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REVIEWED Structural Calculations 2-21-20Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL AMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 STRUCTURAL CALCULATIONS 2/21 /2020 AS WASy� C J ; iwpp'�r 47 NOT VALID WITHOUT SIGNATURE Project Description: Pickering Edmonds Project Location: 300, 302 & 304 6th Avenue South, Edmonds, WA 98020 Client: Chris Pickering 2611 Northeast 113th Street #300 Seattle, WA 98125 Project Number: E1396 Date: February 21, 2020 Design Criteria: Code: 2015 IBC / ASCE 7-10 Wind: 110 mph Exposure: B Kzt: 1.00 Seismic Data: Design Category D Site Class D Spectra: By Lat/Long - USGS website Design Gravity Loads: Snow: 25 psf S Roof: 15 psf DL Floor: 40 psf LL 15 psf DL Deck: 60 psf LL 10 psf DL Soil: Allowable Bearing: 2500 psf Passive Pressure: 200 pcf Active Pressure: 40 pcf 60 pcf Friction: M 0.35 Equilibria STRUCTURAL ENGINEERING (unrestrained) (restrained) Project: E1396 Sheet No: 1 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUCfUHAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 ROOF FRAMING PLAN NTS Project: E1396 Sheet No: 2 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL G6111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: GT1 Uniform Loads Span: 12.3 ft start end (ft) 0 12.3 Member: GIRDER TRUSS E psi 1.00E+10 x = 6.13 (ft) inA4 #### M @ x = 9 (k-ft) A in12 #### V @ x = 0 (k) Results M allow = 1000.00 (k-ft) Loading Diagram: GT1 M max = 9.00 (k-ft) R1 = 2.94 (k) a 1000 R2 = 2.94 (k) O Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) _ 480 480 v max = 0 (psi) D soo Deflect. = 0.000 (in) 0 = L 0 2 4 6 8 10 12 ######## SHOWN TO DETERMINE REACTIONS Beam Span: 29 ft GT2 Member: GIRDER TRUSS E psi 1.00E+10 inA4 #### A i n ^2 #### Results Uniform Loads start end (ft) 0 9.5 9.5 29 x = 14.5 (ft) M @ x = 28.2 (k-ft) V @ x = -1.3 (k) M allow = 1000.00 (k-ft) Loading Diagram: GT2 M max = 33.67 (k-ft) R1 = 5.02 (k) w 600 00 R2 = 2.58 (k) 0 400 v max = 0 (psi) J 200 Deflect. = 0.000 (in) o = L 0 5 ######## SHOWN TO DETERMINE REACTIONS Beam: Span: 9.5 ft GT3 Member: GIRDER TRUSS E psi 1.00E+10 in^4 #### A i n ^2 #### Results 1 0.8 0.6 0.4 0 0.2 a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 310 310 9.5 2.94 88 88 10 15 20 25 Uniform Loads start end (ft) 0 9.5 x = 4.75 (ft) M @ x = 3.5 (k-ft) V @ x = 0 (k) M allow = 1000.00 (k-ft) Loading Diagram: GT3 4000 3000 S 2000 m Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 310 310 M max = 3.50 (k-ft) 1 R1 = 1.47 (k) w 800 0.8 600 R2 = 1.47 (k) 400 0.6 c 0.4 c v max = 0 (psi) 0 200 0.2 Deflect. = 0.000 (in) 0 0 = L 0 1 2 3 4 5 6 7 8 9 ######## SHOWN TO DETERMINE REACTIONS Project: E1396 Sheet No: 3 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL G6111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: GT4 Uniform Loads Span: 14.3 ft start end (ft) 0 12.3 Member: GIRDER TRUSS 12.3 14.3 E psi 1.00E+10 x = 7.13 (ft) inA4 #### M @ x = 8.36 (k-ft) A in12 #### V @ x = 0.23 (k) Results _ M allow = 1000.00 (k-ft) Loading Diagram: GT4 M max = 8.46 (k-ft) R1 = 2.12 (k) a 1000 R2 = 3.46 (k) v max = 0 soo (psi) Deflect. = 0.000 D (in) 0 = L 0 2 4 ######## SHOWN TO DETERMINE REACTIONS Beam Span: 29 ft GT5 Member: GIRDER TRUSS E psi 1.00E+10 inA4 #### A i n ^2 #### Results Uniform Loads start end (ft) 0 19.6 19.6 29 x = 14.5 (ft) M @ x = 40.8 (k-ft) V @ x = -0.1 (k) M allow = 1000.00 (k-ft) Loading Diagram: GT5 M max = 40.83 (k-ft) R1 = 4.66 (k) w 600 00 R2 = 5.61 (k) 0 400 v max = 0 (psi) J 200 Deflect. = 0.000 (in) 0 = L 0 ######## SHOWN TO DETERMINE REACTIONS Beam: Span: 29 ft GT6 Member: GIRDER TRUSS E psi 1.00E+10 in^4 #### A i n ^2 #### Results Magnitude(plf) Point Loads _start end (plf) distance(ft) 265 265 12.3 430 430 6 8 10 Magnitude(plf) Point Loads start end (plf) distance(ft) 90 90 9.5 310 310 19.6 5 10 15 20 Uniform Loads start end (ft) 0 9.5 9.5 29 x = 14.5 (ft) M @ x = 40.8 (k-ft) V @ x = 0.09 (k) M allow = 1000.00 (k-ft) Loading Diagram: GT6 M max = 40.83 (k-ft) R1 = 5.60 (k) w 600 00 R2 = 4.68 (k) 0 400 v max = 0 (psi) J 200 Deflect. = 0.000 (in) o = L 0 5 ######## SHOWN TO DETERMINE REACTIONS Magnitude(k) 1.47 2000 1500 1000 500 a 0 12 14 Magnitude(k) 3.46 2.12 25 4000 3000 2000 0 1000 0 0 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 310 310 9.5 2.12 90 90 19.6 3.46 10 15 20 25 4000 3000 2000 m 0 1000 Ja 0 Project: E1396 Sheet No: 4 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 3.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 3.44 M max = 3.05 R1 = 2.65 R2 = 1.99 vmax = 157 Deflect. = 0.032 = L 1295 Cd=1.15 Beam Span: 3.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.77 R1 = 0.88 R2 = 0.88 v max = 52 Deflect. = 0.010 = L 4365 Beam: Span: 3 ft RHD1 (k-ft) (k-ft) (k) (k) (psi) (in) RHD2 (k-ft) (k-ft) (k) (k) (psi) (in) RHD3 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.76 (k-ft) R1 = 1.01 (k) R2 = 1.01 (k) v max = 91 (psi) Deflect. = 0.023 (in) = L 1579 Uniform Loads start end (ft) 0 1.42 1.42 3.5 x = 1.75 (ft) M @ x = 2.71 (k-ft) V @ x = -1.1 (k) Loading Diagram: RHD1 2000 fl. 1500 m 1000 0 500 0 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 715 715 1.42 2.58 505 505 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 3.5 x = 1.75 (ft) M @ x = 0.77 (k-ft) V @ x = 0 (k) Loading Diagram: RHD2 3000 2000 m 1000 0 a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 505 505 1500 1 0.8 7 a 1000 2 0.6 500 0.4 0 D 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.76 (k-ft) V @ x = 0 (k) Loading Diagram: RHD3 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 675 675 2000 1 1500 0.8 'am 1000 0.6 Z 0.4 f0 0 0 500 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 5 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 9.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.35 R1 = 0.57 R2 = 0.57 vmax = 34 Deflect. = 0.124 = L 919 Beam Span: 5.5 ft Member: 4x8 DF#2 E psi 1.60E+06 inA4 111 A inA2 25.4 Results M allow = 2.99 M max = 2.70 R1 = 1.97 R2 = 1.97 v max = 116 Deflect. = 0.083 = L 795 Beam: Span: 3.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 3.44 M max = 3.19 R1 = 2.34 R2 = 2.39 v max = 141 Deflect. = 0.034 = L 1229 Cd=1.15 RHD4 (k-ft) (k-ft) (k) (k) (psi) (in) RHD5 (k-ft) (k-ft) (k) (k) (psi) (in) RHD6 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 9.5 x = 4.75 (ft) M @ x = 1.35 (k-ft) V @ x = 0 (k) Loading Diagram: RHD4 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 120 120 1 a 300 0.8 7 0 200 0.6 c 0.4 0 100 0.2 a 0 0 0 1 2 3 4 5 6 7 8 9 Uniform Loads start end (ft) 0 5.5 x = 2.75 (ft) M @ x = 2.7 (k-ft) V @ x = 0 (k) Loading Diagram: RHD5 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 715 715 2000 1 0.8 g 1500 0.6 c m 1000 � c 0.4 o n s00 0.2 a 0 0 0 1 2 3 4 5 Uniform Loads start end (ft) 0 1.66 1.66 3.5 x = 1.75 (ft) M @ x = 3.09 (k-ft) V @ x = -1.1 (k) Loading Diagram: RHD6 2000 fl. 1500 m 1000 0 500 0 0 0.5 1 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 505 505 1.66 2.58 715 715 1.5 2 2.5 3 3.5 3000 2000 m 1000 0° a 0 Project: E1396 Sheet No: 6 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 6.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.71 R1 = 0.44 R2 = 0.44 vmax = 26 Deflect. = 0.031 = L 2549 Beam Span: 3 ft RHD7 (k-ft) (k-ft) (k) (k) (psi) (in) RHD8 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.15 (k-ft) R1 = 0.20 (k) R2 = 0.20 (k) v max = 18 (psi) Deflect. = 0.005 (in) = L 7896 Beam: Span: 9.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.52 R1 = 0.64 R2 = 0.64 v max = 38 Deflect. = 0.140 = L 817 RHD9 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 6.5 x = 3.25 (ft) M @ x = 0.71 (k-ft) V @ x = 0 (k) Loading Diagram: RHD7 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 135 135 400 1 a 300 0.8 200 0.6 Z f0 0.4 f0 0 0 D 100 0.2 a 0 0 0 1 2 3 4 5 6 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.15 (k-ft) V @ x = 0 (k) Loading Diagram: RHD8 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 135 135 400 1 a 300 0.8 Z 200 0.6 c 0.4 o 100 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 9.5 x = 4.75 (ft) M @ x = 1.52 (k-ft) V @ x = 0 (k) Loading Diagram: RHD9 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 135 135 400 1 a 300 0.8 200 0.6 Z f0 0.4 f0 0 0 100 0.2 a 0 0 0 1 2 3 4 5 6 7 8 9 Project: E1396 Sheet No: 7 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: RHD10 Span: 3 ft Member: (2) 2x6 HF#2 E psi 1.30E+06 inA4 41.6 A inA2 16.6 Results M allow = 1.40 (k-ft) M max = 0.80 (k-ft) R1 = 1.07 (k) R2 = 1.07 (k) v max = 97 (psi) Deflect. = 0.024 (in) = L 1491 Beam Span: 6.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.71 R1 = 0.44 R2 = 0.44 v max = 26 Deflect. = 0.031 = L 2549 Beam: Span: 3 ft RHD11 (k-ft) (k-ft) (k) (k) (psi) (in) RHD12 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.15 (k-ft) R1 = 0.20 (k) R2 = 0.20 (k) v max = 18 (psi) Deflect. = 0.005 (in) = L 7896 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.8 (k-ft) V @ x = 0 (k) Loading Diagram: RHDQO Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 715 715 2000 1 0.8 n 1500 0.6 � m 1000 Z. 0 0.4 o 500 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 6.5 x = 3.25 (ft) M @ x = 0.71 (k-ft) V @ x = 0 (k) Loading Diagram: RHD11 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 135 135 400 1 300 0.8 1 200 0.6 c 0.4 o 100 0.2 a 0 0 0 1 2 3 4 5 6 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.15 (k-ft) V @ x = 0 (k) Loading Diagram: RHD12 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 135 135 400 1 a 300 0.8 200 0.6 Z f0 0.4 f0 0 0 100 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 8 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALL AMILMING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 i i l l!! I 11.-.I_ I I I I -� I I I I I I I I 1 1 1 1 1 1 I 1 1 1 1 1 1 1 I IIIIIIIIIIIIIIIIII IMME .� MM mm .� US .� .n .� IMC .CI .I MI " r • . 2ND FLOOR FRAMING PLAN NTS Project: E1396 Sheet No: 9 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B1 Uniform Loads Span: 17.3 ft start end (ft) 0 13.5 Member: 5 1/8" x 15" 24F V4 GLB 13.5 17.3 E psi 1.80E+06 x = 8.63 (ft) in14 1441 M @ x = 30.1 (k-ft) A inA2 76.9 V @ x = -0 (k) Results M allow = 38.40 (k-ft) Loading Diagram: 61 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) _ 815 815 760 760 M max = 30.12 (k-ft) 1 R1 = 7.01 (k) w 2000 0.8 , R2 = 6.85 (k) a 1500 0.6 v max = 136 (psi) loon soo o.4 mo 0.2 a Deflect. = 0.623 (in) 0 0 = L 0 2 4 6 8 10 12 14 16 332 Beam: B1 DEFL Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 17.3 ft start end (ft) start end (plf) distance(ft) 0 13.5 590 590 Member: 5 1/8" x 15" 24F V4 GLB 13.5 17.3 550 550 E psi 1.80E+06 x = 8.63 (ft) in14 1441 M @ x = 21.8 (k-ft) A in^2 76.9 V @ x = -0 (k) Results M allow = 38.40 (k-ft) Loading Diagram: B1 DEFL M max = 21.80 (k-ft) 1 R1 = 5.07 (k) a 1500 0.8 R2 = 4.96 (k) loon 0.6 v max = 99 (psi) c soo c 0.40.2 a Deflect. = 0.451 (in) 0 0 = L 0 2 4 6 8 10 12 14 16 459 Beam: B2 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 24 ft start end (ft) end (plf) distance(ft) 0 1.75 _start 815 815 Member: 6 3/4" x 18" 24F V4 GLB 1.75 12.8 845 845 E psi 1.80E+06 x = 12 (ft) 12.8 24 815 815 1 in^4 3281 M @ x = 59.9 (k-ft) A in12 122 V @ x = -0.1 (k) Results M allow = 67.07 (k-ft) Loading Diagram: _ 62 M max = 59.88 (k-ft) 1 R1 = 10.01 (k) a 2000 0.8 R2 = 9.88 (k) 0.6 v max = 123 (psi) (p ) 0 l000 0.4 0 0.2 a Deflect. = 1.053 (in) 0 0 = L 0 5 10 15 20 274 Cv=0.92 Project: E1396 Sheet No: 10 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( "df.,\GIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B2 DEFL Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 24 ft start end (ft) end (plf) distance(ft) 0 1.75 _start 590 590 _ Member: 6 3/4" x 18" 24F V4 GLB 1.75 12.8 615 615 E psi 1.80E+06 x = 12 (ft) 12.8 24 590 590 1 in14 3281 M @ x = 43.5 (k-ft) A inA2 122 V @ x = -0.1 (k) Results M allow = 67.07 (k-ft) _ Loading Diagram: 132 DEFL M max = 43.48 (k-ft) 1 R1 = 7.27 (k) a 1500 0.8 R2 = 7.16 (k) 1000 0.6 v max = 89 (psi) soo 0.4 o 0.2 a Deflect. = 0.765 (in) D 0 0 = L 0 5 10 15 20 377 Cv=0.92 Beam: B3 Span: 17.3 ft Member: E psi inA4 A inA2 Results M allow = M max = R1 = R2 = vmax = Deflect. = Beam: Span: Uniform Loads start end (ft) 0 3.75 5 1/8" x 15" 24F V4 GLB 3.75 17.3 1.80E+06 x = 8.63 (ft) 1441 M @ x = 30.1 (k-ft) 76.9 V @ x = 0.03 (k) 38.40 (k-ft) 30.12 (k-ft) 6.85 (k) 7.01 (k) 136 (psi) 0.623 (in) L 332 17.3 ft B3 DEFL Loading Diagram: 63 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 760 760 815 815 1 w 2000 0.8 1 1500 0.6 c 1000 0.4 0 500 0.2 Ja 0 0 0 2 4 6 8 10 12 14 16 Uniform Loads start end (ft) Member: 5 1/8" x 15" 24F V4 GLB 3.75 17.3 E psi 1.80E+06 x = 8.63 (ft) in14 1441 M @ x = 21.8 (k-ft) A inA2 76.9 V @ x = 0.02 (k) Results M allow = 38.40 (k-ft) Loading Diagram: B3 DEFL M max = 21.80 (k-ft) R1 = 4.96 (k) ' lsoo a. R2 = 5.07 (k) -o loon v max = 99 (psi) Deflect. = 0.451 (in) = L 459 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 550 550 590 590 0 500 0 0 2 4 6 8 10 12 14 16 1 0.8 0.6 0.4 0 0.2 Ja 0 Project: E1396 Sheet No: 11 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B4 Span: 10 ft Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 3.19 (k-ft) R1 = 1.28 (k) R2 = 1.28 (k) v max = 92 (psi) Deflect. = 0.124 (in) = L 972 Beam Span: 7 ft B5 Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 in^4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 7.21 (k-ft) R1 = 5.02 (k) R2 = 4.32 (k) v max = 181 (psi) Deflect. = 0.070 (in) = L 1203 Beam: Span: 7 ft B6 Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 inA4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 8.65 (k-ft) R1 = 3.87 (k) R2 = 4.33 (k) v max = 156 (psi) Deflect. = 0.076 (in) = L 1109 Uniform Loads start end (ft) 0 10 x = 5 (ft) M @ x = 3.19 (k-ft) V @ x = 0 (k) Loading Diagram: 64 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 255 255 1 a 600 0.8 0.6 a 400 c 0.4 0 200 0.2 a 0 0 0 1 2 3 4 5 6 7 8 9 10 Uniform Loads start end (ft) 0 1.63 1.63 5.13 x = 3.5 (ft) 5.13 7 M @ x = 7.2 (k-ft) V @ x = -0.1 (k) Loading Diagram: 65 3000 a 2000 0 1000 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 10851085 1.63 2.65 370 370 5.13 1.99 875 875 0 1 2 3 4 5 6 7 Uniform Loads start end (ft) 0 2.5 2.5 7 x = 3.5 (ft) M @ x = 8.52 (k-ft) V @ x = -0.5 (k) Loading Diagram: 66 3000 a 2000 0 1000 n 0 0 1 2 Project: E1396 Sheet No: 12 Magnitude(plf) start end (plf) 370 370 1085 1085 3 4 Point Loads distance(ft) 2.5 3000 2000 1000 0 a 0 Magnitude(k) 2.39 3000 2000 M 1000 0 a 0 5 6 7 2/21 /2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B7 Span: 10 ft Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 3.19 (k-ft) R1 = 1.28 (k) R2 = 1.28 (k) v max = 92 (psi) Deflect. = 0.124 (in) = L 972 Beam Span: 3.83 ft B8 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.28 (k-ft) R1 = 0.30 (k) R2 = 0.30 (k) v max = 21 (psi) Deflect. = 0.002 (in) = L 28449 Beam: Span: 7.17 ft B9 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.76 (k-ft) R1 = 0.42 (k) R2 = 0.33 (k) v max = 30 (psi) Deflect. = 0.015 (in) = L 5787 Uniform Loads start end (ft) 0 10 x = 5 (ft) M @ x = 3.19 (k-ft) V @ x = 0 (k) Loading Diagram: B7 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 255 255 1 a 600 0.8 1 0.6 400 c 0.4 MO200 0.2 a 0 0 0 1 2 3 4 5 6 7 8 9 10 Uniform Loads start end (ft) 0 3.83 x = 1.92 (ft) M @ x = 0.28 (k-ft) V @ x = 0 (k) Loading Diagram: 68 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 155 155 1 w 400 0.8 300 s 0.6 c zoo 0.4 o j 100 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 1.92 1.92 7.17 x = 3.59 (ft) M @ x = 0.73 (k-ft) V @ x = -0.1 (k) Loading Diagram: 69 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 36.7 36.7 1.92 0.3 73.3 73.3 200 400 300 150 - c 100 200 M 50 100 a 0 0 0 1 2 3 4 5 6 7 Project: E1396 Sheet No: 13 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B10 Span: 3.83 ft Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.86 (k-ft) R1 = 0.90 (k) R2 = 0.90 (k) v max = 65 (psi) Deflect. = 0.005 (in) = L 9382 Beam Span: 7 ft B11 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 1.00 (k-ft) R1 = 0.38 (k) R2 = 0.99 (k) v max = 72 (psi) Deflect. = 0.018 (in) = L 4561 Beam: Span: 4 ft B12 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.42 (k-ft) R1 = 0.42 (k) R2 = 0.42 (k) v max = 30 (psi) Deflect. = 0.003 (in) = L 18433 Uniform Loads start end (ft) 0 3.83 x = 1.92 (ft) M @ x = 0.86 (k-ft) V @ x = 0 (k) Loading Diagram: 1310 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 470 470 1 a 1000 0.:2 :2 0.6 v 0 500 0.4 o 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 6 6 7 x = 3.5 (ft) M @ x = 0.89 (k-ft) V@x= 0.13 (k) Loading Diagram: 1311 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 73.3 73.3 6 0.9 36.7 36.7 1000 200 _^ 800 a 150 600 c 0 100 400 0 50 200 a 0 0 0 1 2 3 4 5 6 7 Uniform Loads start end (ft) 0 4 x = 2 (ft) M @ x = 0.42 (k-ft) V @ x = 0 (k) Loading Diagram: B12 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 210 210 600 1 0.8 400 0.6 0 200 0.4 0 n 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 4 Project: E1396 Sheet No: 14 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B13 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 9.17 ft start end (ft) start end (plf) distance(ft) 0 1.88 36.7 36.7 1.88 0.42 Member: 1 3/4" x 11 7/8" LVL 1.88 9.17 73.3 73.3 E psi 1.90E+06 x = 4.59 (ft) inA4 245 M @ x = 1.13 (k-ft) A inA2 20.8 V @ x = -0.1 (k) Results M allow = 8.90 (k-ft) Loading Diagram: B13 M max = 1.17 (k-ft) 500 R1 = 0.61 (k) _ 200 V 400 1 R2 = 0.41 (k) 1so 100 300 Z v max = 44 (psi) 0 J 50 � 200 0 100 J a Deflect. = 0.039 (in) 0 0 = L 0 1 2 3 4 5 6 7 8 9 2858 Beam: B14 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 4 ft end (ft) start end (plf) distance(ft) _start 0 4 470 470 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 x = 2 (ft) in14 245 M @ x = 0.94 (k-ft) A inA2 20.8 V @ x = 0 (k) Results M allow = 8.90 (k-ft) Loading Diagram: B14 M max = 0.94 (k-ft) 1 R1 = 0.94 (k) a loo0 0.8 1 R2 = 0.94 (k) ° 0.6 v max = 68 (psi) n soo 0.4 m 0.2 J Deflect. = 0.006 (in) � 0 a 0 = L 0 0.5 1 1.5 2 2.5 3 3.5 4 8236 Beam: B15 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 8 ft start end (ft) start end (plf) distance(ft) 0 6 73.3 73.3 6 0.94 Member: 1 3/4" x 11 7/8" LVL 6 8 36.7 36.7 E psi 1.90E+06 x = 4 (ft) inA4 245 M @ x = 1.49 (k-ft) A inA2 20.8 V @ x = 0.23 (k) Results M allow = 8.90 (k-ft) Loading Diagram: B15 M max = 1.79 (k-ft) 1000 R1 = 0.52 (k) _ 200 V 150 800 1 R2 = 0.93 (k) 100 600 v max = 67 (psi) ° 50 � 200 ° 200 a Deflect. = 0.039 (in) 0 0 = L 0 1 2 3 4 5 6 7 8 2437 Project: E1396 Sheet No: 15 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B16 Span: 4 ft Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.31 (k-ft) R1 = 0.31 (k) R2 = 0.31 (k) v max = 22 (psi) Deflect. = 0.002 (in) = L 24974 Beam Span: 7.17 ft B17 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.90 (k-ft) R1 = 0.36 (k) R2 = 0.37 (k) v max = 27 (psi) Deflect. = 0.016 (in) = L 5321 Beam: Span: 4 ft B18 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 1.21 (k-ft) R1 = 1.21 (k) R2 = 1.21 (k) v max = 87 (psi) Deflect. = 0.008 (in) = L 6398 Uniform Loads start end (ft) 0 4 x = 2 (ft) M @ x = 0.31 (k-ft) V @ x = 0 (k) Loading Diagram: B16 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 155 155 1 w 400 0.8 N 300 2 0.6 0 zoo 0.4 0 100 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 4 Uniform Loads start end (ft) 0 3 3 7.17 x = 3.59 (ft) M @ x = 0.85 (k-ft) V @ x = -0.1 (k) Loading Diagram: B17 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 36.7 36.7 3 0.31 73.3 73.3 200 400 300 a 150 - c 100 200 50 100 a 0 0 0 1 2 3 4 5 6 7 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) 0 4 605 605 2 (ft) 1.21 (k-ft) 0 (k) Loading Diagram: B18 1 a 1500 0.8 1 1000 0.6 J 0.4 0 500 0.2 a 0 A 0 0 0.5 1 1.5 2 2.5 3 3.5 4 Project: E1396 Sheet No: 16 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: B19 Span: 13 ft Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 3.04 (k-ft) R1 = 0.67 (k) R2 = 1.42 (k) v max = 102 (psi) Deflect. = 0.197 (in) = L 793 Beam Span: 8 ft HD1 Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 in^4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 11.00 (k-ft) R1 = 4.39 (k) R2 = 5.72 (k) v max = 206 (psi) Deflect. = 0.127 (in) = L 758 Beam: Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.34 R1 = 1.66 R2 = 1.62 v max = 98 Deflect. = 0.012 = L 3024 HD2 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) 0 10.9 73.3 73.3 10.9 1.21 10.9 13 36.7 36.7 x = 6.5 (ft) M @ x = 2.79 (k-ft) V @ x = 0.19 (k) Loading Diagram: B19 200 lsoo 150 1000 :2 100 M 500 50 a 0 0 0 2 4 6 8 10 12 Uniform Loads start end (ft) 0 5.5 5.5 8 x = 4 (ft) M @ x = 10.6 (k-ft) V @ x = 0.89 (k) Loading Diagram: HD1 3000 a 2000 M 1000 0 0 1 2 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 1.33 (k-ft) V @ x = -0.1 (k) Loading Diagram: HD2 a 2000 1000 0 0 0.5 1 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 875 875 5.5 2.58 1085 1085 3000 2000 1000 0 0 a 3 4 5 6 7 8 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 985 985 1.33 0.33 1.5 2 2.5 3 400 300 A 200 m 100 a 0 Project: E1396 Sheet No: 17 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: HD3 Uniform Loads Span: 9.5 ft start end (ft) 0 9.5 Member: 5 1/8" x 7 1/2" 24F V4 GLB E psi 1.80E+06 x = 4.75 (ft) in14 180 M @ x = 6.32 (k-ft) A in12 38.4 V @ x = 0 (k) Results M allow = 9.60 (k-ft) Loading Diagram: HD3 M max = 6.32 (k-ft) R1 = 2.66 (k) .... lsoo a R2 = 2.66 (k) M l000 O Magnitude(plf) start end (plf) 560 560 Point Loads distance(ft) Magnitude(k) v max = 104 (psi) 500 Deflect. = 0.317 (in) 0 L 0 1 2 3 4 5 6 7 8 9 359 Beam Span: 5.5 ft Member: 6x8 DF#1 E psi 1.60E+06 inA4 175 A inA2 39.9 Results M allow = 5.42 M max = 2.01 R1 = 1.28 R2 = 1.38 v max = 52 Deflect. = 0.038 = L 1724 Beam: Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.32 R1 = 1.55 R2 = 1.65 v max = 97 Deflect. = 0.012 = L 3091 HD4 (k-ft) (k-ft) (k) (k) (psi) (in) HD5 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 5.5 x = 2.75 (ft) M @ x = 1.98 (k-ft) V@x= 0.16 (k) Loading Diagram: HD4 a 1000 v o 500 0 0 1 Uniform Loads start end (ft) 0 1.66 1.66 3 x = 1.5 (ft) M @ x = 1.3 (k-ft) V@x= 0.19 (k) Loading Diagram: HD5 a 2000 1000 0 0 0.5 1 1 0.8 1 0.6 0.4 0 0.2 Ja 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 410 410 3.42 0.41 500 400 s 300 c 200 0 100 a 0 2 3 4 5 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 905 905 1.66 0.37 985 985 1.5 2 2.5 3 400 300 A 200 M 100 a 0 Project: E1396 Sheet No: 18 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: HD6 Span: 8 ft Member: 5 1/8" x 7 1/2" 24F V4 GLB E psi 1.80E+06 x = in14 180 M @ x = Ain^2 38.4 V @ x = Results M allow = 9.60 (k-ft) Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) _ 0 8 875 875 4 (ft) 7 (k-ft) 0 (k) Loading Diagram: HD6 M max = 7.00 (k-ft) 1 R1 = 3.50 (k) a 2000 0.8 1 R2 = 3.50 (k) 0.6 v max = 137 0 1000 (psi) 0.4 0 0.2 a Deflect. = 0.249 (in) 0 0 A = L 0 1 2 3 4 5 6 7 8 385 Beam Span: 6.