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Specifications (8) li.g 7ST(21.1.J‘c ct.,5"---7160(e),et-st,c)1,._7 7.1,4,,, ,i,lit, ..,4,,L,,,i .4, :j.,,,,,,i,,, • APR 2 . )0, 1 '12 ' ,' �' fig'' a:'t,> Structural Calculations y�7i,,.71V, `° t-`' for New Deck at 13376 SW Ascension Dr Tigard, Oregon April 22, 2015 DESIGN PARAMETERS 2014 Oregon Residential Specialty Code ve ,,2,,.,,,-.4 dws , ' *11,,,,„ 1v. r i 0 „ „ .e., :, ...,,,: ).0:Li....,,,,, , :c2iv R. Ykl,''' ,, F.,0-E.:4WD: t,; Scope of Work: These calculations pertain to one (1) new deck that attaches to an existing residence.This scope of work does not include any analysis of the existing structure. By: sr Date: • 1111 ,HA o o EN CortsuLtin4 F n ineer Chk: Date: 9 s J' tructural. Engineering Job #: 15134 (503)968-9994(phone) (503) 968-8444(fox) Sheet: Of: • I = T -10 c vc-:.- 1 c ► r ,.R C -Tr 9 /o ` a D.E111 { . BY DATE Ilk'[6 -Consulting Engineers ti` = t )„ f q Y 1 i. 5tructuraL Engineering JOB NO_ 1?7 __ (503) 968-9994 p (503) 968-8444 f { SHEET \ OF 1 1 �� Project Title: IHIA! 1 m E1I Engineer: Project ID: Project Descr: - Consulting Lngineers otructural .ngineering iWood Beam File=z;tproreds12015PR-1a15134s-Ilsmieser.ec6 ENERCALC,INC,1983.2015,Bu kt615.1.19,Ver:6.15.1.19 Lic.#: KW-06005543 Licensee-: HAYDEN CONSULTING ENGINEERS Description: joists CODE REFERENCES Calculations per NDS 2012, IBC 2012, CBC 2013,ASCE 7-10 Load Combination Set:ASCE 7-10 Material Properties Analysis Method: Allowable Stress Design Fb-Tension 850.0 psi E:Modulus of Elasticity Load Combination ASCE 7-10 Fb-Compr 850.0 psi Ebend-xx 1,300.0ksi Fc-Pill 1,300.0 psi Eminbend-xx 470.0 ksi Wood Species : Hem Fir Fc-Perp 405.0 psi Wood Grade :No.2 Fv 150.0 psi Ft 525.0 psi Density 27.70 pcf Beam Bracing : Completely Unbraced Repetitive Member Stress Increase { i D(0.0199)L(0.0532) i �D(0.015)L(0.04) x. ' t 2x10 2x10 Span=12.0 ft Span=3.0 ft Applied Loads Service loads entered.Load Factors will be applied for calculations. Load for Span Number 1 Uniform Load: D=0.0150, L=0.040 ksf, Tributary Width=1.330 ft Load for Span Number 2 Uniform Load: D=0.0150, L=0.040 ksf, Tributary Width=1,0 ft DESIGN SUMMARY Desi•n OK Maximum Bending Stress Ratio = 0.912 1 Maximum Shear Stress Ratio = 0.365 : 1 Section used for this span 2x10 Section used for this span 2x10 1b:Actual = 670.86 psi iv:Actual = 43.85 psi FB:Allowable = 735.59 psi Fv:Allowable 120.00 psi Load Combination +D+L+H Load Combination +D+L+H Location of maximum on span = 5.698ft Location of maximum on span - 11.263 ft Span#where maximum occurs = Span#1 Span#where maximum occurs = Span#1 Maximum Deflection Max Downward Transient Deflection 0.182 in Ratio= 791 j Max Upward Transient Deflection -0.126 in Ratio= 570 Max Downward Total Deflection 0.250 in Ratio= 575 Max Upward Total Deflection -0.174 in Ratio= 414 i i — Vertical Reactions Support notation:Far left is#1 Values In KIPS Load Combination Support 1 Support 2 Support 3 Overall MA�Cmum 0.304 0.434 _ --_._---_--- —A__ — —___.. ------- Overall MINimum 0.114 0.170 D Only 0.114 0.170 L Only 0.304 0.454 S Only � Project TitlI 'Ai'D Engineer: Project ID: ' Consulting-ngineers Project Des°r: . 3tructuraL Lngineering Wood Beam File=Z`prtyects12015PR-1ti151343-1tsxsdeser;ec6 ENERCALC,INC 1983-2015,Build:615.1_19,Ver.8.15.1.19 Lic.