing of outdoor piping and heat exchangers, including self - regulating heat tracing, include automatic controls capable of shutting off the systems when outdoor air temperatures meet code criteria. Location In plans/specs where compliance can be identified (enter NA if not applicable) i A ❑ 13. [503.2.4.8] Separate air distribution systems. Zones with special process temperature requirements and /or humidity requirements are served by separate air distribution systems from those serving zones requiring only comfort conditions; or shall indude supplementary control provisions so that the primary systems may be specifically controlled for comfort purposes only. ❑ Exception: [503.2.4.8 +] Zones requiring only comfort heating or comfort cooling that are served by a system primarily used for process temperature and humidity control. Location in plans/specs where compliance can be identified (enter NA if not applicable) A 0 14. [503.2.4.9] Humidity control. If a system is equipped with a means to add or remove moisture to maintain specific humidity levels in a zone or zones, a humidity control device is provided. Location in plans/specs where compliance can be identified (enter NA if not applicable) ` t�, f A ❑ 15. [503.2.4.9.1] Humidity control. Where a humidity control device exists it is set to prevent the use of fossil fuel or electricity to produce relative humidity in excess of 30 percent. Where a humidity control device is used for dehumidification, it is set to prevent the use of fossil fuel or electricity to reduce relative humidity below 60 percent. ❑ Exception: Hospitals, process needs, archives, museums, critical equipment, and other non - comfort situations with specific humidity requirements outside this range. /� IA Location in plans/specs where compliance can be identified (enter NA if not applicable) � Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cc k Page 2 of 5 f t ❑ 16. [503.2.4.9.2] Humidity control. Where a humidity control device exists it is set to maintain a deadband of at least 10% relative humidity where no active humidification or dehumidification takes place. ❑ Exception: Heating for dehumidification is provided with heat recovery or heat pumping and the mechanical cooling system efficiency is 10 percent higher than required in section 503.2.3, HVAC equipment performance requirements. Location in plans/specs where compliance can be identified (enter NA if not applicable)- ` y E117. [503.2.5] Ventilation. Ventilation, either natural or mechanical, is provided in accordance with Chapter 4 of the International Mechanical Code. Where.mechanical_ventilation-is provided, the system has- the.capability- to-reduce-the outdoor- air-supply -to the- minimum - - -- - - required by Chapter 4 of the International Mechanical Code. Location In plans/specs where compliance can be Identified (enter NA if not applicable) A C.A I L S ❑ 18. [503.2.5.1 +] Demand controlled ventilation (DCV). DCV is required for•spaces larger than 500 ft2 for simple systems and spaces larger than 150 ft2 for multiple zone systems. ❑ Exception: Systems with energy recovery complying with Section 503.2.6 ❑ Exception: Spaces less than 750 ft2 (69.7 m2) where an occupancy sensor turns the fan off, closes the ventilation damper, or doses the zone damper when the space is unoccupied. Location in plans/specs where compliance can be identified (enter NA if not applicable) 11/4-11 ❑ 19. [503.2.5.2 +] Kitchen hoods. Kitchen makeup is provided as required by the Oregon Mechanical Specialty Code. ❑ Exception: Where hoods are used to exhaust ventilation air that would otherwise be exhausted by other fan systems. ❑ Exception: Kitchen exhaust systems that include exhaust air energy recovery complying with section 503.2.6. Location In plans/specs where compliance can be Identified (enter NA If not applicable). I W / `` ' ❑ 20. [503.2.5.3 +] Enclosed parking garage ventilation controls. In Group S-2, enclosed parking garages used for storing or handling automobiles employs automatic carbon monoxide sensing devices. yam` Location in plans /specs where compliance can be identified (enter NA If not applicable): ❑ 21. [5032.6 +] Energy recovery ventilation systems. Individual fan systems that have both a design supply air capacity of 5,000 cfm or greater and a minimum outside air supply of 70 percent or greater of the design supply air quantity have an energy recovery system. ❑ Exception: Where energy recovery systems are prohibited by the International Mechanical Code. (3 Exception: Systems serving spaces that are not cooled and are heated to less than 60 °F. ❑ Exception: Where more than 60 percent of the outdoor heating energy is provided from site - recovered or site solar energy. ❑ Exception: Type 1 kitchen exhaust hoods. ❑ Exception: Cooling systems in dimates with a 1- percent cooling design wet -bulb temperature less than 64 °F (18 °C). ❑ Exception: Systems requiring dehumidification that employ series -style energy recovery coils wrapped around the cooling coil when the evaporative coil is located upstream of the exhaust air stream. ❑ Exception: Systems exhausting toxic, flammable, paint exhaust, corrosive fumes, or dust ❑ Exception: Laboratory fume hood systems that include qualifying features. Location in ptans/specs where compliance can be Identified (enter NA if not applicable)• A/t. s ' 22. [503.2.7 +] Duct and plenum insulation and sealing. All supply and return air ducts and plenums are insulated with the specified Insulation. When located within a building envelope assembly, the duct or plenum is separated from the building exterior or unconditioned or exempt spaces by a minimum of R-8 insulation. All ducts, air handlers and filter boxes are sealed. Joints and seams comply with Section 603.9 of the International Mechanical Code. ❑ Exception: When located within equipment ❑ Exception: When the design temperature difference between the interior and exterior of the duct or plenum does not exceed 15 °F (8 °C). 