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.39 R1 = 0.24 R2 = 0.24 vmax = 14 Deflect. = 0.017 = L 4695 Beam: Span: 3.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.25 R1 = 1.43 R2 = 1.43 vmax = 84 Deflect. = 0.016 = L 2705 HD7 (k-ft) (k-ft) (k) (k) (psi) (in) HD8 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 6.5 x = 3.25 (ft) M @ x = 0.39 (k-ft) V @ x = 0 (k) Loading Diagram: HD7 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 73.3 73.3 200 1 a 150 0.8 s 0.6 c 0 100 0.4 o j 50 0.2 a 0 0 0 1 2 3 4 5 6 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) 0 3.5 815 815 1.75 (ft) 1.25 (k-ft) 0 (k) Loading Diagram: HD8 1 w 2000 0.8 1 1500 0.6 v 0 1000 0.4 0 500 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Project: E1396 Sheet No: 19 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 6.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.35 R1 = 0.83 R2 = 0.83 v max = 49 Deflect. = 0.058 = L 1350 Beam Span: 2.75 ft Member: 4x8 DF#2 E psi 1.60E+06 inA4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.26 R1 = 1.84 R2 = 1.84 v max = 108 Deflect. = 0.010 = L 3404 Beam: Span: 2.75 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 5.44 R1 = 4.77 R2 = 5.09 v max = 300 Deflect. = 0.036 = L 908 HD9 (k-ft) (k-ft) (k) (k) (psi) (in) HD10 (k-ft) (k-ft) (k) (k) (psi) (in) HD11 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 6.5 x = 3.25 (ft) M @ x = 1.35 (k-ft) V @ x = 0 (k) Loading Diagram: HD9 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 255 255 1 a 600 0.8 1 0.6 400 0 0.4 0 200 0.2 a 0 0 0 1 2 3 4 5 6 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) 0 2.75 13351335 1.38 (ft) 1.26 (k-ft) 0 (k) Loading Diagram: HD10 4000 1 3000 0.8 ' v 2000 0.6 Z f0 0.4 m 0 J 1000 -' � .2 a 0 0 0 0.5 1 1.5 2 2.5 Uniform Loads start end (ft) 0 1.13 1.13 2.75 x = 1.38 (ft) M @ x = 5.29 (k-ft) V @ x = 1.77 (k) Loading Diagram: HD11 4000 3000 2000 0 1000 0 0 0.5 Project: E1396 Sheet No: 20 Magnitude(plf) start end (plf) 890 890 1335 1335 Point Loads distance(ft) 1.13 1.46 Magnitude(k) 1.67 5.02 6000 4000 M 2000 S a 0 1.5 2 2.5 2/21 /2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 2.75 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.84 R1 = 1.22 R2 = 1.22 vmax = 72 Deflect. = 0.006 = L 5107 Beam Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.00 R1 = 1.34 R2 = 1.34 v max = 79 Deflect. = 0.009 = L 3933 Beam: Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.45 R1 = 1.94 R2 = 1.94 v max = 114 Deflect. = 0.013 = L 2714 HD12 (k-ft) (k-ft) (k) (k) (psi) (in) HD13 (k-ft) (k-ft) (k) (k) (psi) (in) HD14 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 2.75 x = 1.38 (ft) M @ x = 0.84 (k-ft) V @ x = 0 (k) Loading Diagram: HD12 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 890 890 1 a 2000 o.s 0.6 0 1000 0.4 o n 0.2 0 0 0 0.5 1 1.5 2 2.5 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) _start end (ft) start end (plf) distance(ft) 0 3 890 890 1.5 (ft) 1 (k-ft) 0 (k) Loading Diagram: HD13 1 a 2000 o.s 0.6 0 1000 0.4 o 0.2 a 0 A 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) 0 3 1290 1290 1.5 (ft) 1.45 (k-ft) 0 (k) Loading Diagram: HD14 1 a 3000 0.8 1 0.6 2000 0 4 0 1000 0.2 a 0 A 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 21 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.96 R1 = 1.28 R2 = 1.28 v max = 75 Deflect. = 0.009 = L 4118 Beam Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.50 R1 = 2.00 R2 = 2.00 v max = 118 Deflect. = 0.014 = L 2622 Beam: Span: 3 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.00 R1 = 1.34 R2 = 1.34 v max = 79 Deflect. = 0.009 = L 3933 HD15 (k-ft) (k-ft) (k) (k) (psi) (in) HD16 (k-ft) (k-ft) (k) (k) (psi) (in) HD17 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.96 (k-ft) V @ x = 0 (k) Loading Diagram: HD15 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 850 850 1 a 2000 0.8 1 0.6 0 1000 0.4 0 0.2 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) _start end (ft) start end (plf) distance(ft) 0 3 1335 1335 1.5 (ft) 1.5 (k-ft) 0 (k) Loading Diagram: HD16 4000 1 3000 0.8 ' v 2000 0.6 Z f0 0.4 m 0 J 1000 -' � .2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) 0 3 890 890 1.5 (ft) 1 (k-ft) 0 (k) Loading Diagram: HD17 1 a 2000 o.s 0.6 0 1000 0.4 0 0.2 Ja 0 A 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 22 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Span: 6.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.35 R1 = 0.83 R2 = 0.83 v max = 49 Deflect. = 0.058 = L 1350 Beam Span: 3.5 ft Member: 4x8 DF#2 E psi 1.60E+06 inA4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.25 R1 = 1.43 R2 = 1.43 vmax = 84 Deflect. = 0.016 = L 2705 Beam: Span: 6.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 0.39 R1 = 0.24 R2 = 0.24 vmax = 14 Deflect. = 0.017 = L 4695 HD18 (k-ft) (k-ft) (k) (k) (psi) (in) HD19 (k-ft) (k-ft) (k) (k) (psi) (in) HD20 (k-ft) (k-ft) (k) (k) (psi) (in) Uniform Loads start end (ft) 0 6.5 x = 3.25 (ft) M @ x = 1.35 (k-ft) V @ x = 0 (k) Loading Diagram: HD18 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 255 255 1 a 600 0.8 1 0.6 400 0 0.4 0 200 0.2 a 0 0 0 1 2 3 4 5 6 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) _start end (ft) start end (plf) distance(ft) 0 3.5 815 815 1.75 (ft) 1.25 (k-ft) 0 (k) Loading Diagram: HD19 1 w 2000 0.8 1 1500 0.6 0 1000 0.4 0 500 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 6.5 x = 3.25 (ft) M @ x = 0.39 (k-ft) V @ x = 0 (k) Loading Diagram: HD20 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 73.3 73.3 200 1 150 0.8 2 0.6 0 100 0.4 0 50 0.2 a 0 0 0 1 2 3 4 5 6 Project: E1396 Sheet No: 23 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: HD21 Span: 3.33 ft Member: (2) 2x6 HF#2 E psi 1.30E+06 inA4 41.6 A inA2 16.6 Results M allow = 1.40 (k-ft) M max = 0.24 (k-ft) R1 = 0.29 (k) R2 = 0.29 (k) v max = 26 (psi) Deflect. = 0.009 (in) = L 4454 Beam Span: 3.5 ft HD22 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.59 (k-ft) R1 = 0.67 (k) R2 = 0.67 (k) v max = 61 (psi) Deflect. = 0.024 (in) = L 1744 Uniform Loads start end (ft) 0 3.33 x = 1.67 (ft) M @ x = 0.24 (k-ft) V @ x = 0 (k) Loading Diagram: HD21 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 175 175 1 a 400 0.8 1 0.6 J 200 0.4 0 n 0.2 Ja 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.5 x = 1.75 (ft) M @ x = 0.59 (k-ft) V @ x = 0 (k) Loading Diagram: HD22 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 385 385 w 1 1000 a o.s 0.6 c 0 500 0.4 0 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Project: E1396 Sheet No: 24 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS "'°' C II RAL ENGIN LRIN0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Design Criteria: 2015 NDS Section 3.7 & Section 15.3 Assumptions: 2x: Posts are framed in stud walls w/ HF plates sheathing braces the posts in weak direction studs are nailed together per NDS 15.3.3 4x & 6x: Posts are checked in weak direction Design Values: HF#2 sill: Fc prp = 405 psi 2x4 HF#2: Fc pll = 1495 psi 2x4 HF stud: Fc pll = 840 psi 2x6 HF#2: Fc pll = 1430 psi 2x6 HF stud: Fc pll = 800 psi 4x4 DF#1: Fc pll = 1725 psi 4x4 DF#2: Fc pll = 1555 psi 4x6 DF#1: Fc pll = 1650 psi 4x6 DF#2: Fc pll = 1485 psi 6x6 DF#2: Fc pll = 700 psi Height 8 ft 9 ft loft (2) 2x4 HF #2 4.25 4.03 3.31 (3) 2x4 HF #2 6.38 6.04 4.96 (4) 2x4 HF #2 8.51 8.05 6.62 (5) 2x4 HF #2 10.6 10.1 8.27 (2) 2x4 HF stud 4.24 3.51 2.93 (3) 2x4 HF stud 6.36 5.26 4.39 (4) 2x4 HF stud 8.49 7.02 5.86 (5) 2x4 HF stud 10.6 8.77 7.32 (2) 2x6 HF #2 6.68 6.68 6.68 (3) 2x6 HF #2 10.0 10.0 10.0 (4) 2x6 HF #2 13.4 13.4 13.4 (5) 2x6 HF #2 16.7 16.7 16.7 (2) 2x6 HF stud 6.68 6.68 6.68 (3) 2x6 HF stud 10.0 10.0 10.0 (4) 2x6 HF stud 13.4 13.4 13.4 (5) 2x6 HF stud 16.7 16.7 16.7 4x4 DF#1 4.96 4.96 4.96 4x6 DF#1 7.80 7.80 7.80 4x4 DF#2 4.96 4.96 4.70 4x6 DF#2 7.80 7.80 7.36 6x6 DF#2 12.3 12.3 12.3 Project: E1396 Sheet No: 25 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUCfUHAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 1ST FLOOR FRAMING PLAN NTS Project: E1396 Sheet No: 26 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FB1 Span: 10 ft Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 inA4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 10.00 (k-ft) R1 = 4.00 (k) R2 = 4.00 (k) v max = 144 (psi) Deflect. = 0.184 (in) = L 652 Beam Span: 20.7 ft FB2 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) start end (plf) distance(ft) _ 0 10 800 800 x = 5 (ft) M @ x = 10 (k-ft) V @ x = 0 (k) Loading Diagram: F61 1 w 2000 0.8 1500 :20.6 v 0 1000 0.4 o 500 0.2 a 0 0 0 1 2 3 4 5 6 7 8 9 10 Uniform Loads start end (ft) 0 1.75 Member: 6 3/4" x 19 1/2" 24F V4 GLB 1.75 4.75 E psi 1.80E+06 x = 10.3 (ft) 4.75 7.25 1 inA4 4170 M @ x = 57.9 (k-ft) 7.25 20.7 A inA2 132 V @ x = -5.1 (k) 0 20.7� Results M allow = 85.60 (k-ft) Loading Diagram: F132 M max = 73.10 (k-ft) R1 = 13.98 (k) a z000 R2 = 6.12 (k) I v max = 159 (psi) - 1000 Deflect. = 0.613 (in) 0 = L 405 Cv=0.9357 Beam: FB3 Span: 3.13 ft Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.47 (k-ft) R1 = 0.55 (k) R2 = 0.35 (k) v max = 39 (psi) Deflect. = 0.002 (in) = L 24157 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 985 985 1.75 1.43 175 175 4.75 1.43 985 985 7.25 11 73.3 73.3 26 26 0 5 10 15 20 Uniform Loads start end (ft) 0 1.13 1.13 3.13 x = 1.56 (ft) M @ x = 0.41 (k-ft) V @ x = -0.2 (k) Loading Diagram: F133 600 a v 400 0 200 0 Magnitude(plf) _start end (plf) 225 225 110 110 Point Loads distance(ft) 1.13 15000 10000 5000 a 0 Magnitude(k) 0.42 0 0.5 1 1.5 2 2.5 3 500 400 $ 300 200 c 100 Ja 0 Project: E1396 Sheet No: 27 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FB4 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 7.33 ft start end (ft) start end (plf) distance(ft) 0 3.5 73.3 73.3 3.5 0.35 Member: 1 3/4" x 11 7/8" LVL 3.5 7.33 325 325 E psi 1.90E+06 x = 3.67 (ft) inA4 245 M @ x = 2.02 (k-ft) A inA2 20.8 V @ x = 0.04 (k) Results M allow = 8.90 (k-ft) Loading Diagram: F134 M max = 2.03 (k-ft) 400 R1 = 0.70 (k) a 800600 300 R2 = 1.15 (k) 0 400 200 0 v max = 83 (psi) 200 100 a Deflect. = 0.040 (in) 0 0 = L 0 1 2 3 4 5 6 7 2209 Beam: FB5 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 7.33 ft start end (ft) start end (plf) distance(ft) 0 7.33 160 160 Member: 4x6 DF#2 E psi 1.60E+06 x = 3.67 (ft) in14 48.5 M @ x = 1.07 (k-ft) A inA2 19.3 V @ x = 0 (k) Results M allow = 1.72 (k-ft) Loading Diagram: F135 M max = 1.07 (k-ft) 1 R1 = 0.59 (k) v 400 R2 = 0.59 (k) 0 200 o.s o v max = 46 (psi) D a Deflect. = 0.134 (in) o 0 L 0 1 2 3 4 5 6 7 655 Beam: FB7 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 20.5 ft start end (ft) end (plf) distance(ft) 0 20.5 _start 370 370 Member: 7" x 11 7/8" PSL E psi 2.00E+06 x = 10.3 (ft) inA4 975 M @ x = 19.4 (k-ft) A inA2 83.1 V @ x = 0 (k) Results IIII M allow = 39.80 (k-ft) Loading Diagram: F137 M max = 19.44 (k-ft) 1 a 1000 R1 = 3.79 (k) 0.8 1 0.6 = R2 = 3.79 (k) soo 0 0.4 0 v max = 68 (psi) 0.2 Deflect. = 0.756 (in) 0 0 L 0 5 10 15 20 326 BEAM DELETED AND NO LONGER USED (FB6 AND FB15 ALSO NOT USED) Project: E1396 Sheet No: 28 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FB7DEFL Span: 20.5 ft Member: 7" x 11 7/8" PSL E psi 2.00E+06 inA4 975 A inA2 83.1 Results M allow = 39.80 (k-ft) M max = 14.03 (k-ft) R1 = 2.74 (k) R2 = 2.74 (k) v max = 49 (psi) Deflect. = 0.545 (in) = L 451 Beam Span: 3 ft FB8 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.57 (k-ft) R1 = 0.66 (k) R2 = 0.40 (k) v max = 47 (psi) Deflect. = 0.002 (in) = L 21358 Beam: Span: 7.33 ft FB9 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 2.11 (k-ft) R1 = 0.73 (k) R2 = 1.17 (k) v max = 84 (psi) Deflect. = 0.041 (in) = L 2128 Uniform Loads start end (ft) 0 20.5 x = 10.3 (ft) M @ x = 14 (k-ft) V @ x = 0 (k) Loading Diagram: F67 DER Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) _ 267 267 800 1 600 0.8 400 0.6 v f0 0.4 c0 o n zoo 0.2 a 0 0 0 5 10 15 20 Uniform Loads start end (ft) 0 1.07 1.07 3 x = 1.5 (ft) M @ x = 0.48 (k-ft) V @ x = -0.2 (k) Loading Diagram: F68 600 a v 400 0 200 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 225 225 1.07 0.61 105 105 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.5 3.5 7.33 x = 3.67 (ft) M @ x = 2.11 (k-ft) V @ x = 0.02 (k) Loading Diagram: F139 Magnitude(plf) Point Loads start end (plf) distance(ft) 73.3 73.3 3.5 325 325 800 a 600 c 400 200 0 0 1 2 3 4 5 800 600 400 200 � a 0 Magnitude(k) 6 7 500 400 1 300 200 c 100 0 Project: E1396 Sheet No: 29 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FB10 Uniform Loads Span: 7.33 ft start end (ft) 0 5.5 Member: (2) 1 3/4" x 11 7/8" PSL 5.5 7.33 E psi 2.00E+06 x = 3.67 (ft) inA4 490 M @ x = 4.71 (k-ft) A inA2 41.6 V @ x = 1.07 (k) Results M allow = 19.90 (k-ft) _ Loading Diagram: FB10 M max = 6.46 (k-ft) R1 = 1.50 (k) .... 3000 a R2 = 4.56 (k) M 2000 v max = 164 (psi) 0 1000 Deflect. = 0.051 (in) 0 = L 1708 Beam Span: 3 ft FB11 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 0.40 (k-ft) R1 = 0.52 (k) R2 = 0.33 (k) v max = 38 (psi) Deflect. = 0.001 (in) = L 28840 Beam: Span: 8.07 ft FB12 Member: 1 3/4" x 11 7/8" LVL E psi 1.90E+06 inA4 245 A inA2 20.8 Results M allow = 8.90 (k-ft) M max = 2.23 (k-ft) R1 = 1.20 (k) R2 = 0.68 (k) v max = 87 (psi) Deflect. = 0.052 (in) = L 1851 Magnitude(plf) Point Loads start end (plf) distance(ft) 120 120 5.5 1120 1120 Magnitude(k) 3.35 0 1 2 3 4 5 6 7 Uniform Loads start end (ft) 0 1 1 3 x = 1.5 (ft) M @ x = 0.35 (k-ft) V @ x = -0.1 (k) Loading Diagram: F611 w 600 a 400 200 0 Magnitude(plf) Point Loads start end (plf) distance(ft) 240 240 1 125 125 4000 3000 A 2000 m 1000 a 0 Magnitude(k) 0.36 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.83 3.83 8.07 x = 4.04 (ft) M @ x = 2.15 (k-ft) V @ x = -0.4 (k) Loading Diagram: FB12 400 300 A 200 m 100 � a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 325 325 3.83 0.33 73.3 73.3 400 w 800 300 600 - c 400 200 c 200 100 Ja 0 0 0 1 2 3 4 5 6 7 8 Project: E1396 Sheet No: 30 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FB13 Span: 7 ft Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 inA4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 4.96 (k-ft) R1 = 3.46 (k) R2 = 3.46 (k) v max = 125 (psi) Deflect. = 0.047 (in) = L 1771 Beam Span: 12.5 ft FB14 Member: 5 1/4" x 11 7/8" PSL E psi 2.00E+06 in^4 735 A inA2 62.3 Results M allow = 29.90 (k-ft) M max = 29.88 (k-ft) R1 = 11.77 (k) R2 = 6.91 (k) v max = 283 (psi) Deflect. = 0.562 (in) = L 267 Beam: Span: 12.5 ft FB14 DEFL Member: 5 1/4" x 11 7/8" PSL E psi 2.00E+06 inA4 735 A inA2 62.3 Results M allow = 29.90 (k-ft) M max = 21.18 (k-ft) R1 = 8.39 (k) R2 = 4.81 (k) v max = 202 (psi) Deflect. = 0.396 (in) = L 379 Uniform Loads start end (ft) 0 2 2 5.5 x = 3.5 (ft) 5.5 7 M @ x = 4.84 (k-ft) V @ x = -0.2 (k) Loading Diagram: FB13 a 2000 1000 0 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 985 985 2 1.43 175 175 5.5 1.43 985 985 0 1 2 3 4 5 6 7 Uniform Loads start end (ft) 0 2.5 2.5 12.5 x = 6.25 (ft) 0 12.5 M @ x = 27.6 (k-ft) V @ x = -1.9 (k) Loading Diagram: FB14 w 2000 1500 0 1000 500 0 0 2 4 Uniform Loads start end (ft) 0 2.5 2.5 12.5 x = 6.25 (ft) 0 12.5 M @ x = 19.4 (k-ft) V @ x = -1.4 (k) Loading Diagram: FB14 DER _^ 1500 a 1000 0 500 0 0 2 4 2000 1500 ' 1000 M 500 a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 73.3 73.3 2.5 10.5 785 785 14 14 15000 10000 5000 0 a 0 6 8 10 12 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 53.3 53.3 2.5 7.61 545 545 0 0 6 8 10 12 8000 6000 4000 m 2000 a 0 Project: E1396 Sheet No: 31 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Rooflet Rafters Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 4 ft start end (ft) start end (plf) distance(ft) 0 4 80 80 _ Member: 2x6 HF#2 @ 24" O.C. E psi 1.30E+06 x = 2 (ft) inA4 20.8 M @ x = 0.16 (k-ft) A inA2 8.3 V @ x = 0 (k) Results M allow = 0.70 (k-ft) Loading Diagram: Rooflet Rafters M max = 0.16 (k-ft) 1 R1 = 0.16 (k) a 200 0.8 R2 = 0.16 (k) v max = 0 100 29 (psi) 0 50 0.4 c 0.2 a Deflect. = 0.017 (in) 0 A 0 = L 0 0.5 1 1.5 2 2.5 3 3.5 4 2811 Beam: Deck Joists Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 7.5 ft end (ft) start end (plf) distance(ft) _start 0 7.5 93.3 93.3 Member: 2x8 DF#2 @ 16" O.C. E psi 1.60E+06 x = 3.75 (ft) in14 47.6 M @ x = 0.66 (k-ft) A in12 10.9 V @ x = 0 (k) Results L I I II II M allow = 1.18 (k-ft) Loading Diagram: Deck Joists M max = 0.66 (k-ft) 1 R1 = 0.35 (k) a zoo 0.8 1 R2 = 0.35 (k) 0.6 ° 0.4 v max = 48 (psi) n 100 0 2 J � a Deflect. = 0.087 (in) 0 0 L 0 1 2 3 4 5 6 7 1030 Tapered Deck Joists @ 1/8" per V to min 7 1/4" Beam: Span: 3 ft FHD1 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.13 (k-ft) R1 = 0.18 (k) R2 = 0.18 (k) v max = 16 (psi) Deflect. = 0.004 (in) = L 8883 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.13 (k-ft) V @ x = 0 (k) Loading Diagram: FHD1 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 120 120 1 a 300 0.8 1 200 0.6 0 0.4 0 100 0.2 Ja 0 1 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 32 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNG6 ILMIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD2 Span: 3.5 ft Member: (2) 2x6 HF#2 E psi 1.30E+06 inA4 41.6 A inA2 16.6 Results M allow = 1.40 (k-ft) M max = 0.24 (k-ft) R1 = 0.28 (k) R2 = 0.28 (k) v max = 25 (psi) Deflect. = 0.010 (in) = L 4196 Add 40o1f For Rooflet Beam Span: 3 ft FHD3 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.76 (k-ft) R1 = 1.01 (k) R2 = 1.01 (k) v max = 91 (psi) Deflect. = 0.023 (in) = L 1579 Beam: Span: 3.5 ft FHD4 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.11 (k-ft) R1 = 0.13 (k) R2 = 0.13 (k) v max = 12 (psi) Deflect. = 0.005 (in) = L 9158 Uniform Loads start end (ft) 0 3.5 x = 1.75 (ft) M @ x = 0.24 (k-ft) V @ x = 0 (k) Loading Diagram: FHD2 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 160 160 1 w 400 0.8 v 300 0.6 c 200 0.4 c 100 0.2 Ja 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 3 x = 1.5 (ft) M @ x = 0.76 (k-ft) V @ x = 0 (k) Loading Diagram: FHD3 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 675 675 2000 1 1500 0.8 ' 1000 0.6 f0 0.4 m 0 0 D s00 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.5 x = 1.75 (ft) M @ x = 0.11 (k-ft) V @ x = 0 (k) Loading Diagram: FHD4 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 73.3 73.3 200 1 150 0.8 a 0.6 0 100 0.4 0 50 0.2 Ja 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Project: E1396 Sheet No: 33 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD5 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 8 ft start end (ft) start end (plf) distance(ft) 0 8 120 120 _ Member: 4x8 DF#2 E psi 1.60E+06 x = 4 (ft) in14 111 M @ x = 0.96 (k-ft) A inA2 25.4 V @ x = 0 (k) Results M allow = 2.99 (k-ft) Loading Diagram: FHDS M max = 0.96 (k-ft) 1 R1 = 0.48 (k) a 300 0.8 R2 = 0.48 (k) 200 0.6 v max = 28 (psi) 0 100 0.4 0 0.2 Deflect. = 0.062 (in) 0 a 0 = L 0 1 2 3 4 5 6 7 8 1538 Beam: FHD6 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 3.5 ft end (ft) start end (plf) distance(ft) _start 0 3.5 1180 1180 Member: 4x8 DF#2 E psi 1.60E+06 x = 1.75 (ft) inA4 111 M @ x = 1.81 (k-ft) A inA2 25.4 V @ x = 0 (k) Results M allow = 2.99 (k-ft) Loading Diagram: FHD6 M max = 1.81 (k-ft) 1 R1 = 2.07 (k) a 3000 0.8 1 R2 = 2.07 (k) z000 0.6 v max = 122 (psi) 0 1000 0.4 0 0.a Deflect. = 0.022 (in) 0 0 = L 0 0.5 1 1.5 2 2.5 3 3.5 1868 Beam: FHD7 Total Load Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 20.5 ft start end (ft) start end (plf) distance(ft) 0 1.25 13651365 1.25 4.66 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 980 980 3.25 3.08 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 970 970 15.3 9.15 1 inA4 3281 M @ x = 80.7 (k-ft) 15.3 18.4 120 120 18.4 1.94 A in12 122 V @ x = 1.33 (k) 18.4 20.51 1410 1410 Results M allow = 72.90 (k-ft) Loading Diagram: FHD7 Total Load M max = 81.63 (k-ft) 4000 10000 R1 = 19.52 (k) 2= 3000 8000 1 R2 = 17.99 (k) � z000 6000 Z v max = 240 (psi) 0 � 1000 2000 0 000 a Deflect. = 1.081 (in) 0 0 = L 0 5 10 15 20 228 Total Load Calc; Not for Design Project: E1396 Sheet No: 34 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD7 DL Uniform Loads Span: 20.5 ft start end (ft) 0 1.25 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 1 in14 3281 M @ x = 32.8 (k-ft) 15.3 18.4 A inA2 122 V @ x = 0.49 (k) 18.4 20.5 Results M allow = 61.41 (k-ft) Loading Diagram: FHD7 DL M max = 33.12 (k-ft) R1 = 7.82 (k) _ 1500 a l000 R2 = 7.17 (k) v max = 96 (psi) soo Deflect. = 0.438 (in) 0 = L 561 DL=.9 Cv=.936 Beam Span: 20.5 ft FHD7 SL Magnitude(plf) Point Loads Magnitude(k) end (plf) distance(ft) _start 535 535 1.25 1.75 405 405 3.25 1.23 410 410 15.3 3.47 90 90 18.4 0.69 550 550 0 5 10 15 20 Uniform Loads start end (ft) 0 1.25 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 1 inA4 3281 M @ x = 21.3 (k-ft) 15.3 18.4 A inA2 122 V @ x = 0.79 (k) 18.4 20.5� Results M allow = 68.23 (k-ft) Loading Diagram: FHD7 SL M max = 24.12 (k-ft) R1 = R2 = 6.46 5.65 (k) (k) w 1000 a v max = 79 Deflect. = 0.300 = L 821 Cv=.936 Beam: Span: 20.5 ft o soo (psi) (in) 0 FHD7 LL 4000 3000 A 2000 m 1000 a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 385 385 1.25 2.91 165 165 3.25 1.32 90 90 15.3 4.51 0 0 18.4 0.61 410 410 - 0 5 10 15 20 Uniform Loads start end (ft) 0 1.25 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 1 inA4 3281 M @ x = 26.8 (k-ft) 15.3 18.4 A inA2 122 V @ x = 0.05 (k) 18.4 20.5 Results M allow = 68.23 (k-ft) Loading Diagram: FHD7 LL M max = 26.83 (k-ft) R1 = 5.29 (k) a l000 R2 = 5.20 (k) v max = 65 (psi) n soo Deflect. = 0.347 (in) 0 - - = L o 5 710 5000 4000 1 3000 c 2000 c 1000 a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 450 450 1.25 0 415 415 3.25 0.53 475 475 15.3 1.17 30 30 18.4 0.64 455 455 10 15 20 1500 1000 M 500 �° a 0 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD7 D+L Uniform Loads Span: 20.5 ft start end (ft) 0 1.25 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 1 in14 3281 M @ x = 59.7 (k-ft) 15.3 18.4 A inA2 122 V @ x = 0.54 (k) 18.4 20.5 Results M allow = 68.23 (k-ft) Loading Diagram: FHD7 D+L M max = 59.82 (k-ft) 3000 R1 = 13.11 (k) a z000 R2 = 12.37 (k) v max = 161 (psi) l000 Deflect. = 0.785 (in) 0 = L 0 5 313 Cv=.936 Cd=1.0 Beam Span: 20.5 ft FHD7 D+S Uniform Loads start end (ft) 0 1.25 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 1 inA4 3281 M @ x = 45.8 (k-ft) 15.3 18.4 A inA2 122 V @ x = 0.91 (k) 18.4 20.5 Results I M allow = 78.47 (k-ft) Loading Diagram: FHD7 D+S M max = 46.62 (k-ft) R1 = 11.45 (k) a 2000 R2 = 10.85 (k) v max = 141 (psi) l000 Deflect. = 0.618 (in) 0 = L 398 Cv=.936 Cd=1.15 Magnitude(plf) start end (plf) 985 985 820 820 885 885 120 120 1005 1005 10 Magnitude(plf) start end (plf) 920 920 570 570 500 500 90 90 960 960 Point Loads distance(ft) 1.25 3.25 15.3 18.4 15 Point Loads distance(ft) 1.25 3.25 15.3 18.4 Magnitude(k) 1.75 1.76 4.64 1.33 20 5000 4000 1 3000 2000 c 1000 Ja 0 Magnitude(k) 2.91 1.85 5.68 1.25 0 5 10 15 20 6000 4000 M 2000 g a 0 Beam: FHD7 D+.75(S+L) Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 20.5 ft start end (ft) start end (plf) distance(ft) 0 1.25 1161 1161 1.25 3.93 Member: 6 3/4" x 18" 24F V4 GLB 1.25 3.25 840 840 3.25 2.62 E psi 1.80E+06 x = 10.3 (ft) 3.25 15.3 834 834 15.3 7.73 1 in14 3281 M @ x = 68.9 (k-ft) 15.3 18.4 113 113 18.4 1.63 A in12 122 V @ x = 1.12 (k) 18.4 20.5 1199 1199 Results M allow = 78.47 (k-ft) Loading Diagram: FHD7 D+.75(S+L) M max = 69.67 (k-ft) 10000 R1 = 16.63 (k) a 3000 s000 R2 = 15.31 (k) 2000 6000 v max = 204 (psi) ° 1000 4000 02000 a Deflect. = 0.923 (in) 0 0 = L o 5 10 15 20 267 Cv=.936 Cd=1.15 Project: E1396 Sheet No: 36 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD8 Total Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 20.6 ft start end (ft) start end (plf) distance(ft) 0 3 14551455 3 6.69 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 1010 1010 15.3 8.69 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 120 120 18.12 1 in14 3281 M @ x = 86.2 (k-ft) 18.1 20.6I 1455 1455 A inA2 122 V @ x = 1.02 (k) Results M allow = 72.90 (k-ft) Loading Diagram: FHD8 Total M max = 86.76 (k-ft) 10000 _ 4000 R1 = 19.46 (k) a 3000 8000 1 R2 = 18.64 (k) 2000 6000 Z v max = 239 (psi) 0 1000 4000 0 2000 a Deflect. = 1.171 (in) 0 0 = L o s 10 15 20 211 Total Load Calc; Not for Design Beam: FHD8 DL Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 20.6 ft end (ft) start end (plf) distance(ft) _start 0 3 560 560 3 2.58 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 420 420 15.3 3.28 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 90 90 18.1 0.71 1 in14 3281 M @ x = 34.6 (k-ft) 18.1 20.6 560 560 A in12 122 V @ x = 0.38 (k) Results M allow = 61.41 (k-ft) - Loading Diagram: FHD8 DL - M max = 34.74 (k-ft) 4000 R1 = 7.71 (k) lsoo a 3000 R2 = 7.35 (k) i 1000 2000 v max = 95 (psi) soo loon a Deflect. = 0.468 (in) 0 0 = L o s 10 15 20 529 Cv=.936 Dead load Factor = .9 Beam: FHD8 LL Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 20.6 ft start end (ft) start end (plf) distance(ft) 0 3 485 485 3 0.57 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 505 505 15.3 1.25 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 30 30 18.1 0.68 1 in14 3281 M @ x = 29.2 (k-ft) 18.1 20.6 485 485 A in12 122 V @ x = 0.07 (k) Results M allow = 68.23 (k-ft) Loading Diagram: FHD8 LL M max = 29.17 (k-ft) 1500 1500 R1 = 5.79 (k) a 1000 loon R2 = 5.66 (k) v max = 71 (psi) n soo soo S Deflect. = 0.382 (in) n 0 a 0 = L o s 10 15 20 648 Cv=.936 Project: E1396 Sheet No: 37 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( Ndf.,\GIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD8 SL Uniform Loads Span: 20.6 ft start end (ft) 0 3 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 1 in14 3281 M @ x = 22.5 (k-ft) 18.1 20.6 A inA2 122 V @ x = 0.57 (k) Results M allow = 78.47 (k-ft) Loading Diagram: FHD8 SL M max = 24.31 (k-ft) R1 = 5.97 (k) w loon a R2 = 5.64 (k) v max = 73 (psi) soo Deflect. = 0.321 (in) 0 = L 770 Cv=.936, Cd=1.15 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 410 410 3 3.54 85 85 15.3 4.15 0 0 18.1 0.62 410 410 o s 10 15 20 Beam: FHD8 D+.75(S+L) Uniform Loads Magnitude(plf) Span: 20.6 ft end (ft) start end (plf) _start 0 3 1230 1230 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 865 865 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 113 113 1 inA4 3281 M @ x = 73.4 (k-ft) 18.1 20.6 1235 1235 A in12 122 V @ x = 0.86 (k) Results M allow = 78.47 (k-ft) Loading Diagram: FHD8 D+.75(S+L) M max = 73.85 (k-ft) R1 = 16.53 (k) a 3000 R2 = 15.84 (k) 2000 v max = 203 Deflect. = 0.997 = L 248 Cv=.936 Cd=1.15 Beam: Span: 20.6 ft (psi) 0 1000 (in) 0 FHD8 D+L Point Loads distance(ft) 3 15.3 18.1 5000 4000 1 3000 2000 c 1000 Ja 0 Magnitude(k) 5.66 7.33 1.69 o s 10 15 20 Uniform Loads start end (ft) � 3 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 1 inA4 3281 M @ x = 63.7 (k-ft) 18.1 20.6 A inA2 122 V @ x = 0.45 (k) Results M allow = 68.23 (k-ft) Loading Diagram: FHD8 D+L M max = 63.83 (k-ft) 3000 R1 = 13.49 (k) w z000 R2 = 13.00 (k) v max = 166 (psi) - 1000 Deflect. = 0.850 (in) 0 = L o s 291 8000 6000 A 4000 m 2000 a 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 10451045 3 3.15 925 925 15.3 4.53 120 120 18.1 1.39 1045 1045 10 1s 20 5000 4000 1 3000 v 2000 c 1000 a 0 Cv=.936 Project: E1396 Sheet No: 38 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD8 D+S Uniform Loads Span: 20.6 ft start end (ft) 0 3 Member: 6 3/4" x 18" 24F V4 GLB 3 15.3 E psi 1.80E+06 x = 10.3 (ft) 15.3 18.1 1 in14 3281 M @ x = 57.1 (k-ft) 18.1 20.6 A inA2 122 V @ x = 0.95 (k) Results M allow = 78.47 (k-ft) Loading Diagram: FHD8 D+S M max = 57.98 (k-ft) R1 = 13.67 (k) V z000 R2 = 12.99 (k) 0 v max = 168 (psi) - 1000 Deflect. = 0.790 (in) 0 = L 313 Cv=.936 Cd=1.15 Beam Span: 4.5 ft Member: 4x8 DF#2 E psi 1.60E+06 inA4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.63 R1 = 1.45 R2 = 1.45 v max = 86 Deflect. = 0.034 = L 1608 Beam: Span: 3.5 ft Member: 4x8 DF#2 E psi 1.60E+06 in^4 111 A inA2 25.4 Results M allow = 2.99 M max = 1.19 R1 = 1.37 R2 = 1.37 vmax = 81 Deflect. = 0.015 = L 2826 FHD9 (k-ft) (k-ft) (k) (k) (psi) (in) FHD10 (k-ft) (k-ft) (k) (k) (psi) (in) Magnitude(plf) Point Loads Magnitude(k) end (plf) distance(ft) _start 970 970 3 6.12 505 505 15.3 7.43 90 90 18.1 1.33 970 970 0 5 10 15 20 Uniform Loads start end (ft) 0 4.5 x = 2.25 (ft) M @ x = 1.63 (k-ft) V @ x = 0 (k) Loading Diagram: FHD9 8000 6000 A 4000 m 2000 0 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 645 645 1 a 1500 0.8 1 0.6 1000 0.4 0 500 0.2 a 0 A 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 Uniform Loads Magnitude(plf) Point Loads Magnitude(k) start end (ft) _start end (plf) distance(ft) 0 3.5 780 780 1.75 (ft) 1.19 (k-ft) 0 (k) Loading Diagram: FHD10 1 w z000 0 8 1500 � 0.6 c 1000 0.4 c 500 0.2 Ja 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Project: E1396 Sheet No: 39 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD11 Span: 3.17 ft Member: (2) 2x6 HF#2 E psi 1.30E+06 inA4 41.6 A inA2 16.6 Results M allow = 1.40 (k-ft) M max = 0.43 (k-ft) R1 = 0.55 (k) R2 = 0.55 (k) v max = 49 (psi) Deflect. = 0.015 (in) = L 2619 Beam Span: 3.5 ft FHD12 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.15 (k-ft) R1 = 0.18 (k) R2 = 0.18 (k) v max = 16 (psi) Deflect. = 0.006 (in) = L 6713 Beam: Span: 2.83 ft FHD13 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.35 (k-ft) R1 = 0.49 (k) R2 = 0.49 (k) v max = 44 (psi) Deflect. = 0.009 (in) = L 3681 Uniform Loads start end (ft) 0 3.17 x = 1.59 (ft) M @ x = 0.43 (k-ft) V @ x = 0 (k) Loading Diagram: FHD11 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) _ 345 345 1000 1 a 0.8 1 500 0.6 v 0 0.4 c0 0 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.5 x = 1.75 (ft) M @ x = 0.15 (k-ft) V @ x = 0 (k) Loading Diagram: FHD12 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 100 100 300 1 200 0.8 s a 0.6 0 100 0 4 0 n 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 2.83 x = 1.42 (ft) M @ x = 0.35 (k-ft) V @ x = 0 (k) Loading Diagram: FHD13 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 345 345 1000 1 a 0.8 1 500 0.6 v 0 0.4 c0 0 0.2 a 0 0 0 0.5 1 1.5 2 2.5 Project: E1396 Sheet No: 40 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD14 Span: 3.33 ft Member: (2) 2x6 HF#2 E psi 1.30E+06 inA4 41.6 A inA2 16.6 Results M allow = 1.40 (k-ft) M max = 0.40 (k-ft) R1 = 0.48 (k) R2 = 0.48 (k) v max = 44 (psi) Deflect. = 0.015 (in) = L 2688 Beam Span: 3.17 ft FHD15 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.43 (k-ft) R1 = 0.55 (k) R2 = 0.55 (k) v max = 49 (psi) Deflect. = 0.015 (in) = L 2619 Beam: Span: 3.17 ft FHD16 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.61 (k-ft) R1 = 0.77 (k) R2 = 0.77 (k) v max = 69 (psi) Deflect. = 0.020 (in) = L 1863 Uniform Loads start end (ft) 0 3.33 x = 1.67 (ft) M @ x = 0.4 (k-ft) V @ x = 0 (k) Loading Diagram: FHD14 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) _ 290 290 800 1 0.8 1 a 600 0.6 0 400 0.4 o 200 0.2 Ja 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.17 x = 1.59 (ft) M @ x = 0.43 (k-ft) V @ x = 0 (k) Loading Diagram: FHD15 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 345 345 1000 1 a 0.8 500 0.6 0 0.4 m 0 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.17 x = 1.59 (ft) M @ x = 0.61 (k-ft) V @ x = 0 (k) Loading Diagram: FHD16 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 485 485 1 0.8 1 a1000 06" 0 500 0 4 0 n 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 41 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNGIS111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: FHD17 Span: 3.33 ft Member: (2) 2x6 HF#2 E psi 1.30E+06 inA4 41.6 A inA2 16.6 Results M allow = 1.40 (k-ft) M max = 0.94 (k-ft) R1 = 1.12 (k) R2 = 1.12 (k) v max = 101 (psi) Deflect. = 0.035 (in) = L 1155 Beam Span: 3.5 ft FHD18 Member: (2) 2x6 HF#2 E psi 1.30E+06 in^4 41.6 A in12 16.6 Results M allow = 1.40 (k-ft) M max = 0.77 (k-ft) R1 = 0.88 (k) R2 = 0.88 (k) v max = 80 (psi) Deflect. = 0.032 (in) = L 1329 Beam: Span: 3.17 ft FHD19 Member: 5 1/4" x 11 7/8" PSL E psi 2.00E+06 inA4 735 A inA2 62.3 Results M allow = 29.90 (k-ft) M max = 7.70 (k-ft) R1 = 8.41 (k) R2 = 3.51 (k) v max = 202 (psi) Deflect. = 0.007 (in) = L 5239 Uniform Loads start end (ft) 0 3.33 x = 1.67 (ft) M @ x = 0.94 (k-ft) V @ x = 0 (k) Loading Diagram: FHD17 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) _ 675 675 2000 1 1500 0.8 1000 0.6 v f0 0.4 c00 0 n 500 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 Uniform Loads start end (ft) 0 3.5 x = 1.75 (ft) M @ x = 0.77 (k-ft) V @ x = 0 (k) Loading Diagram: FHD18 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 505 505 1500 1 0.8 a 1000 s 0.6 500 0.4 0 n 0.2 a 0 0 0 0.5 1 1.5 2 2.5 3 3.5 Uniform Loads start end (ft) 0 3.17 x = 1.59 (ft) M @ x = 5.47 (k-ft) V @ x = -3.4 (k) Loading Diagram: FHD19 Magnitude(plf) Point Loads Magnitude(k) start end (plf) distance(ft) 73.3 73.3 0.92 11.7 15000 200 150 10000 m 100 m 5000 50 a 0 0 0 0.5 1 1.5 2 2.5 3 Project: E1396 Sheet No: 42 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS "'°' C II RAL ENGIN LRIN0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Design Criteria: 2015 NDS Section 3.7 & Section 15.3 Assumptions: 2x: Posts are framed in stud walls w/ HF plates sheathing braces the posts in weak direction studs are nailed together per NDS 15.3.3 4x & 6x: Posts are checked in weak direction Design Values: HF#2 sill: Fc prp = 405 psi 2x4 HF#2: Fc pll = 1495 psi 2x4 HF stud: Fc pll = 840 psi 2x6 HF#2: Fc pll = 1430 psi 2x6 HF stud: Fc pll = 800 psi 4x4 DF#1: Fc pll = 1725 psi 4x4 DF#2: Fc pll = 1555 psi 4x6 DF#1: Fc pll = 1650 psi 4x6 DF#2: Fc pll = 1485 psi 6x6 DF#2: Fc pll = 700 psi Height 8 ft 9 ft loft (2) 2x4 HF #2 4.25 4.03 3.31 (3) 2x4 HF #2 6.38 6.04 4.96 (4) 2x4 HF #2 8.51 8.05 6.62 (5) 2x4 HF #2 10.6 10.1 8.27 (2) 2x4 HF stud 4.24 3.51 2.93 (3) 2x4 HF stud 6.36 5.26 4.39 (4) 2x4 HF stud 8.49 7.02 5.86 (5) 2x4 HF stud 10.6 8.77 7.32 (2) 2x6 HF #2 6.68 6.68 6.68 (3) 2x6 HF #2 10.0 10.0 10.0 (4) 2x6 HF #2 13.4 13.4 13.4 (5) 2x6 HF #2 16.7 16.7 16.7 (2) 2x6 HF stud 6.68 6.68 6.68 (3) 2x6 HF stud 10.0 10.0 10.0 (4) 2x6 HF stud 13.4 13.4 13.4 (5) 2x6 HF stud 16.7 16.7 16.7 4x4 DF#1 4.96 4.96 4.96 4x6 DF#1 7.80 7.80 7.80 4x4 DF#2 4.96 4.96 4.70 4x6 DF#2 7.80 7.80 7.36 6x6 DF#2 12.3 12.3 12.3 Project: E1396 Sheet No: 43 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( Ndf.,\G6111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 NDS 2015 WOOD COLUMN DESIGN: NDS 3.7.1 (Co CALCULATION Column: C2 Member: 6x8 DF#2 Wood Type: S S = Sawn Lumber, E = PSL/LVL Engineered Lumber, G = Glulam Post, P = Pole (Sawn) Length (L) : 8.0 ft Length of column Ke = 1.00 Effective length factor, pin -pin K = 1.0 Width (B) : 7.5 in Supported column dimension Depth (D) : 5.5 in Critical column dimension to be checked in calculations Kf, built up C: 1.0 Built up column factor, Kf, only applies for buckling with respect to Width (B For built up columns not supported by a wall, see NDS 15.3.2.4 Kf = 0.60 nailed built up column, Kf = 0.75 bolted built up column le =F-96-1 in Ke x L, Effective length of column in inches le / D =F1_77 -51 < 50 OK Slenderness limit for wood columns shall not exceed 50 (Can be 75 for construction) NDS 3.7.1.4 Fc pll = 600 psi E = 1.30 x 106 psi Emin = 0.47 x 10' psi Fc prp (sill) = 405 psi Ci (for E=0.95) = 1.00 Ci (for Fc=0.80) = 1.00 Cd = 1.00 Cm (for E) = 1.00 Cm (for Fc) = 1.00 Cm (for Fcprp) = 1.00 NDS Table F1: COVe values Sawn Lumber: 0.25 E(1-1.645*COVe)(1.03)/1.66 PSL/LVL: 0.11 Glulam: 0.10 COVE = 0.25 Incising factor for E (0.95 for PT) Incising factor for Fc pll (0.80 for PT) Load duration factor Wet service factor for E (See NDS tables 4A-4F) 1.00 for dry Wet service factor for Fc (See NDS tables 4A-4F) 1.00 for dry Wet service factor for Fcprp (See NDS tables 4A-4F) 1.00 for dry E'min = 0.47 x 101 psi Fc* = 600 psi FcE = 1281 psi Cp = FO.88 F'c pll = 527 psi F'c prp = 1405 1 psi Pallow =F1_6_._71 kips Notes: Emin x Ci x Cm Adjusted Modulus of Elasticity Fc pll x Ci x Cd x Cm Adjusted compressive stress 0.822 E'min / (le / D)2 NDS equation 3.7-1 NDS 3.7.1: c values Sawn Lumber: 0.80 Cp x Fc* Adjusted parallel to grain stress PSL/LVL: 0.90 Fc prp x Cm (Ci for Pc prp = 1.00) Glulam: 0.90 Rounds/Poles: 0.85 Sill plate crushing controls c = 0.80 L D a Project: E1396 Sheet No: 44 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUMTRAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 DECK 2x WOOD LEDGER CONNECTION DESIGN Total floor load (psf) = 70 psf x NDS values are derived from Table 11 NDS 1012 Tributary length to ledger (ft) = 4 ft = National Design Specification for Wood Construction Ledger connection load = 280 Ib/ft SIDS values from Simpson Technical Literature Min spacing SIDS = 3", 3/4" edge min, 4" end dist. (See Simpson C-F-14) FIG. A: Common Fastener Capacities Maximum fastener spacing (in) G = 0.43, 1 1/2" side member over 1/2" sheathing into Beam Fastener NDS (Ibs) x p/10D adjust. x Cd = Allowable (Ibs) #8 x 3-1/2" screw 80 x 0.915 x 1.00 = 73 Ibs 3.14 in #10 x 3-1/2" screw 101 x 0.789 x 1.00 = 80 Ibs 3.42 in 1/4" SDS x 5" 245 x 1.000 x 1.00 = 245 Ibs 10.50 in #12 x 3-1/2" screw 128 x 0.694 x 1.00 = 89 Ibs 3.81 in FIG. B: Common Fastener Capacities *Number of fasteners per stud G = 0.43, 1 1/2" side member over 1/2" sheathing into 2x wall studs Fastener NDS (Ibs) x p/10D adjust. x Cd = Allowable (Ibs) 12" O.C. 16" o.c. 24" o.c. #8 x 5" screw 80 x 1.000 x 1.00 = 80 Ibs 4 5 7 #10 x 5" screw 101 x 1.000 x 1.00 = 101 Ibs 3 4 6 1/4" SIDS x 5" 190 x 1.000 x 1.00 = 190 Ibs 2 2 3 #12 x 5" screw 128 x 1.000 x 1.00 = 128 Ibs 3 3 5 10d common nail 102 x 0.676 x 1.00 = 69 Ibs 5 6 9 16d sinker nail 102 x 0.845 x 1.00 = 86 Ibs r4 5 7 16d common nail 122 x 0.926 x 1.00 = 113 Ibs 1 3 4 1 5 * Number of specified fasteners per vertical 2x wall stud based on wall stud spacing, typically 16" o.c. 2x H F#2 RIM JOIST 2x H F#2 2x H F#2 LEDGER LEDGER 19 /2" -4-] FIG. A 12„ SHEATHING SHEATHING 2x H F#2 STUDS FIG. B Project: E1396 Sheet No: 45 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUMTRAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 ROOFLET 2x WOOD LEDGER CONNECTION DESIGN Total floor load (psf) = 40 psf x NDS values are derived from Table 11 NDS 1012 Tributary length to ledger (ft) = 2 ft = National Design Specification for Wood Construction Ledger connection load = 80 Ib/ft SIDS values from Simpson Technical Literature Min spacing SIDS = 3", 3/4" edge min, 4" end dist. (See Simpson C-F-14) FIG. A: Common Fastener Capacities Maximum fastener spacing (in) G = 0.43, 1 1/2" side member over 1/2" sheathing into 2x rim joist Fastener NDS (Ibs) x p/10D adjust. x Cd = Allowable (Ibs) #8 x 3-1/2" screw 80 x 0.915 x 1.00 = 73 Ibs 1 10.98 in #10 x 3-1/2" screw 101 x 0.789 x 1.00 = 80 Ibs 11.96 in 1/4" SIDS x 3 1/2" 245 x 0.600 x 1.00 = 147 Ibs 22.05 1-13.33 in #12 x 3-1/2" screw 128 x 0.694 x 1.00 = 89 Ibs in FIG. B: Common Fastener Capacities *Number of fasteners per stud G = 0.43, 1 1/2" side member over 1/2" sheathing into 2x wall studs Fastener NDS (Ibs) x p/10D adjust. x Cd = Allowable (Ibs) 12" O.C. 16" o.c. 24" o.c. #8 x 5" screw 80 x 1.000 x 1.00 = 80 Ibs 1 2 2 #10 x 5" screw 101 x 1.000 x 1.00 = 101 Ibs 1 2 2 1/4" SIDS x 5" 190 x 1.000 x 1.00 = 190 Ibs 1 1 1 #12 x 5" screw 128 x 1.000 x 1.00 = 128 Ibs 1 1 1 2 10d common nail 102 x 0.676 x 1.00 = 69 Ibs 2 2 3 16d sinker nail 102 x 0.845 x 1.00 = 86 Ibs 1 2 2 16d common nail 122 x 1 0.926 x 1.00 = 113 Ibs 1 1 2 * Number of specified fasteners per vertical 2x wall stud based on wall stud spacing, typically 16" o.c. 2x H F#2 RIM JOIST 2x H F#2 2x H F#2 LEDGER LEDGER 19 /2" -4-] FIG. A 12„ SHEATHING SHEATHING 2x H F#2 STUDS FIG. B Project: E1396 Sheet No: 46 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( Ndf.,\G64k]UING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 STUD AND POST WIND DESIGN - PAGE 1/2 Name: TYP Member: 2x6 HF#2 STUD Wood Type: S S = Sawn Lumber, E = PSL/LVL Engineered Lumber, G = Glulam Post, P = Pole (Sawn) Length (L) : 8.0 ft Length of column Ke = 1.00 Effective length factor, pin -pin K = 1.0 Width (B) : 1.5 in Supported column dimension Depth (D) : 5.5 in Critical column dimension to be checked in calculations Kf, built up C: 1.0 Built up column factor, Kf, only applies for buckling with respect to Width (B) For built up columns not supported by a wall, see NDS 15.3.2.4 Kf = 0.60 nailed built up column, Kf = 0.75 bolted built up column le = F-967 in Ke x L, Effective length of column in inches le / D = Fl-7-.5-1 < 50 F0__K_1 Slenderness limit for wood columns shall not exceed 50 (Can be 75 for construction) NDS 3.7.1.4 Fc pll = 800 psi compression allowable stress NDS Table F1: COVe values Fb = 675 psi bending allowable stress w/ size factor Sawn Lumber: 0.25 E = 1.20 x 106 psi PSL/LVL: 0.11 Ervin = 0.44 x 10' psi E(1-1.645*COVe)(1.03)/1.66 Glulam: 0.10 L Fc prp (sill) = 405 psi COVE = 0.25 Ci (E=0.95) = 1.00 Incising factor for E (0.95 for PT) Ci (Fc,Fb=0.80) = 1.00 Incising factor for Fc pll and Fb (0.80 for PT) D a Cd = 1.60 Load duration factor Cm (for E) = 1.00 Wet service factor for E (See NDS tables 4A-4F) 1.00 for dry Cm (for Fc) = 1.00 Wet service factor for Fc (See NDS tables 4A-4F) 1.00 for dry Cm (for Fcprp) = 1.00 Wet service factor for Fcprp (See NDS tables 4A-4F) 1.00 for dry Cm (for Fb) = 1.00 Wet service factor for Fb (See NDS tables 4A-4F) 1.00 for dry Cfu (for Fb) = 1.00 Flat use factor for bending Cr (for Fb) = 1.00 Repetitive member factor for bending E'min = 0.44 x 10' psi Emin x Ci x Cm Adjusted Modulus of Elasticity Fc* = 1280 psi Fc pll x Ci x Cd x Cm Adjusted compressive stress FcE = 1183 psi 0.822 E'min / (le / D)2 Critical buckling design stress Cp = 0.7 NDS equation 3.7-1 NDS 3.7.1: c values F'c prp = 405 psi Fc prp x Cm (Ci for Pc prp = 1.00) Sawn Lumber: 0.80 Fb' = 1080 psi PSL/LVL: 0.90 Axial Pallow = 3.3 kips Sill plate crushing controls Glulam: 0.90 