# : KW-06005543 Licensee: HAYDEN CONSULTING ENGINEERS Description: main beams CODE REFERENCES Calculations per NDS 2012, IBC 2012, CBC 2013,ASCE 7-10 Load Combination Set:ASCE 7-10 Material Properties Analysis Method: Allowable Stress Design Fb-Tension 675.0 psi E:Modulus of Elasticity Load Combination ASCE 7-10 Fb-Compr 675.0 psi Ebend-xx 1,100.0 ksi Fc-Pill 500.0 psi Eminbend-xx 400.0 ksi Wood Species : Hem Fir Fc-Perp 405.0 psi Wood Grade No.2 Fv 140.0 psi Ft 350.0 psi Density 27.70 pcf Beam Bracing : Completely Unbraced D(0.135)L(0.38) + i D(0.1425)L(0.38)lir * * • 3 n�,t, u jr‘ r A6x10 8x10 I Span=8.0ft Span=3.0ft Applied Loads Service loads entered.Load Factors will be applied for calculations. Load for Span Number 1 Uniform Load: D=0.0150, L=0.040 ksf, Tributary Width=9.0 ft Load for Span Number 2 Uniform Load: D=0.0150, L=0.040 ksf, Tributary Width=9.50 ft DESIGN SUMMARY Desi ii n OK Maximum Bending Stress Ratio = 0.7731 Maximum Shear Stress Ratio = 0.486 : 1 Section used for this span 6x10 Section used for this span 6x10 fb:Actual = 416.53 psi fv:Actual = 54.48 psi FB:Allowable = 539.06psi Fv:Allowable = 112.00si Load Combination +D+L+H Load Combination +D+L+H p Location of maximum on span = 3.397ft Location of maximum on span = 7.240ft Span#where maximum occurs = Span#1 Span#where maximum occurs = Span#1 Maximum Deflection Max Downward Transient Deflection 0.053 in Ratio= 1816 Max Upward Transient Deflection -0.023 in Ratio= 3094 Max Downward Total Deflection 0.073 in Ratio= 1320 Max Upward Total Deflection -0.032 in Ratio= 2250 Vertical Reactions Support notation Far left is#1 Values In KIPS Load Combination Support 1 Support 2 _ . Support 3 Overall MAXimum 1.226 2.794 _. ._ Overall MINimum 0.460 1.048 D Only 0.460 1.048 L Only 1.226 2.794 S Only J .. 1-1. 1W,ILItEIEN11 Project Title: Engineer: Project ID: Project Descr: Consulting Lngineers - Structural Lngineering Wood Beam File Z\projects12015PR-1115134S-115mleser.ec6 ENERCALC,INC.1983.2015,Build:6.15.1.19,Ver:6.15.1.19 Lic.#: KW-06005543 Licensee : HAYDEN CONSULTING ENGINEERS Description: landing beams CODE REFERENCES Calculations per NDS 2012, IBC 2012,CBC 2013,ASCE 7-10 Load Combination Set:ASCE 7-10 Material Properties Analysis Method: Allowable Stress Design Fb-Tension 850.0 psi E:Modulus of Elasticity Load Combination ASCE 7-10 Fb-Compr 850,0 psi Ebend-xx 1,300.0ksi Fc-Pr1l 1,300.0 psi Eminbend-xx 470.0 ksi Wood Species :Hem Fir Fc Perp 405.0 psi Wood Grade :No.2 Fv 150.0 psi Ft 525.0 psi Density 27.70pcf Beam Bracing : Completely Unbraced D(0.071)140 2) t t +r '''Ili"[ ' d' f }' 4 E t A \\A , I Span=7.50 ft Applied Loads Service loads entered.Load Factors will be applied for calculations. Uniform Load: D=0.0150, L=0.040 ksf, Tributary Width=5.0 ft DESIGN SUMMARY Desi.n OK Maximum Bending Stress Ratio = 0.860 1 Maximum Shear Stress Ratio = 0.426 : 1 Section used for this span 4x8 Section used for this span 4x8 tb:Actual = 756.75 psi fv:Actual = 51.17 psi FB:Allowable = 880.01 psi Fv:Allowable = 120.00 psi Load Combination +D+L+H Load Combination +D+L+H Location of maximum on span = 3,750ft Location of maximum on span = 6.898 ft Span#where maximum occurs = Span#1 Span#where maximum occurs = Span#1 Maximum Deflection Max Downward Transient Deflection 0.104 in Ratio= 862 Max Upward Transient Deflection 0.000 in Ratio= 0<360 Max Downward Total Deflection 0.143 in Ratio= 627 Max Upward Total Deflection 0.000 in Ratio= 0<240 Vertical Reactions Support notation:Far left is#1 Values in KIPS Load Combination Support 1 Support 2 Overall MAXimum 0.750 0.750 Overall MINimum 0.281 0,281 D Only 0.281 0.281 L Only 0.750 0.750 S Only 1 � ‘J-- (7)1t- ‘f v-44sty A 17 61-D14 61/41)3 i .nt_ 1, (1 ,1 (2-) -2A 10 �� M BY ( DATE 412-1,1l� n a o EN Consulting EO�� ngineers I CrC Ar REV DATE - 5tructuraL Engineering JOB NO.