922 W Park Ln - Plan - Laserfiche WebLink

Home Browse Search

Deflection amplification factor Cdδ = 4 Seismic importance factor Ie = 1 Chord forces from shear walls above Chord WL(lb) Eq(lb) DLC.(lb) DLT.(lb) LL(lb) Lr(lb) SL(lb) RL(lb) Ch1 -376 -448 0 0 0 0 0 0 Ch2 376 448 0 0 0 0 0 0 DLC :Compressive Dead point load , DLT :Tensile Dead point load From ASCE 7-16 - cl.2.4.1 and cl. 2.4.5 Basic combinations Load combination no.1 D + 0.6W Load combination no.2 D + 0.7E Load combination no.3 D + 0.75Lf + 0.45W + 0.75(Lr or S or R) Load combination no.4 D + 0.75Lf + 0.525E + 0.75S Load combination no.5 0.6D + 0.6W Load combination no.6 0.6D + 0.7E Adjustment factors Load duration factor – Table 2.3.2 CD=1.6 Size factor for tension – Table 4A CFt=1.5 Size factor for compression – Table 4A CFc=1.15 Wet service factor for tension – Table 4A CMt=1 Wet service factor for compression – Table 4A CMc=1 Wet service factor for modulus of elasticity – Table 4A CME=1 Temperature factor for tension – Table 2.3.3 Ctt=1 Temperature factor for compression – Table 2.3.3 Ctc=1 Temperature factor for modulus of elasticity – Table 2.3.3 CtE=1 Incising factor – cl.4.3.8 C i=1 Buckling stiffness factor – cl.4.4.2 CT=1 Bearing area factor - cl. 3.10.4 C b=1 For sawn lumber c=0.8 Adjusted modulus of elasticity E min' = Emin× CME× CtE× Ci× CT=580000 psi Critical buckling design value F cE = 0.822×Emin' /(H/d)2= 633.714 psi Reference compression design value F c' = Fc× CD× CMc× Ctc× CFc× Ci=2484 psi Column stability factor – eqn.3.7-1 Cp = (1+(FcE/Fc'))/(2×c)-√([(1+(FcE/Fc'))/(2×c)]2-(FcE/Fc')/c)= 0.24 From SDPWS Table 4.3.3 Maximum Shear Wall Aspect Ratios Maximum shear wall aspect ratio 3.5 Shear wall length B = 18.2 ft Page 56 of 290