Allowable axial only load Rounds/Poles: 0.85 Shown because sill crushing may control c S = 7.56 in3 Section Modulus I = 20.8 in4 Moment of inertia Allowable Moment = Fb'*S = 681 lb-ft 0.68 k-ft Loads: I I Factored Loads: C&C Wind = 22.2 psf unfactored C&C wind pressures Lateral C&C Wind 0.6W = 17.72 plf MWFRS Wind = 15.8 psf unfactored MWFRS wind pressures Lateral MWFRS Wind 0.6W = 12.61 plf Snow Load = 406 plf S = k, unfactored Snow Lateral MWFRS Wind 0.75(0.6W) = 9.46 plf Live Load = 452 plf L = Rik, k, unfactored Live Axial D + 0.6W = 0.73 k Dead Load = 549 plf D = unfactored Dead Axial D + 0.75E + 0.75(0.6W) + 0.75S = 1.59 k Gravity Trib w = Wind Trib w = 1.33 1.33 ft, stud ft, stud spacing / trib width (option: set to zero and manually input S, L and D for posts) spacing / tributary width Effective area = 21.3 ft2, greater of tributary area or effective area Project: E1396 Sheet No: 47 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL GISI'LAIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com i Mukilteo, WA 98275 Phone: (360) 386-9476 STUD AND POST WIND DESIGN - PAGE 2/2 C&C Wind Design Flexural Only Design: Load Case: D + 0.6W Lateral C&C Wind 0.6W = 17.7 plf Moment = w12/8 = 142 Ib-ft Allow Moment = Fb'*S = 681 lb-ft OK 0.14 k-ft 0.68 k-ft Deflection = 0.046 in (C&C loads multiplied by 0.70 as allowed by IRC deflection table) L L 2096 Allowable Deflection = 180 OK Reaction for connection = 71 Ibs, used for design of connection to top and bottom plates and to check shear if desired (rarely controls wind post design) Post connection design notes: Typ IBC (3) 3" x 0.131" end -nail capacity (Doug -Fir) = 3 nails * 1.60 (Cd) * 0.67 (Ceg) * 97 lb/nail = 312 Ibs Typ IBC (3) 3" x 0.131" end -nail capacity (Hem -Fir) = 3 nails * 1.60 (Cd) * 0.67 (Ceg) * 84 lb/nail = 270 Ibs 270 Ibs * 3 total studs = 810 Ibs OK (use 4 nails per stud) MWFRS Combined Loading Check Load Case: D + 0.6W Lateral MWFRS Wind 0.6W = 12.6 plf Moment = w12/8 = 000.87 lb-ft 1210.4 lb -in 0.10 k-ft Summary Axial =D + 0.75L + 0.75(0.6W) + 0.75S = 0.73 k Sill Crushing: OK Combined loading: OK fb = 160 psi fc = 88.5 psi Check fc < FcE OK Buckling: OK Fb' = 1080 psi F'c pll = 849 psi Slenderness: OK bending: 15% %axial: 10% R = 0.17 NDS3.9-3 Interaction Check R<1.0? Ok (fc/F'c pll)12 + fb / (Fb'*(1-(fc/FcE)) MWFRS Combined Loading Check Load Case: D + 0.75L + 0.75(0.6W) + 0.75S Lateral MWFRS Wind 0.75(0.6W) = Ck plf Moment = w12/8 = 75.65 lb-ft lb -in 0.08 k-ft Summary Axial =D + 0.75L + 0.75(0.6W) + 0.75S = Sill Crushing: OK Combined loading: OK fb = 120 psi fc = 192 psi Check fc < FcE OK Buckling: OK 84 Fb' = 1080 psi F'c pll = 9 psi Slenderness: OK bending: 11 % %axial: 23% R = 0.18 NDS3.9-3 Interaction Check R<1.0? OK (fc/F'c pll)^2 + fb / (Fb'*(1-(fc/FcE)) iviisc aesign or notes: Project: E1396 Sheet No: 48 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL AMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 - - - - - - - - - - - - - - - - L------------J--------------- r., r� FL jr------ II I I II ILI1 I I� _]I ------t LII -- II — I --� 1L� I --J I �� 1 LL--J-� I I --J I �� J� � I IrL-L-----------J - FOUNDATION PLAN NTS Project: E1396 Sheet No: 49 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( Ndf.,\G6 ILMIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 FOUNDATION SPREAD FOOTING GRAVITY LOAD CHECK Wall Line or Location: South Wall Line Tributary Calculator Uniform (psf) Point (plf) Results (plf) Level Cant ft Span or Wall Height ft Opp Cant ft Tributary Length ft D psf L psf S psf D plf L plf S plf From Left ft React % D plf L plf S plf Total psf Running Total plf Roof 1.5 29.5 1.5 16.250 19 0 25 0 0 0 0 1.05 309 0 406 715 1 715.0 3W 8 10 80 80 1 795.0 3rd 0 19.5 0 9.750 15 40 0 0 0 0 0 1 146 390 0 536 1331.3 2W 8 10 80 80 1411.3 2nd 0 1.33 0 0.665 15 40 0 0 0 0 0 1 9.98 26.6 0 36.6 1447.8 1 W 8 10 80 80 1527.8 1st 0 T 0 0 0.000 1 15 1 40 0 0 0 1 0 0 1 0 0 0 0 0 1527.8 Totals: 705 417 406 1527.8 Foundation Self Weight (FSW) = 300 plf Dead load + FSW = 1005 plf Dead Load = 1005 plf Live Load = 417 plf Snow Load = 406 plf Total = 1827.8 plf ASD combinations ASCE 7-10 2.4.1 Combination 2: D + L = 1422 plf Combination 3: D + S = 1411 plf Combination 4: D + 0.75 * (L + S) = 1622 plf ASD Controlling Load = 1622 pIf LRFD combinations ASCE 7-10 2.3.2 Combination 1: 1.4D = 1407 plf Combination 2: 1.21D + 1.61- + 0.5S = 2076 plf Combination 3: 1.2D + 1.6S + L = 2273 plf LRFD Controlling Load = 2273 plf 1622 plf, ASD factored design load Allowable Soil Bearing = 2500 1 psf Required Minimum Footing Width =1 0.65 ft 7.79 lin Footing Notes: 8" stemwall w/ 16" Foundation Project: E1396 Sheet No: 50 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( NALLNGINUAING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Footing: F36 Soil Bearing: 2500 psf assume uniform pressure on bottom of footing Axial Load (P): 16.6 k assume footing is fixed at location of post Ftg. Weight: 1.35 k analyze 1 ft wide strip of footing as a cantilever P Min Width (B): 2.68 ft LRFD concrete design Ftg. Width: Ftg. Depth: Rebar Size: # of Rebar: Mu = � Mn = Vu = � VC = 3.0 ft 12 in # 4B 4 3.59 k-ft 6.82 k-ft ok 4.79 k 7.88 k ok As(min) = 3 f'c(12) b(d) / fy = 0.39 in As(min) = 200 b(d) / fy = 0.53 in2 (4/3 Mu < � Mn) As(min) = N/A in2 f'c = 2.5 ksi As = 0.26 in ok fy = 40 ksi b = 12 in �m = 0.90 d = 8.75 in �V = 0.75 Ag = 105 in d d d ° B Beam: Maximum point load on foundation check Post Load (k): 15.3 ( Unfactored Load ) Span (L) ft. 2.3 L = 1/2 of Required Distribution Length Load (plf): 3333 (Footing Width = 16") Results: M = 14.0 (k-ft) J Shear = 12.2 (k) Soil Bearing Pressure (plf ) POST As = 0.393 in.12 d = 21.5 in. Size of bars = # 4 LOAD = 0.9 b = 8 in. Number of bars = 2 + fy = 40 ksi. fc = 2.5 ksi. As fy �" M(ArroWro) _ As fy [ d - (1/2) 0.85 fc b j = 297.3 k-in = 24.8 k-ft d °d (2) #4 BARS n _ As (MIN) = 3*(fca/z)bd = 0.645 200*b*d in.^2 ( or) = 0.860 in.^2-- fy fy b ACI Provision 10.5.3: 1.33 x M < � Mn YES As min is N/A Shear for Concrete = � V� = 12900 lbs. OK Project: E1396 Sheet No: 51 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL GIMI]UING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 STAIR WALL FOUNDATION THICKENED FOOTING GRAVITY LOAD CHECK Wall Line or Location: Stair Foundation Tributary Calculator Uniform (psf) Point (plf) Results (plf) Level Cant ft Span or Wall Height ft Opp Cant ft Tributary Length ft D psf L psf S psf D plf L plf S plf From Left ft React % D plf L plf S plf Total psf Running Total plf Roof 0 0 0 0.000 15 0 25 0 0 0 0 0 0 0 0 0 1 0.0 3W 0 10 0 0 0.0 3rd 0 0 0 0.000 15 40 0 0 0 0 0 0 0 0 0 0 0.0 2W 0 10 0 0 0.0 2nd 0 28.5 0 14.250 15 40 0 0 0 0 0 1 214 570 0 784 783.8 1 W 8 10 80 80 863.8 1 St 1 0 0 0 0.000 15 40 0 0 0 0 0 1 0 0 0 0 0 863.8 Totals: 294 570 0 863.8 Foundation Self Weight (FSW) = 300 plf Dead load + FSW = 594 plf Dead Load = 594 plf Live Load = 570 plf Snow Load = 0 plf Total = 1163.8 plf ASD combinations ASCE 7-10 2.4.1 Combination 2: D + L = 1164 plf Combination 3: D + S = 594 Of Combination 4: D + 0.75 * ( L + S) = 1021 plf ASD Controlling Load = 1164 p I f LRFD combinations ASCE 7-10 2.3.2 Combination 1: 1.4D = 831 plf Combination 2: 1.2D + 1.6L + 0.5S = 1625 plf Combination 3: 1.2D + 1.6S + L = 1283 Of LRFD Controlling Load = 1625 p I f 1164 plf, ASD factored design load Allowable Soil Bearing = 2500 1 psf Required Minimum Footing Width =1 0.47 ft 5.59 lin Footing Notes: 12" Thickened Slab S12 Project: E1396 Sheet No: 52 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Footing: S12 Soil Bearing: 2500 psf assume uniform pressure on bottom of footing Axial Load (P): 1.42 k assume footing is fixed at location of post Ftg. Weight: 0.15 k analyze 1 ft wide strip of footing as a cantilever Min Width (B): 0.79 ft LRFD concrete design Ftg. Width: 1.0 ft As(min) = 3 f'c("2) b(d) / fy = 0.39 in Ftg. Depth: 12 in As(min) = 200 b(d) / fy = 0.53 in Rebar Size: # 4 # of Rebar: 2 (4/3 Mu < � Mn) As(min) = N/A in Mu = 0.31 k-ft f'c = 2.5 ksi As = 0.39 in ok � Mn = 9.95 k-ft ok fy = 40 ksi b = 12 in Vu = 1.26 k �m = 0.90 d = 8.75 in � VC = 7.88 k ok �V = 0.75 Ag = 105 in Footing: F24 Soil Bearing: 2500 psf assume uniform pressure on bottom of footing Axial Load (P): 7.40 k assume footing is fixed at location of post Ftg. Weight: 0.60 k analyze 1 ft wide strip of footing as a cantilever Min Width (B): 1.79 ft LRFD concrete design Ftg. Width: 2.0 ft As(min) = 3 f'c("2) b(d) / fy = 0.39 in Ftg. Depth: 12 in As(min) = 200 b(d) / fy = 0.53 in Rebar Size: # 4 # of Rebar: 2 (4/3 Mu < � Mn) As(min) = N/A in Mu = 1.60 k-ft f'c = 2.5 ksi As = 0.20 in ok � Mn = 5.11 k-ft ok fy = 40 ksi b = 12 in Vu = 3.20 k �m = 0.90 d = 8.75 in � VC = 7.88 k ok �V = 0.75 Ag = 105 in Footing: F30 Soil Bearing: 2500 psf assume uniform pressure on bottom of footing Axial Load (P): 9.88 k assume footing is fixed at location of post Ftg. Weight: 0.94 k analyze 1 ft wide strip of footing as a cantilever Min Width (B): 2.08 ft LRFD concrete design Ftg. Width: 2.5 ft As(min) = 3 f'c("2) b(d) / fy = 0.39 in Ftg. Depth: 12 in As(min) = 200 b(d) / fy = 0.53 in Rebar Size: # 4 # of Rebar: 2 (4/3 Mu < � Mn) As(min) = N/A in Mu = 2.16 k-ft f'c = 2.5 ksi As = 0.16 in ok � Mn = 4.10 k-ft ok fy = 40 ksi b = 12 in Vu = 3.46 k �m = 0.90 d = 8.75 in � VC = 7.88 k ok �V = 0.75 Ag = 105 in P d �a�I� B P d d a d d Q d O d O B O P O d O B Project: E1396 Sheet No: 53 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( NALLNGINUAING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Maximum point load on Strip Footing Post Load (k): 8.41 ( Unfactored Load ) Span (L) ft. 1.26 L = 1/2 of Required Distribution Length Load (plf): 3333 (Footing Width = 16") j Results: M = 4.2 (k-ft) Shear = 6.7 / (k) f f f f } f f Soil Bearing Pressure (plf ) POST As = 0.393 in.12 d = 8.75 in. Size of bars = # 4 LOAD = 0.9 b = 16 in. Number of bars = 2 1 fy 40 ksi. fc = 2.5 ksi. M(ArroWro) _ As fy [ d - (1/2) As fy j = 120.4 k-in = 10.0 k-ft d 0.85 fc b (2) #4 BARS°� n OK As (MIN) _ 3*(fc(1i2)bd = 0.525 d 200*b* in.^2 (or) = 0.700 in.^2 a 1�_ .� -- --- fy fy `��i�i �� b ��, ACI Provision 10.5.3: 1.33 x M < � Mn YES As min is N/A Shear for Concrete = � Vc = 10500 lbs. OK Project: E1396 Sheet No: 54 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STRUCTURAL RNCINEMNc 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 IC Herds by Location Search Information Atldreae: 3M M Ave S. EtlmmW WA WMD, LMA Coonllnatse= 57.86Y721; %999991-122.3751t13139999M T I m as tamp: 2 619-02-WT2 3A Z 6d. 52 1[Z FlMrtl Type: Seismic Reference Document: IIBG-2015 Risk CaNgory: II Site Clsaa: d Report Title: E1396 Id�f%P wiri f C'_ :;le MCER Horiz-Dntal Response Spectrum samh 12a 1.00 D.Ba 6.6a 6AA 023 o.Da tka 1A 20 3.6 Text Results Basio Parameters Name V2111e SS 1259 Si 6.497 SWO 1259 Sim 11.7d7 SOS 0.1145 SDI OA98 rih�rYEveMI la Yil " nymppi NatmolFa-k V. ❑lyTq[ a Na7i3081 r6re51 Kern d.6 6.a 6.6 RACER y[und rrKAun jperltxl-O.A) MCER tjound mcWn jpermd-1.13e) SMEL odlted SpeOV31 WOELleratlan value 316e-rnoflltIled SpPanl WOeler3lon value Hlrneft selarnlod"n value al D2&SA Nlrneft eelarnlo6Ba n value a11A&SA Oluimp wWenaf jSheOl N gifpn}I F4�S S U o r.Ortap wcR�rr.r M, Kq- a —P �p Design Horizontal Response Spectrum Sa19M (1.81) a.60 a.46 a2t3 0.01) 7.6 PUM [aM 6.a 1.0 2.6 3A 4A S. Project: E1396 Sheet No: 55 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( Ndf.,\G6 ILMIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 LATERAL ANALYSIS -THREE STORY STRUCTURE Site Class: D SS : 1.27 ( mapped spectral accel. Short period) Fa :F115 (TABLE 11.4-1) SDS = (2/3)Fa SS =IO501 0.85 S1 : 0.50 ( mapped spectral accel. 1-sec. period) F ( TABLE 11.4-2) Spy = (2/3)F�, S, = Design Method - ASCE 7-10 Simplified Procedure V = (F*Sds/R)*W = 0.156 W AISC 12.14.8.1 F = 1.2 for three-story buildings Seismic Force -Resisting System Description R = 6.5 (ASCE 7-10 Table 12.14-1) Light -framed walls sheathed with wood structural panels I = 1 1.0 (ASCE 7-10 Table 1.5-2) Calculating Structure Contributing Seismic Weights: Diaphragm Description Area psf W (k) V (k) Roof 2930sf = 2930 15 43.950 Roof Solar Ready Zone 600sf = 600 4 2.400 7.079 3rd Floor Walls 1/2*(84.5ft*3+29.5ft*7)*8ft = 1840 10 18.400 3rd Floor 3rd Floor Walls 1/2*(84.5ft*3+29.5ft*7)*8ft = 1840 10 18.400 7.581 3rd Floor 2552sf = 2552 15 38.280 2nd Floor Walls 1/2*(84.5ft*2+29.5ft*5)*8ft = 1266 10 12.660 2nd Floor Walls 1/2*(84.5ft*2+29.5ft*5)*8ft = 1266 10 12.660 2nd Floor 2nd Floor 2340sf = 2340 15 35.100 6.551 Deck 140sf = 140 10 1.400 1st Floor Walls 1/2*(84.5ft*2.5+29.5ft*7)*6ft = 1076 10 1 10.763 Totals 1 94.013 21.211 Using allowable stress design load combinations per ASCE 2.4.1 V = 0.7 x 0.156 x 194.013 = 21.211 kips Note to reviewer: Vertically (gravity) the units are structurally independent per IRC. Since the diaphragms are to be connected via sheathing, it is not possible that the units are laterally independent. Therefore laterally the building is designed to act as a single structure. Project: E1396 Sheet No: 56 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SIR1 C I( RALLMANE RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 ASCE 7-10 Chapter 27 Directional Procedure Wind Load Design Procedure: Enclosed Buildings Velocity Pressure Coefficients, Kh and Kz Desian Parameters: Table 27.3-1 az = 0.00256 * Kz * Kzt * Kd * VA = V = 110 mph (Figure 26.5-1A) Exposure: B Kd = 0.85 ASCE table 26.6-1 Kzt = 1 Topographic factor RC 1 2 JRisk Category 1.5-2 Velocity is based upon Risk Catergory, and there is no longer an importance wind factor. G = 0.85 Gust Factor 6.5.8 Gcpi = 0.18 (+/- figure 6-5) h = 29 mean roof height (ft, h) 30 snap to nearest table height qh = 18.4 velocity pressure @ mean roof roof pitch = 4 rise Height, z Exposure qz B C D ft psf 0-15 0.57 0.85 1.03 15.0 20 0.62 0.90 1.08 16.3 25 0.66 0.94 1.12 17.4 30 0.70 0.98 1.16 18.4 40 0.76 1.04 1.22 20.0 50 0.81 1.09 1.27 21.3 60 0.85 1.13 1.31 22.4 70 0.89 1.17 1.34 23.4 80 0.93 1.21 1.38 24.5 90 0.96 1.24 1.40 25.3 100 0.99 1.26 1.43 26.1 12 run q = 16.43 aeg Main Wind Force Resisting System - Part 1 All Heights Figure 27.4-1 (confd)r External Pressure Coefficients, Cp Walls & Roofs Enclosed, Partially Enclosed Buildings Wall Pressure Coefficients, Cp Surface L/B Cp Use With Windward Wall All Values 0.8 qz Leeward Wall 0-1 -0.5 qh 2 -0.3 >=4 -0.2 Side Wall I All Values -0.7 1 ah Roof Pressure Coefficients, Cp, for use with qh Windward Leeward Wind Angle,q(degrees) Angle, q(de g.) Direction h/L 10 15 20 25 30 35 45 >60 10 15 >20 -0.70 -0.50 -0.30 -0.20 -0.20 0.00 < 25 -0.30 -0.50 -0.60 -0.18 0.00 0.20 0.30 0.30 0.40 0.40 0.18 Normal to 0.5 -0.90 -0.70 -0.40 -0.30 -0.20 -0.20 0.00 -0.50 -0.50 -0.60 ridge for q >10 deg -0.18 -0.18 0.00 0.20 0.20 0.30 0.40 0.18 -1.30 -1.00 -0.70 -0.50 -0.30 -0.20 0.00 > 1.0 -0.70 -0.60 -0.60 -0.18 -0.18 -0.18 0.00 0.20 0.20 0.30 0.18 Horizontal distance Value provided for Normal to from windward edge C p interpolation ridge for q 0 to h/2 -0.90 -0.18 Value can be reduced <10 deg <.5 h/2 to h -0.90 -0.18 linearly as follows and Area (sq ft) Reduction h to 2h -0.50 -0.18 Parallel to < 100 1 ridge for I > 2h -0.30 -0.18 >1 0 0 to h/2 -1.30 -0.18 250 0.9 all q > 1000 0.8 > h/2 -0.70 0.181 Project: E1396 Sheet No: 57 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUCfUHAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 W 81 SF W 83 Sf W 45 SF Vx ZONE ELEVATIONS Not to Scale h_ = 0.34 L = 2.86 zone: ( R ) Roof or ( W ) Wall zone L B B = L = 29.5 1 84.5 Horizontal dimension of building, in feet, measured perpendicular to wind direction Horizontal dimension of building, in feet, measured parallel to wind direction Diaphragm zone Windward Cp Leeward Cp zone Total Area Design Wind Pressure, psf Force Min. Force z ft qz (sq. ft) windward leeward *total (kips) R 0.2 -0.6 30 18.4 53 3.1 -9.4 12.5 0.66 0.42 W 0.8 -0.257 40 20 14 13.6 -4.0 17.6 0.25 0.22 Roof W 0.8 -0.257 30 18.4 134 12.5 -4.0 16.6 2.22 2.14 W 0.8 -0.257 25 17.4 81 11.8 -4.0 15.8 1.28 1.30 - I - I - 1 0.0 0.00 0.00 Compare Min w/ calculated: Total Area = 282 Roof Total Wind Force (kips) 4.41 4.09 W 0.8 -0.257 1 25 117.4 83 11.8 -4.0 15.8 1.31 1.33 3rd Floor W 0.8 -0.257 20 16.3 161 11.1 -4.0 15.1 2.44 2.58 W 0.8 -0.257 15 1 15 45 10.2 -4.0 14.2 0.64 0.72 Compare Min w/ calculated: Total Area = 289 3rd Floor Total Wind Force (kips) 4.39 4.62 W 0.8 -0.257 15 15 280 10.2 -4.0 14.2 3.98 4.48 2nd Floor - - - 0.0 0.00 0.00 - - - 0.0 0.00 0.00 Compare Min w/ calculated: Total Area = 280 2nd Floor Total Wind Force (kips) 3.98 4.48 Windward Design Pressure = gGCp - gi(Gcpi) q = qz, velocity pressure @ wall height 851 Total Wind Force: Factored Force (0.6*W): 13.19 7.92 Leeward (and all roof) Design Pressure = gGCp - gi(Gcpi) Min. Wind Pressure Controls? : YES q = qh, velocity pressure @ mean roof height Note: Internal pressures cancel each other out per Table 26.11-1 note 3. Combine loads per ASCE Figure 27.4-1 *total roof pressures are projected onto vertical surface of structure Project: E1396 Sheet No: 58 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,,1(1 [ I( Ndf.,\GINUAING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 W 187 S W 209 SE 21 12 VV ZONE ELEVATIONS Not to Scale h_ = 0.98 L = 0.35 zone: ( R ) Roof or ( W ) Wall zone L B B = L = 84.5 1 29.5 Horizontal dimension of building, in feet, measured perpendicular to wind direction Horizontal dimension of building, in feet, measured parallel to wind direction Diaphragm zone Windward Cp Leeward Cp zone Total Area Design Wind Pressure, psf Force Min. Force z ftr17.4 (sq. ft) windward leeward *total (kips) R 0 -0.6 30 438 0.0 -9.4 9.4 4.12 3.50 W 0.8 -0.5 30 187 12.5 -7.8 20.4 3.81 2.99 Roof W 0.8 -0.5 25 209 11.8 -7.8 19.6 4.11 3.34 - - 0.0 0.00 0.00 - i - i 0.0 0.00 0.00 Compare Min w/ calculated: Total Area = 834 Roof Total Wind Force (kips) 12.03 9.84 W 0.8 -0.5 1 25 117.4 215 11.8 1 -7.8 19.6 4.22 3.44 3rd Floor W 0.8 -0.5 20 16.3 424 11.1 -7.8 18.9 8.03 6.78 W 0.8 -0.5 15 1 15 124 10.2 -7.8 18.0 2.24 1.98 Compare Min w/ calculated: Total Area = 763 3rd Floor Total Wind Force (kips) 14.49 12.21 W 0.8 -0.5 15 15 762 10.2 -7.8 18.0 13.75 12.19 2nd Floor - - - 0.0 0.00 0.00 - - - 0.0 0.00 0.00 Compare Min w/ calculated: Total Area = 762 2nd Floor Total Wind Force (kips) 13.75 12.19 Windward Design Pressure = gGCp - gi(Gcpi) q = qz, velocity pressure @ wall height 2359 Total Wind Force: Factored Force (0.6*W): 40.27 24.16 Leeward (and all roof) Design Pressure = gGCp - gi(Gcpi) Min. Wind Pressure Controls? : NO q = qh, velocity pressure @ mean roof height Note: Internal pressures cancel each other out per Table 26.11-1 note 3. Combine loads per ASCE Figure 27.4-1 *total roof pressures are projected onto vertical surface of structure Project: E1396 Sheet No: 59 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS SIRl C I( RALL AMILMING 9999 Harbour Place Suite 107 email@equilibria-engineering.com i Mukilteo, WA 98275 Phone: (360) 386-9476 Summary (Loads are factored per ASCE 2.4.1) Direction *R&R Seismic Wind Vx 1.00 21.211 kips 7.915 kips Vy 1.30 27.575 kips 24.160 kips *Seismic reliability and redundancy factor 3rd Floor Shear Walls: (diaphragm above 3rd floor shear walls) 3rd Floor Seismic 3rd Floor Wind Seismic VEX = 7.079 kips = 240.0 plf Wind Vwx = 2.453 kips = 83.1 plf 29.50 ft 29.50 ft Seismic VEy = 9.203 kips = 108.9 plf Wind Vwy = 7.219 kips = 85.4 plf 84.50 ft 84.50 ft 2nd Floor Shear Walls: (diaphragm above 2nd floor shear walls) 2nd Floor Seismic Seismic VEX = 7.581 kips = 257.0 plf 29.50 ft 2nd Floor Wind Wind Vwx = 2.774 kips = 94.0 plf 29.50 ft Seismic VEy = 9.855 kips = 116.6 plf Wind Vwy = 8.694 kips = 102.9 plf 84.50 ft 84.50 ft 1 st Floor Shear Walls: (diaphragm above 1 st floor shear walls) 1st Floor Seismic 1st Floor Wind Seismic VEX = 6.551 kips = 222.1 plf 29.50 ft Seismic VEy = 8.517 kips = 100.8 plf 84.50 ft Totals Seismic VEX = 21.211 kips Seismic VEy = 27.575 kips Wind Vwx = 2.688 kips = 91.1 plf 29.50 ft Wind Vwy = 8.247 kips = 97.6 plf 84.50 ft Totals Wind Vwx = 7.915 kips Wind Vwy = 24.160 kips Project: E1396 Sheet No: 60 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL AMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 �.3 r2.3 T 3.3-I r I � F --- -- ----- -- - - - -- - - I I I -_ -- --- --- - -- -- - - - I - _ --_ -- I I I I I I 1.3 2.3 3.3 THIRD FLOOR SHEAR WALLS Not to Scale 4.3 A.3 Project: E1396 Sheet No: 61 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL AMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 9 1.2 2.2 3.2 4.2 I I I I 7- F-1 Ll 1t -o- t s 2.2 3.2 SECOND FLOOR SHEAR WALLS Not to Scale 4.2 l Project: E1396 Sheet No: 62 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL AMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 A.1 B.1 ON 2.1 3.1 i I I 0 1 1 1 1 U 3.1 FIRST FLOOR SHEAR WALLS Not to Scale B.1 Project: E1396 Sheet No: 63 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS I °' ( I ( RAL LNGIN'AING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 3-Story Shear Wall Design RP M Page 1/3 Walls Wall Height (ft) Min Wall Length 3.5:1 (ft) Shear Tributary Length (ft) Seismic Diaph Shear (plf) Wind Diaph Shear (plf) ASD Seismic Shear (k) ASD Wind Shear (k) Diaph Dead Load (psf) Wall Dead Load (psf) A.3 TA.2 A.1 Roof Diaphragm 8.00 8.00 2.286 14.75 240.0 2.286 14.75 257.0 83.1 94.0 3.540 1.226 15 1.387 15 10 10 2nd Floor 3.790 1st Floor 8.00 2.286 1 14.75 222.1 91.1 3.276 1.344 15 10 Direction X Total 10.606 3.958 Dead Load Factor (ASD) Seismic Load Factor (ASD) Tension Neglect: Cd (Deflection Amplification): Typical Chord Post Area: End Post Modulus of Elasticity: 0.6 Overturning resistance Deflection and OS cells (to account for R&R use 0.70*1.3 = 0.91) kips Shear Wall Properties ASCE table 12.2-1 SW 11 SW21 SW31 SW41 SW51 SW61 SW7 in2 Capacities 150 350 456 595 1707 1911 11190 I psi Ga (OSB) 15 22 28 42 1 44 1 56 1 84 0.7 0.25 4 16.5 1.60E+06 Roof Diaphragm Shear Walls Grid A.3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length =H122ft VE Seismic Shear E = 3.54 kips (ASD) Vw Wind Shear W = 1.23 kips (ASD) Average Shear =Of A.3 Grid Line A.3 . 