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Home My WebLink About217 E 11th St Technical - BuildingTECHNICAL Permit# 09-Sy7 Address n E S+ Project description 512_, s-F \>azt,c,k-e.el GaArixle Date the permit was finaled 0 Number of technical pages 32-- Asia L i PA /k.1 v' 2i1 tr i l AY 1.,M? 4 5Mt /14 s 7 7 9 1 -3 I. 1 1 1 A n n n {KNEE 5R,4CE SCALE 1" 1' -0" 4X4 DF KNEE BRACE CUT AS SHOWN 4X8 DF POST CONTINUOUS FROM FLOOR TO SEAM (2) 3" WIDE X 1'3" LONG 3/8" LDED AT W °L PLATE (3) 1/2" DIA. LAG BOLTS WITH MIN. 3" EMBEDMENT IN TO POST OR BEAM -5 1/8 X 22 1/2 GLB RIDGE BEAM PROVID (3) 1/2" DIA. 3' EMBEDMENT ININ. RIDGE BEAM 2X4 BLOCK 13 1/2" LONG A4,4 IAAmdowea s l'j is t,11vo 151744 sfmirw Apeoo t 0 CST AT WALL SCALE I" 1 -0" J PROVIDE MIN. (2) VENT NOTCHES PER BLOCK PROVIDE SOLID 2X BLOCKING ALIIGN U F JI NEUJ POST S T ILUALLOF EXISTING NEW 4X8 DF NO2 POST NOTCH AROUND TOP AND RIDGE BEALIA1TES 5 RR1 /8YXp2 E 2 1/2 GLB ,43 ONE E t OF NE POST TO BO TOM AND TOP PLATES 6 oto r IN+ 0 4,4 eirotie7,7 (.41 40teviek.1 LAO (.4-cet ()Vine/4 ■,4,V) te) tx..1 e.7 er11 Sert OAS 40--v 016°1441, om L s/) 0 107 T;;ITL:17. I eirtttY'\ -FAA„. 4 04 1,1 La „Bo 47 --ocAN:Itim 4-10i -11-zoti. vip,A.L.troiNci eiet-i,+4,19 )710;Aot4 ...e# Vtekt,t0 Project: Location. Column 2 Column ,;12009 International Building Code(2005 NDS)] 35 IN x 7.25 IN x 10 5 FT #2 Douglas- Fir -Larch Dry Use Section Adequate By 55.9% DEFLECTIONS Deflection due to lateral loads only' Live Load Deflection Criteria: VERTICAL REACTIONS Live Load: Dead Load Total Load: COLUMN DATA Total Column Length. Unbraced Length (X -Axis) Ly Unbraced Length (Y -Axis) Ly Column End Condtion -K (e): Axial Load Duration Factor Lateral Load Duration Factor (Wind /Seismic) COLUMN PROPERTIES #2 Douglas- Fir -Larch Compressive Stress: Bending Stress (X -X Axis). Bending Stress (Y Y Axis): Modulus of Elasticity Min. Mod. of Elasticity' Column Section (X -X Axis): Column Section (Y Y Axis): Area: Section Modulus (X- X.Axis): Section Modulus (Y Y Axis): Slenderness Ratio: NOTES 4s149 L.'1 N1I410S 91,D6 FoTTS Defl= 019 Vert-LL -Rxn Vert-DL -Rxn Vert-TL -Rxn 10.5 105 2 1 1 00 1 33 IN U648 U180 ft ft ft 0 lb 58 lb 58 lb HORIZONTAL REACTIONS Total Reaction at Top of Column: TL -Rxn -Top 66 Ib Total Reaction at Bottom of Column: TL -Rxn- Bottom =66664}lb Base Values Adiusted Fc 1350 psi Fc' 1182 psi Cd =1 33 Cf=1 05 Cp =0.63 Fbx 900 psi Fbx' 1551 psi Cd =1 33 CF =1 30 C1 =1 00 Fby 900 psi Fby' 1556 psi Cd =1.33 CF =1 30 E 1600 ksi E' 1600 ksi E_min 580 ksi E_min' 580 ksi dx 7.25 in dy 3 5 in A 25 38 in2 Sx 30 66 in3 Sy 14.8 in3 Lex/dx 17 38 Ley /dy 6.86 Column Calculations (Controlling Case Only): Controlling Load Case' Axial Dead Load and Lateral loads (D W or E) Actual Compressive Stress. 2 psi Allowable Compressive Stress: 1182 psi Eccentricity Moment (X -X Axis): 0 ft -lb Eccentricity Moment (Y Y Axis): Moment Due to Lateral Loads (X -X Axis): Moment Due to Lateral Loads (Y Y Axis): Bending Stress Lateral Loads Only (X -X Axis): Allowable Bending Stress (X -X Axis): Bending Stress Lateral Loads Only (Y Y Axis) Allowable Bending Stress (Y Y Axis): Combined Stress Factor Fc Fc' Mx -ex My -ey Mx My Fbx Fbx' Fby Fby' CSF 0 1743 0 682 1551 0 1556 0.44 ft -lb ft-lb ft -lb psi psi psi psi StruCalc Version 8.0.100 0 LOADING DIAGRAM AXIAL LOADING Live Load: Dead Load: Column Self Weight: Total Load: PL 0 lb PD 0 lb CSW 58 lb PT 58 lb LATERAL LOADING (Dy Face) Uniform Lateral Load: wL -Lat 126 plf 4/26/2010 7.39 AM page V Pfoject: Location. Column 3 Column 4 [2009 International Building Code(2005 NDS)] 3.5 IN x 7.25 IN x 12.0 FT #2 Douglas- Fir -Larch Dry Use Section Adequate By 38.5% DEFLECTIONS Deflection due to lateral loads only Live Load Deflection Criteria. VERTICAL REACTIONS Live Load: Dead Load: Total Load: COLUMN DATA Total Column Length. Unbraced Length (X -Axis) Ly Unbraced Length (Y -Axis) Ly Column End Condtion -K (e): Axial Load Duration Factor Lateral Load Duration Factor (Wind /Seismic) COLUMN PROPERTIES #2 Douglas- Fir -Larch Column Section (X -X Axis): Column Section (Y Y Axis): Area. Section Modulus (X -X Axis): Section Modulus (Y Y Axis): Slenderness Ratio NOTES 494 Lci i4A►Vg.1v5 Defl 0 35 IN U407 U180 Vert-LL -Rxn Vert-DL -Rxn Vert-TL -Rxn HORIZONTAL REACTIONS Total Reaction at Top of Column: TL -Rxn -Top 810 lb Total Reaction at Bottom of Column: TL- Rxn Bottom 0 114 12 12 2 1 1 00 1.33 ft ft ft Base Values Adjusted Compressive Stress: Fc 1350 psi Fc' 990 psi Cd =1 33 Cf=1 05 Cp =0.52 Bending Stress (X -X Axis): Fbx 900 psi Fbx' 1551 psi Cd =1 33 CF =1 30 CI =1 00 Bending Stress (Y Y Axis) Fby 900 psi Fby' 1556 psi Cd =1 33 CF =1 30 Modulus of Elasticity' E 1600 ksi E' 1600 ksi Min. Mod. of Elasticity E_min 580 ksi E_min' 580 ksi dx dy A= Sx Sy Lex/dx Ley /dy 0 lb 66 lb 66 lb 7.25 3.5 25 38 30 66 148 19 86 6.86 in in in2 in3 in3 Column Calculations (Controlling Case Only): Controlling Load Case. Axial Dead Load and Lateral loads (D W or E) Actual Compressive Stress: Fc Allowable Compressive Stress: Fc' Eccentricity Moment (X -X Axis): Mx -ex Eccentricity Moment (Y Y Axis): My -ey 0 Moment Due to Lateral Loads (X -X Axis). Mx 2430 Moment Due to Lateral Loads (Y Y Axis): My 0 Bending Stress Lateral Loads Only (X -X Axis) Fbx 951 Allowable Bending Stress (X -X Axis): Fbx' 1551 Bending Stress Lateral Loads Only (Y Y Axis): Fby 0 Allowable Bending Stress (Y Y Axis) Fby' 1556 Combined Stress Factor CSF 0.61 3 psi 990 psi 0 ft -lb ft-lb ft-lb ft -lb psi psi psi psi StruCalc Version 8.0.100.0 LOADING DIAGRAM AXIAL LOADING Live Load: Dead Load: Column Self Weight: Total Load: 12ft PL PD CSW PT 0 lb 0 lb 66 lb 66 lb LATERAL LOADING (Dy Face) Uniform Lateral Load: wL -Lat 135 plf 4/26/2010 7 41 AM page /of '2-0 449 S 319 s. peabody; suite b port angeles, wa 98362 360.452.6116 fax 360.452.7064 Project: iNi14.1weat stp)br Subiect:. Date. 12,11"V &-7,6i) UPI r Afal"' 4. 