8 23. [503.2.7.1.1 +] Low - pressure duct systems. All longitudinal and transverse joints, seams and connections of low- pressure supply and return ducts are securely fastened and sealed with welds, gaskets, mastics (adhesives), mastic -plus- embedded -fabric systems or tapes installed in accordance with the manufacturer's installation instructions. ❑ Exception: Continuously welded and locking -type longitudinal joints and seams on ducts operating at static pressures less than 2 inches w.g. pressure classification. • Location In plans /specs where compliance can be Identified (enter NA if not applicable)• ❑ 24. [503.2.7.1.2 +] Medium - pressure duct systems. All ducts and plenums designed to operate medium- pressure are insulated and sealed in accordance with Section 503.2.7. Pressure classifications specific to the duct system are clearly indicated on the construction documents. Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 3 of 5 1 ; N.) h„ Location in plans/specs where compliance can be identified (enter NA if not applicable)* ❑ 25. [503.2.7.1.3 +] High - pressure duct systems. Ducts designed to operate at high - pressure are insulated and sealed in accordance with Section 503.2.7. In addition, ducts and plenums are leak- tested in accordance with the SMACNA HVAC Air Duct Leakage Test Manual. Location in plans/specs where compliance can be identified (enter NA if not applicable)* /6. [503.2.9.1 +] Air system balancing. Each supply air outlet and zone terminal device is equipped with means for air balancing in accordance with the requirements of IMC 603.17. Discharge dampers intended to modulate airflow are prohibited on constant volume fans and variable volume fans_with motors 10 horsepower. _ _ Location in plans/specs where compliance can be Identified (enter NA If not applicable)* • 2 27. [503.2.9.3 +] Manuals. The construction documents require that an operating and maintenance manual be provided to the building owner by the mechanical contractor. See long description for specifications. Location in plans /specs where compliance can be identified (enter NA if not applicable) ❑ 28. [503.2.10 +] Air System Design and Control. Each HVAC system having a total fan system motor nameplate hp exceeding 5 hp meets the provisions of Sections 503.2.10.1 through 503.2.10.2. Location in plans/specs where compliance can be identified (enter NA If not applicable)* Y`1, /A ❑ 29. [503.2.10.1 +] Allowable fan floor horsepower. Each HVAC system at fan system design conditions does not exceed the allowable fan system motor nameplate hp (Option 1) or fan system bhp (Option 2) as shown and calulated in requirement details. ❑ Exception: Hospital and laboratory systems that utilize flow control devices on exhaust and /or return to maintain space pressure relationships necessary for occupant health and safety or environmental control shall be permitted to use variable volume fan power limitation. ❑ Exception: Individual exhaust fans with motor nameplate horsepower of 1 hp or less. J� Location in plars/specs where compliance can be identified (enter NA If not applicable)* A /A. ❑ 30. [503.2.10.2 +] Motor nameplate horsepower. For each fan, the selected fan motor is no larger than the first available motor size greater than the brake horsepower (bhp). ❑ Exception: For fans less than 6 bhp, where the first available motor larger than the brake horsepower has a nameplate rating within 50 percent of the bhp, selection of the next larger nameplate motor size is allowed. ❑ Exception: For fans 6 bhp and larger, where the first available motor larger than the bhp has a nameplate rating within 30 percent of the bhp, selection of the next larger nameplate motor size is allowed. ss ,, Location In plans/specs where compliance can be identified (enter NA if not applicable)* t , /A ❑ 31. [503.2.10.3.1] Large Volume Fan Systems. Fan systems over 8,000 (7 m3/s) dm without direct expansion cooling coils that serve single zones reduce airflow based on space thermostat heating and cooling demand. A two-speed motor or variable frequency drive reduces airflow to a maximum 60 percent of peak airflow or minimum ventilation air requirement as required by Chapter 4 of the International Mechanical Code, whichever is greater. ❑ Exception: Systems where the function of the supply air is for purposes other than temperature control, such as maintaining specific humidity levels or supplying an exhaust system. Location In plans/specs where compliance can be identified (enter NA if not applicable)* /4/• /� " ❑ 32. [503.2.10.3.2 +] All air - conditioning equipment and air - handling units with direct expansion cooling and a cooling capacity at ARI conditions greater than or equal to 110,000 Btu/h that serve single zones have their supply fan operation controlled according to code specific requirements. ❑ Exception: Systems where the function of the supply air is for purposes other than temperature control, such as maintaining specific humidity levels or supplying an exhaust system. �y Location In plans/specs where compliance can be identified (enter NA If not applicable)• r / 4 ❑ 33. [503.2.10.4] Series fan - powered terminal unit fan motors. Fan motors for series fan- powered terminal units are electronically- commutated motors and have a minimum motor efficiency of 70 percent when rated in accordance with NEMA Standard MG 1 -2006 at full load rating conditions. Location in plans/specs where compliance can be identified (enter NA if not applicable)* N/A ❑ 34. [503.2.12] Hot Gas Bypass Limitation. For cooling systems <= 240 kBtu/h, maximum hot gas bypass capacity is no more than 50% total cooling capacity. �� Location In plans/specs where compliance can be Identified (enter NA If not applicable) Section 5: Compliance Statement Compliance Statement: The proposed mechanical alteration project represented in this document is consistent with the building plans, specifications and other calculations submitted with this permit application. The proposed mechanical alteration project has been designed to Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 4 of 5 v meet the Oregon Energy Efficiency Specialty Code, Chapter 8, requirements in COMcheck Version 3.8.2 and to comply with the mandatory requirements in the Requirements Checklist. Dfm.e /....nut y4 uf Date X z Name - Title ✓ S' nat • • • Project Title: McCormack Properties Report date: 08/02/12 Data filename: Untitled.cck Page 5 of 5 [Page Too Large for OCR Processing] [Page Too Large for OCR Processing]