-._Er"? (503) 968-9994 p (503) 968-8444 f SHEET GJ OF (� Project Title: . . ILI ]IIJflENI( Engineer: Project ID: Project Descr: -- Consulting Engineers .3tructuraL Engineering Wood Column File==Z:lproJec1s12015PR-11151345-1lsmleser,ec6 ' ENERCALC,INC,1983.2015,Build:6.15.1.19,Vec6.15.1.19 Lic.#:KW-06005543 Licensee: HAYDEN CONSULTING ENGINEERS Description: landing column Code References Calculations per 2012 NDS, IBC 2012,CBC 2013,ASCE 7-10 Load Combinations Used:ASCE 7-10 General Information Analysis Method: Allowable Stress Design Wood Section Name 4x4 End Fixities Top&Bottom Pinned Wood GradinglManuf. Graded Lumber Overall Column Height 5.0 ft Wood Member Type Sawn (Used for non-slender calculations) Wood Species Hem Fir Exact Width 3.50 in Allow Stress Modification Factors Wood Grade No.2 Exact Depth 3.50 in Cf or CV for Bending 1.50 Fb Tension 575 psi RI 140 psi Area 12.250 in^2 Cf or Cv for Compression 1.150 lx 12.505 in^4 Cf or Cv for Tension 1.50 Fb Compr 575 psi Ft 375 psi ly 12.505 In^4 Cm:Wet Use Factor 1.0 Fc-PrIl 575 psi Density 27.7 pd Incising Factors: Ct:Temperature Factor 1.0 Fc-Perp 405 psi E:Modulus of Elasticity... x-x Bending y-y Bending Axial for Bending 0.80 Cfu:Flat Use Factor 1.0 for Elastic Modulus 0.95 Kf:Built-up columns 1.0 NDS 15.3 2 Basic 1100 1100 1100 ksi Use Cr:Repetitive 7 No(tori-gln rely) Minimum 400 400 Brace condition for deflection(buckling)along columns: X-X(width)axis: Unbraced Length for X-X Axis buckling=5.0 ft,K=1.0 Y-Y(depth)axis: Unbraced Length for X-X Axis buckling=5.0 ft,K=1.0 Applied Loads Service loads entered.Load Factors will be applied for calculations. Column self weight included: 11.782 lbs*Dead Load Factor AXIAL LOADS. .. Axial Load at 5.0 ft,D=0.2850,L=0.750 k DESIGN SUMMARY Bending&Shear Check Results PASS Max.Axial+Bending Stress Ratio = 0.1844:1 Maximum SERVICE Lateral Load Reactions.. Load Combination +D+L+H Top along Y-Y 0.0 k Bottom along Y-Y 0.0 k Governing NDS Forumla Comp Only,fc/Fc' Top along X-X 0,0 k Bottom along X-X 0.0 k Location of max.above base 0.0 ft Maximum SERVICE Load Lateral Deflections,.. At maximum location values are... AlongY-Y Applied Axial 1.047 k 0.0 in at 0.0 ft above base Applied Mx 0.0 k-ft for load combination: n/a Applied My 0.0 k-ft Along X-X 0.0 In at 0.0 ft above base Fc:Allowable 463.454 psi for load combination:n/a Other Factors used to calculate allowable stresses... PASS Maximum Shear Stress Ratio= 0.0:1 Bending Compression Tension Load Combination +0.60D+0.70E+0,60H Cf or Cv:Size based factors 1.500 1.150 Location of max.above base 5.0 ft Applied Design Shear 0.0 psi Allowable Shear 112.0 psi \( f ` �.' fl E +i Pro$hcr. ect Title: l Enneer Project ID: Proct .III Consulting engineers Structural Lngineering Wood Beam File=Z;\projects12015PR-11151345-118mieser,ec6 ENERCALC,INC,1983-2015,Fluild:6.15.1.19,Var$.15.1.19 Lic.