1 i:c7V Iit)d )2 rnpof 'dY 44943:If pdp 1' 1 alp ,vi 4 3 C 010 OAF Wit iva" 9/'c "r P Project No. Br 5 Sheet, of -!7 MeoiTACT t, `"IF VtlAtirMIX: r T SU 0 1.1.9 pa% E aft, st ClEfif[E DEC 0 3 2009 CITY OF PORT ANGELES 0-15elin BUILDING DIVISION LINDBERMITH A R C H I C T S 319 S. Peabody Suite B Port Angeles, WA 98362 360 452.6116 fax 360.452.7064 contactnlinddarch.com www.lindarch.com Project: AlN Lel 5' t-vp 2 l Subject: I A L Date 08v1Suo 1j G7' 1 SHEAR WALL SUMMARY WI L I H I V I V/L I SW 55 lo 2 1 U.0 v A, )3 1 B 2 11G0 22 2 2v ld1 ic 41$4 41-53 413$ I /ALL OFIT/FIRMINFO/FORMS /SHEARWAL 11 Project No By C.1 Sheet VH- WL /2 +121 OW of I POST 3 rr WOO HOLD DOWN HbtArl 4 m52 1 1 1 SIM 3-- A. PLYWOOD OR O.S.B. SHEAR WALLS 1 MAXIMUM SHEAR 250 P.L.F USE W SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 6" 0 C FOR FRAMING, USE DF NO.2. PROVIDE W DIAMETER ANCHOR. BOLTS AT 32" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE: WALL, SEE FRAMING /SHEAR WALL PLANS. 2. MAXIMUM SHEAR 315 P L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 5° O C FOR FRAMING, USE DF NO.2. PROVIDE DIAMETER ANCHOR BOLTS AT 32" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 3 MAXIMUM SHEAR 375 P L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 4" 0 C FOR FRAMING, USE 3X DF NO.2. PROVIDE DIAMETER ANCHOR BOLTS AT 24" 0 C. MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 4 MAXIMUM SHEAR 490 P.L.F USE W SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 3" O C FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 5/8" DIAMETER ANCHOR BOLTS AT 32' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 5. MAXIMUM SHEAR 560 P.L.F USE SHEATING ONE SIDE OF WALL NAIL ALL EDGES WITH 10d NAILS AT 3' 0 C FOR FRAMING USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 5/8" DIAMETER ANCHOR BOLTS AT 24° O.C. MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 6. MAXIMUM SHEAR 685 P L.F USE l" SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2 1/2° 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS PROVIDE 5/8" DIAMETER ANCHOR BOLTS AT 20' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 7 MAXIMUM SHEAR 770 P.L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2" O.C. STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 5/8' DIAMETER ANCHOR BOLTS AT 18' 0 C. MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 8. MAXIMUM SHEAR 870 P.L.F USE SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 3 1/2" 0 C. FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED, BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4' DIAMETER. ANCHOR BOLTS AT 20' 0 C. MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. MAXIMUM SHEAR 980 P L.F USE SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 3' 0 C FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS PROVIDE 3/4" DIAMETER ANCHOR BOLTS AT 18" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 10 MAXIMUM SHEAR 1,200 P.L.F USE 1/2' SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 3" 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS PROVIDE 3/4" DIAMETER ANCHOR BOLTS AT 14' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 11 MAXIMUM SHEAR 1,540 P L.F USE SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2" 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4" DIAMETER ANCHOR BOLTS AT 11" 0 C. MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 12. MAXIMUM SHEAR 1 740 P L.F USE 5/8" SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2" 0 C. STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS PROVIDE 3/4" DIAMETER ANCHOR BOLTS AT 9" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS ao X 2 DF 2 h ROOF FRA INCB PLAN xlrywee% HAMER EACH JOIE? KCAL& 1/4' P.0" SCALE, V4' P-O' PLYWOOD OR 0.5.8. SHEAR WALLS 2. MAXPU1 SHEAR a@ pp1.P. USE VP 6I€ATNG ONE SIDE or WALL MIL ALL EDGES WIN SC HAILB AT 6' 00 FOR FRANK um DP NO1 PROVIDE V!" DIAMETER ANCHOR DOLTS AT 92' 00 M4XMM SPACING AT THE POU DATIOIL FOR TIE DOWNE AT EACH END OP THE WALL, SEE PR8MNG/134EAR PLAN& S MAXIM SHEAR 660 PLF. USE VP SHEATHS ONE SIDE OF WALL. NAIL ALL EDGES MN 10d MILS AT 3' 00 FOR A� USE 3k CP NO1 mow D01TOM PLATES ARE AE01WED, DOLT BOTH PLATES WITH ANCHOR BOLTS. PROVIDE W DIAMETER ANCHOR DOLTS AT 24' 00 MAXMU I WOG AT THE SEE A R4116111 AR PT.O& AT EACH END OF TIM WALL 6. MAXFUI SHEAR 656 PLP. USE 1/2" SHEATHS ONE SIDE CP WAIL MU. ALL EONS 16TH 10d HAILS AT 21/1' 00 STABGBNED FOR FROMM USE 3X OF 3101 DOUBLE 6011 /11 PLATES ARE REQARED, BOLT THROUGH !LOW PLATES 1111114 ANCHOR EOLTS. AT FFAWA?ICNL MR TIE DOING AT AT 20' 00 MA2011111 EACH END OP WA LL SEE M S SSHEAR PLANS. ALL SNEA11N2 GENERAL REOUIRMIENTS 9SN,q a 6 a+F SHA L WE BA ED WM W dam DE1UEBd ROOF SHEATNO AND WALL SIf.A SIEATHNG AND LOVER WALL SHEATHING SH411 DE SUCH THAT REWIRED EDGE MLNG PER SCHEDULE 16 CONT60006 THROU DLOO iCN AND AT z4 0 0 4' TWO MD IE DOOM aT IN�'D ON FLOOR AT 0 IG4L THE TM DOUNI6 SHALL DE BOLTED TO THE UPPER AND LO ER WALL 61106 p�pg� �pe� AND CO SE I GTED DT THREADED ROD A6 PER MA PACTURE M6 rag ?OP KATE n TYPICAL WALL 'A' NO SHEAR W4LI. REQUIRED WALL 15' NO REQUIRED SHEAR WALL SPEAR WALL. PLAN UPPER LEVEL Tr i9 FLOOR FRAINC PLAN SHEAR WALL PLAN LOWER LEVEL SCALE• V4' P•0' SCALS 1/4' P-0' i if Roof Beam( 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on. 12 -02 2009 12:34 12 AM Project: 217 E 11TH Location: WINDOW HEADER Summary 3.5 IN x 7.25 IN x 7 5 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 67 0% Controlling Factor Section Modulus Depth Required 5.61 In Deflections. Dead Load: Live Load: Total Load: Reactions (Each End) Live Load: Dead Load: Total Load: Bearing Length Required (Beam only support capacity not checked) Beam Data. Span: Maximum Unbraced Span: Pitch Of Roof: Live Load Deflect. Criteria: Total Load Deflect. Criteria. Roof Loading: Roof Live Load -Side One. Roof Dead Load -Side One: Tributary Width -Side One Roof Live Load -Side Two Roof Dead Load -Side Two Tributary Width -Side Two Roof Duration Factor Beam Self Weight: Slope /Pitch Adjusted Lengths and Loads: Adjusted Beam Length: Beam Uniform Live Load Beam Uniform Dead Load: Total Uniform Load: Properties For #2 Douglas Fir -Larch Bending Stress: Shear Stress: Modulus of Elasticity Stress Perpendicular to Grain: Adjusted Properties Fb' (Tension) Adjustment Factors. Cd =1 15 CI =1 00 Cf =1 30 Fv' Adjustment Factors. Cd =1 15 Design Requirements: Controlling Moment: M= 3 75 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections: Section Modulus (Moment) Sreq= Shear S= Area (Shear) Areq= A= Moment of Inertia (Deflection): Ireq= 1= DLD= 0 05 IN LLD= 0.07 IN U1285 TLD= 0 12 IN L/770 LL -Rxn= 656 LB DL -Rxn= 438 LB TL -Rxn= 1094 LB BL= 0.50 IN L= 7.5 FT Lu= 2.0 FT RP= 4 12 U 240 L/ 180 LL1= 25.0 PSF DL1= 15 0 PSF TW1= 