1 A.3 . 2 A.3 . 3 A.3 . 4 A.3 . 5 A.3 . 6 A.3 . 7 A.3 . 8 Single Wall Wall Length (ft) 8 8 9 5 8 Wall Height (ft) 8 SW Designation SW2 SW2 SW2 Nom. Capacity (plf) 350 350 350 *2w/h 1.000 1.000 1.000 Red. Capacity (k) 2.800 3.150 1.750 Shear Distrib (%) 0.364 0.409 0.227 V, Shear (plf) E 160.9 160.9 160.9 V, Shear (plf) W 55.7 55.7 55.7 Vmax, Shear (plf) 160.9 160.9 160.9 Reduced Cap (plf) 350.0 350.0 350.0 OTM (k-ft) E 10.30 11.58 6.44 OTM (k-ft) W 3.57 4.01 2.23 OTMmax (k-ft) 10.30 11.58 6.44 OS Comb Couple (k) E 1.84 1.84 1.84 OTM Couple (k) E 1.29 1.29 1.29 OTM Couple (k) W 0.45 0.45 0.45 Trib DL Length (ft) 16.00 16.00 10.00 Resist Force (k) 2.560 2.880 1.150 RM ASD (k-ft) 6.144 7.776 1.725 T (k) E 0.519 0.423 0.942 T (k) W Tmax (k) 0.519 0.423 0.942 Hold Down MSTC28 MSTC28 MSTC28 MSTC661133 - - - - oa, Anchor Slip (in) 0.125 0.125 0.125 End Post Area (in2) 16.50 16.50 16.50 6 (in) E 0.213 0.199 0.291 Cd*6 (in) E 0.852 0.795 1.163 Cd*6 / hsx E 0.009 0.008 0.012 Wall Rigidity RI 5.784 1 6.518 1 3.585 *For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Total Capacity: 1 7.700 kips Capacity > Demand? I OK Project: E1396 Sheet No: 64 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNG6 ILMIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam Overstren th Calculations Beam: I HD1 Applicable ASCE load combinations ASCE 12.14.3.2: Case 5: (1.0 + 0.14Sds)D + 1.75Qe Case 6b: (1.0 + 0.105Sds)D + 1.313Qe + 0.75L + 0.75S Case 8 w/ O.S.: (0.6 - 0.14Sds)D + 1.75 Qe Case 8 w/ no O.S.: (0.6 - 0.14Sds)D + 0.70 Qe Beam Span: 8 ft Qe = Seismic Load / 0.7 Overstrength factor = 2.5 Sds: 0.85 R&R: 1.00 Dead Load Factors: 1.12 D 1.09 D 0.48 D 0.48 D OS 1-1131 L+S Uniform Loads Magnitude(plf) Point Loads Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 in^4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 6.85 (k-ft) R1 = 2.72 (k) R2 = 3.57 (k) v max = 129 (psi) Deflect. = 0.079 (in) = L 1218 Beam: Span: 8 ft OS HD1 D Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 inA4 490 A inA2 41.6 Results M allow = 19.90 (k-ft) M max = 4.13 (k-ft) R1 = 1.65 (k) R2 = 2.14 (k) v max = 77 (psi) Deflect. = 0.048 (in) = L 2019 _start end (ft) start end (plf) distance(ft) 0 5.5 542 542 5.5 5.5 8 681 681 x = 4 (ft) M @ x = 6.56 (k-ft) V @ x = 0.56 (k) Loading Diagram: OS HD1 L+S 2000 1500 1000 0 500 0 0 1 2 3 4 5 6 Uniform Loads start end (ft) 0 5.5 5.5 8 x = 4 (ft) M @ x = 3.96 (k-ft) V @ x = 0.33 (k) Loading Diagram: OS HID1 D Magnitude(k) 2000 1500 1000 0 soo a 0 7 8 Magnitude(plf) Point Loads Magnitude(k) _start end (plf) distance(ft) 330 330 5.5 0.97 403 403 1500 1000 a , 1000 0 500 soo 0 � a 0 0 0 1 2 3 4 5 6 7 8 Project: E1396 Sheet No: 65 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Load: E (unfactored - 0.7 divided out to get unfactored load) Span (L) ft. 8 W1 (plf) 0 P1 P2 W2 (plf) 0 W1 P1 (k): 1.98 a (ft): 3.33 P2 (k): b (ft): P3 (k): c (ft): P4 (k): d (ft): Negative values indicate uplift Results: M = 3.85 (k-ft) P3 P4 W2 W1 1T� a b c d R1 L R2 R1 = 1.16 (k) ATE = N/A (in) R2 = 0.82 (k) = L N/A Results: Live and Snow Dead Load Seismic Case 5: Case 6b: Case 8: Moment: 6.85 4.13 3.85 11.36 14.69 -4.75 Uplift w/ O.S. 2.72 1.65 -1.16 -0.18 2.31 -1.24 Uplift no O.S. 2.72 1.65 -1.16 - - -0.02 Reaction: 3.57 2.14 1.16 4.42 6.53 3.06 Min DL case Beam Check: Member: 3 1/2" x 11 7/8" PSL E psi 2.00E+06 inA4 490 A inA2 41.6 Ma k-ft 19.9 Va psi 290 (allowable shear stress) *M allow = 31.84 (k-ft) Maximum Moment = 14.69 k-ft Minimum Moment = 4.75 k-ft **V allow =1 12.87 1 (k) Maximum Shear = 6.53 k Minimum Shear = 1.24 Ik *Cd = 1.6 *2/3*Vallow*Area/1000 Positive Load Path to Foundation: Maximum Uplift = -0.02 k Anchorage design load (ASD) Load path design: No Cap Required Project: E1396 Sheet No: 66 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,t1 [ I( RALLNG6 ILMIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam Overstren th Calculations Beam: I HD6 Applicable ASCE load combinations ASCE 12.14.3.2: Case 5: (1.0 + 0.14Sds)D + 1.75Qe Case 6b: (1.0 + 0.105Sds)D + 1.313Qe + 0.75L + 0.75S Case 8 w/ O.S.: (0.6 - 0.14Sds)D + 1.75 Qe Case 8 w/ no O.S.: (0.6 - 0.14Sds)D + 0.70 Qe Qe = Seismic Load / 0.7 Overstrength factor = 2.5 Sds: 0.85 R&R: 1.00 Dead Load Factors: 1.12 D 1.09 D 0.48 D 0.48 D Beam: OS HD6 L+S Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 8 ft end (ft) start end (plf) distance(ft) _start 0 8 542 542 Member: 5 1/8" x 7 1/2" 24F V4 GLB E psi 1.80E+06 x = 4 (ft) in14 180 M @ x = 4.33 (k-ft) A in12 38.4 V @ x = 0 (k) Results M allow = 9.60 (k-ft) Loading Diagram: OS HD6 L+S M max = 4.33 (k-ft) 1500 1 R1 = 2.17 (k) w a 0.8 R2 = 2.17 (k) l000 0.6 v max = 84 (psi) c soo 0.4 0 0.2 a Deflect. = 0.154 (in) 0 0 = L 0 1 2 3 4 5 6 7 8 622 Beam: OS HD6 D Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 8 ft start end (ft) start end (plf) distance(ft) 0 8 330 330 Member: 5 1/8" x 7 1/2" 24F V4 GLB E psi 1.80E+06 x = 4 (ft) in14 180 M @ x = 2.64 (k-ft) A in12 38.4 V @ x = 0 (k) Results M allow = 9.60 (k-ft) Loading Diagram: OS HD6 D M max = 2.64 (k-ft) 1 R1 = 1.32 (k) a 800 0.8 1 R2 = 1.32 (k) 600 0.6 Z v max = 51 (psi) c 400 200 0.4 c 0.2 a Deflect. = 0.094 (in) 0 0 = L 0 1 2 3 4 5 6 7 8 1021 Project: E1396 Sheet No: 67 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALLNGIMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Load: E (unfactored - 0.7 divided out to get unfactored load) Span (L) ft. 8 W1 (plf) 0 P1 P2 W2 (plf) 0 W1 1 P1 (k): 1.98 a (ft): 1.75 , I P2 (k): b (ft): P3 (k): c (ft): P4 (k): d (ft): Negative values indicate uplift Results: M = 2.71 (k-ft) P3 P4 W2 W1 1T� a b c d R1 L R2 R1 = 1.55 (k) ATE = N/A (in) R2 = 0.43 (k) = L N/A Results: Live and Snow Dead Load Seismic Case 5: Case 6b: Case 8: Moment: 4.33 2.64 2.71 7.69 9.68 -3.46 Uplift w/ O.S. 2.17 1.32 -1.55 -1.24 1.03 -2.08 Uplift no O.S. 2.17 1.32 -1.55 - - -0.45 Reaction: 2.17 1.32 1.55 4.19 5.10 3.35 Min DL case Beam Check: Member: 5 1/8" x 7 1/2" 24F V4 GLB E psi 1.80E+06 inA4 180 A in12 38.4 Ma k-ft 9.6 Va psi 265 (allowable shear stress) *M allow = 15.36 (k-ft) Maximum Moment = 9.68 k-ft Minimum Moment = -3.46 k-ft **V allow = 10.85 (k) Maximum Shear = 5.10 k Minimum Shear = 2.08 Ik *Cd = 1.6 *2/3*Vallow*Area/1000 Positive Load Path to Foundation: Maximum Uplift = -0.45 k Anchorage design load (ASD) Load path design: Simpson EPC6Z cap = 1435 Ibs of seismic uplift capacity Project: E1396 Sheet No: 68 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUCfUHAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 2nd Floor Shear Walls Grid A.2 Page 2/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 22.2 ft 3.54 1.23 VE from above = kips Vw from above = kips Average Shear = 331 1 plf VE Seismic Shear E = 3.79 kips Vw Wind Shear W = 1.39 kips Total VE Seismic Shear E = 7.33 kips Total Vw Wind Shear W = 2.61 kips A.2 Grid Line A.2 . 1 1 A.2 . 2 1 A.2 . 3 1 A.2 . 4 A.2 . 5 A.2 . 6 A.2 . 7 1 A.2 . 8 Single Wall Wall Length (ft) 3.29 3.29 9 3.29 3.29 Wall Height (ft) 8 8 8 8 8 SW Designation SW3 SW3 SW3 SW3 SW3 Nom. Capacity (plf) _456-V__456 456 456 456 **2w/h 0.823 0.823 1.000 0.823 0.823 Red. Capacity (k) 1.234 1.234 4.104 1.234 1.234 Shear Distrib (%) 0.137 0.137 0.454 0.137 0.137 V, Shear (plf) E 304.1 304.1 369.8 304.1 304.1 V, Shear (plf) W 108.4 108.4 131.8 108.4 108.4 Vmax, Shear (plf) 304.1 304.1 369.8 304.1 304.1 Reduced Cap (plf) 375.1 375.1 456.0 375.1 375.1 OTM (k-ft) E 8.00 8.00 26.62 8.00 8.00 OTM (k-ft) W 2.85 2.85 9.49 2.85 2.85 OTMmax (k-ft) 8.00 8.00 26.62 8.00 8.00 OTM Couple (k) E 2.43 2.43 2.96 2.43 2.43 OTM Couple (k) W 0.87 0.87 1.05 0.87 0.87 OS Comb Couple (k) E 3.48 5.31 6.06 5.31 3.48 „ ,...,) E 8.00 18.30 38.21 14.44 8.00 A (k-ft) W 2.85 6.42 13.51 5.08 2.85 JTMmax (k-ft) 8.00 18.30 38.21 14.44 8.00 1 T (k) E 2.265 5.079 2.922 3.994 2.265 A T (k) W 0.700 1.468 1.150 0.700 ned Tmax (k) 2.265 5.079 2.922 3.994 2.265 Trib DL Length (ft) 6.00 6.00 6.00 6.00 6.00 Resist Force (k) 0.559 1.612 4.410 1.316 0.559 RM ASD (k-ft) 0.552 1.591 11.907 1.299 0.552 Total T (k) E 2.265 3.236 2.922 3.325 2.265 Total T (k) W 0.700 0.830 0.919 0.700 Total Tmax (k) 2.265 3.236 2.922 3.325 2.265 Hold Down MSTC40 MSTC52 MSTC52 MSTC52 MSTC40 - - - - oa, Anchor Slip (in) 0.125 0.125 0.125 0.125 0.125 End Post Area (in2) 16.50 16.50 16.50 16.50 16.50 6 (in) E 0.449 0.449 0.271 0.449 0.449 Cd*6 (in) E 1.794 1.794 1.085 1.794 1.794 Cd*6 / hsx E 0.019 0.019 0.011 0.019 0.019 Wall Rigidity RI 2.468 2.468 6.907 2.468 2.468 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 9.040 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 69 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS STBUCfUHAL ENGINEERING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 V 1st Floor Shear Walls Grid A.1 Page 3/3 Manual VE adjustment = VE from above = VE Seismic Shear E = Total VE Seismic Shear E = kips Manual Vw adjustment = kips Vw from above = kips Vw Wind Shear W = kips Total Vw Wind Shear W = kips Total Wall Length -1 35.1 ft kips Average Shear = 302 plf kips kips 7.33 3.28 10.61 2.61 1.34 3.96 A.1 Grid Line A.1 . 1 A.1 .2 1 A.1 .3 1 A.1 . 4 1 A.1 .5 1 A.1 .6 A.1 .7 1 A.1 .8 Single Wall Wall Length (ft) 10.29 3.29 9 3.29 9.21 Wall Height (ft) 8 8 8 8 8 SW Designation SW2 SW2 SW2 SW2 SW2 Nom. Capacity (plf) 350 350 350 50 350 **2w/h 1.000 0.823 1.000 0.823 1.000 Red. Capacity (k) 3.602 0.947 3.150 0.947 3.224 Shear Distrib (%) 0.303 0.080 0.265 0.080 0.272 or V, Shear (plf) E 312.7 257.2 312.7 257.2 312.7 V, Shear (plf) W 116.7 96.0 116.7 96.0 116.7 Vmax, Shear (plf) 312.7 257.2 312.7 257.2 312.7 Reduced Cap (plf) 350.0 287.9 350.0 287.9 350.0 OTM (k-ft) E 25.74 6.77 22.52 6.77 23.04 OTM (k-ft) W 9.61 2.53 8.40 2.53 8.60 OTMmax (k-ft) 25.74 6.77 22.52 6.77 23.04 OTM Couple (k) E 2.50 2.06 2.50 2.06 2.50 OTM Couple (k) W 0.93 0.77 0.93 0.77 0.93 OS Comb Couple (k) E 7.05 8.25 9.64 8.25 7.05 1. ,...,) E 33.75 25.07 60.72 21.21 31.05 A (k-ft) W 12.46 8.95 21.91 7.61 11.45 JTMmax (k-ft) 33.75 25.07 60.72 21.21 31.05 I T (k) E 2.323 6.999 5.046 5.914 2.514 A T (k) W 0.254 2.098 0.733 1.780 0.387 ned Tmax (k) 2.323 6.999 5.046 5.914 2.514 Trib DL Length (ft) 4.00 4.00 4.00 4.00 4.00 Resist Force (k) 3.190 2.073 5.670 1.777 2.855 RM ASD (k-ft) 9.847 2.046 15.309 1.754 7.889 Total T (k) E 3.978 5.156 5.046 5.245 4.078 Total T (k) W 0.844 1.460 0.733 1.548 0.945 Total Tmax (k) 3.978 5.156 5.046 5.245 4.078 Hold Down HDU5 HDU5 HDU5 HDU5 HDU5 - - - - oa, Anchor Slip (in) 0.125 0.125 0.125 0.125 0.125 End Post Area (in2) 16.50 16.50 16.50 16.50 16.50 6 (in) E 0.266 0.455 0.281 0.455 0.279 Cd*6 (in) E 1.066 1.820 1.125 1.820 1.114 Cd*6 / hsx E 0.011 0.019 0.012 0.019 0.012 Wall Rigidity RI 7.463 2.332 6.518 2.332 6.672 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 11.869 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 70 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS I °' ( I ( RAL LNGIN'AING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 3-Story Shear Wall Design RP M Page 1/3 Walls Wall Height (ft) Min Wall Length 3.5:1 (ft) Shear Tributary Length (ft) Seismic Diaph Shear (plf) Wind Diaph Shear (plf) ASD Seismic Shear (k) ASD Wind Shear (k) Diaph Dead Load (psf) Wall Dead Load (psf) B.3 FB.7B. Roof Diaphragm 8.00 8.00 2.286 14.75 240.0 2.286 14.75 257.0 83.1 94.0 3.540 1.226 15 1.387 15 10 10 2nd Floor 3.790 1st Floor 8.00 2.286 1 14.75 222.1 91.1 3.276 1.344 15 10 Direction X Total 10.606 3.958 Dead Load Factor (ASD) Seismic Load Factor (ASD) Tension Neglect: Cd (Deflection Amplification): Typical Chord Post Area: End Post Modulus of Elasticity: 0.6 Overturning resistance Deflection and OS cells (to account for R&R use 0.70*1.3 = 0.91) kips Shear Wall Properties ASCE table 12.2-1 SW 11 SW21 SW31 SW41 SW51 SW61 SW7 in2 Capacities 150 350 456 595 1707 1911 11190 I psi Ga (OSB) 15 22 28 42 1 44 1 56 1 84 0.7 0.25 4 16.5 1.60E+06 Roof Diaphragm Shear Walls Grid B.3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 29.9 ft VE Seismic Shear E = 3--SA kips (ASD) Vw Wind Shear W = 1.23 kips (ASD) Average Shear = 1 118 1 Dlf B.3 Grid Line B.3 . 1 1 B.3 . 2 B.3 . 3 B.3 . 4 B.3 . 5 B.3 . 6 B.3 . 7 B.3 .8 Single Wall Wall Length (ft) 7.75 12.625 9.5 Wall Height (ft) 8 8 8 SW Designation SW1 SW1 SW1 Nom. Capacity (plf) 150 150 150 *2w/h 1.000 1.000 1.000 Red. Capacity (k) 1.163 1.894 1.425 Shear Distrib (%) 0.259 0.423 0.318 V, Shear (plf) E 118.5 118.5 118.5 V, Shear (plf) W 41.1 41.1 41.1 Vmax, Shear (plf) 118.5 118.5 118.5 Reduced Cap (plf) 150.0 150.0 150.0 OTM (k-ft) E 7.35 11.97 9.00 OTM (k-ft) W 2.55 4.15 3.12 OTMmax (k-ft) 7.35 11.97 9.00 OS Comb Couple (k) E 1.35 1.35 1.35 OTM Couple (k) E 0.95 0.95 0.95 OTM Couple (k) W 0.33 0.33 0.33 Trib DL Length (ft) 15.25 15.00 15.00 Resist Force (k) 2.393 3.851 2.898 RM ASD (k-ft) 5.563 14.584 8.258 T (k) E T (k) W Tmax (k Hold Down - - - - - oa, Anchor Slip (in) 0.125 0.125 0.125 End Post Area (in2) 16.50 16.50 16.50 8 (in) E 0.223 0.172 0.198 Cd*8 (in) E 0.891 0.686 0.793 Cd*8 / hsx E 0.009 0.007 0.008 Wall Rigidity RI 4.989 1 8.168 1 6.130 *For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Total Capacity: 1 4.481 kips Capacity > Demand? I OK Project: E1396 Sheet No: 71 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 2nd Floor Shear Walls Grid B.2 Page 2/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 24.7 ft 3.54 1.23 VE from above = kips VW from above = kips Average Shear = 297 1 plf VE Seismic Shear E = 3.79 kips Vw Wind Shear W = 1.39 kips Total VE Seismic Shear E = 7.33 kips Total VW Wind Shear W = 2.61 kips B.2 Grid Line B.2 . 1 1 B.2 .2 B.2 . 3 B.2 . 4 B.2 . 5 B.2 . 6 B.2 . 7 B.2 . 8 Single Wall Wall Length (ft) 7.58 7.58 8 9.5 Wall Height (ft) 8 8 SW Designation SW2 SW2 SW2 Nom. Capacity (plf) 350 350 350 **2w/h 1.000 1.000 1.000 Red. Capacity (k) 2.653 2.653 3.325 Shear Distrib (%) 0.307 0.307 0.385 V, Shear (plf) E 297.2 297.2 297.2 V, Shear (plf) W 106.0 106.0 106.0 Vmax, Shear (plf) 297.2 297.2 297.2 Reduced Cap (plf) 350.0 350.0 350.0 OTM (k-ft) E 18.02 18.02 22.59 OTM (k-ft) W 6.43 6.43 8.05 OTMmax (k-ft) 18.02 18.02 22.59 OTM Couple (k) E 2.38 2.38 2.38 OTM Couple (k) W 0.85 0.85 0.85 OS Comb Couple (k) E 4.75 4.75 4.75 „ ,...,) E 25.37 29.99 31.59 A (k-ft) W 8.97 10.57 11.17 JTMmax (k-ft) 25.37 29.99 31.59 J T (k) E 2.327 2.945 2.058 A T (k) W 0.383 ned Tmax (k) 2.327 2.945 2.058 Trib DL Length (ft) 4.00 4.00 4.00 Resist Force (k) 3.402 3.373 4.228 RM ASD (k-ft) 7.735 7.670 12.048 Total T (k) E 2.305 2.314 2.058 Total T (k) W Total Tmax (k) 2.305 2.314 2.058 Hold Down MSTC40 MSTC40 MSTC40 - - - - - - oa, Anchor Slip (in) 0.125 0.125 0.125 End Post Area (in2) 16.50 16.50 16.50 6 (in) E 0.295 0.295 0.267 Cd*6 (in) E 1.180 1.180 1.066 Cd*6 / hsx E 0.012 0.012 0.011 Wall Rigidity RI 5.476 5.476 6.884 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 8.631 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 72 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 1st Floor Shear Walls Grid B.1 Page 3/3 Manual VE adjustment = VE from above = VE Seismic Shear E = Total VE Seismic Shear E = kips Manual Vw adjustment = kips VW from above = kips VW Wind Shear W = kips Total VW Wind Shear W = kips Total Wall Length = 33.9 ft kips Average Shear = 313 plf kips kips 7.33 3.28 10.61 2.61 1.34 3.96 B.1 Grid Line B.1 . 1 1 B.1 . 2 B.1 . 3 B.1 . 4 B.1 . 5 B.1 . 6 B.1 . 7 B.1 . 8 Single Wall Wall Length (ft) 7.58 7.58 8 18.75 Wall Height (ft) 8 2.5 SW Designation SW2 SW2 SW2 Nom. Capacity (plf) 350 350 350 **2w/h 1.000 1.000 1.000 Red. Capacity (k) 2.653 2.653 6.563 Shear Distrib (%) 0.224 0.224 0.553 V, Shear (plf) E 312.8 312.8 312.8 V, Shear (plf) W 116.7 116.7 116.7 Vmax, Shear (plf) 312.8 312.8 312.8 Reduced Cap (plf) 350.0 350.0 350.0 OTM (k-ft) E 18.97 18.97 14.66 OTM (k-ft) W 7.08 7.08 5.47 OTMmax (k-ft) 18.97 18.97 14.66 OTM Couple (k) E 2.50 2.50 0.78 OTM Couple (k) W 0.93 0.93 0.29 OS Comb Couple (k) E 8.33 8.33 5.87 „ ,...,) E 44.34 48.96 46.26 A (k-ft) W 16.05 17.65 16.65 JTMmax (k-ft) 44.34 48.96 46.26 1 T (k) E 4.510 5.128 A T (k) W 0.779 0.998 ned Tmax (k) 4.510 5.128 Trib DL Length (ft) 4.00 4.00 4.00 Resist Force (k) 4.463 4.434 9.938 RM ASD (k-ft) 10.148 10.084 55.898 Total T (k) E 4.489 4.498 1.126 Total T (k) W 0.771 0.780 Total Tmax (k) 4.489 4.498 1.126 Hold Down HDU5 HDU5 STHD14 - - - - - - oa, Anchor Slip (in) 0.125 0.125 0.125 End Post Area (in2) 16.50 16.50 16.50 6 (in) E 0.304 0.304 0.068 Cd*6 (in) E 1.214 1.214 0.270 Cd*6 / hsx E 0.013 0.013 0.009 Wall Rigidity RI 5.476 5.476 43.974 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 11.869 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 73 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS I °' ( I ( RAL LNGIN'AING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 3-Story Shear Wall Design Page 1/3 Walls Wall Height (ft) Min Wall Length 3.5:1 (ft) Shear Tributary Length (ft) Seismic Diaph Shear (plf) Wind Diaph Shear (plf) ASD Seismic Shear (k) ASD Wind Shear (k) Diaph Dead Load (psf) Wall Dead Load (psf) 1.3 1.2 1.1 Roof Diaphragm 10.00 2.857 14.10 108.9 2.286 14.10 116.6 85.4 102.9 1.536 1.205 15 1.451 15 10 10 2nd Floor 8.00 1.644 1st Floor 8.00 2.286 1 14.10 100.8 97.6 1.421 1.376 15 10 Direction Y Tota 11 4.601 4.031 Dead Load Factor (ASD) Seismic Load Factor (ASD) Tension Neglect: Cd (Deflection Amplification): Typical Chord Post Area: End Post Modulus of Elasticity: 0.6 Overturning resistance Deflection and OS cells (to account for R&R use 0.70*1.3 = 0.91) kips Shear Wall Properties ASCE table 12.2-1 SW 11 SW21 SW31 SW41 SW51 SW61 SW7 in2 Capacities 150 350 456 595 1707 1911 11190 I psi Ga (OSB) 15 22 28 42 1 44 1 56 1 84 0.91 0.25 4 16.5 1.60E+06 Roof Diaphragm Shear Walls Grid 1.3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 5 ft VE Seismic Shear E = 1.54 kips (ASD) VW Wind Shear W = 1.20 3.kips (ASD) Average Shear = 439 1 Of 1.3 Grid Line 1.3 . 1 1.3 . 2 1.3 . 3 1.3 . 4 1.3 . 5 1.3 . 6 1.3 . 7 1.3 . 8 Single Wall Wall Length (ft) 3.5 8.66 Wall Height (ft) SW Designation SW4 Nom. Capacity (plf) 595 *2w/h 0.941 Red. Capacity (k) 1.959 Shear Distrib (%) V, Shear (plf) E 438.7 V, Shear (plf) W 344.2 Vmax, Shear (plf) 438.7 Reduced Cap (plf) 559.7 OTM (k-ft) E 13.30 10.43 OTM (k-ft) W OTMmax (k-ft) 13.30 OS Comb Couple (k) E 4.18 OTM Couple (k) E 3.80 OTM Couple (k) W 2.98 Trib DL Length (ft) 4.00 Resist Force (k) 0.513 RM ASD (k-ft) 0.539 T (k) E 3.646 T (k) W 2.827 Tmax (k) 3.646 Hold Down - - - - - - MSTC52 Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 8 (in) E 0.436 Cd*8 (in) E 1.743 Cd*8 / hsx E 0.017 Wall Rigidity R 2.602 *For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Total Capacity: 1.959 kips Capacity > Demand? OK Project: E1396 Sheet No: 74 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 2nd Floor Shear Walls Grid 1.2 Page 2/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 11 ft 1.54 1.20 VE from above = kips VW from above = kips Average Shear = 289 plf VE Seismic Shear E = 1.64 kips Vw Wind Shear W = 1.45 kips Total VE Seismic Shear E = 3.18 kips Total VW Wind Shear W = 2.66 kips 1.2 Grid Line 1.2 . 1 1.2 . 2 1.2 . 3 1.2 . 4 1.2 . 5 1.2 . 6 1.2 . 7 1.2 . 8 Single Wall Wall Length (ft) 11 8 SW2 Wall Height (ft) SW Designation Nom. Capacity (plf) 350 **2w/h 1.000 Red. Capacity (k) 3.850 Shear Distrib (%) V, Shear (plf) E 289.1 V, Shear (plf) W 241.4 Vmax, Shear (plf) 289.1 Reduced Cap (plf) 350.0 OTM (k-ft) E 25.44 OTM (k-ft) W 21.24 OTMmax (k-ft) 25.44 OTM Couple (k) E 2.31 OTM Couple (k) W 1.93 OS Comb Couple (k) E 6.72 1. ,...,) E 38.74 A (k-ft) W 31.67 JTMmax (k-ft) 38.74 1 T (k) E 2.576 A T (k) W 1.934 ned Tmax (k) 2.576 Trib DL Length (ft) 4.00 Resist Force (k) 3.153 RM ASD (k-ft) 10.404 Total T (k) E 5.167 Total T (k) W 3.966 Total Tmax (k) 5.167 Hold Down - - - - - - MSTC66 Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.211 Cd*6 (in) E 0.844 Cd*6 / hsx E 1 0.009 Wall Rigidity RI 7.984 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 3.850 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 75 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 1st Floor Shear Walls Grid 1.1 Page 3/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 29.5 ft 3.18 2.66 VE from above = kips VW from above = kips Average Shear = 156 plf VE Seismic Shear E = 1.42 kips VW Wind Shear W = 1.38 kips Total VE Seismic Shear E = 4.60 kips Total VW Wind Shear W = 4.03 kips 1.1 Grid Line 1.1 .1 1.1 . 2 1.1 . 3 1.1 . 4 1.1 . 5 1.1 . 6 1.1 . 7 1.1 . 