#: KW-06005543 Licensee: HAYDEN CONSULTING ENGINEERS Description: step down ledger beam CODE REFERENCES Calculations per NDS 2012, IBC 2012, CBC 2013,ASCE 7-10 Load Combination Set:ASCE 7-10 Material Properties Analysis Method: Allowable Stress Design Fb_Tension 850 psi E:Modulus of Elasticity Load Combination ASCE 7-10 Fb-Compr 850 psi Ebend-xx 1300ksi Fc-PrIl 1300 psi Eminbend-xx 470 ksi Wood Species •Hem Fir Fc-Perp 405 psi Wood Grade :No.2 Fv 150 psi Ft 525 psi Density 27.7pcf Beam Bracing : Beam is Fully Braced against lateral-torsion buckling .0091.02a rr j 6 v�r A 2-2x10 Span=3.0 ft Applied Loads Service loads entered. Load Factors will be applied for calculations. Uniform Load: D=0.0150, L=0.040 ksf, Tributary Width=6.0 ft DESIGN SUMMARY Desin OK Maximum Bending Stress Ratio = 0.111: 1 Maximum Shear Stress Ratio = 0.087 : 1 Section used for this span 2-2x10 Section used for this span 2-2x10 fb:Actual = 104.13psi fv:Actual = 13.09 psi FB:Allowable = 935,00 psi Fv:Allowable = 150.00 psi Load Combination +D+L+H Load Combination +D+L+H Location of maximum on span = 1.500ft Location of maximum on span = 0.000 ft Span#where maximum occurs = Span#1 Span#where maximum occurs = Span#1 Maximum Deflection Max Downward Transient Deflection 0.002 in Ratio= 21047 Max Upward Transient Deflection 0.000 in Ratio= 0<360 Max Downward Total Deflection 0.002 in Ratio= 15307 Max Upward Total Deflection 0.000 in Ratio= 0<240 Vertical Reactions Support notation:Far left is#1 Values in KIPS Load Combination Support 1 Support 2 Overall MAXimum U,-3fiO 0.360 Overall MINimum 0.135 0.135 D Only 0.135 0.135 L Only 0.360 0.360 S Only (42 ' . "f" . At �. - r) - <s 2:\ 44" ( a Af .,td 1,.,�,1 3 4 ll "'Vok .7A a . \ --. 1 " c = \V\tN , t: At. . 1 a \k u n O _�� BY DATE 1 ielir .1,- .- REV DATE Consulting �.ngineers • .3tructural L ngineering JOB NO '-a I (503)968=9994 p (503) 968-8444 f SHEET '-4-- of 4/22/2015 Design Maps Summary Report . (, S Design Maps Summary Report liz User-Specified Input Report Title smelser deck Wed April 22,2015 16:24:18 UTC Building Code Reference Document ASCE 7-10 Standard (which utilizes USGS hazard data available in 2008) Site Coordinates 45.42496°N, 122.82336°W Site Soil Classification Site Class D - "Stiff Soil" Risk Category I/II/III t.. 2ro7 err ��.r•yre �� YfP �` :a Farmington 'fir � { ti1w "4,, Y E yet 4th 1#4!#L##y"s3lz rY'##z3 y, R ' i Lake rn _ P . UitWB Scha ` oi ''.4C) ''''', C-..0101a ..- 4ia , icing GitY i_ " :l AMERICA WI I t 6';n, 02Ql1S MOPtl A MapQuest USGS-Provided Output SS = 0.958 g SMS = 1.070 g SDs = 0.713 g S1 = 0.423 g SM1 = 0.667 g S01 = 0.445 g For information on how the SS and Si. values above have been calculated from probabilistic (risk-targeted) and deterministic ground motions in the direction of maximum horizontal response, please return to the application and select the"2009 NEHRP"building code reference document. MCER Response Spectrum Design Response Spectrum 1.10 0.72 0.99 0.64 0.56 0.09 0.77 ^ 0.40 S. 0.66 N 0.44 0.55 0.40 to 0.32 0.33 0.24 0.22 0.16 0.11 0.06 0.00 0.00 0.00 0.20 0.40 0.60 0.90 1.00 1.20 1.40 1.60 1.00 2.00 0.00 0.20 0.40 0.60 0.90 1.00 1.20 1.40 1.60 1.90 2.00 Period, T(sec) Period, T(sec) For PGAM, T„ CRS, and CR1 values, please view the detailed report. Sht1pJ/ehp4-earthquake.cr.usgs.govidesignmaps/us/stanmary.php?template=minimal&latitude=45.4249833&longitude=-172.8233644&siteclass=3&riskcategory... 