2.0 FT LL2= 25 0 PSF DL2= 15.0 PSF TW2= 5 0 FT Cd= 1 15 BSW= 6 PLF Ladi= 7.5 FT wL= 175 PLF wD_adi= 117 PLF wT= 292 PLF Fb= 900 PSI Fv= 95 PSI E= 1600000 PSI Fc_perp= 625 PSI Fb'= 1342 PSI Fv'= 109 PSI 2052 FT -LB 919 LB 18.36 N3 30.66 N3 12.62 N2 25.38 N2 25.97 N4 111 15 N4 Roof Beam' 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on. 12 -02 2009 12:34:51 AM Project: 217 E 11TH Location. WINDOW HEADER Summary 2 1.5 IN x 5.5 IN x 3 0 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 295.1% Controlling Factor Area Depth Required 2.41 In Deflections: Dead Load: DLD= Live Load: LLD= Total Load: TLD= Reactions (Each End) Live Load: LL -Rxn= Dead Load: DL -Rxn= Total Load: TL -Rxn= Bearing Length Required (Beam only support capacity not checked) BL= Beam Data: Span. L= Maximum Unbraced Span: Lu= Pitch Of Roof RP= Live Load Deflect. Criteria: L/ Total Load Deflect. Criteria: L/ Roof Loading: Roof Live Load -Side One. LL1= Roof Dead Load -Side One DL1= Tributary Width -Side One: TW1= Roof Live Load -Side Two. LL2= Roof Dead Load -Side Two DL2= Tributary Width -Side Two: TW2= Roof Duration Factor Cd= Beam Self Weight: BSW= Slope /Pitch Adjusted Lengths and Loads. Adjusted Beam Length. Ladj= Beam Uniform Live Load: wL= Beam Uniform Dead Load: wD_ad'1= Total Uniform Load: wT= Properties For #2 Douglas Fir -Larch Bending Stress: Fb= Shear Stress: Fv= Modulus of Elasticity E= Stress Perpendicular to Grain: Fc_perp= Adjusted Properties Fb' (Tension) Fb'= Adjustment Factors. Cd =1 15 CI =1 00 Cf =1.30 Fv' Fv'= Adjustment Factors. Cd =1 15 Design Requirements: Controlling Moment: M= 1.5 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections. Section Modulus (Moment) Sreq= S= Area (Shear) Areq= A= Moment of Inertia (Deflection) lreq= 1= 0 00 IN 0.00 IN L/7513 0 01 IN L/4539 262 LB 172 LB 435 LB 0.23 IN 3 0 FT 2.0 FT 4 12 240 180 25.0 PSF 15 0 PSF 2.0 FT 25 0 PSF 15 0 PSF 5 0 FT 1 15 4 PLF 3.0 FT 175 PLF 115 PLF 290 PLF 900 PSI 95 PSI 1600000 PSI 625 PSI 1341 PSI 109 PSI 326 FT -LB 304 LB 2.92 N3 15.13 N3 4 18 N2 16.50 N2 165 N4 41.59 N4 Roof Beam[ 2000 International Building Code (97 NDS) 1 Ver 6.00 7 By Charles Smith Lindberg Smith on. 12 -02 2009 12:35 18 AM Project: 217 E 11TH Location WINDOW HEADER Summary 2 1.5 IN x 5.5 IN x 3.75 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 191 1% Controlling Factor Area Depth Required 3.02 In Deflections. Dead Load: DLD= 0 01 IN Live Load LLD= 0 01 IN U3847 Total Load: TLD= 0 02 IN L/2324 Reactions (Each End) Live Load: LL -Rxn= 328 LB Dead Load: DL -Rxn= 215 LB Total Load: TL -Rxn= 543 LB Bearing Length Required (Beam only support capacity not checked) BL= 0.29 IN Beam Data. Span. L= 3 75 FT Maximum Unbraced Span. Lu= 2.0 FT Pitch Of Roof RP= 4 12 Live Load Deflect. Criteria: U 240 Total Load Deflect. Criteria. U 180 Roof Loading: Roof Live Load -Side One. LL1= 25 0 PSF Roof Dead Load -Side One: DL1= 15.0 PSF Tributary Width -Side One: TW1= 2.0 FT Roof Live Load -Side Two LL2= 25 0 PSF Roof Dead Load -Side Two DL2= 15 0 PSF Tributary Width -Side Two TW2= 5.0 FT Roof Duration Factor Cd= 1 15 Beam Self Weight: BSW= 4 PLF Slope /Pitch Adjusted Lengths and Loads. Adjusted Beam Length. Ladi= 3.75 FT Beam Uniform Live Load: wL= 175 PLF Beam Uniform Dead Load: wD_adj= 115 PLF Total Uniform Load: wT= 290 PLF Properties For #2 Douglas Fir -Larch Bending Stress. Fb= 900 PSI Shear Stress: Fv= 95 PSI Modulus of Elasticity' E= 1600000 PSI Stress Perpendicular to Grain: Fc_perp= 625 PSI Adjusted Properties Fb' (Tension) Fb'= 1341 PSI Adjustment Factors: Cd =1 15 CI =1 00 Cf =1.30 Fv' Fv'= 109 PSI Adjustment Factors: Cd =1 15 Design Requirements: Controlling Moment: M= 509 FT -LB 1 875 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= 413 LB At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections. Section Modulus (Moment) Sreq= 4.56 N3 S= 15 13 N3 Area (Shear) Areq= 5.67 N2 A= 16.50 N2 Moment of Inertia (Deflection) Ireq= 3.22 N4 1= 41.59 N4 Combination Roof and Floor Beam' 2000 International Building Code (97 NDS) 1 Ver 6 00 7 By Charles Smith Lindberg Smith on. 12 -02 2009 12.3709 AM Project: 217 E 11TH Location: WINDOW HEADER Summary 3.5 IN x 7.25 IN x 4 0 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 33 1% Controlling Factor Area Depth Required 5.51 In Deflections. Dead Load: DLD= Live Load: LLD= Total Load: TLD= Reactions (Each End) Live Load. LL -Rxn= Dead Load: DL -Rxn= Total Load: TL -Rxn= Bearing Length Required (Beam only support capacity not checked) BL= Beam Data: Span: L= Maximum Unbraced Span: Lu= Live Load Deflect. Criteria: U Total Load Deflect. Criteria: L/ Roof Loading: Roof Live Load -Side One: RLL1= 25.0 Roof Dead Load -Side One: RDL1= 15.0 Roof Tributary Width -Side One. RTW1= 2.0 Roof Live Load -Side Two: RLL2= 25 0 Roof Dead Load -Side Two: RDL2= 15.0 Roof Tributary Width -Side Two RTW2= 5.0 Roof Duration Factor Cd -roof= 1 15 Floor Loading Floor Live Load -Side One. FLL1= 40 0 Floor Dead Load -Side One. FDL1= 15 0 Floor Tributary Width -Side One FTW1= 10 0 Floor Live Load -Side Two. FLL2= 40.0 Floor Dead Load -Side Two FDL2= 15 0 Floor Tributary Width -Side Two: FTW2= 0 0 Floor Duration Factor Cd -floor= 1 00 Wall Load: WALL= 150 Beam Loads: Roof Uniform Live Load: wL -roof= 175 Roof Uniform Dead Load (Adjusted for roof pitch) wD -roof= 111 Floor Uniform Live Load: wL -floor= 400 Floor Uniform Dead Load: wD -floor= 150 Beam Self Weight: BSW= 6 Combined Uniform Live Load: wL= 575 Combined Uniform Dead Load: wD= 417 Combined Uniform Total Load: wT= 992 Controlling Total Design Load: wT -cont= 992 Properties For #2 Douglas Fir -Larch Bending Stress: Fb= 900 Shear Stress: Fv= 95 Modulus of Elasticity E= 1600000 Stress Perpendicular to Grain. Fc_perp= 625 Adjusted Properties Fb (Tension) Fb'= 1342 Adjustment Factors: Cd =1 15 CI =1 00 Cf =1.30 Fv' Fv'= 109 Adjustment Factors: Cd =1 15 Design Requirements: Controlling Moment: M= 2.0 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections: Section Modulus (Moment) Sreq= 17 74 S= 30.66 Area (Shear): Areq= 19 07 A= 25.38 Moment of Inertia (Deflection) Ireq= 17.85 I= 111 15 0 01 IN 0 02 IN U2578 0.03 IN U1494 1150 LB 834 LB 1984 LB 0.91 IN 4 0 FT 1.67 FT 360 240 PSF PSF FT PSF PSF FT PSF PSF FT PSF PSF FT PLF PLF PLF PLF PLF PLF PLF PLF PLF PLF PSI PSI PSI PSI PSI PSI 1984 FT -LB 1389 LB N3 N3 N2 N2 N4 N4 L BER. MI`I I A R C H I 'A C T S 319 s. peabody, suite b port angeles, wa 98362 360.45 .6116 fax 360.452.7064 Project Subject: L41 1.. Date. AUao '200a/ Project No By Sheet I of Low F i b ?ON t310T 4 G�b WS 15)/ 1:7e.4,i4)7 -1 G. oa v>', r' t. I 7'2... .q FILE LINDBERq TH ARCHIT C TS 319 S. Peabody Suite B. Port Angeles, WA 98362 360 452.6116 fax 360.452.7064 contactnlindarch.com wwwilindarch.com Probe/ tQ, Lt ',./1 l ;3d1" Project No Subject: UA7 A.L By r.