8 Single Wall Wall Length (ft) 29.5 8 SW2 Wall Height (ft) SW Designation Nom. Capacity (plf) 350 **2w/h 1.000 Red. Capacity (k) 10.325 Shear Distrib (%) V, Shear (plf) E 156.0 V, Shear (plf) W 136.7 Vmax, Shear (plf) 156.0 Reduced Cap (plf) 350.0 OTM (k-ft) E 36.81 OTM (k-ft) W 32.25 OTMmax (k-ft) 36.81 OTM Couple (k) E 1.25 OTM Couple (k) W 1.09 OS Comb Couple (k) E 8.09 1. ,...,) E 75.55 A (k-ft) W 63.93 JTMmax (k-ft) 75.55 1 T (k) E A T (k) W ned Tmax (k) Trib DL Length (ft) 10.50 Resist Force (k) 15.461 RM ASD (k-ft) 136.829 Total T (k) E 2.722 Total T (k) W 1.367 Total Tmax (k) 2.722 Hold Down - - - - - - - HDU5 Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.097 Cd*6 (in) E 0.389 Cd*6 / hsx E 0.004 Wall Rigidity RI 21.550 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 10.325 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 76 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS I °' ( I ( RAL LNGIN'AING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 3-Story Shear Wall Design RP M Page 1/3 Walls Wall Height (ft) Min Wall Length 3.5:1 (ft) Shear Tributary Length (ft) Seismic Diaph Shear (plf) Wind Diaph Shear (plf) ASD Seismic Shear (k) ASD Wind Shear (k) Diaph Dead Load (psf) Wall Dead Load (psf) 2.3 F2.2 2.1 Roof Diaphragm 10.33 2.951 28.10 108.9 2.286 28.10 116.6 85.4 102.9 3.060 2.401 15 2.891 15 10 10 2nd Floor 8.00 3.277 1st Floor 8.00 2.286 1 28.10 100.8 97.6 2.832 2.743 15 10 Direction Y Total 9,170 8.034 Dead Load Factor (ASD) Seismic Load Factor (ASD) Tension Neglect: Cd (Deflection Amplification): Typical Chord Post Area: End Post Modulus of Elasticity: 0.6 Overturning resistance Deflection and OS cells (to account for R&R use 0.70*1.3 = 0.91) kips Shear Wall Properties ASCE table 12.2-1 SW 11 SW21 SW31 SW41 SW51 SW61 SW7 in2 Capacities 150 350 456 595 1707 1911 11190 I psi Ga (OSB) 15 22 28 42 1 44 1 56 1 84 0.7 0.25 4 16.5 1.60E+06 Roof Diaphragm Shear Walls Grid 2.3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 21.8 ft VE Seismic Shear E = 3.06 kips (ASD) Vw Wind Shear W = 2.40 kips (ASD) Average Shear = 1 141 1 Of 2.3 Grid Line 2.3 .1 1 2.3 . 2 2.3 . 3 2.3 . 4 2.3 . 5 2.3 . 6 2.3 . 7 2.3 . 8 Single Wall Wall Length (ft) 21.75 10.33 Wall Height (ft) SW Designation SW1 Nom. Capacity (plf) 150 *2w/h 1.000 Red. Capacity (k) 3.263 Shear Distrib (%) 1.000 V, Shear (plf) E 140.7 V, Shear (plf) W 110.4 Vmax, Shear (plf) 140.7 Reduced Cap (plf) 150.0 OTM (k-ft) E 31.61 OTM (k-ft) W 24.80 OTMmax (k-ft) 31.61 OS Comb Couple (k) E 2.08 OTM Couple (k) E 1.45 OTM Couple (k) W 1.14 Trib DL Length (ft) 4.00 Resist Force (k) 3.552 RM ASD (k-ft) 23.175 T (k) E 0.388 T (k) W Tmax (k) 0.388 Hold Down MSTC28 - - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 8 (in) E 0.201 Cd*8 (in) E 0.804 Cd*8 / hsx E 0.006 Wall Rigidity R 10.901 *For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Total Capacity: 3.263 kips Capacity > Demand? OK Project: E1396 Sheet No: 77 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 2nd Floor Shear Walls Grid 2.2 Page 2/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 21.8 ft 3.06 2.40 VE from above = kips VW from above = kips Average Shear = 291 1 plf VE Seismic Shear E = 3.28 kips Vw Wind Shear W = 2.89 kips Total VE Seismic Shear E = 6.34 kips Total VW Wind Shear W = 5.29 kips 2.2 Grid Line 2.2 .1 2.2 . 2 2.2 . 3 2.2 . 4 2.2 . 5 2.2 . 6 2.2 . 7 2.2 . 8 Single Wall Wall Length (ft) 21.75 8 Wall Height (ft) SW Designation SW2 Nom. Capacity (plf) 350 **2w/h 1.000 Red. Capacity (k) 7.613 Shear Distrib (%) 1.000 V, Shear (plf) E 291.4 V, Shear (plf) W 243.3 Vmax, Shear (plf) 291.4 Reduced Cap (plf) 350.0 OTM (k-ft) E 50.70 OTM (k-ft) W 42.33 OTMmax (k-ft) 50.70 OTM Couple (k) E 2.33 OTM Couple (k) W 1.95 OS Comb Couple (k) E 5.41 1. ,...,) E 82.31 A (k-ft) w 67.13 JTMmax (k-ft) 82.31 1 T (k) E 1.806 A T (k) W 1.108 ned Tmax (k) 1.806 Trib DL Length (ft) 4.00 Resist Force (k) 6.597 RM ASD (k-ft) 43.044 Total T (k) E 1.806 Total T (k) W 1.108 Total Tmax (k) 1.806 Hold Down MSTC40 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.200 Cd*6 (in) E 0.801 Cd*6 / hsx E 0.008 Wall Rigidity RI 15.867 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 7.613 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 78 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 1st Floor Shear Walls Grid 2.1 Page 3/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 21.8 ft 6.34 5.29 VE from above = kips VW from above = kips Average Shear = 422 1 plf VE Seismic Shear E = 2.83 kips VW Wind Shear W = 2.74 kips Total VE Seismic Shear E = 9.17 kips Total VW Wind Shear W = 8.03 kips 2.1 Grid Line 2.1 .1 2.1 . 2 2.1 . 3 2.1 . 4 2.1 . 5 2.1 . 6 2.1 . 7 2.1 . 8 Single Wall Wall Length (ft) 21.75 Wall Height (ft) 8 SW Designation SW3 Nom. Capacity (plf) 456 **2w/h 1.000 Red. Capacity (k) 9.918 Shear Distrib (%) 1.000 V, Shear (plf) E 421.6 V, Shear (plf) W 369.4 Vmax, Shear (plf) 421.6 Reduced Cap (plf) 456.0 OTM (k-ft) E 73.36 OTM (k-ft) W 64.27 OTMmax (k-ft) 73.36 OTM Couple (k) E 3.37 OTM Couple (k) W 2.96 OS Comb Couple (k) E 10.22 „ ,...,) E 155.67 A (k-ft) W 131.41 JTMmax (k-ft) 155.67 J T (k) E 4.265 A T (k) W 3.149 ned Tmax (k) 4.265 Trib DL Length (ft) 4.00 Resist Force (k) 9.642 RM ASD (k-ft) 62.913 Total T (k) E 4.265 Total T (k) W 3.149 Total Tmax (k) 4.265 Hold Down HDU5 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.222 Cd*6 (in) E 0.889 Cd*6 / hsx E 0.009 Wall Rigidity RI 16.823 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 9.918 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 79 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS I °' ( I ( RAL LNGIN'AING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 3-Story Shear Wall Design RP M Page 1/3 Walls Wall Height (ft) Min Wall Length 3.5:1 (ft) Shear Tributary Length (ft) Seismic Diaph Shear (plf) Wind Diaph Shear (plf) ASD Seismic Shear (k) ASD Wind Shear (k) Diaph Dead Load (psf) Wall Dead Load (psf) 3.3 F3.2 3,1 Roof Diaphragm 10.33 2.951 28.10 108.9 2.286 28.10 116.6 85.4 102.9 3.060 2.401 15 2.891 15 10 10 2nd Floor 8.00 3.277 1st Floor 8.00 2.286 1 28.10 100.8 97.6 2.832 2.743 15 10 Direction Y Total 9,170 8.034 Dead Load Factor (ASD) Seismic Load Factor (ASD) Tension Neglect: Cd (Deflection Amplification): Typical Chord Post Area: End Post Modulus of Elasticity: 0.6 Overturning resistance Deflection and OS cells (to account for R&R use 0.70*1.3 = 0.91) kips Shear Wall Properties ASCE table 12.2-1 SW 11 SW21 SW31 SW41 SW51 SW61 SW7 in2 Capacities 150 350 456 595 1707 1911 11190 I psi Ga (OSB) 15 22 28 42 1 44 1 56 1 84 0.7 0.25 4 16.5 1.60E+06 Roof Diaphragm Shear Walls Grid 3.3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 21.8 ft VE Seismic Shear E = 3.06 kips (ASD) Vw Wind Shear W = 2.40 kips (ASD) Average Shear = 1 141 1 Of 3.3 Grid Line 3.3 .1 1 3.3 . 2 3.3 . 3 3.3 . 4 3.3 . 5 3.3 . 6 3.3 . 7 3.3 . 8 Single Wall Wall Length (ft) 21.75 Wall Height (ft) 10.33 SW Designation SW1 Nom. Capacity (plf) 150 *2w/h 1.000 Red. Capacity (k) 3.263 Shear Distrib (%) 1.000 V, Shear (plf) E 140.7 V, Shear (plf) W 110.4 Vmax, Shear (plf) 140.7 Reduced Cap (plf) 150.0 OTM (k-ft) E 31.61 OTM (k-ft) W 24.80 OTMmax (k-ft) 31.61 OS Comb Couple (k) E 2.08 OTM Couple (k) E 1.45 OTM Couple (k) W 1.14 Trib DL Length (ft) 4.00 Resist Force (k) 3.552 RM ASD (k-ft) 23.175 T (k) E 0.388 T (k) W Tmax (k) 0.388 Hold Down MSTC28 - - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 8 (in) E 0.201 Cd*8 (in) E 0.804 Cd*8 / hsx E 0.006 Wall Rigidity R 10.901 *For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Total Capacity: 3.263 kips Capacity > Demand? OK Project: E1396 Sheet No: 80 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 2nd Floor Shear Walls Grid 3.2 Page 2/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 21.8 ft 3.06 2.40 VE from above = kips VW from above = kips Average Shear = 291 1 plf VE Seismic Shear E = 3.28 kips Vw Wind Shear W = 2.89 kips Total VE Seismic Shear E = 6.34 kips Total VW Wind Shear W = 5.29 kips 3.2 Grid Line 3.2 .1 3.2 . 2 3.2 . 3 3.2 . 4 3.2 . 5 3.2 . 6 3.2 . 7 3.2 . 8 Single Wall Wall Length (ft) 21.75 8 SW2 Wall Height (ft) SW Designation Nom. Capacity (plf) 350 **2w/h 1.000 Red. Capacity (k) 7.613 Shear Distrib (%) 1.000 V, Shear (plf) E 291.4 V, Shear (plf) W 243.3 Vmax, Shear (plf) 291.4 Reduced Cap (plf) 350.0 OTM (k-ft) E 50.70 OTM (k-ft) W 42.33 OTMmax (k-ft) 50.70 OTM Couple (k) E 2.33 OTM Couple (k) W 1.95 OS Comb Couple (k) E 5.41 1. ,.. ,.) E 82.31 A (k-ft) W 67.13 JTMmax (k-ft) 82.31 1 T (k) E 1.806 A T (k) W 1.108 ned Tmax (k) 1.806 Trib DL Length (ft) 4.00 Resist Force (k) 6.597 RM ASD (k-ft) 43.044 Total T (k) E 1.806 Total T (k) W 1.108 Total Tmax (k) 1.806 Hold Down MSTC40 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.200 Cd*6 (in) E 0.801 Cd*6 / hsx E 0.008 Wall Rigidity RI 15.867 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 7.613 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 81 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 1st Floor Shear Walls Grid 3.1 Page 3/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 21.8 ft 6.34 5.29 VE from above = kips VW from above = kips Average Shear = 422 1 plf VE Seismic Shear E = 2.83 kips VW Wind Shear W = 2.74 kips Total VE Seismic Shear E = 9.17 kips Total VW Wind Shear W = 8.03 kips 3.1 Grid Line 3.1 .1 1 3.1 . 2 3.1 . 3 3.1 . 4 3.1 . 5 3.1 . 6 3.1 . 7 3.1 . 8 Single Wall Wall Length (ft) 21.75 8 Wall Height (ft) SW Designation SW3 Nom. Capacity (plf) 456 **2w/h 1.000 Red. Capacity (k) 9.918 Shear Distrib (%) 1.000 V, Shear (plf) E 421.6 V, Shear (plf) W 369.4 Vmax, Shear (plf) 421.6 Reduced Cap (plf) 456.0 OTM (k-ft) E 73.36 OTM (k-ft) W 64.27 OTMmax (k-ft) 73.36 OTM Couple (k) E 3.37 OTM Couple (k) W 2.96 OS Comb Couple (k) E 10.22 „ ,...,) E 155.67 A (k-ft) W 131.41 JTMmax (k-ft) 155.67 J T (k) E 4.265 A T (k) W 3.149 ned Tmax (k) 4.265 Trib DL Length (ft) 4.00 Resist Force (k) 9.642 RM ASD (k-ft) 62.913 Total T (k) E 4.265 Total T (k) W 3.149 Total Tmax (k) 4.265 Hold Down HDU5 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.222 Cd*6 (in) E 0.889 Cd*6 / hsx E 0.009 Wall Rigidity RI 16.823 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 9.918 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 82 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS I °' ( I ( RAL LNGIN'AING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 3-Story Shear Wall Design Page 1/3 Walls Wall Height (ft) Min Wall Length 3.5:1 (ft) Shear Tributary Length (ft) Seismic Diaph Shear (plf) Wind Diaph Shear (plf) ASD Seismic Shear (k) ASD Wind Shear (k) Diaph Dead Load (psf) Wall Dead Load (psf) 4.3 F4.2 4. 1 Roof Diaphragm 10.33 2.951 14.15 108.9 2.286 14.15 116.6 85.4 102.9 1.541 1.209 15 1.456= 15 10 10 2nd Floor 8.00 1.650 1st Floor 8.00 2.286 1 14.15 100.8 97.6 1.426 1.381 15 10 Direction Y Tota 11 4.618 4.046 Dead Load Factor (ASD) Seismic Load Factor (ASD) Tension Neglect: Cd (Deflection Amplification): Typical Chord Post Area: End Post Modulus of Elasticity: 0.6 Overturning resistance Deflection and OS cells (to account for R&R use 0.70*1.3 = 0.91) kips Shear Wall Properties ASCE table 12.2-1 SW 11 SW21 SW31 SW41 SW51 SW61 SW7 in2 Capacities 150 350 456 595 1707 1911 11190 I psi Ga (OSB) 15 22 28 42 1 44 1 56 1 84 0.7 0.25 4 16.5 1.60E+06 Roof Diaphragm Shear Walls Grid 4.3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = ft VE Seismic Shear E = 1.54 kips (ASD) VW Wind Shear W = 1.21 5.75kips (ASD) Average Shear = 268 1 Dlf 4.3 Grid Line 4.3 . 1 1 4.3 . 2 4.3 . 3 4.3 . 4 4.3 . 5 4.3 . 6 4.3 . 7 4.3 . 8 Single Wall Wall Length (ft) 5.75 9 Wall Height (ft) SW Designation SW2 Nom. Capacity (plf) 350 *2w/h 1.000 Red. Capacity (k) 2.013 Shear Distrib (%) 1.000 V, Shear (plf) E 268.0 V, Shear (plf) W 210.2 Vmax, Shear (plf) 268.0 Reduced Cap (plf) 350.0 OTM (k-ft) E 13.87 OTM (k-ft) W 10.88 OTMmax (k-ft) 13.87 OS Comb Couple (k) E 3.45 OTM Couple (k) E 2.41 OTM Couple (k) W 1.89 Trib DL Length (ft) 4.00 Resist Force (k) 0.863 RM ASD (k-ft) 1.488 T (k) E 2.153 T (k) W 1.633 Tmax (k) 2.153 Hold Down MSTC40 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.367 Cd*6 (in) E 1.468 Cd*6 / hsx E 0.014 Wall Rigidity R 3.657 *For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Total Capacity: 2.013 kips Capacity > Demand? OK Project: E1396 Sheet No: 83 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 2nd Floor Shear Walls Grid 4.2 Page 2/3 Manual VE adjustment = VE from above = VE Seismic Shear E = Total VE Seismic Shear E = kips Manual Vw adjustment = kips VW from above = kips Vw Wind Shear W = kips Total VW Wind Shear W = kips Total Wall Length = 11 ft kips Average Shear = 290 plf kips kips 1.54 1.65 3.19 1.21 1.46 2.66 4.2 Grid Line 4.2 . 1 1 4.2 . 2 4.2 . 3 4.2 . 4 4.2 . 5 4.2 . 6 4.2 . 7 4.2 . 8 Single Wall Wall Length (ft) 11 Wall Height (ft) 8 SW Designation SW2 Nom. Capacity (plf) 350 **2w/h 1.000 Red. Capacity (k) 3.850 Shear Distrib (%) 1.000 V, Shear (plf) E 290.1 V, Shear (plf) W 242.2 Vmax, Shear (plf) 290.1 Reduced Cap (plf) 350.0 OTM (k-ft) E 25.53 OTM (k-ft) W 21.32 OTMmax (k-ft) 25.53 OTM Couple (k) E 2.32 OTM Couple (k) W 1.94 OS Comb Couple (k) E 6.76 1. ,...,) E 39.40 A (k-ft) w 32.20 JTMmax (k-ft) 39.40 1 T (k) E 2.625 A T (k) W 1.970 ned Tmax (k) 2.625 Trib DL Length (ft) 4.00 Resist Force (k) 3.190 RM ASD (k-ft) 10.527 Total T (k) E 3.776 Total T (k) W 2.873 Total Tmax (k) 3.776 Hold Down MSTC52 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 6 (in) E 0.247 Cd*6 (in) E 0.990 Cd*6 / hsx E 0.010 Wall Rigidity RI 7.984 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 3.850 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 84 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SI1U C I( RALLCGINELRING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 1st Floor Shear Walls Grid 4.1 Page 3/3 Manual VE adjustment = kips Manual Vw adjustment = kips Total Wall Length = 11 ft 3.19 2.66 VE from above = kips VW from above = kips Average Shear = 420 plf VE Seismic Shear E = 1.43 kips VW Wind Shear W = 1.38 kips Total VE Seismic Shear E = 4.62 kips Total VW Wind Shear W = 4.05 kips 4.1 Grid Line 4.1 .1 1 4.1 . 2 4.1 . 3 4.1 . 4 4.1 . 5 4.1 . 6 4.1 . 7 4.1 . 8 Single Wall Wall Length (ft) 11 Wall Height (ft) 2.75 SW Designation SW3 Nom. Capacity (plf) 456 **2w/h 1.000 Red. Capacity (k) 5.016 Shear Distrib (%) 1.000 V, Shear (plf) E 419.8 V, Shear (plf) W 367.8 Vmax, Shear (plf) 419.8 Reduced Cap (plf) 456.0 OTM (k-ft) E 12.70 OTM (k-ft) W 11.13 OTMmax (k-ft) 12.70 OTM Couple (k) E 1.15 OTM Couple (k) W 1.01 OS Comb Couple (k) E 8.41 1. ,...,) E 52.10 A (k-ft) w 43.32 JTMmax (k-ft) 52.10 1 T (k) E 3.243 A T (k) W 2.445 ned Tmax (k) 3.243 Trib DL Length (ft) 9.00 Resist Force (k) 4.978 RM ASD (k-ft) 16.426 Total T (k) E 4.394 Total T (k) W 3.348 Total Tmax (k) 4.394 Hold Down HDU5 - - - - - - - Aa, Anchor Slip (in) 0.125 End Post Area (in2) 16.50 8 (in) E 0.090 Cd*8 (in) E 0.362 Cd*8 / hsx E 0.011 Wall Rigidity RI 24.857 *Combined OTM and T loads assume the shear wall is a rigid body and Total Capacity: 5.016 kips if tie -downs aren't continuous the shear wall may require special Capacity > Demand? OK design. Actual T loads are calculated and used by combining the upper wall OTM couple with the lower walls T loads. Combined OTM is only applicable if the upper walls are the same size, or smaller than the lower walls. **For single wall reduction: 1.25-0.125h/b (NDS 4.3.4.2) Project: E1396 Sheet No: 85 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SIR1 C I( RALLMANE RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 FLOOR TIES / HOLDOWNS STUD HOLDOWN MARK STRAP NAILING HOLDOWN ANCHORAGE ANCHOR BOLTS MSTC48B MSTC48B3 ( 54 ) 10d 3 common MSTC66B MSTC66B3 ( 56 ) 10d 3 common MSTC40 MSTC40 ( 36 ) 16d sinker MSTC52 MSTC52 ( 48 ) 16d sinker MSTC66 MSTC66 ( 68 ) 16d sinker STHD14 STHD14 (38) 16d N/A STHD14RJ sinker HDU2 HDU2 - SDS2.5 (6) SIDS 1/4" x 2 1/2" 5/8" 0 SSTB16 wood screws Anchor Bolt HDU5 HDU5 - SDS2.5 ( 14 ) SDS 1/4" x 2 1/2" 5/8" 0 SB 5/8x24 wood screws HDU8 HDU8 - SDS2.5 ( 20 ) SDS 1/4" x 2 1/2" 1 7/8" 0 SB 7/8x24 wood screws 1) Locate Holdown at each end of shearwall. 3) Extend foundation as required for holdown A.B. embedment 2) Cripple wall construct same as shearwall above. 4) Threaded rod and coupler as required. NAILING, SHOWN BELOW, WALL SHEATHING CORRESPONDS TO THE SHEAR IS NOT SHOWN FLOW NAILING IN THE SHEARWALL FOR CLARITY SCHEDULE SHEATHING PER UPPE SHEAR WALL SHEAR WAl STUC BASE PLATE SCHEDULE BAS SHEAR FLOW NAILING PLAT FLOOR DIAPHRAGM 1 RIM EDGE NAILING JOIST TOE NAIL, RIM JOIST OR TOP SHEAR FLOW NAILING SIMPSON L" FLOOR JOIST PER PLAN EDGE NAILING CLIPS PER SHE WALL SCHEDI SHEATHING PER SHEAR WALL SCHEDULE SECTION VIEW SF WHEN CALCULATED SHEAR FORCES ARE LARGER THAN 150 PLF, TOE -NAILING IS NOT ALLOWED. USE A SIMPSON LTP4 CLIP AS SHOWN ABOVE. OBLIQUE VIEW FLOOR DIAPHRAGM BLE PLATE Project: E1396 Sheet No: 86 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( Rdf.,\G6111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 SHEARWALL SCHEDULE MARK SHEATHING NAILING * SHEAR FLOW NAILING SILL PLATE ANCHORS" EDGES FIELD BASE PLATE TOE NAIL RIM BLOCKED JOIST OR TOP 7/16" OSB 8d @ 8d @ 16d @ 16d TOE NAILS @ 1/2" 0 Anchor Bolt SW1 1 side 6" o.c. 12" o.c. 8" o.c. 5" o.c. @ 48" o.c. & @ ends 7/16" OSB 8d @ 8d @ 16d @ Simpson LTP4 Clip 1/2" 0 Anchor Bolt SW2 1 side 4" o.c. 12" o.c. 5" o.c. @ 17" o.c. @ 32" o.c. & @ ends SW3 7/16" OSB 8d @ 8d @ 16d @ Simpson LTP4 Clip 1/2" 0 Anchor Bolt 1 side 3" o.c. 12" o.c. 4" o.c. @ 13" o.c. @ 24" o.c. & @ ends SW4 7/16" OSB 8d @ 8d @ 16d @ Simpson LTP4 Clip 1/2" 0 Anchor Bolt *** 1 side 2" o.c. 12" o.c. 3" o.c. @ 10" O.C. @ 19" o.c. & @ ends Use common nails for all nailing. ') Anchor bolt washers must be 3" x 3" x 0.229" thick. **) Framing members receiving edge nailing from abutting panels shall not be less than a single 3-inch nominal member or (2) 2x6 HF#2 stitched together with (2) rows of 16d @ 7" D.C. staggered. **) Sill plates & framing members receiving edge nailing from abutting panels shall not be less than a single 3-inch nominal member or (2) 2x6 HF#2 stitched together with (2) rows of 16d @ 5" o.c. staggered. ***) Sill plates & framing members receiving edge nailing from abutting panels shall not be less than a single 3-inch nominal member. Shear wall Capacity based on sheathing: SW 1 = 260*0.93 = 240 plf limited to 150 plf for toenailing rim joist per NDS 4.1.7 SW2 = 380*0.93 = 353 plf limited to 350 plf for single member at abutting panel edges SW3 = 490*0.93 = 456 plf SW4 = 640*0.93 = 595 plf per footnote 3 of AF&PA SDPWS-2008 Table 4.3A: capacity is reduced for framing material other than douglas-fir-larch or southern pine with specific gravity adjustment factor = [1-(0.5-SG)] = [1-(0.50-0.43)] = 0.93 per footnote 2 of AF&PA SDPWS-2008 Table 4.3A: 15/32" values can be used for 7/16" sheathing if studs are spaced at a maximum of 16" o.c. Shear Transfer from Diaphragm to Wall & Wall to Foundation Base plate nailing allowed shear 16d nails G = 0.43, 1 1/2" side member Z = 122 lb/nail. Z' = Z*Cd = 122 lb/nail * 1.6 = 195 lb/nail reduction for embedment into rim joist = 3.5" - 1.5" - 3/4" = 1.25" embed. 