027 M.: , Project Title: Hil { m EIJ Engineer: Project ID: Project Descr: ' • II i Consulting Lngineers Structural. Engineering Wood Column File=Z.1projects12015PR-1115134S-fsmieser.ec6 - ENERCALC.INC.1983-2015,Build:6.15.1.19,Ver:6.15.1.19 Lica#:KW-06005543 Licensee: HAYDEN CONSULTING ENGINEERS Description: posts Code References Calculations per 2012 NDS, IBC 2012,CBC 2013,ASCE 7-10 Load Combinations Used:ASCE 7-10 General Information Analysis Method: Allowable Stress Design Wood Section Name 6x8 End Fixities Top Free, Bottom Fixed Wood GradinglManuf. Graded Lumber Overall Column Height 6.0 ft Wood Member Type Sawn (Used for non-slender calculations) Wood Species Hem Fir Exact Width 5.50 in Allow Stress Modification Factors Wood Grade No.2 Exact Depth 7.50 in Cf or Cv for Bending 1.0 Fb Tension 575.0 psi Fv 140.0 psi Area 41.250 in42 Cf or Cv for Compression 1.0 Ix 193.359 inM Cf or Cv for Tension 1.0 Fb-Compr 575.0 psi Ft 375.0 psi ly 103.984 inM Cm:Wet Use Factor 1,0 Fc-Prll 575.0 psi Density 27.70 pcf Incising Factors: Ct:Temperature Factor 1.0 Fc Perp 405.0 psi for Bending 0.80 Cfu:Flat Use Factor 1.0 E:Modulus of Elasticity.., x-x Bending y-y Bending Axial for Elastic Modulus 0.95 Kf:Built-up columns 1.0 NDS 15.3 2 Basic 1,100.0 1,100.0 1,100.0 ksi Use Cr:Repetitive 1 No(non-gib only] Minimum 400.0 400.0 Brace condition for deflection(buckling)along columns: X-X(width)axis: Unbraced Length for X-X Axis buckling=6.0 ft,1<=2,1 Y-Y(depth)axis: Unbraced Length for X-X Axis buckling=6.0 ft,K=2.1 Applied Loads Service loads entered.Load Factors will be applied for calculations. Column self weight included:47.609 lbs*Dead Load Factor AXIAL LOADS.. . Axial Load at 6.0 ft,D=1.050,L=2.80 k BENDING LOADS... Lat.Point Load at 6.0 ft creating Mx-x,E=0.730 k DESIGN SUMMARY Bending&Shear Check Results FAIL Max.Axial+Bending Stress Ratio = 1.016:1 Maximum SERVICE Lateral Load Reactions.. Load Combination +D+0.70E+H Top along Y-Y 0.0 k Bottom along Y-Y 0.730 k Governing NDS Forumla Comp+Mxx, NDS Eq.3.9-4 Top along X-X 0.0 k Bottom along X-X 0.0 k Location of max.above base 0.0 ft Maximum SERVICE Load Lateral Deflections... At maximum location values are,,, Along Y-Y 0.4472 in at 6.0 ft above base Applied Axial 1.098 k for load combination: E Only Applied Mx -3.066 k-ft Applied My 0.0 k-ft Along X-X 0.0 in at 0.0 ft above base Fc:Allowable 363.893 psi for load combination:n/a Other Factors used to calculate allowable stresses... PASS Maximum Shear Stress Ratio= 0.06913:1 Bending Compression Tension Load Combination +D+0,70E+H Cf or Cv:Size based factors 1.000 1.000 Location of max.above base 5.960 ft Applied Design Shear 18.582 psi Allowable Shear 179.20 psi 01l • cr law (6-- ' g 41 ._ Z 'Le.-- A a tk • Zn�` U d o.E � BY ve... DATEaitz-241 .i LCOnsUtting c_ngineer5 REV DATE. - -Structural Engineering JOB NO _ '503) 968-9994 p (503) 968-8444 f SHEET h OF fl 1 )II/1D Project Title: ,: , f , EIJ Engineer: Project ID: Project Descr: Consulting Engineers 5tructuraL E.nyineeriny Wood Column Flle 2 Zlprojects12015PR-1115134S-1lsmleser.ec6 ENERCALC,INC.1983-2015,Build:6.15.1.19,Ver.6.15.1.19 Lic.#: KW-06005543 Licensee: HAYDEN CONSULTING ENGINEERS Description: knee brace Code References Calculations per 2012 NDS, IBC 2012, CBC 2013,ASCE 7-10 Load Combinations Used:ASCE 7-10 General Information Analysis Method: Allowable Stress Design Wood Section Name 2x6 End Fixities Top&Bottom Pinned Wood Grading/Manuf, Graded Lumber Overall Column Height 7.0 ft Wood Member Type Sawn (Used for non-slender calculations) Exact Width Wood Species Hem Fir 1.50 in Allow Stress Modification Factors Wood Grade No.2 Exact Depth 5.50 in Cf or Cv for Bending 1.30 Fb-Tension 575.0 psi Fv 140.0 psi Area 8.250 in^2 Cf or Cv for Compression 1.10 Ix 20.797 in^4 