�4 Date 2,vJLp 2e2cc Sheet of SHEAR WALL SUMMARY WI L H V I t I 4' 6' to 2 )1 4-24 La wtrrz 3635 Z 13,5 56=55 A i t 1 11 PaiOvoir Iva[ovto rJ' 4 .3'1 ry phON I /ALL OFIT/FIRMINF O/FORMS /SHEARW AL V/L I SW I VH- WL /2 I POST HOLD DOWN 21 4 o71 110 IV 4 2 LP AT ALL AT A L L- r r age Otil 2 )�d 17�tN 4 I 1-a DL 4 4 440(..-o DEW S A. PL -YWOOD OR O.S.B. SHEAR WALLS 1 MAXIMUM SHEAR 250 P L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 6" 0 C FOR FRAMING USE DF NO.2. PROVIDE DIAMETER ANCHOR BOLTS AT 32" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 2. MAXIMUM SHEAR 315 P L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 5" 0 C FOR FRAMING, USE DF NO.2. PROVIDE DIAMETER ANCHOR BOLTS AT 32" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 3 MAXIMUM SHEAR 375 P.L.F USE'/" SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 4' 0 C FOR FRAMING, USE 3X DF NO.2. PROVIDE DIAMETER ANCHOR BOLTS AT 24' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 4 MAXIMUM SHEAR 490 P.L.F USE 14" SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 3' O C FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 5/8" DIAMETER ANCHOR BOLTS AT 32' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 5. MAXIMUM SHEAR 560 P.L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 3" 0 C FOR FRAMING USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 5/8" DIAMETER ANCHOR BOLTS AT 24° 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 6. MAXIMUM SHEAR 685 P L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2 1/2" 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 5/8" DIAMETER ANCHOR BOLTS AT 20' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 7 MAXIMUM SHEAR 770 P.L.F USE SHEATING ONE SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2' 0 C STAGGERED FOR FRAMING, USE 3X OF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH. ANCHOR BOLTS PROVIDE 5/8' DIAMETER ANCHOR BOLTS AT 18' 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 8. MAXIMUM SHEAR 870 P.L.F USE 1/2' SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 3 1/2" 0 C FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4' DIAMETER ANCHOR BOLTS AT 20' 0 C. MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 9. MAXIMUM SHEAR 980 P L.F USE SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 8d NAILS AT 3' 0 C FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED, BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4" DIAMETER ANCHOR BOLTS AT 18" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 10 MAXIMUM SHEAR 1,200 P L.F USE 1/2' SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 3" 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4' DIAMETER ANCHOR BOLTS AT 14" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS. 11 MAXIMUM SHEAR 1,540 P L.F USE SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2" 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4 DIAMETER ANCHOR BOLTS AT 11 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS 12. MAXIMUM SHEAR 1 740 P L.F USE 5/8" SHEATING BOTH SIDE OF WALL. NAIL ALL EDGES WITH 10d NAILS AT 2" 0 C STAGGERED FOR FRAMING, USE 3X DF NO.2. DOUBLE BOTTOM PLATES ARE REQUIRED BOLT THROUGH BOTH PLATES WITH ANCHOR BOLTS. PROVIDE 3/4" DIAMETER ANCHOR BOLTS AT 9" 0 C MAXIMUM SPACING AT THE FOUNDATION. FOR TIE DOWNS AT EACH END OF THE WALL, SEE FRAMING /SHEAR WALL PLANS i I ROOF PRANG PLAN DP DP J i tam FLOOR PRANG PLAN eft S T1'PIGAL EACH AT24 p��PI �TOTOI'PLATE 6CALEi 1/4' P-0' SCALE, V4' P.0' PLYWOOD OR 0.623. SHEAR WALLS 2. mart SWEAR SE PLF. INE V2' S1EAt1 b ONE 607E OF 014LL NAL ALL EDGES MTN Sd NA0.6 AT If' 0,C. FOR Pue DP NO?. P a' DIAMETER ANCNOR DOLT* AT 32' OG AGN9 AT 11 TI04. FOR TIE DONS AT EACH END OP /MB OWL. SEE: PPAMING NEAR PI.ANA 4 M4XPQI SEAR 450 P.L.P. USE V2' 6NDATN6�61DE GP OWL. NAL ALL EDGES INT14 3 IL.6 d NA AT 3' O.C. FOR USN 3k DP NO2. Doom bottom PLATES AAE MOPED, DOLT DOTN PLATE* (11114 ANCHOR DOLTS. PROVIDE 6/*" DIAMETER ANCHOR DOLTS AT 32' OG MAJG'11'1WOO AT 11$ SEE A PLAN& AT EACH END OF tie OW L E 6 E OR OIEA TRJ3 OR OR10�i UPPER WALL ROOF 15114/1N5 IND IWL SIEATHING AND LOIEIt WALL ONIATHN9 SHALL EE NCH THAT maim EDGE N4LLN4 PER SCIEDLO,E lb CONTNICUS 110O03I4 DI.00KNA AND LW 14 E L TeL PwYI AT a NI 0011 ON6N1Dw�AE1N4 TE BNY.L DE O TO TN! UPPER ROINE I ANO COMM NY 133$4DED MO AS PER MANPAGTUFER'* WALL W /42 SWEAR RECOPIED N4t.L I WALL 'A' NO SHEAR WALL REGUIRED 0441. A' NO SOAR 1lC114AD WALL h 11 A. N0 SHEAR EAU REHIRED SHEAR WALL PLAN UPPER LEVEL 6CALI5 4 411% M A SHEAR WALL PLAN LOWER LE VEL SCALE. V4' NO' c.-...1 ...'z ROOF FAIN G PLAN ,4 s I L 0 6 1:• )4 4$ C a •4 II 1, e 't. 4 scati 1/4' r-o. 7; PLYWOOD OR O.S.B. SHEAR WALLS 2. MAXIMUM NEAR NS PLF. USE 1/2' IN-EATING ONE SIDE OF WALL MIL ALL EDGES W1714 ed NAILS AT S” 0.C. FOR PROMO, USE DP NO1 PROVIDE 1/2' MA/17M At4C14OR BOLTS AT 32' Oa MAXItill 114 AT THE RSIVATION. FOR TIE WRNS AT EACN 13.0 CP THE U.IALL, e ITRAMINSASIEAR PLAN& 4 MAXINII sem 46, PLF. USE 1/2' &EATING ONE SIDE OF WALL NAL ALL EDGES WM4 ed NAILS AT 3" O. FOR PI/MINS, USE 3X OF NO2. DOUBLE BOTTOM PLATES AFE REQUIRED, BOLT 'THROWN BON MATES WT14 ANCHCR BOLTS PROVIDE SW DIAMETER ANCHOR BOLTS AT 32' OL.NAX11111 6PACINA AT THE FOINDATION. FOR 11E DOUNS AT EACH BID GP NE WALL, SEE RRAMWslellEAR PLANS. emu. RECIANEere ALL SWATHS EDGES SHALL BE BACKED IUITH 'NAMING Saff TAW WALL octane OR 2' 1401114444. BLOCIGNS. ROOF SHEATINS AND WALT NBATNG OR 12E1SEEN UPPER WALL SHEA114INS AP LASER WALL 8NEATI411.4 NOLL 13E SUCH THAT RE61.11p EDGE NALNS PER SCHEDULE 16 C4111410.