1.25 / (10 * 0.162) = 0.772 Z' reduced = 195 lb/nail * 0.772 = 151 lb/nail allowed shear from Simpson LTP5 = 535 lb/clip (horizontal) SW 1 = (151 lb/nail) / 150 Ib/ft = 12.1 in 8" o.c. ok SW2 = (151 lb/nail) / 350 Ib/ft = 5.2 in 5" o.c. ok SW3 = (151 lb/nail) / 456 Ib/ft = 4.0 in 4" o.c. ok SW4 = (151 lb/nail) / 595 Ib/ft = 3.0 in 3" o.c. ok Project: E1396 Sheet No: 87 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL AMI RING 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Rim joist and blocking to top plate of shear wall allowed shear from 16d toenailing w/ 1-1/2" HF side member = Z*Cd*Ctn = 122 lb/nail * 1.6 * 0.83 = 162 lb/nail allowed shear from Simpson LTP4 = 515 lb/clip (installed vertical or horizontal) SW 1 = (162 lb/nail) / 150 Ib/ft = 13.0 in 5" o.c. ok SW2 = (515 lb/clip) / 350 Ib/ft = 17.7 in 17" o.c. ok SW3 = (515 lb/clip) / 456 Ib/ft = 13.6 in 13" o.c. ok SW4 = (515 lb/clip) / 595 Ib/ft = 10.4 in 10" o.c. ok Sill plate anchors into foundation allowed shear from 1/2" dia. anchor bolt w/ 1-1/2" HF on conc. = Z*Cd = 590 lb/bolt * 1.6 = 944 lb/bolt SW 1 = (944 lb/bolt) / 150 Ib/ft = 75.5 in 48" o.c. ok SW2 = (944 lb/bolt) / 350 Ib/ft = 32.4 in 32" o.c. ok SW3 = (944 lb/bolt) / 456 Ib/ft = 24.8 in 24" o.c. ok SW4 = (944 lb/bolt) / 595 Ib/ft = 19.0 in 19" O.C. ok (2) 2x6 in lieu of 3x nominal at abutting panels and sill plates allowed shear from 16d w/ 1-1/2" HF side member = Z*Cd = 122 lb/nail * 1.6 = 195 lb/nail SW3 = (195 lb/nail) / 456 Ib/ft = 5.1 in (2) rows @ 7" o.c. ok SW4 = (195 lb/nail) / 595 Ib/ft = 3.9 in (2) rows @ 7" o.c. ok Project: E1396 Sheet No: 88 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,1,z1 [ I( RALL G6111AIN 0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Assumptions: Gravity Design: CANTILEVERED SUSPENDED ROOF TO WALL DESIGN Wind Uplift (C&C Simplified procedure for roof overhangs) _ -31 psf (unfactored) From ASCE Fig 30.5-1 Factored wind vertical uplift component for 4:12 pitch: Pitch = 0 /12 Angle = 0 degrees Vertical uplift component = -31 psf (unfactored) Wind factor = 0.6 Dead factor = 0.6 Design Loads: Factored uplift minus factored dead lead = -9.8 psf 25 psf Snow Load 15 psf Dead Load Simple Shear and Reaction Cantilever Length = 2 ft Truss Spacing = 2 ft o/c Gravity Shear at ledger per truss/rafter = 160 Ibs Uplift Shear at ledger per truss/rafter = -39 Ibs Prying moment Design Notes: Simpson A35 clip capacity = 595 Ibs OK Ledger connection required SIDS screws = 190 lb/screw OK Provide (2) screws top and bottom Assume (1) screw resists shear while the other screw resists pullout Moment @ wall = 160 lb-ft 1920 lb -in (Gravity Loading) Vertical distance between top and bottom chord at wall surface = 9.8 inches Pullout force = 197 Ibs #14 Screw NDS 12.213: 121 lb/screw Uplift (wind) prying force = 48.4 Ibs 121 lb * 1.15 * 2.5 in = 348 Ibs/screw Sheath bottom of trusses to connect to bottom Pullout force @ H3 clip = 160 Ibs Wall stud flexure check Stud spacing = 1.33 ft o/c Moment in studs assuming pin/pin = 106 lb-ft (Assume moment is near column end) ledger and provide (2) Simpson SIDS screws Simp H3=160lbs Capacity Provide blocking in wall bay to stiffen the wall in -plane 2x6 HF Stud capacity = 430 lb-ft OK OK wind loads will control the stud design Project: E1396 Sheet No: 89 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SIR1 C I( RALLMANIA9 ENG 9999 Harbour Place Suite 107 email@equilibria-engineering.com i Mukilteo, WA 98275 Phone: (360) 386-9476 GUARDRAIL AND HANDRAIL POST ANALYSIS Name/Description: I Steel guardrail system P = 200 Ibs Design point load W = 0 Ib/ft Design uniform load H = 42.00 in Height of rail system L = 72.00 in Post spacing and span of hand/guard railing E = 29.00 x10^3 ksi Modulus of Elasticity of material Fy = 36.00 ksi Note: 304 SS Fy = 30ksi, 316 SS = (30 ksi - 50 ksi) depending on specs Qb = 1.67 ASD Factor of Safety (1.67 Steel, 1.00 Wood & Fy = Fb) Fa = 21.60 Allowable stress I (rail) = 1.187 in4 Railing moment of inertia I (post) = 0.422 in4 Post moment of inertia Crail = EI/L 0.48 Rail stiffness Cpost = EI/H 0.29 Post stiffness CR = 1.641 Crail/Cpost for use in RAILING SYSTEM LOAD DISTRIBUTION chart Note: Higher CR values are more conservative Approximate Typical Pf Values: Pf (end post) = 0.850 End Posts of 2-span rail - 0.85 End posts of 3+ spans - 0.82 Pf (mid post) = 0.650 Intermediate posts of 2-span rail - 0.65 Intermediate posts of 3+ spans - 0.60 Note: Single span rails Pf = 1.00 End Post Mid Post Load from P 170 Load from W 0 Controlling Load 170 Moment 595 Shear 170 Req'd S 0.331 Req'd Z 0.331 Round approx S 0.194 Hollow approx S 1 0.245 130 Ibs Ibs Ibs lb-ft Ibs in3 in3 in3 in3 0 130 455 130 0.253 0.253 0.149 0.187 Approx S round is based on Shape Factor = 1.70 Approx S hollow is based on Shape Factor = 1.35 Post Deflection 1 0.343 Deflection Ratio H 122 OK 0.262 in H 160 OK P*Pf W*L (Mid) & W*L/2 (End) P control ling*h/(Fallow) Used for traditional design P control ling*h/(Fallow) Used for plastic moment design For plastic design (Z) use this to search for S for solid rounds For plastic design (Z) use this to search for S for hollow tubes (Used for quickly searching shapes) (Used for quickly searching shapes) PHA3/3E1 Check H/60 (L/120) deflection limitation Project: E1396 Sheet No: 90 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS ,SIR1 C I( RALLCGIN4ll9UNG 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 STEEL RECTANGULAR PLATE/BAR AND ROUND FLEXURAL DESIGN Name/Description: I Guardrail Post Note: Rounds and weak axis bending are designed only considering yielding Lb = 42.00 in d = t = S = Z = Fy = E = Qb = � = Cb = 1.50 in in in3 in3 ksi psi 1.50 0.563 0.844 36.00 2.90E+07 1.67 0.90 1.00 (Lb*d) / t^2 = 28.00 0.08*E / Fy = 64 1.9*E / Fy = 1531 Length between points that are either braced against lateral displacement of the compression region, or between points braced to prevent twist of the cross section Depth of rectangular bar Width of bar parallel to axis of bending (Thickness) Section modulus of a rectangle = t*dA2/6 Plastic section modulus of a rectangle = t*dA2/4 OR 1.5*My Note: (304 Stainless Fy = 30ksi) Note: (304 Stainless E = 28000 ksi, E = 23,600 ksi for deflection) ASD Factor of Safety LRFD Reduction Factor Compare to limits to determine failure mode Maximum for limit state of Yielding Maximum for limit state of Lateral Torsional Buckling Controlled by: I Section is controlled by Yielding AISC F11-1 Nominal capacity based on yielding AISC F11-1: My = 20.250 k-in Yielding strength, Fy*S 1.6*My = 32.400 k-in Yielding strength, 1.6* Fy*S Mp = 30.375 k-in Plastic yielding strength, Fy*Z AISC F11-1 Mn (yielding) = 30.375 k-in Nominal strength based on limit state of yielding (Lesser of 1.6My and Mp) Nominal capacity based on transition zone AISC F11-2: Mn (transition) = 30.375 k-in Nominal strength based on lesser of the transition zone or Mp Fcr = Mn (L.T.B.) = AIZ)U r"I "1-4 Lesser of Fcr * Sx and Mp Controlling nominal moment capacity: Mn = 30.375 k-in ASD Mn/f2b = 18.19 k-in 1.516 k-ft 18188.6 lb -in 1515.7 lb-ft Notes: Post moment = 595 lb-ft OK LRFD �Mn = 27.34 k-in 2.278 k-ft 27337.5 lb -in 2278.1 lb-ft Project: E1396 Sheet No: 91 2/21/2020 Equilibria Equilibria Structural Engineering, Inc PS "'°' C II RAL ENGIN LRIN0 9999 Harbour Place Suite 107 email@equilibria-engineering.com Mukilteo, WA 98275 Phone: (360) 386-9476 Beam: Guard Rail 6ft span Uniform Loads Magnitude(plf) Point Loads Magnitude(k) Span: 6 ft start end (ft) start end (plf) distance(ft) 0 6 0 0 3 0.2 Member: 1 1/4" thick x 2 1/4" wide bar E psi 2.90E+07 x = 3 (ft) in14 1.19 M @ x = 0.3 (k-ft) A inA2 2.81 V @ x = 0.1 (k) Results M allow = 2.82 (k-ft) Loading Diagram: Guard Rail 6ft span M max = 0.30 (k-ft) 2000 250 R1 = 0.10 (k) a 1500 200 1 R2 = 0.10 (k) 1000 1so Z 0 v max = 53 (psi) 500 100 0 50 a Deflect. = 0.045 (in) 0 0 = L 0 1 2 3 4 5 6 1589 6ft vertical rail support spacing Connection design: Guard post to deck rim Height = 42 inches Bolt size = 1/2" through bolts Force = 200 Ibs Edge distance = 1.5 * 1/2 in = 0.75 inches (Use 2") Duration factor = 1.60 (Edge distance derived from NDS table 11.5.1 C perp to grain unloaded edge) Assume minimum distancd between bolts is 3 1/4" (Moment arm = 3.25in+2in = 5.25in) Moment = 200 Ibs * 42 inches = 8400 lb -in Pullout = 8400 lb -in / 5.25 in + 200 lb = 1800 Ibs DTT2Z = 1800 allowable load per Simpson OK Attach to DTT2Z clip @ each guard Attach plate to beam with (4) 1/2" diameter x 3" bolts spaced minimum 3 1/4" apart Check weld assuming (2) weld lines that are 6" long each Sw = d12/3 = 6in^2/3 = 12 in2 f = M/Sw = 8400 lb -in / 12 in2 = 700 Win (Max shear due to moment) Shear due to shear = 200 lb / (6in * 2 lines) = 16.67 lb/in Total = sgrt(16.67A2+700^2) = 700.2 lb/in 1/4" fillet weld capacity = 0.928*4*1000 = 3712 lb/in > 700.2 lb/in OK Weld both sides of bar to plate w/ 1/4" fillet welds Project: E1396 Sheet No: 92 2/21/2020 aFORTE'Em. JOB SUMMARY REPORT E1396 2020-02-21 3rdFloor Member Name Results Current Solution Comments Span A Passed 1 piece(s) 11 7/8" TJI@ 210 @ 16" OC B20 Passed 1 piece(s) 1 3/4" x 11 7/8" 2.0E Microllam@ LVL B21 Passed 1 piece(s) 1 3/4" x 11 7/8" 2.0E Microllam@ LVL Span B Passed 1 piece(s) 11 7/8" TJI@ 210 @ 16" OC Span C IPassed 1 piece(s) 11 7/8" TJI@ 110 @ 16" OC 2nd Floor Member Name Results Current Solution Comments Span A Passed 1 piece(s) 11 7/8" TJI@ 360 @ 16" OC Span B Passed 1 piece(s) 11 7/8" TJI@ 110 @ 16" OC ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3 Weyerhaeuser File Name: E1396 2020-02-21 Page 1 / 8 a" O R T CM MEMBER REPORT PASSED 3rdFloor, Span A 1 piece(s) it 7/8" TJI@ 210 @ 16" OC Overall Length: 21' 6" 0 0 All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 667 @ 21' 1/2" 1005 (1.75") Passed (66%) 1.00 1.0 D + 1.0 L (Alt Spans) Shear (Ibs) 667 @ 21' 1/2" 1655 Passed (40%) 1.00 1.0 D + 1.0 L (Alt Spans) Moment (Ft-Ibs) 3036 @ 11' 11 5/16" 3795 Passed (80%) 1.00 1.0 D + 1.0 L (Alt Spans) Live Load Defl. (in) 0.431 @ 11' 7 5/8" 0.470 Passed (L/524) 1.0 D + 1.0 L (Alt Spans) Total Load Defl. (in) 0.550 @ 11' 8 15/16" 1 0.627 1 Passed (L/410) 1.0 D + 1.0 L (Alt Spans) TJ-ProTm Rating 34 1 34 1 Passed • Deflection criteria: LL (L/480) and TL (L/360). • Overhang deflection criteria: LL (2L/480) and TL (2L/360). • Top Edge Bracing (Lu): Top compression edge must be braced at 4' 1" o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 8' 8" o/c based on loads applied, unless detailed otherwise. • A structural analysis of the deck has not been performed. • Deflection analysis is based on composite action with a single layer of decking_2332Edge that is gluedAndNailedDown. • Additional considerations for the TJ-ProT`° Rating include: None. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Snow Total 1 - Stud wall - PSL 5.50" 5.50" 3.50" 423 645 115 1183 Blocking 2 - Hanger on 11 7/8" GLB beam 5.50" Hangers 1 1.75" / - z 175 526 -12 701/-12 See note s • Blocking Panels are assumed to carry no loads applied directly above them and the full load is applied to the member being designed. • At hanger supports, the Total Bearing dimension is equal to the width of the material that is supporting the hanger • s See Connector grid below for additional information and/or requirements. • 2 Required Bearing Length / Required Bearing Length with Web Stiffeners System : Floor Member Type : Joist Building Use : Residential Building Code : IBC 2015 Design Methodology : ASO Connector: Simpson Strong -Tie Support Model Seat Length Top Fasteners Face Fasteners Member Fasteners Accessories 2- Face Mount Hanger IUS2.06/11.88 2.00" N/A 10-10d 2-Strong-Grip Dead Floor Live Snow Vertical Loads Location (Side) Spacing (0.90) (1.00) (1.15) Comments 1 - Uniform (PSF) 0 to 21' 6" 16" 15.0 40.0 - Residential - Living Areas 2 - Point (PLF) 0 16" 126.0 12.0 77.0 Weyerhaeuser Notes Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to www.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Paget/8 a" O R T CM MEMBER REPORT PASSED 3rdFloor, B20 1 piece(s) 1 3/4" x 11 7/8" 2.0E Microllam@ LVL 2' ❑0 Overall Length: 21' 6" 19' 6" All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. 0 Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 720 @ 21' 1/2" 1969 (1.50") Passed (37%) 1.0 D + 1.0 L (Alt Spans) Shear (Ibs) 681 @ 315 3/8" 3948 Passed (17%) 1.00 1.0 D + 1.0 L (All Spans) Moment (Ft-Ibs) 3260 @ 11' 11 3/4" 8924 Passed (37%) 1.00 1.0 D + 1.0 L (Alt Spans) Live Load Defl.(in) 0.321 @ 11'7 5/8" 0.470 Passed (L/704) 1.0 D + 1.0 L (Alt Spans) Total Load Defl. (in) 0.437 @ 11' 9 1/8" 0.941 Passed (L/516) 1.0 D + 1.0 L (Alt Spans) • Deflection criteria: ILL (L/480) and TL (L/240). • Overhang deflection criteria: ILL (2L/480) and TL (2L/240). • Top Edge Bracing (Lu): Top compression edge must be braced at 14' 7" o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 21' 1" o/c based on loads applied, unless detailed otherwise. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Snow Total 1 - Stud wall - SPF 5.50" 5.50" 1.91" 696 571 400 1667 Blocking 2 - Hanger on 11 7/8" GLB beam 5.50" Hangers 1 1.50" 227 526 -25 753/-25 See note s • ciocKmg raneis are assumea to carry no ioaas appnea airecay aoove tnem ano the run ioaa is appneo to the memoer Deing oesignea. • At hanger supports, the Total Bearing dimension is equal to the width of the material that is supporting the hanger • s See Connector grid below for additional information and/or requirements. System : Floor Member Type : Flush Beam Building Use : Residential Building Code : IBC 2015 Design Methodology : ASO Connector: Simpson Strong -Tie Support Model Seat Length Top Fasteners Face Fasteners Member Fasteners Accessories 2 - Face Mount Hanger IUS1.81/9.5 2.00" N/A 8-10d 2-10dx1.5 Dead Floor Live Snow Vertical Loads Location (Side) Tributary Width (0.90) (1.00) (1.15) Comments 0 - Self Weight (PLF) 0 to 21' 112" N/A 6.1 1 - Uniform (PSF) 2' to 21' 6" (Front) 1' 4" 15.0 40.0 - Residential - Living Areas 2 - Uniform (PLF) 0 to 2' (Front) N/A 202.5 26.6 187.5 Weyerhaeuser Notes 1111101111111 i Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to Nww.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Page 3/8 a" O R T CM MEMBER REPORT PASSED 3rdFloor, B21 1 piece(s) 1 3/4" x 11 7/8" 2.0E Microllam@ LVL Overall Length: 20' 112" 1 18' 1 f2" 1❑ All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 1379 @ 2' 2 3/4" 4091 (5.50") Passed (34%) 1.0 D + 0.75 L + 0.75 S (All Spans) Shear (Ibs) 626 @ 3' 5 3/8" 3948 Passed (16%) 1.00 1.0 D + 1.0 L (All Spans) Moment (Ft-Ibs) 2738 @ 11' 3 3/8" 8924 Passed (31%) 1.00 1.0 D + 1.0 L (Alt Spans) Live Load Defl. (in) 0.234 @ 10' 10 7/8" 0.434 Passed (L/890) 1.0 D + 1.0 L (Alt Spans) Total Load Defl. (in) 0.314 @ 11' 1/2" 0.868 Passed (L/663) 1.0 D + 1.0 L (Alt Spans) • Deflection criteria: LL (L/480) and TL (L/240). • Overhang deflection criteria: LL (2L/480) and TL (2L/240). • Top Edge Bracing (Lu): Top compression edge must be braced at 17' 5" o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 19' 7" o/c based on loads applied, unless detailed otherwise. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Snow Total 1 - Stud wall - SPF 5.50" 5.50" 1.85" 679 532 402 1613 Blocking 2 - Hanger on 11 7/8" GLB beam 5.50" Hangers 1 1.50" 206 487 -27 693/-27 See note s • Blocking Panels are assumed to carry no loads applied directly above them and the full load is applied to the member being designed. • At hanger supports, the Total Bearing dimension is equal to the width of the material that is supporting the hanger • s See Connector grid below for additional information and/or requirements. System : Floor Member Type : Flush Beam Building Use : Residential Building Code : IBC 2015 Design Methodology : ASO Connector: Simpson Strong -Tie Support Model Seat Length Top Fasteners Face Fasteners Member Fasteners Accessories 2 - Face Mount Hanger IUS1.81/9.5 2.00" N/A 8-10d 2-10dx1.5 Dead Floor Live Snow Vertical Loads Location (Side) Tributary Width (0.90) (1.00) (1.15) Comments 0 - Self Weight (PLF) 0 to 19' 7" N/A 6.1 1 - Uniform (PSF) 2' to 20' 1/2" (Front) 1' 4" 15.0 40.0 - Residential - Living Areas 2 - Uniform (PLF) 0 to 2' (Front) N/A 202.5 26.6 187.5 Weyerhaeuser Notes I i Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to www.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Page 4 / 8 a" O R T CM MEMBER REPORT PASSED 3rdFloor, Span B 1 piece(s) it 7/8" TJI@ 210 @ 16" OC Overall Length: 19' 6" 0 0 All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 684 @ 19' 1/2" 1005 (1.75") Passed (68%) 1.00 1.0 D + 1.0 L (All Spans) Shear (Ibs) 684 @ 19' 1/2" 1655 Passed (41%) 1.00 1.0 D + 1.0 L (All Spans) Moment (Ft-Ibs) 3194 @ 9' 8 1/2" 3795 Passed (84%) 1.00 1.0 D + 1.0 L (All Spans) Live Load Defl. (in) 0.418 @ 9' 8 1/2" 0.467 Passed (L/536) 1.0 D + 1.0 L (All Spans) Total Load Defl. (in) 0.575 @ 9' 8 1/2" 1 0.622 1 Passed (L/390) 1.0 D + 1.0 L (All Spans) TJ-Pro'"" Rating 34 1 34 1 Passed • Deflection criteria: LL (L/480) and TL (L/360). • Top Edge Bracing (Lu): Top compression edge must be braced at 4' o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 19' 1" o/c based on loads applied, unless detailed otherwise. • A structural analysis of the deck has not been performed. • Deflection analysis is based on composite action with a single layer of decking_2332Edge that is gluedAndNailedDown. • Additional considerations for the TJ-Pro'" Rating include: None. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Total 1 - Stud wall - SPF 5.50" 5.50" 1.75" 194 518 712 Blocking 2 - Hanger on 11 7/8" PSL beam 5.50" Hangers 1 1.75" / - z 196 522 718 See note s • Blocking Panels are assumed to carry no loads applied directly above them and the full load is applied to the member being designed. • At hanger supports, the Total Bearing dimension is equal to the width of the material that is supporting the hanger • s See Connector grid below for additional information and/or requirements. • Required Bearing Length / Required Bearing Length with Web Stiffeners System : Floor Member Type : Joist Building Use : Residential Building Code : IBC 2015 Design Methodology : ASD Connector: Simpson Strong -Tie Support Model Seat Length Top Fasteners Face Fasteners Member Fasteners Accessories 2 - Face Mount Hanger IUS2.06/11.88 2.00" N/A 10-10d 2-Strong-Grip Dead Floor Live Vertical Load Location (Side) Spacing (0.90) (1.00) Comments 1 - Uniform (PSF) 0 to 19' 6" 16" 15.0 40.0 Residential - Living Areas Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to www.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Page 5/8 a" O R T CM MEMBER REPORT PASSED 3rdFloor, Span C 1 piece(s) it 7/8" TJI@ 110 @ 16" OC Overall Length: 13' 2' All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 448 @ 6 3/4" 910 (1.75") Passed (49%) 1.00 1.0 D + 1.0 L (All Spans) Shear (Ibs) 448 @ 6 3/4" 1560 Passed (29%) 1.00 1.0 D + 1.0 L (All Spans) Moment (Ft-Ibs) 1371 @ 6' 8 1/8" 3160 Passed (43%) 1.00 1.0 D + 1.0 L (All Spans) Live Load Defl. (in) 0.098 @ 6' 8 1/8" 0.306 Passed (L/999+) 1.0 D + 1.0 L (All Spans) Total Load Defl. (in) 0.135 @ 6' 8 1/8" 1 0.408 1 Passed (L/999+) 1.0 D + 1.0 L (All Spans) TJ-Pro'"" Rating 53 1 34 1 Passed • Deflection criteria: LL (L/480) and TL (L/360). • Top Edge Bracing (Lu): Top compression edge must be braced at 4' 10" o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 12' 6" o/c based on loads applied, unless detailed otherwise. • A structural analysis of the deck has not been performed. • Deflection analysis is based on composite action with a single layer of decking_2332Edge that is gluedAndNailedDown. • Additional considerations for the TJ-Pro'"' Rating include: None. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Total 1 - Hanger on 11 7/8" GLB beam 6.75" Hanger' 1.75" / - z 134 356 490 See note 1 2 - Stud wall - PSL 5.50" 4.25" 1 1.75" 130 346 476 1 1/4" Rim Board • Rim Board is assumed to carry all loads applied directly above it, bypassing the member being designed. • At hanger supports, the Total Bearing dimension is equal to the width of the material that is supporting the hanger • 1 See Connector grid below for additional information and/or requirements. • z Required Bearing Length / Required Bearing Length with Web Stiffeners System : Floor Member Type : Joist Building Use : Residential Building Code : IBC 2015 Design Methodology : ASD Connector: Simpson Strong -Tie Support Model Seat Length Top Fasteners Face Fasteners Member Fasteners Accessories 1 - Face Mount Hanger IUS1.81/11.88 2.00" N/A 10-10d 2-Strong-Grip Dead Floor Live Vertical Load Location (Side) Spacing (0.90) (1.00) Comments 1 - Uniform (PSF) 0 to 13' 2" 16" 15.0 40.0 Residential - Living Areas Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to www.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Page 6/8 a" O R T CM MEMBER REPORT PASSED 2nd Floor, Span A 1 piece(s) it 7/8" TJI@ 360 @ 16" OC Overall Length: 21' 1" L 21' 1 " r 0 ❑2 All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 772 @ 20' 8 1/2" 1505 (3.50") Passed (51%) 1.00 1.0 D + 1.0 L (All Spans) Shear (Ibs) 746 @ 3 1/2" 1705 Passed (44%) 1.00 1.0 D + 1.0 L (All Spans) Moment (Ft-Ibs) 3852 @ 30' 5 1/2" 6180 Passed (62%) 1.00 1.0 D + 1.0 L (All Spans) Live Load Defl. (in) 0.477 @ 10' 5 1/2" 0.512 Passed (L/516) 1.0 D + 1.0 L (All Spans) Total Load Defl. (in) 0.656 @ 10' 5 1/2" 1 1.025 1 Passed (L/375) 1.0 D + 1.0 L (All Spans) TJ-Pro'"" Rating 39 1 35 1 Passed • Deflection criteria: LL (L/480) and TL (L/240). • Top Edge Bracing (Lu): Top compression edge must be braced at 4' 8" o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 21' o/c based on loads applied, unless detailed otherwise. • A structural analysis of the deck has not been performed. • Deflection analysis is based on composite action with a single layer of decking_2332Edge that is gluedAndNailedDown. • Additional considerations for the TJ-Pro'" Rating include: 1/2" Gypsum ceiling. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Total 1 - Stud wall - SPF 3.50" 3.50" 1.75" 209 558 767 Blocking 2 - Stud wall - SPF 5.50" 4.25" 1 1.75" 213 567 780 1 1/4" Rim Board • Rim Board is assumed to carry all loads applied directly above it, bypassing the member being designed. • Blocking Panels are assumed to carry no loads applied directly above them and the full load is applied to the member being designed. Dead Floor Live Vertical Load Location (Side) Spacing (0.90) (1.00) Comments 1 - Uniform (PSF) 0 to 21' 1" 16" 15.0 40.0 Residential - Living Areas System : Floor Member Type : Joist Building Use : Residential Building Code : IBC 2015 Design Methodology : ASD Weyerhaeuser Notes Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to www.