Cf or Cv for Tension 1.30 Fb-Compr 575.0 psi Ft 375.0 psi ly 1.547104 Cm:Wet Use Factor 1,0 Fc-Pill 575.0 psi Density 27.70 pcf Incising Factors: Ct:Temperature Factor 1.0 Fc-Perp 405.0 psi for Bending 0.80 Cfu:Flat Use Factor 1.0 E:Modulus of Elasticity.., x-x Bending y-y Bending Axial for Elastic Modulus 0.95 Kf:Built-up columns 1.0 NDS 15 3 2 Basic 1,100.0 1,100.0 1,100.0 ksi Use Cr:Repetitive? No(non-gin only) Minimum 400.0 400.0 Brace condition for deflection(buckling)along columns: X-X(width)axis: Lu for X-X Axis buckling:3.5 ft,K=1.0 Y-Y(depth)axis: Lu for Y-Y Axis buckling:K=1.0 Applied Loads Service loads entered. Load Factors will be applied for calculations. Column self weight included:11.109 lbs*Dead Load Factor AXIAL LOADS... Axial Load at 7.0 ft,E=1.035 k DESIGN SUMMARY Bending&Shear Check Results PASS Max.Axial+Bending Stress Ratio = 0.2469:1 Maximum SERVICE Lateral Load Reactions.. Load Combination +0+0.70E+H Top along Y-Y 0.0 k Bottom along Y-Y 0.0 k Governing NDS Forumla Comp Only,fc/Fc' Top along X-X 0.0 k Bottom along X-X 0.0 k Location of max,above base 0.0 ft Maximum SERVICE Load Lateral Deflections... At maximum location values are... Along Y-Y 0.0 in at 0.0 ft above base Applied Axial 0,7356 k Applied Mx 0.0 k-ft for load combination: n/a Applied My 0.0 k-ft Along X-X 0.0 in at 0.0 ft above base Fc:Allowable 361.197 psi for load combination:n/a Other Factors used to calculate allowable stresses... PASS Maximum Shear Stress Ratio= 0.0:1 Bending Compression Tension Load Combination +0.60D+0.70E+0.60H Cf or Cv:Size based factors 1.300 1.100 Location of max.above base 7.0 ft Applied Design Shear 0,0 psi Allowable Shear 179.20 psi y { VI. 1 i,,,, +s'4i; AL— (. 1,J `r" t t,--,\�J ih- * k ' � ' k t , ALt— \P N' 1 : \z-° ' ` 1y µ 0 kit` 1 s, its -- �-14.,6 ( - '' = < .a ___T \\,,,,,,,, ,,,,, ,,.....1,,, ,,.. ... * , , ,..4.,1 N,— e'v ' ,,,, <:''',. ' --I. 1 , 1(//;,-", „ 0.,_ .,,,, , k----1:;7' L 4t , i-... 4. ofd✓ s it' ( ,�,t ;.tori - k.4 sl.`,._ - (.i . . ({, ,A ( -_,.. n� u �/ BY DATE 412` .,.LL Consulting EnLcY_gineers & '" REV _,__,, -i�_rDATE - .truc-Eural Engineering JOB No_ i<a'' 7',,.>'`It -...._._n_ (503) 968-9994 p (503) 968-8444 f SHEET 12.- OF_ V Project Title: i �� .VU E11[ II , ' Project Descr: i Consulting Engineers . . Structural. Engineering Wood Beam File=Z:1p(c*ts12615f+it-11151346-1Ismleser,ec8 ENERCALC,INC.1983.2015,Build:6.15.1.19,Ver.6.15.1.19 Lic.#:KW-06005543 Licensee:HAYDEN CONSULTING ENGINEERS Description: top of stair joists CODE REFERENCES Calculations per NDS 2012, IBC 2012, CBC 2013,ASCE 7-10 Load Combination Set:ASCE 7-10 Material Properties Analysis Method: Allowable Stress Design Fb Tension 850.0 psi E:Modulus of Elasticity ^A Load Combination ASCE 7-10 Fb-Compr 850,0 psi Ebend-xx 1,300.0ksi Fc-Pril 1,300,0 psi Eminbend-xx 470.0 ksi Wood Species :Hem Fir Fc-Perp 405.0 psi Wood Grade :No.2 Fv 150.0 psi Ft 525,0 psi Density 27.70pcf Beam Bracing : Completely Unbraced Repetitive Member Stress Increase + + 0(0.045)L(0.12) + + D(0.015 L(0.04) 4 i 2-2x10 A Span=12.01 Applied Loads Service loads entered.Load Factors will be applied for calculations. Uniform Load D=0.0150, L=0.040 ksf, Tributary Width=1.0 ft Uniform Load: D=0.0450, L=0.120 k/ft,Extent=3.0-->>7.0 ft, Tributary Width=1.0 ft DESIGN SUMMARY. . Desi n OK Maximum Bending Stress Ratio = 0.856 1 Maximum Shear Stress Ratio = 0.304 : 1 ' Section used for this span 2-2x10 Section used for