$ 114RCUS4 LOM* AND WALL PLATE& SPACE 10d MILS AT 2' 01. ALON2 114104NEDIATE FRAM MEMBER& MO TIE DOOM AM REWIND ON UP PER FLOOR WALLS, THE TIE DOW* WALL OE BOLTED TO THE UPPER LORER EAU. STUDS AND COMECTED BY THREADED ROD 46 PER 41414FACIUSEIRS Roof Beami 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on 08 -18 -2009 12:45:38 AM Projec Location. ROOF 1 Summary* 5 125 IN x 22.5 IN x 25 0 FT 24F V4 Visually Graded Western Species Dry Use Section Adequate By 146.3% Controlling Factor* Section Modulus Depth Required 14.84 In Deflections: Dead Load: DLD= Live Load LLD= Total Load: TLD= Reactions (Each End) Live Load. LL -Rxn= Dead Load: DL -Rxn= Total Load: TL -Rxn= Bearing Length Required (Beam only support capacity not checked) BL= Camber Reqd C= Beam Data. Span: L= Maximum Unbraced Span: Lu= Pitch Of Roof RP= Live Load Deflect. Criteria: L/ Total Load Deflect. Criteria. L/ Camber Adjustment Factor CAF= Roof Loading: Roof Live Load -Side One. LL1= Roof Dead Load -Side One. DL1= Tributary Width -Side One. TW1= Roof Live Load -Side Two LL2= Roof Dead Load -Side Two DL2= Tributary Width -Side Two TW2= Roof Duration Factor Cd= Beam Self Weight: BSW= Slope /Pitch Adjusted Lengths and Loads: Adjusted Beam Length: Ladj= Beam Uniform Live Load: wL= Beam Uniform Dead Load: wD_adj= Total Uniform Load: wT= Properties For 24F V4- Visually Graded Western Species Bending Stress: Fb= Shear Stress: Fv= Modulus of Elasticity Ex= Ey= Stress Perpendicular to Grain. Fc perp= Bending Stress of Comp Face in Tension. Fb_cpr= Adjusted Properties Fb' (Tension). Fb'= Adjustment Factors: Cd =1 15 CI =0 99 Cv =0.92 Fv' Fv'= Adjustment Factors. Cd =1 15 Design Requirements: Controlling Moment: 12.5 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections: Section Modulus (Moment) Sreq= 175.55 S= 432.42 Area (Shear) Areq= 35.20 A= 115.31 Moment of Inertia (Deflection) lreq= 1397 10 1= 4864 75 0.20 IN 0.28 IN U1087 048 IN =L/627 3437 LB 2524 LB 5962 LB 1 79 IN 0.30 IN 25.0 FT 2.0 FT 4 12 240 180 1 5 X DLD 25 0 PSF 150 PSF 5.5 FT 25 0 PSF 15.0 PSF 5.5 FT 1 15 28 PLF 25 0 FT 275 PLF 202 PLF 477 PLF 2400 PS 190 PS 1800000 PS 1600000 PS 650 PS 1200 PS 2547 PS 219 PS M= 37262 FT -LB V= 5127 LB N3 N3 N2 N2 N4 N4 Roof Beamf 2000 International Building Code (97 NDS) 1 Ver 6 00 7 By Charles Smith Lindberg Smith on 08 -18 -2009 12:46.42 AM Project: Location. ROOF 2 Summary (2) 1.5 IN x 3.5 IN x 4 0 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 216 3% Controlling Factor Section Modulus Depth Required 1 97 In Deflections: Dead Load: DLD= 0 02 IN Live Load: LLD= 0 03 IN U1906 Total Load: TLD= 0 04 IN L/1144 Reactions (Each End) Live Load: LL -Rxn= 150 LB Dead Load: DL -Rxn= 100 LB Total Load: TL -Rxn= 250 LB Bearing Length Required (Beam only support capacity not checked) BL= 0 13 IN Beam Data. Span. L= 4 0 FT Maximum Unbraced Span: Lu= 2.0 FT Pitch Of Roof RP= 4 12 Live Load Deflect. Criteria. U 240 Total Load Deflect. Criteria. U 180 Roof Loading: Roof Live Load -Side One. LL1= 25 0 PSF Roof Dead Load -Side One. DL1= 15.0 PSF Tributary Width -Side One: TW1= 1 0 FT Roof Live Load -Side Two LL2= 25 0 PSF Roof Dead Load -Side Two DL2= 15 0 PSF Tributary Width -Side Two TW2= 2.0 FT Roof Duration Factor Cd= 1 15 Beam Self Weight: BSW= 3 PLF Slope /Pitch Adjusted Lengths and Loads. Adjusted Beam Length. Ladj= 4.0 FT Beam Uniform Live Load: wL= 75 PLF Beam Uniform Dead Load: wD_adj= 50 PLF Total Uniform Load: wT= 125 PLF Properties For #2 Douglas Fir -Larch Bending Stress: Fb= 900 PSI Shear Stress. Fv= 95 PSI Modulus of Elasticity' E= 1600000 PSI Stress Perpendicular to Grain. Fc_perp= 625 PSI Adjusted Properties Fb' (Tension) Fb'= 1549 PSI Adjustment Factors. Cd =1 15 CI =1 00 Cf =1.50 Fv' Fv'= 109 PSI Adjustment Factors. Cd =1 15 Design Requirements. Controlling Moment: M= 250 FT -LB 2.0 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear* V= 215 LB At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections: Section Modulus (Moment) Sreq= 1.94 N3 S= 6 13 N3 Area (Shear) Areq= 2.95 N2 A= 10.50 N2 Moment of Inertia (Deflection) lreq= 1.69 N4 I= 10 72 N4 Roof Rafter[ 2000 International Building Code (97 NDS) 1 Ver• 6 00 7 By Charles Smith Lindberg Smith on 08 -18 -2009 12.47 42 AM Project: Location. RAFTER 1 Summa., TJI 230 11.875 Trus Joist MacMillan x 12.0 FT (11 1) A 24 0 C Section Adequate By 122.8% Controlling Factor Allowable end reaction Consult manufacturers specifications for all cantilever applications. Hoists were designed for simple spans with a limited cantilever using the joist manufacturers published values. If the design does not match the actual joist loading or span conditions in any way contact the joist manufacturer for design verification Interior Span Deflections. Dead Load DLD- Interior= 0 05 IN Live Load: LLD- Interior= 0 07 IN L/1916 Total Load. TLD- Interior= 0 12 IN L/1182 Eave Deflections (Positive Deflections used for design) Dead Load: DLD -Eave= 0 00 IN Live Load LLD -Eave= 0 00 IN 21/41716 Total Load: TLD -Eave= 0 00 IN 2L/25298220 Rafter End Loads and Reactions: LOADS RXNS: Upper Live Load: 138 PLF 275 LB Upper Dead Load 86 PLF 172 LB Upper Total Load: 224 PLF 447 LB Lower Live Load: 164 PLF 327 LB Lower Dead Load. 103 PLF 207 LB Lower Total Load: 267 PLF 534 LB Upper Equiv Tributary Width: UTWeq= 5.5 FT Lower Equiv Tributary Width. LTWeq= 6.55 FT Rafter Data. Interior Span: L= 11 0 FT Eave Span: L -Eave= 1 0 FT Rafter Spacing: Spacing= 24 0 IN 0 C Rafter Pitch. RP= 4 0 12 Roof sheathing applied to top of joists -Top of rafters fully braced. Live Load Deflect. Criteria: L/ 240 Total Load Deflect. Criteria. L/ 180 Rafter Loads: Roof Live Load: LL= 25 0 PSF Roof Dead Load: DL= 15 0 PSF Roof Duration Factor. Cd= 1 15 Slope Adjusted Spans And Loads: Interior Span. L -adi= 11.6 FT Eave Span: L- Eave -adj= 1 05 FT Rafter Live Load. wL -adj= 45 PLF Rafter Dead Load: wD -adi= 28 PLF Rafter Total Load. wT -adj= 73 PLF Properties For TJI 230 11 875- Trus Joist MacMillan Depth: D= 11.875 IN Moment Capacity. Mcap= 4015 FT -LB Shear Capacity Vcap= 1655 LB El: El= 310000000 LB -IN2 End Reaction Capacity Rcap= 1035 LB Comparisons With Required Sections: Controlling Moment: M= 1227 FT -LB Adjusted Moment Capacity Mcap -adj= 4617 FT -LB Controlling Shear V= 361 LB Adjusted Shear Capacity Vcap -adj= 1903 LB El Required: El -req= 47189720 LB -IN2 El El= 310000000 LB -IN2 Maximum End Reaction: Rmax= 534 LB Adjusted Reaction Capacity Rcap -adj= 1190 LB Floor Joist( 2000 International Building Code (97 NDS)1 Ver• 6.00 7 By Charles Smith Lindberg Smith on. 08 -18 -2009 12:50:29 AM Project: i Location: FLOOR JOISTS 1 Summary TJI 560 11 785 Trus Joist MacMillan x 21 0 FT A 12 0 C Section Adequate By 64.6% Controlling Factor Allowable Deflection I- joists were designed for simple spans using the joist manufacturers published values. If the design does not match the actual joist loading or span conditions in any way contact the joist manufacturer for design verification. Joist Span Deflections: Dead Load: DLD- Center= 0 12 IN Live Load: LLD- Center= 0.31 IN L1815 Total Load: TLD- Center= 0.43 IN L/593 Joist Span Left End Reactions (Support A) Live Load. LL- Rxn -A= 420 LB Dead Load: DL- Rxn -A= 158 LB Total Load: TL- Rxn -A= 577 LB Bearing Length Required (Beam only support capacity not checked) BL -A= 1 75 IN Joist Span Right End Reactions (Support B) Live Load: LL- Rxn -B= 420 LB Dead Load: DL- Rxn -B= 158 LB Total Load: TL- Rxn -B= 577 LB Bearing Length Required (Beam only support capacity not checked) BL -B= 1 75 IN Joist Data: Joist Span Length: L2= 21.0 FT Floor sheathing applied to top of joists -top of joists fully braced. Live Load Duration Factor Cd= 1 00 Live Load Deflect. Criteria. U 480 Total Load Deflect. Criteria: L/ 360 Joist Span Loading: Uniform Floor Loading: Live Load: LL 2= 40.0 PSF Dead Load: DL 2= 15.0 PSF Total Load: TL -2= 55.0 PSF Total Load Adjusted for Joist Spacing wT 2= 55 PLF Properties For TJI 560 11 785- Trus Joist MacMillan Depth. D= 11 785 IN Moment Capacity Mcap= 9500 FT -LB Shear Capacity Vcap= 2050 LB El El= 636000000 LB -IN2 End Reaction Capacity Rcap= 1265 LB Comparisons With Required Sections: Controlling Moment: M= 3032 FT -LB Adjusted Moment Capacity Mcap -adj= 9500 FT -LB Controlling Shear V= 531 LB Adjusted Shear Capacity Vcap -adj= 2050 LB El Required: El-req= 386275500 LB -IN2 El El= 636000000 LB -IN2 Maximum End Reaction Rmax= 577 LB Adjusted Reaction Capacity Rcap -adj= 1265 LB Combination Roof and Floor Beamf 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on. 08 -18 -2009 12:52:20 AM Project: Location. FLOOR 1 Summary 1 75 IN x 11 875 IN x 11.5 FT Versa -Lam 2800 Fb DF Boise Cascade Section Adequate By 14.3% Controlling Factor Section Modulus Depth Required 11 11 In Deflections. Dead Load DLD= 0.11 IN Live Load: LLD= 0.29 IN U476 Total Load: TLD= 0.40 IN L/342 Reactions (Each End) Live Load: LL -Rxn= 2070 LB Dead Load: DL -Rxn= 814 LB Total Load TL -Rxn= 2884 LB Bearing Length Required (Beam only support capacity not checked) BL= 1.83 IN Beam Data: Span: L= 11.5 FT Maximum Unbraced Span: Lu= 1 0 FT Live Load Deflect. Criteria: U 360 Total Load Deflect. Criteria: U 240 Roof Loading: Roof Live Load -Side One. RLL1= 25.0 PSF Roof Dead Load -Side One. RDL1= 15 0 PSF Roof Tributary Width -Side One: RTW1= 0 0 FT Roof Live Load -Side Two RLL2= 25 0 PSF Roof Dead Load -Side Two RDL2= 15.0 PSF Roof Tributary Width -Side Two' RTW2= 0 0 FT Roof Duration Factor' Cd -roof= 1 15 Floor Loading: Floor Live Load -Side One. FLL1= 40 0 PSF Floor Dead Load -Side One FDL1= 15.0 PSF Floor Tributary Width -Side One FTW1= 9 0 FT Floor Live Load -Side Two FLL2= 40 0 PSF Floor Dead Load -Side Two FDL2= 15 0 PSF Floor Tributary Width -Side Two FTW2= 0 0 FT Floor Duration Factor Cd -floor= 1 00 Wall Load. WALL= 0 PLF Beam Loads: Roof Uniform Live Load: wL -roof= 0 PLF Roof Uniform Dead Load (Adjusted for roof pitch) wD -roof= 0 PLF Floor Uniform Live Load: wL -floor= 360 PLF Floor Uniform Dead Load: wD -floor= 135 PLF Beam Self Weight: BSW= 6 PLF Combined Uniform Live Load: wL= 360 PLF Combined Uniform Dead Load: wD= 141 PLF Combined Uniform Total Load: wT= 501 PLF Controlling Total Design Load: wT -cont= 501 PLF Properties For Versa -Lam 2800 Fb DF Boise Cascade Bending Stress. Fb= 2800 PSI Shear Stress. Fv= 285 PSI Modulus of Elasticity E= 2000000 PSI Stress Perpendicular to Grain. Fc_perp= 900 PSI Adjusted Properties Fb' (Tension) Fb'= 2765 PSI Adjustment Factors. Cd =1 00 C1 =0 99 Cf =1 00 Fv' Fv'= 285 PSI Adjustment Factors. Cd =1 00 Design Requirements: Controlling Moment: M= 8290 FT -LB 5.75 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= 2422 LB At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections: Section Modulus (Moment) Sreq= 35.98 N3 S= 41 13 N3 Area (Shear) Areq= 12.75 N2 A= 20 78 N2 Moment of Inertia (Deflection) Ireq= 184 76 N4 1= 244.21 N4 Multi- Loaded Beam' 2000 International Building Code (97 NDS) 1 Ver 6 00 7 By Charles Smith Lindberg Smith on. 08 -18 -2009 12:54 17 AM Location. FLOOR 2 Project SUMMtai y 5.25 IN x 11.875 IN x 21 0 FT Versa -Lam 3080 Fb DF Boise Cascade Section Adequate By 151.3% Controlling Factor Moment of Inertia Depth Center Span Deflections. Dead Load: Live Load: Total Load: Center Span Left End Reactions (Support A) Live Load: Dead Load Total Load: Bearing Length Required (Beam only support capacity not checked) Center Span Right End Reactions (Support B) Live Load: Dead Load: Total Load: Bearing Length Required (Beam only support capacity not checked) Beam Data: Center Span Length: Center Span Unbraced Length -Top of Beam Center Span Unbraced Length- Bottom of Beam. Live Load Duration Factor Live Load Deflect. Criteria: Total Load Deflect. Criteria. Center Span Loading: Uniform Load: Live Load: Dead Load: Beam Self Weight: Total Load: Point Load 1 Live Load: Dead Load: Location (From left end of span): Properties For Versa -Lam 3080 Fb DF Boise Cascade Bending Stress: Shear Stress: Modulus of Elasticity Stress Perpendicular to Grain: Adjusted Properties Fb' (Tension) Adjustment Factors: Cd =1 00 C1 =0 97 Cf =1 00 Fv' Adjustment Factors. Cd =1.00 Design Requirements: Controlling Moment: 3.15 Ft from left support of span 2 (Center Span) Critical moment created by combining all dead loads and live loads on span(s) 2 Controlling Shear At a distance d from left support of span 2 (Center Span) Critical shear created by combining all dead loads and live loads on span(s) 2 Comparisons With Required Sections: Section Modulus (Moment) Sreq= S= Area (Shear): Areq= A= Moment of Inertia (Deflection) lreq= 1= Required 8 73 In DLD- Center= LLD Center= TLD- Center= LL- Rxn -A= DL- Rxn -A= TL- Rxn -A= BL -A= LL- Rxn -B= DL- Rxn -B= TL- Rxn -B= BL -B= L2= Lu2 Top= Lu2- Bottom= Cd= L/ U wL -2= wD -2= BSW= wT -2= PL1 -2= PD1 -2= X1 2= Fb= Fv= E= Fc_perp= Fv'= M= V= 0 16 IN 0.26 IN U971 0 42 IN L/603 1984 LB 981 LB 2965 LB 0 63 IN 506 LB 400 LB 905 LB 0 19 IN 21.0 FT 18 0 FT 21 0 FT 1 00 360 240 20 PLF 8 PLF 19 