this span 2-2x10 fb:Actual = 725.07 psi fv:Actual = 36.44 psi FB:Allowable = 848.06 psi Fv:Allowable = 120.00 psi Load Combination +D+L+H Load Combination +D+L+H Location of maximum on span = 5.518ft Location of maximum on span = 0.000ft Span#where maximum occurs = Span#1 Span#where maximum occurs = Span#1 Maximum Deflection Max Downward Transient Deflection 0.189 in Ratio= 760 Max Upward Transient Deflection 0.000 in Ratio= 0<360 Max Downward Total Deflection 0.260 in Ratio= 553 Max Upward Total Deflection 0.000 in Ratio= 0<240 i Vertical Reactions Support notation:Far left is#1 Values in KIPS Load Combination Support 1 Support 2 Overall MAXimumJ 0,520 0.440 Overall MINimum 0.195 0.165 D Only 0.195 0.165 L Only 0.520 0.440 S Only Project Title: ic- - t TiEngineer: Project ID: Project Descr: ConsultingLngineers - . Structural Engineering Wood Column File=Z:1projects12015PR-A15134S-1lsmieser.ec6 ENERCALC,INC.1983-2015,Build:6.15,1.19,Ver:6.15.1.19 Lic.#: KW-06005543 Licensee HAYDEN CONSULTING ENGINEERS Description: X brace Code References Calculations per 2012 NDS, IBC 2012,CBC 2013,ASCE 7-10 Load Combinations Used:ASCE 7-10 General Information Analysis Method: Allowable Stress Design Wood Section Name 2x6 End Fixities Top&Bottom Pinned Wood Grading/Manuf. Graded Lumber Overall Column Height 9.440 ft Wood Member Type Sawn (Used for non-slender calculations) Wood Species Hem Fir Exact Width 1.50 in Allow Stress Modification Factors Wood Grade No.2 Exact Depth 5.50 in Cf or Cv for Bending 1.30 Fb Tension 575.0 psi Fv 140.0 psi Area 8.250 InA2 Cf or Cv for Compression 1.10 lx 20.797 in"4 Cf or Cv for Tension 1.30 Fb-Compr 575.0 psi Ft 375.0 psi ly 1.547 inA4 Cm:Wet Use Factor 1.0 Fc-PM 575.0 psi Density 27.70 pcf Incising Factors: Ct:Temperature Factor 1.0 Fc-Perp 405.0 psi for Bending 0.80 Cfu:Flat Use Factor 1.0 E:Modulus of Elasticity.,. x-x Bending y-y Bending Axial for Elastic Modulus 0.95 Kf:Built-up columns 1.0 NDS 1532 Basic 1,100.0 1,100.0 1,100.0 ksi Use Cr:Repetitive 7 - No(non-gib only) Minimum 400.0 400.0 Brace condition for deflection(buckling)along columns: X-X(width)axis: Lu for X-X Axis buckling:4.72 ft,K=1.0 Y-Y(depth)axis: Unbraced Length for X-X Axis buckling=9.440 ft,K=1.0 Applied Loads Service loads entered. Load Factors will be applied for calculations. Column self weight included:14.981 lbs*Dead Load Factor AXIAL LOADS. . . Axial Load at 9.440 ft,E=0.30 k DESIGN SUMMARY Bending&Shear Check Results PASS Max.Axial+Bending Stress Ratio = 0.1268:1 Maximum SERVICE Lateral Load Reactions.. Load Combination +D+0,70E+H Top along Y-Y 0.0 k Bottom along Y-Y 0.0 k Governing NDS Forumla Comp Only,fc/Fc' Top along X-X 0.0 k Bottom along X-X 0.0 k Location of max.above base 0.0 ft Maximum SERVICE Load Lateral Deflections.., At maximum location values are... AlongY-Y Applied Axial 0.2250 k 0.0 in at 0.0 ft above base Applied Mx 0.0 k-ft for load combination:n/a Applied My 0.0 k-ft Along X-X 0.0 in at 0.0 ft above base Fc:Allowable 215.048 psi for load combination:n/a Other Factors used to calculate allowable stresses.., PASS Maximum Shear Stress Ratio= 0.0:1 Bending Compression Tension Load Combination +0.60D+0,70E+0.60H Cf or Cv:Size based factors 1.300 1.100 Location of max.above base 9.440 ft Applied Design Shear 0.0 psi Allowable Shear 179.20 psi - Theledger Board .pecks that are attached to a house require a ledger board to be fastened to the house structure, and the deck