PLF 47 PLF 2070 LB 814 LB 3 0 FT 3080 PSI 285 PSI 2000000 PSI 900 PSI Fb'= 2976 PSI 285 PSI 8675 FT -LB 2926 LB 34.97 N3 123.39 N3 15 40 N2 62.34 N2 291.55 N4 732.62 N4 Multi- Loaded Beam( 2000 International Building Code (97 NDS)1 Ver 6 00 7 By Charles Smith Lindberg Smith on: 08 -18 -2009 1 PM Location FLOOR 3 Project, Summa., 5.5 IN x 9.5 IN x 4 Section Adequate Center Span Deflections: Dead Load: Live Load: Total Load: Center Span Left End Reactions (Support A) Live Load: Dead Load: Total Load: Bearing Length Required (Beam only support capacity not checked) Center Span Right End Reactions (Support B) Live Load. Dead Load: Total Load Bearing Length Required (Beam only support capacity not checked) Beam Data: Center Span Length. Center Span Unbraced Length -Top of Beam: Center Span Unbraced Length- Bottom of Beam: Live Load Duration Factor Live Load Deflect. Criteria: Total Load Deflect. Criteria. Center Span Loading: Uniform Load: Live Load Dead Load: Beam Self Weight: Total Load: Point Load 1 Live Load: Dead Load: Location (From left end of span) Trapezoidal Load 1 Left Live Load: TRL -Left -1 2= Left Dead Load: TRD- Left-1 -2= Right Live Load TRL Right -1 2= Right Dead Load TRD- Right -1 2= Load Start: A -1 2= Load End: B -1 -2= Load Length. C -1 -2= Trapezoidal Load 2 Left Live Load: TRL -Left-2 2= Left Dead Load: TRD -Left-2 2= Right Live Load: TRL Right -2 2= Right Dead Load: TRD- Right -2 2= Load Start: A-2 2= Load End B-2-2= Load Length: C-2 2= Properties For #2 Douglas Fir -Larch Bending Stress: Shear Stress: Modulus of Elasticity' Stress Perpendicular to Grain. Adjusted Properties Fb' (Tension) Adjustment Factors. Cd =1.00 CI =1.00 Cf=1 00 Fv' Adjustment Factors. Cd =1 00 Design Requirements. Controlling Moment: 2.24 Ft from left support of span 2 (Center Span) Critical moment created by combining all dead loads and live loads on span(s) 2 Controlling Shear At a distance d from right support of span 2 (Center Span) Critical shear created by combining all dead loads and live loads on span(s) 2 Comparisons With Required Sections. Section Modulus (Moment) Sreq= S= Area (Shear) Areq= A= Moment of Inertia (Deflection) keg= 1= 0 FT #2 Douglas Fir -Larch Dry Use By 47.2% Controlling Factor Area Depth Required 6 78 In DLD- Center= LLD Center= TLD- Center= LL- Rxn -A= DL- Rxn -A= TL- Rxn -A= BL -A= LL- Rxn -B= DL- Rxn -B= TL- Rxn -B= BL -B= L2= Lu2 Top= Lu2- Bottom= Cd= U U wL 2= wD -2= BSW= wT -2= PL1 2= PD1 -2= X1 2= Fb= Fv= E= Fc_perp= Fb'= Fv'= M= V= 001 0.01 0.02 1697 1023 2720 0 79 1749 1095 2844 0.83 40 1.67 40 1 00 360 240 325 PLF 263 PLF 13 PLF 601 PLF 506 LB 400 LB 2.5 FT 440 PLF 165 PLF 440 PLF 165 PLF 0 0 FT 2.5 FT 2.5 FT 360 PLF 135 PLF 360 PLF 135 PLF 2.5 FT 4.0 FT 1.5 FT 875 PSI 85 PSI 1300000 PSI 625 PSI 874 PSI IN IN U4600 IN L/2832 LB LB LB IN LB LB LB IN FT FT FT 85 PSI 3068 FT -LB 2011 LB 42.12 82.73 35 49 52.25 33.30 392.96 N3 N3 N2 N2 N4 N4 Multi- Loaded Beam( 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on: 08 -18 -2009 1.58:30 PM Project. Location. RPPF 4 Summary 5 125 IN x 15 0 IN x 14 0 FT 24F V4 Visually Graded Western Species Dry Use Section Adequate By 29 6% Controlling Factor Section Modulus Depth Required 13 18 In Center Span Deflections. Dead Load. Live Load Total Load: Camber Required: Center Span Left End Reactions (Support A): Live Load: Dead Load: Total Load: Bearing Length Required (Beam only support capacity not checked) Center Span Right End Reactions (Support B) Live Load: Dead Load: Total Load: Bearing Length Required (Beam only support capacity not checked) Beam Data: Center Span Length. Center Span Unbraced Length -Top of Beam: Center Span Unbraced Length- Bottom of Beam: Live Load Duration Factor Live Load Deflect. Criteria. Total Load Deflect. Criteria: Center Span Loading Uniform Load: Live Load: Dead Load Beam Self Weight: Total Load: Point Load 1 Live Load: Dead Load: Location (From left end of span) Properties For 24F V4- Visually Graded Western Species Bending Stress. Shear Stress: Modulus of Elasticity Stress Perpendicular to Grain. Bending Stress of Comp. Face in Tension. Adjusted Properties Fb' (Tension): Adjustment Factors. Cd =1 00 CI =0.99 Fv' Adjustment Factors. Cd =1 00 Design Requirements. Controlling Moment: 7 0 Ft from left support of span 2 (Center Span) Critical moment created by combining all dead loads and live loads on span(s) 2 Controlling Shear At a distance d from left support of span 2 (Center Span) Critical shear created by combining all dead loads and live loads on span(s) 2 Comparisons With Required Sections: Section Modulus (Moment) Area (Shear). Moment of Inertia (Deflection) DLD- Center= 016 IN LLD Center= 0.18 IN L/950 TLD- Center= 0.33 IN L/506 C= 0.23 IN LL- Rxn -A= 2519 LB DL- Rxn -A= 2386 LB TL- Rxn -A= 4904 LB BL -A= 147 IN LL- Rxn -B= 2519 LB DL- Rxn -B= 2386 LB TL- Rxn -B= 4904 LB BL -B= 147 IN L2= 14 0 FT Lug Top= 7 0 FT Lu2- Bottom= 14 0 FT Cd= 100 L/ 360 L/ 240 wL -2= 75 PLF wD -2= 113 PLF BSW= 19 PLF wT 2= 207 PLF PL1 2= 3987 LB PD1 -2= 2928 LB X1 2= 7 0 FT Fb= 2400 PS Fv= 190 PS Ex= 1800000 PS Ey= 1600000 PS Fc perp= 650 PS Fb_cpr= 1200 PS Fb'= 2368 PS Fv'= 190 PS M= V= 29266 FT -LB 4673 LB Sreq= 148.32 N3 S= 192.19 N3 Areq= 36.89 N2 A= 76 88 N2 Ireq= 683.84 N4 1= 1441 41 N4 Multi- Loaded Beam( 2000 International Building Code (97 NDS) 1 Ver 6 00.7 By' Charles Smith Lindberg Smith on. 08 -18 -2009 1 11 PM Proiec, Location: FLOOR 5 Summary' 5.5 IN x 11.5 IN x 4 0 FT #2 Douglas Fir -Larch Dry Use Section Adequate By' 20 4% Controlling Factor Area Depth Required 9.55 In Center Span Deflections Dead Load: DLD- Center= Live Load. LLD Center= Total Load: TLD- Center= Center Span Left End Reactions (Support A) Live Load: Dead Load: Total Load: Bearing Length Required (Beam only support capacity not checked) Center Span Right End Reactions (Support B) Live Load Dead Load. Total Load: Bearing Length Required (Beam only support capacity not checked) Beam Data: Center Span Length. Center Span Unbraced Length -Top of Beam: Center Span Unbraced Length- Bottom of Beam Live Load Duration Factor' Live Load Deflect. Criteria: Total Load Deflect. Criteria: Center Span Loading: Uniform Load: Live Load: wL 2= Dead Load: wD -2= Beam Self Weight: BSW= Total Load: wT 2= Point Load 1 Live Load: PL1 2= Dead Load. PD1 -2= Location (From left end of span) X1 2= Trapezoidal Load 1 Left Live Load: TRL- Left -1 -2= Left Dead Load: TRD -Left-1 2= Right Live Load: TRL Right -1 2= Right Dead Load. TRD- Right -1 2= Load Start: A -1 2= Load End: B -1 -2= Load Length C -1 -2= Properties For #2 Douglas Fir -Larch Bending Stress: Fb= Shear Stress: Fv= Modulus of Elasticity' E= Stress Perpendicular to Grain: Fc_perp= Adjusted Properties Fb' (Tension) Fb'= Adjustment Factors: Cd =1 00 CI =1 00 Cf =1 00 Fv' Fv'= Adjustment Factors: Cd =1 00 Design Requirements. Controlling Moment: 2.48 Ft from left support of span 2 (Center Span) Critical moment created by combining all dead loads and live loads on span(s) 2 Controlling Shear At a distance d from right support of span 2 (Center Span) Critical shear created by combining all dead loads and live loads on span(s) 2 Comparisons With Required Sections: Section Modulus (Moment) Sreq= S= Area (Shear). Areq= A= Moment of Inertia (Deflection) Ireq= I= 0 00 IN 001 IN =L/5566 0 01 IN L/3581 LL- Rxn -A= 2150 LB DL- Rxn -A= 1208 LB TL- Rxn -A= 3358 LB BL -A= 0.98 IN LL- Rxn -B= 2234 LB DL- Rxn -B= 1299 LB TL- Rxn -B= 3533 LB BL -B= 103 IN L2= 4 0 FT Lu2 Top= 1 67 FT Lu2- Bottom= 4 0 FT Cd= 100 U 360 U 240 325 PLF 263 PLF 15 PLF 603 PLF 1984 LB 981 LB 2.5 FT 440 PLF 165 PLF 440 PLF 165 PLF 0 0 FT 2.5 FT 2.5 FT 875 PSI 85 PSI 1300000 PSI 625 PSI 874 PSI 85 PSI M= 4613 FT -LB V= 2977 LB 63 34 121.23 52.54 63.25 46.72 697.07 N3 N3 N2 N2 N4 N4 Combination Roof and Floor Beam[ 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on: 08 -18 -2009 2:03.12 PM Project "y Location: ROOF 7 Summary' 3 5 IN x 5.5 IN x 4 0 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 2.9% Controlling Factor' Area Depth Required 5.35 In Deflections: Dead Load: DLD= 0 02 IN Live Load: LLD= 0.04 IN L/1182 Total Load: TLD= 0 06 IN L/741 Reactions (Each End) Live Load: LL -Rxn= 1095 LB Dead Load: DL -Rxn= 653 LB Total Load: TL -Rxn= 1748 LB Bearing Length Required (Beam only support capacity not checked) BL= 0.80 IN Beam Data. Span: L= 4 0 FT Maximum Unbraced Span: Lu= 1 0 FT Live Load Deflect. Criteria. L/ 360 Total Load Deflect. Criteria. L/ 240 Roof Loading: Roof Live Load -Side One: RLL1= 25 0 PSF Roof Dead Load -Side One: RDL1= 15 0 PSF Roof Tributary Width -Side One: RTW1= 2.0 FT Roof Live Load -Side Two: RLL2= 25 0 PSF Roof Dead Load -Side Two: RDL2= 15 0 PSF Roof Tributary Width -Side Two RTW2= 5 5 FT Roof Duration Factor' Cd -roof= 1 15 Floor Loading: Floor Live Load -Side One: FLL1= 40 0 PSF Floor Dead Load -Side One: FDL1= 15.0 PSF Floor Tributary Width -Side One: FTW1= 9.0 FT Floor Live Load -Side Two: FLL2= 40 0 PSF Floor Dead Load -Side Two: FDL2= 15 0 PSF Floor Tributary Width -Side Two FTW2= 0 0 FT Floor Duration Factor Cd -floor= 1 00 Wall Load: WALL= 68 PLF Beam Loads: Roof Uniform Live Load: wL -roof= 188 PLF Roof Uniform Dead Load (Adjusted for roof pitch) wD -roof= 119 PLF Floor Uniform Live Load: wL -floor= 360 PLF Floor Uniform Dead Load: wD -floor= 135 PLF Beam Self Weight: BSW= 5 PLF Combined Uniform Live Load: wL= 548 PLF Combined Uniform Dead Load wD= 326 PLF Combined Uniform Total Load: wT= 874 PLF Controlling Total Design Load: wT -cont= 874 PLF Properties For #2 Douglas Fir -Larch Bending Stress: Fb= 900 PSI Shear Stress: Fv= 95 PSI Modulus of Elasticity E= 1600000 PSI Stress Perpendicular to Grain. Fc_perp= 625 PSI Adjusted Properties F Fb' (Tension) b'= 1344 PSI Adjustment Factors: Cd =1 15 CI =1.00 Cf =1.30 Fv' Fv'= 109 PSI Adjustment Factors: Cd =1 15 Design Requirements. Controlling Moment: M= 1748 FT -LB 2.0 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= 1363 LB At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections. Section Modulus (Moment) Sreq= 15 60 N3 S= 17 65 N3 Area (Shear) Areq= 18 71 N2 A= 19.25 N2 Moment of Inertia (Deflection) Ireq= 15 73 N4 I= 48.53 N4 Combination Roof and Floor Beam[ 2000 International Building Code (97 NDS) Ver 6 00 7 By Charles Smith Lindberg Smith on: 08 -18 -2009 2:02:26 PM Project: Location. ROOF 6 Summary 2 1.5 IN x 5.5 IN x 4 0 FT #2 Douglas Fir -Larch Dry Use Section Adequate By 247 1% Controlling Factor Area Depth Required 2.82 In Deflections: Dead Load DLD= Live Load. LLD= Total Load: TLD= Reactions (Each End) Live Load: LL -Rxn= Dead Load: DL -Rxn= Total Load TL -Rxn= Bearing Length Required (Beam only support capacity not checked) BL= Beam Data: Span. L= Maximum Unbraced Span Lu= Live Load Deflect. Criteria. U Total Load Deflect. Criteria. L/ Roof Loading: Roof Live Load -Side One: RLL1= Roof Dead Load -Side One: RDL1= Roof Tributary Width -Side One: RTW1= Roof Live Load -Side Two RLL2= Roof Dead Load -Side Two RDL2= Roof Tributary Width -Side Two RTW2= Roof Duration Factor Cd -roof= Floor Loading: Floor Live Load -Side One FLL1= Floor Dead Load -Side One FDL1= Floor Tributary Width -Side One: FTW1= Floor Live Load -Side Two FLL2= Floor Dead Load -Side Two: FDL2= Floor Tributary Width -Side Two: FTW2= Floor Duration Factor Cd -floor= Wall Load: WALL= Beam Loads: Roof Uniform Live Load: wL -roof= Roof Uniform Dead Load (Adjusted for roof pitch) wD -roof= Floor Uniform Live Load wL -floor= Floor Uniform Dead Load. wD -floor= Beam Self Weight: BSW= Combined Uniform Live Load: wL= Combined Uniform Dead Load wD= Combined Uniform Total Load: wT= Controlling Total Design Load: wT -cont= Properties For #2 Douglas Fir -Larch Bending Stress. Fb= Shear Stress. Fv= Modulus of Elasticity E= Stress Perpendicular to Grain. Fc_perp= Adjusted Properties Fb' (Tension) Fb'= Adjustment Factors: Cd =1 15 C1 =0 99 Cf =1.30 Fv' Fv'= Adjustment Factors: Cd =1 15 Design Requirements: Controlling Moment: M= 2.0 ft from left support Critical moment created by combining all dead and live loads. Controlling Shear V= At a distance d from support. Critical shear created by combining all dead and live loads. Comparisons With Required Sections: Section Modulus (Moment) Sreq= 3.98 S= 15 13 Area (Shear) Areq= 4 75 A= 16.50 Moment of Inertia (Deflection) Ireq= 3.99 I= 41.59 0 01 IN 0 01 IN U5839 0 02 IN U2499 190 LB 254 LB 444 LB 0.24 IN 4 0 FT 4 0 FT 360 240 25 0 PSF 15 0 PSF 2.0 FT 25 0 PSF 15 0 PSF 10 FT 1 15 40 0 PSF 15 0 PSF 0.5 FT 40.0 PSF 15.0 PSF 0 0 FT 1 00 68 PLF 75 PLF 47 PLF 20 PLF 8 PLF 4 PLF 95 PLF 127 PLF 222 PLF 222 PLF 900 PSI 95 PSI 1600000 PSI 625 PSI 1337 PSI 109 PSI 444 FT -LB 346 LB N3 N3 N2 N2 N4 N4