joists are fastened to the ledger. If your deck will be free-standing and not attached to the house, skip this section and proceed to Free-Standing Decks. There are several methods for attaching the ledger to the house,depending on how the house was built and how high the deck will be located relative to the house's existing floor framing.The ledger can be fastened to the house band board (or rim joist) (Figure 5 or 6),the wall studs (Figure 7) or a concrete wall(Figure 8).You will need to verify the ex- isting conditions before you apply for a building permit. If you can't verify the existing conditions or if they are different from Figures 5,6,7 or 8 then a free-standing deck is required (see Free-Standing Decks). Siding and Flashings:The siding or exterior finish system must be removed to install the ledger board against the wall sheathing.Two layers of continuous flashing must be properly installed to prevent water from getting into the wall where the siding has been removed. See Figure 5.The flashing material may be copper(using copper nails), stainless steel, galvanized steel coated with 1.85 oz/sf of zinc (G-185 coating), UV-resistant plastic, or self-sealing bituminous (tar) "peel-and-stick"flashing.The first layer is attached directly to the exterior wall sheathing starting behind and above the bottom edge of the building paper and siding, continuing straight down the face of the wall behind the ledger board 1, (before it is installed)and end- First layer flashing behind building ing on the outer face of the Exterior wall sheathing , - and ledger board, and over siding exterior wall siding or foun- (15/32" max sheathing) Second layer"Z"flashingdation below the bottom of y over to P the ledger board. Self-sealing Existing wall and down face of ledger board bituminous peel-and-stick >C flashing is ideal for the first / i//// Decking over layer. Pre-formed Z-shaped Existing 2X • deck joist metal flashing is ideal for the rim (band) outer,second layer of flashing. 2X ledger, same size It is installed after the ledger 2X floor joists ias deck joist board and before the joists, starting behind and above the _��' Joist hanger LUS26 bottom edge of the building (or equal) min. paper and siding, continuing Existing wall framing , 1/2" lag screws or down vertically to the top of or concrete wall (2) #14X4"wood screws or the ledger board, bending (shown dashed) (2) 1/4"X4" Simpson SDS screws oot a ledgere to ota re outer face of the board, and bend- f (or equal) at spacing "S" ing again vertically down the face of the ledger board at least 1/2': A Fig. 5:Attachment of Ledger Board to Band Board with Lag or Wood Screws (See Fig. 12 for spacing and clearances) Spacing"S" Joist Span 1/2"dia.lag screws*! #14 X4"wood screws (2)Simpson SOS V4"X4" 4 0<span <8' 23" 10" 16" 8'<span<_ 10' 18" 8" 16" 10'<span <_14' 13" 6" 12" 14'<span < 16' 11" 5" 9" *The tip of lag screw shall fully extend beyond inside face of rim joist!From table R502.2.2.1 of 2011 0RSC. Manufactured Wood Joists(MWJs): If the existing house floor joists are MWJs,and not %A solid-sawn lumber,you will need to submit a ledger attachment detail that is approved by the MWJ manufacturer or a licensed engineer. Examples of MJWs areTJl, GPI and LPI,.See Figure 4. Older homes constructed with MWJs may have a plywood band .Fig•4:MWJ profile board, while some newer homes may have 1 1/4-inch manufactured wood rim joists. DECK DESIGN GUIDE • 7