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Page 7/8 a" O R T CM MEMBER REPORT PASSED 2nd Floor, Span B 1 piece(s) it 7/8" TJI@ 110 @ 16" OC Overall Length: 13' 3' 1I 0 All locations are measured from the outside face of left support (or left cantilever end). All dimensions are horizontal. Design Results Actual @ Location Allowed Result LDF Load: Combination (Pattern) Member Reaction (Ibs) 1467 @ 1' 7 3/4" 1935 (3.50") Passed (76%) 1.00 1.0 D + 1.0 L (All Spans) Shear (Ibs) 919 @ 1' 6" 1560 Passed (59%) 1.00 1.0 D + 1.0 L (All Spans) Moment (Ft-Ibs) -1431 @ 1' 7 3/4" 3160 Passed (45%) 1.00 1.0 D + 1.0 L (All Spans) Live Load Defl. (in) 0.070 @ 72 5/8" 0.279 Passed (L/999+) 1.0 D + 1.0 L (Alt Spans) Total Load Defl. (in) 0.068 @ 0 0.200 1 Passed (2L/586) 1.0 D + 1.0 L (Alt Spans) TJ-Pro'"" Rating 60 35 1 Passed • Deflection criteria: LL (L/480) and TL (L/240). • Overhang deflection criteria: LL (2L/480) and TL (2L/0.2"). • Top Edge Bracing (Lu): Top compression edge must be braced at 6' 4" o/c based on loads applied, unless detailed otherwise. • Bottom Edge Bracing (Lu): Bottom compression edge must be braced at 4' 9" o/c based on loads applied, unless detailed otherwise. • A structural analysis of the deck has not been performed. • Deflection analysis is based on composite action with a single layer of decking_2332Edge that is gluedAndNailedDown. • Additional considerations for the TJ-ProT`° Rating include: 1/2" Gypsum ceiling. Supports Bearing Length Loads to Supports (Ibs) Accessories Total Available Required Dead Floor Live Snow Total 1 - Stud wall - SPF 3.50" 3.50" 3.50" 618 849 101 1568 Blocking 2 - Hanger on 11 7/8" PSL beam 5.50" Hangers 1 1.75" / - z 58 322/-41 -13 380/-54 See note s • Blocking Panels are assumed to carry no loads applied directly above them and the full load is applied to the member being designed. • At hanger supports, the Total Bearing dimension is equal to the width of the material that is supporting the hanger • s See Connector grid below for additional information and/or requirements. • 2 Required Bearing Length / Required Bearing Length with Web Stiffeners System : Floor Member Type : Joist Building Use : Residential Building Code : IBC 2015 Design Methodology : ASO Connector: Simpson Strong -Tie Support Model Seat Length Top Fasteners Face Fasteners Member Fasteners Accessories 2- Face Mount Hanger IUS1.81/11.88 2.00" N/A 10-10d 2-Strong-Grip Dead Floor Live Snow Vertical Loads Location (Side) Spacing (0.90) (1.00) (1.15) Comments 1 - Uniform (PSF) 0 to 13' 3" 16" 15.0 40.0 - Residential - Living Areas 2 - Point (PLF) 0 16" 308.0 299.0 66.0 Weyerhaeuser Notes Weyerhaeuser warrants that the sizing of its products will be in accordance with Weyerhaeuser product design criteria and published design values. Weyerhaeuser expressly disclaims any other warranties related to the software. Use of this software is not intended to circumvent the need for a design professional as determined by the authority having jurisdiction. The designer of record, builder or framer is responsible to assure that this calculation is compatible with the overall project. Accessories (Rim Board, Blocking Panels and Squash Blocks) are not designed by this software. Products manufactured at Weyerhaeuser facilities are third -party certified to sustainable forestry standards. Weyerhaeuser Engineered Lumber Products have been evaluated by ICC-ES under evaluation reports ESR-1153 and ESR-1387 and/or tested in accordance with applicable ASTM standards. For current code evaluation reports, Weyerhaeuser product literature and installation details refer to www.weyerhaeuser.com/woodproducts/document-library. The product application, input design loads, dimensions and support information have been provided by ForteWEB Software Operator ForteWEB Software Operator Job Notes Jason Lindquist Equilibria Structural Engineering Inc PS (360) 386-9476 jason@equilibria-engineering.com 2/21/2020 6:10:41 PM UTC ForteWEB v2.3, Engine: V8.0.0.21, Data: V7.3.2.0 Weyerhaeuser File Name: E1396 2020-02-21 Page 8/8 Project: E1396 2019-01-14 Jason@equilibria-engineering.com Location: HD10-HD12 Equilibria Structural Engineering Multi -Loaded Multi -Span Beam 9999 Harbour Place Suite 107 of [2015 International Building Code(2015 NDS)] Mukilteo, WA 98275 5.125 IN x 7.5 IN x 7.5 FT (2.5 + 2.5 + 2.5) StruCalc Version 10.0.1.6 10/28/2019 3:08:44 PM 24F-V4 - Visually Graded Western Species - Dry Use Section Adequate By: 33.1 % Controlling Factor: Shear DEFLECTIONS Left Center Right LOADING DIAGRAM Live Load 0.00 IN L/MAX 0.01 IN L/5879 0.00 IN L/MAX Dead Load 0.00 in 0.00 in 0.00 in Total Load 0.00 IN L/MAX 0.01 IN L/4132 0.00 IN L/MAX Live Load Deflection Criteria: L/240 Total Load Deflection Criteria: L/360 REACTIONS A B C D Live Load 639 lb 4259 lb 4811 lb 886 lb Dead Load 161 lb 2292 lb 2821 lb 370 lb Total Load 800 lb 6551 lb 7632 lb 1256 lb Uplift (1.5 F.S) -300 lb 0 lb 0 lb -168 lb Bearing Length 0.24 in 1.97 in 2.29 in 0.38 in BEAM DATA Left Center Right Span Length 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft 2.5 ft Unbraced Length -Top 0 ft 0 ft 0 ft Unbraced Length -Bottom 2.5 ft 2.5 ft 2.5 ft Live Load Duration Factor 1.00 UNIFORM LOADS Left Center Right Notch Depth 0.00 Uniform Live Load 0 plf 0 plf 0 plf MATERIAL PROPERTIES Uniform Dead Load 0 plf 0 plf 0 plf 24F-V4 - Visually Graded Western Species Beam Self Weight 8 plf 8 plf 8 plf Base Values Adjusted Total Uniform Load 8 plf 8 plf 8 plf Bending Stress: Fb = 2400 psi Controlled by: POINT LOADS -CENTER SPAN Fb_cmpr = 1850 psi Fb' = 2400 psi Load Number One Cd=1.00 Live Load 4352 lb Shear Stress: Fv = 265 psi Fv' = 265 psi 38 2 Dead Load 3lb Cd=1.00 Location 1.25 ft Modulus of Elasticity: E = 1800 ksi E' = 1800 ksi Comp. l to Grain: Fe - L = 650 psi Fc -1' = 650 psi TRAPEZOIDAL LOADS - LEFT SPAN Load Number One Controlling Moment: 3313 ft-lb Left Live Load 559 plf 1.25 Ft from left support of span 2 (Center Span) Left Dead Load 330 plf Created by combining all dead loads and live loads on span(s) 2 Right Live Load 559 plf Controlling Shear: -5101 lb Right Dead Load 330 plf 3.0 Ft from left support of span 2 (Center Span) Load Start 0 ft Created by combining all dead loads and live loads on span(s) 2, 3 Load End 2.5 ft Load Length 2.5 ft Comparisons with required sections: Read Provided CENTER SPAN Section Modulus: 16.57 in3 48.05 in3 Load Number One Two Area (Shear): 28.87 in2 38.44 in2 Left Live Load 559 plf 796 plf Moment of Inertia (deflection): 15.7 in4 180.18 in4 Left Dead Load 330 plf 535 plf Moment: 3313 ft-lb 9609 ft-lb Right Live Load 559 plf 796 plf Shear: -5101 lb 6791 lb Right Dead Load 330 plf 535 plf Load Start 0 ft Load End 1.25 ft 1.25 ft 2.5 ft NOTES Load Length 1.25 ft 1.25 ft RIGHT SPAN Load Number One Left Live Load 796 plf Left Dead Load 535 plf Right Live Load 796 plf Right Dead Load 535 plf Load Start 0 ft Load End 2.5 ft Load Length 2.5 ft VMD DIAGRAM 6000 4385 Ibs @ Moment Deflection 2 ft 3000 Shear (Ibs) 0 -3000 -6000 -51011bs@5ft 3313 ft-Ibs @ 4 ft 4000 2000 (ft-lb) 0 -2000 -4000 -1810 ft-Ibs @ 5 ft -0.003 in @ 1.5 ft -0.01 0 (in) 0 0 0.01 0.007 in @ 3.8 ft 2.5 ft 2.5 ft 2.5 ft Project: E1396 2019-01-14 Location: C1 Column [2015 International Building Code(2015 NDS)] 5.5INx7.5INx8.0FT #2 - Douglas -Fir -Larch - Dry Use Section Adequate By: 28.1 % Live Load: Vert-LL-Rxn = 11760 lb Dead Load: Vert-DL-Rxn = 7852 lb Total Load: Vert-TL-Rxn = 19612 lb COLUMN DATA Total Column Length: 8 ft Unbraced Length (X-Axis) Lx: 8 ft Unbraced Length (Y-Axis) Ly: 8 ft Column End Condition-K (e): 1 Axial Load Duration Factor 1.15 COLUMN PROPERTIES #2 - Douglas -Fir -Larch Base Values Adjusted Compressive Stress: Fc = 700 psi Fc' = 661 psi Cd=1.15 Cp=0.82 Bending Stress (X-X Axis): Fbx = 750 psi Fbx' = 863 psi Cd=1.15 CF=1.00 Bending Stress (Y-Y Axis): Fby = 750 psi Fby' = 863 psi Cd=1.15 CF=1.00 Modulus of Elasticity: E = 1300 ksi E' = 1300 ksi Column Section (X-X Axis): dx = 7.5 in Column Section (Y-Y Axis): dy = 5.5 in Area: A = 41.25 in2 Section Modulus (X-X Axis): Sx = 51.56 in3 Section Modulus (Y-Y Axis): Sy = 37.81 in3 Slenderness Ratio: Lex/dx = 12.8 Ley/dy = 17.45 Column Calculations (Controlling Case Only): Controlling Load Case: Axial Total Load Only (L + D) Actual Compressive Stress: Fc = 475 psi Allowable Compressive Stress: Fc' = 661 psi Eccentricity Moment (X-X Axis): Mx -ex = 0 ft-lb Eccentricity Moment (Y-Y Axis): My-ey = 0 ft-lb Moment Due to Lateral Loads (X-X Axis): Mx = 0 ft-lb Moment Due to Lateral Loads (Y-Y Axis): My = 0 ft-lb Bending Stress Lateral Loads Only (X-X Axis): Fbx = 0 psi Allowable Bending Stress (X-X Axis): Fbx' = 863 psi Bending Stress Lateral Loads Only (Y-Y Axis): Fby = 0 psi Allowable Bending Stress (Y-Y Axis): Fby' = 863 psi Combined Stress Factor: CSF = 0.72 jason@equilibria-engineering.com Equilibria Structural Engineering 9999 Harbour Place Suite 107 Mukilteo, WA 98275 StruCalc Version 10.0.1.6 8 ft B A AXIAL LOADING Live Load: PL = 11760 lb Dead Load: PD = 7780 lb Column Self Weight: CSW = 72 lb Total Axial Load: PT = 19612 lb 10/28/2019 3:08:46 PM of Project: E1396 2019-01-14 Location: Rooflet Rafters Floor Joist [2015 International Building Code(2015 NDS)] 1.5INx3.5INx4.0FT(2+2)@24O.C. #2 - Hem -Fir - Dry Use Section Adequate By: 128.2% Controlling Factor: Deflection Live Load -0.01 IN L/3771 0.06 IN 2L/830 Dead Load 0.00 in 0.03 in Total Load -0.01 IN L/2763 0.09 IN 2L/548 Live Load Deflection Criteria: L/360 Total Load Deflection Criteria: L/240 Live Load 50 lb 200 lb Dead Load 0 lb 120 lb Total Load 50 lb 320 lb Uplift (1.5 F.S) -50 lb 0 lb Bearing Length 0.08 in 0.53 in SUPPORT LOADS A B Live Load 25 plf 100 plf Dead Load 0 plf 60 plf Total Load 25 olf 160 olf MATERIAL PROPERTIES #2 - Hem -Fir Base Values Adjusted Bending Stress: Fb = 850 psi Fb' = 1448 psi Cd=1.00 C1=0.99 CF=1.50 Cr-1.15 Shear Stress: Fv = 150 psi Fv' = 150 psi Cd=1.00 Modulus of Elasticity: E = 1300 ksi E' = 1300 ksi Comp.1 to Grain: Fc - L = 405 psi Fc - L' = 405 psi Controlling Moment: -160 ft-lb Over right support of span 2 (Center Span) Created by combining all dead loads and live loads on span(s) 2, 3 Controlling Shear: -160 lb At right support of span 2 (Center Span) Created by combining all dead loads and live loads on span(s) 2, 3 Comparisons with required sections: Read Provided Section Modulus: 1.33 in3 3.06 in3 Area (Shear): 1.6 in2 5.25 in2 Moment of Inertia (deflection): 2.35 in4 5.36 in4 Moment: -160 ft-lb 370 ft-lb Shear: -160 lb 525lb NOTES jason@equilibria-engineering.com Equilibria Structural Engineering 9999 Harbour Place Suite 107 of Mukilteo, WA 98275 StruCalc Version 10.0.1.6 10/28/2019 3:08:46 PM A 2 ft 2 ft JOIST DATA Center Right Span Length 2 ft 2 ft Unbraced Length -Top 0 ft 0 ft Unbraced Length -Bottom 0 ft 0 ft Floor sheathing applied to top of joists -top of joists fully braced. Floor Duration Factor 1.00 Uniform Floor Loading Center Right Live Load ILL = 25 psf 25 psf Dead Load DL = 15 psf 15 psf Total Load TL = 40 psf 40 psf TL Adi. For Joist Spacing wT = 80 olf 80 olf VMD DIAGRAM 200 1601bs @ 2 ft 100 Shear (Ibs) 0 -100 -200 -160 Ibs @ 2 ft 200 100 Moment (ft-lb) 0 -100 -200 -160 ft-Ibs @ 2 ft -0.09 -0.009 in @ 1.2 ft -0.04 Deflection (in) 0 0.04 0.09 0.088 in @ 4 ft 2ft 2ft Project: E1396 2019-01-14 Jason@equilibria-engineering.com Location: HD10-HD12 .75(S+L)+D Equilibria Structural Engineering Multi -Loaded Multi -Span Beam 9999 Harbour Place Suite 107 of [2015 International Building Code(2015 NDS)] Mukilteo, WA 98275 5.125 IN x 7.5 IN x 8.25 FT (2.8 + 2.8 + 2.8) StruCalc Version 10.0.1.6 10/28/2019 3:08:48 PM 24F-V4 - Visually Graded Western Species - Dry Use Section Adequate By: 53.2% Controlling Factor: Shear Live Load 0.00 IN L/MAX 0.01 IN L/6361 0.00 IN L/MAX Dead Load 0.00 in 0.00 in 0.00 in Total Load 0.00 IN L/MAX 0.01 IN L/4085 0.00 IN L/MAX Live Load Deflection Criteria: L/240 Total Load Deflection Criteria: L/360 Live Load 527 lb 3325 lb 3781 lb 731 lb Dead Load 195 lb 2387 lb 2969 lb 424 lb Total Load 722 lb 5712 lb 6750 lb 1155 lb Uplift (1.5 F.S) -182 lb 0 lb 0 lb -34 lb Bearing Length 0.22 in 1.71 in 2.03 in 0.35 in BEAM DATA Left Center Right Span Length 2.75 ft 2.75 ft 2.75 ft Unbraced Length -Top 0 ft 0 ft 0 ft Unbraced Length -Bottom 2.75 ft 2.75 ft 2.75 ft Live Load Duration Factor 1.00 Notch Depth 0.00 MATERIAL PROPERTIES 24F-V4 - Visually Graded Western Species Base Values Adjusted Bending Stress: Fb = 2400 psi Controlled by: Fb_cmpr = 1850 psi Fb' = 2400 psi Cd=1.00 Shear Stress: Fv = 265 psi Fv' = 265 psi Cd=1.00 Modulus of Elasticity: E = 1800 ksi E' = 1800 ksi Comp. l to Grain: Fe - L = 650 psi Fc -1' = 650 psi Controlling Moment: 3067 ft-lb 1.38 Ft from left support of span 2 (Center Span) Created by combining all dead loads and live loads on span(s) 2 Controlling Shear: -4432 lb 3.0 Ft from left support of span 2 (Center Span) Created by combining all dead loads and live loads on span(s) 2, 3 Comparisons with required sections: Read Provided Section Modulus: 15.34 in3 48.05 in3 Area (Shear): 25.09 in2 38.44 in2 Moment of Inertia (deflection): 15.88 in4 180.18 in4 Moment: 3067 ft-lb 9609 ft-lb Shear: -4432lb 6791 lb 75 ft 0 2.75 ft 75 Uniform Live Load 0 plf 0 plf 0 plf Uniform Dead Load 0 plf 0 plf 0 plf Beam Self Weight 8 plf 8 plf 8 plf Total Uniform Load 8 Of 8 Of 8 Of Load Number One Live Load 3264 lb Dead Load 2338 lb Location 1.38 ft Load Number One Left Live Load 419 plf Left Dead Load 330 plf Right Live Load 419 plf Right Dead Load 330 plf Load Start 0 ft Load End 2.75 ft Load Length 2.75 ft CENTER SPAN Load Number One Two Left Live Load 419 plf 597 plf Left Dead Load 330 plf 535 plf Right Live Load 419 plf 597 plf Right Dead Load 330 plf 535 plf Load Start 0 ft 1.38 ft Load End 1.38 ft 2.75 ft Load Length 1.38 ft 1.37 ft RIGHT SPAN Load Number One Left Live Load 597 plf Left Dead Load 535 plf Right Live Load 597 plf Right Dead Load 535 plf Load Start 0 ft Load End 2.75 ft Load Lenoth 2.75 ft VMD DIAGRAM 5000 Moment Deflection 3779 Ibs @ 3 ft 2500 Shear (Ibs) 0 -2500 -5000 -4432 Ibs @ 6 ft 3067 ft-Ibs @ 4 ft 4000 2000 (ft-lb) 0 -2000 -4000 -1761 ft-Ibs @ 6 ft -0.01 -0.003 in @ 1.7 ft 0 (in) 0 0 0.01 0.008 in @ 4.1 ft 2.75ft 2.75ft 2.75ft Project: E1396 2019-01-14 Jason@equilibria-engineering.com Location: HD10-HD12 S+D Equilibria Structural Engineering Multi -Loaded Multi -Span Beam 9999 Harbour Place Suite 107 of [2015 International Building Code(2015 NDS)] Mukilteo, WA 98275 5.125 IN x 7.5 IN x 8.25 FT (2.8 + 2.8 + 2.8) StruCalc Version 10.0.1.6 10/28/2019 3:08:49 PM 24F-V4 - Visually Graded Western Species - Dry Use Section Adequate By: 64.8% Controlling Factor: Shear Live Load 0.00 IN L/MAX 0.00 IN L/6776 0.00 IN L/MAX Dead Load 0.00 in 0.00 in 0.00 in Total Load 0.00 IN L/MAX 0.01 IN L/4238 0.00 IN L/MAX Live Load Deflection Criteria: L/240 Total Load Deflection Criteria: L/360 Live Load 583 lb 3338 lb 3122 lb 486 lb Dead Load 195 lb 2387 lb 2969 lb 424 lb Total Load 778 lb 5725 lb 6091 lb 910 lb Uplift (1.5 F.S) -166 lb 0 lb 0 lb -11 lb Bearing Length 0.23 in 1.72 in 1.83 in 0.27 in BEAM DATA Left Center Right Span Length 2.75 ft 2.75 ft 2.75 ft Unbraced Length -Top 0 ft 0 ft 0 ft Unbraced Length -Bottom 2.75 ft 2.75 ft 2.75 ft Live Load Duration Factor 1.00 Notch Depth 0.00 MATERIAL PROPERTIES 24F-V4 - Visually Graded Western Species Base Values Adjusted Bending Stress: Fb = 2400 psi Controlled by: Fb_cmpr = 1850 psi Fb' = 2400 psi Cd=1.00 Shear Stress: Fv = 265 psi Fv' = 265 psi Cd=1.00 Modulus of Elasticity: E = 1800 ksi E' = 1800 ksi Comp. l to Grain: Fe - L = 650 psi Fc -1' = 650 psi Controlling Moment: 2964 ft-lb 1.38 Ft from left support of span 2 (Center Span) Created by combining all dead loads and live loads on span(s) 2 Controlling Shear: -4120 lb 3.0 Ft from left support of span 2 (Center Span) Created by combining all dead loads and live loads on span(s) 2, 3 Comparisons with required sections: Read Provided Section Modulus: 14.82 in3 48.05 in3 Area (Shear): 23.32 in2 38.44 in2 Moment of Inertia (deflection): 15.31 in4 180.18 in4 Moment: 2964 ft-lb 9609 ft-lb Shear: -4120lb 6791 lb 75 ft 0 2.75 ft 75 Uniform Live Load 0 plf 0 plf 0 plf Uniform Dead Load 0 plf 0 plf 0 plf Beam Self Weight 8 plf 8 plf 8 plf Total Uniform Load 8 Of 8 Of 8 Of Load Number One Live Load 3138 lb Dead Load 2338 lb Location 1.38 ft Load Number One Left Live Load 474 plf Left Dead Load 330 plf Right Live Load 474 plf Right Dead Load 330 plf Load Start 0 ft Load End 2.75 ft Load Length 2.75 ft CENTER SPAN Load Number One Two Left Live Load 474 plf 390 plf Left Dead Load 330 plf 535 plf Right Live Load 474 plf 390 plf Right Dead Load 330 plf 535 plf Load Start 0 ft 1.38 ft Load End 1.38 ft 2.75 ft Load Length 1.38 ft 1.37 ft RIGHT SPAN Load Number One Left Live Load 390 plf Left Dead Load 535 plf Right Live Load 390 plf Right Dead Load 535 plf Load Start 0 ft Load End 2.75 ft Load Lenoth 2.75 ft VMD DIAGRAM 5000 3757 Ibs @ 3 ft 2500 Shear (Ibs) 0 -2500 -5000 41201bs@6ft 2964 ft-Ibs @ 4 ft 3000 1500 Moment (ft-lb) 0 -1500 -3000 -1696 ft-Ibs @ 6 ft -0.01 -0.003 in @ 1.7 ft 0 Deflection (in) 0 0 0.01 0.008 in @ 4.1 ft 2.75 ft 2.75 ft 2.75 ft Jason Lindquist, P.E., S.E. 6ft cantilevered retaining wall EQUILIBRIA STRUCTURAL ENGINEEI Detail 1i; 33 ft i� [--3.25 ft----� Check Summary Concrete f'c = 2500 psi Rebar Fy = 60000 psi Unit Weight = 150 Ib/ft3 #5 @ 18 in (S&T) #5@18in #5 @ 18 in (lapped dowels) Ratio Check Provided Required Combination ----- Stability Checks ----- v/ 0.699 Overturning 2.15 1.50 1.OD + 1.OL+ 1.OH v/ 0.823 Bearing Pressure 2500 psf 2058 psf 1.OD + 1.01- + 1.OH v/ 0.835 Bearing Eccentricity 5.42 in 6.49 in 1.OD + 1.01- + 1.OH ----- Toe Checks ----- v/ 0.277 Shear 4.8 k/ft 1.33 k/ft 1.2D + 1.61- + 1.6H v/ 0.740 Moment 2.5 ft-k/ft 1.85 ft-k/ft 1.2D + 1.61-+ 1.6H ----- Heel Checks ----- ,/ 0.332 Shear 4.8 k/ft 1.59 k/ft 1.4D v/ 0.341 Moment 2.5 ft-k/ft 0.85 ft-k/ft 1.2D + 1.61-+ 1.6H ----- Stem Checks ----- �/ 0.775 Moment 3.49 ft.k/ft 2.71 ft-k/ft 1.2D + 1.61-+ 1.6H 0.357 Shear 3.6 k/ft 1.28 k/ft 1.2D + 1.61- + 1.6H v 0.223 Max Steel 0.0180 0.0040 1.2D + 1.61- + 1.6H v/ 0.774 Min Steel 0.02 in2fin 0.01 in2fin 1.2D + 1.61-+ 1.6H �/ 0.905 Base Development 9 in 8.14 in 1.2D + 1.61- + 1.6H v 0.780 Lap Splice Length 30 in 23.4 in 1.2D + 1.61- + 1.6H V/ 0.000 Horz Bar Rho 0.0000 0.0000 1.2D + 1.61- + 1.6H V 1.000 Horz Bar Spacing 18 in 18 in 1.2D + 1.61- + 1.6H Use basic criteria from common projec...Yes Building Code IBC 2015 Concrete Load Combs IBC 2015 (Strength) Masonry Load Combs ASCE 7-10 (ASD) Stability Load Combs IBC Retaining Wall St... Apply Sds Factor to Seismic Combinat... No Restrained Against Sliding Yes Neglect Bearing At Heel Yes Use Vert. Comp. for OT Yes Use Vert. Comp. for Sliding Yes Use Vert. Comp. for Bearing Yes Use Surcharge for Sliding & OT Yes Use Surcharge for Bearing Yes Neglect Soil Over Toe No Neglect Backfill Wt. for Coulomb No Factor Soil Weight As Dead Yes Use Passive Force for OT Yes Assume Pressure To Top Yes Extend Backfill Pressure To Key Bottom No Use Toe Passive Pressure for Bearing No Required F.S. for OT 1.50 Required F.S. for Sliding 1.50 Has Different Safety Factors for Seismic No Allowable Bearing Pressure 2500 psf Req'd Bearing Location Middle third Wall Friction Angle 25° Friction Coefficent 0.35 Soil Reaction Modulus 172800 Ib/ft3 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 1 of 2 Monday 10/28/19 3:30 PM Jason Lindquist, P.E., S.E. 6ft cantilevered retaining wall EQUILIBRIA STRUCTURAL ENGINEEI DL=0.65 k/ft, LL=0.8 k/ft i� i Y = 120 Ib/ft3 YEFP = 40 Ib/ft3 co co 6 +II i M y= 1201b/ft3 YEFP = 200 Ib/ft3 F Notes Loading Options/Assumptions Passive pressure neglects top 0 ft of soil. Load Combinations IBC 2015 (Strength) 1.2D + 1.61- + 1.61-1 1.2D + 1.61- + 0.91-1 1.2D + 0.51- + 1.61-1 1.2D+0.51-+0.91-1 1.2D + 1.61-1 1.213 + 0.91-1 0.9D + 1.61-1 0.9D + 0.91-1 1.4D QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 2 of 2 Monday 10/28/19 3:30 PM Jason Lindquist, P.E., S.E. 6ft braced retaining wall EQUILIBRIA STRUCTURAL ENGINEEI Detail z cq a; �-3.25 ft---� Check Summary Concrete f'c = 2500 psi Rebar Fy = 60000 psi Unit Weight = 150 Ib/ft3 #5 @ 18 in (S&T) #5@18in #5 @ 18 in (lapped dowels) Ratio Check Provided Required Combination ----- Stability Checks ----- ./ 0.495 Bearing Pressure 2500 psf 1237 psf 1.OD + 1.OL + 1.OH + 0.7E V/ 0.050 Bearing Eccentricity 0.33 in 6.49 in 1.OD + 1.01- + 1.OH + 0.7E ---- Toe Checks ----- v/ 0.169 Shear 4.8 k/ft 0.81 k/ft 1.2D + 1.61- + 1.6H v/ 0.474 Moment 2.5 ft-k/ft 1.18 ft-k/ft 1.2D + 1.61-+ 1.6H ---- Heel Checks ----- ,/ 0.332 Shear 4.8 k/ft 1.59 k/ft 1.4D v/0.398 Moment 2.5ft-k/ft 1ft.k/ft 1.4D ----- Stem Checks ----- v 0.710 Moment 3.49 ft-k/ft 2.48 ft-k/ft 1.2D + 0.51- + 1.6H + 1.0E v/ 0.457 Shear 3.6 k/ft 1.64 k/ft 1.2D + 0.51- + 1.6H + 1.0E v 0.223 Max Steel 0.0180 0.0040 1.2D + 1.61- + 1.6H V/ 0.000 Min Steel 0.02 in2fin 0 in2fin 1.2D + 1.61- + 1.6H v 0.667 Base Development 9 in 6 in 1.2D + 1.61- + 1.6H v/ 0.780 Lap Splice Length 30 in 23.4 in 1.2D + 1.61- + 1.6H V 0.000 Herz Bar Rho 0.0000 0.0000 1.2D + 1.61- + 1.6H V/ 1.000 Herz Bar Spacing 18 in 18 in 1.2D + 1.61- + 1.6H Use basic criteria from common projec...Yes Building Code IBC 2015 Concrete Load Combs IBC 2015 (Strength) Masonry Load Combs ASCE 7-10 (ASD) Stability Load Combs IBC Retaining Wall St... Apply Sds Factor to Seismic Combinat... No Restrained Against Sliding Yes Neglect Bearing At Heel Yes Use Vert. Comp. for OT Yes Use Vert. Comp. for Sliding Yes Use Vert. Comp. for Bearing Yes Use Surcharge for Sliding & OT Yes Use Surcharge for Bearing Yes Neglect Soil Over Toe No Neglect Backfill Wt. for Coulomb No Factor Soil Weight As Dead Yes Use Passive Force for OT Yes Assume Pressure To Top Yes Extend Backfill Pressure To Key Bottom No Use Toe Passive Pressure for Bearing No Required F.S. for OT 1.50 Required F.S. for Sliding 1.50 Has Different Safety Factors for Seismic No Allowable Bearing Pressure 2500 psf Req'd Bearing Location Middle third Wall Friction Angle 25° Friction Coefficent 0.35 Soil Reaction Modulus 172800 Ib/ft3 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 1 of 2 Monday 10/28/19 3:30 PM Jason Lindquist, P.E., S.E. 6ft braced retaining wall EQUILIBRIA STRUCTURAL ENGINEEI DL=0.65 k/ft, LL=0.8 k/ft Loading Options/Assumptions Passive pressure neglects top 0 ft of soil. z u� 0411 y= 120lb/ft3 yEFP = 60 Ib/ft3 c-,48 psf �., M M � 120 Ib/ft3 YEFP = 200 Ib/ft3 F Notes Load Combinations IBC 2015 (Strength) 1.2D + 1.61- + 1.61-1 1.213 + 1.61- + 0.91-1 1.2D+0.51-+1.61-1+1 1.2D + 0.51- + 1.61-1 1.213+0.51-+0.91-1+1 1.2D+0.51-+0.91-1 1.2D + 1.61-1 + 1.0E 1.213 + 1.61-1 1.213+0.91-1+1.0E 1.2D + 0.91-1 0.913 + 1.61-1 + 1.0E 0.913 + 1.61-1 0.9D+0.91-1+1.0E 0.9D + 0.91-1 1.413 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 2 of 2 Monday 10/28/19 3:30 PM Jason Lindquist, P.E., S.E. 4ft cantilevered retaining wall EQUILIBRIA STRUCTURAL ENGINEEI Detail [--2.33 ft- Check Summary Concrete f'c = 2500 psi Rebar Fy = 40000 psi Unit Weight = 150 Ib/ft3 #4 @ 10 in (S&T) #4 @ 16 in-------------- #4 @ 16 in (lapped dowels) Ratio Check Provided Required Combination ----- Stability Checks ----- v/ 0.562 Overturning 2.67 1.50 1.OD + 1.OL+ 1.OH v/ 0.791 Bearing Pressure 2500 psf 1978 psf 1.OD + 1.01- + 1.OH v/ 0.665 Bearing Eccentricity 3.1 in 4.65 in 1.OD + 1.01- + 1.OH ----- Toe Checks ----- v/ 0.053 Shear 4.8 k/ft 0.25 k/ft 1.2D + 1.61- + 1.6H v/ 0.293 Moment 2.5 ft-k/ft 0.73 ft-k/ft 1.2D + 1.61-+ 1.6H ----- Heel Checks ----- ,/ 0.162 Shear 4.8 k/ft 0.78 k/ft 1.4D V/ 0.111 Moment 2.5 ft-k/ft 0.28 ft-k/ft 1.2D + 1.61-+ 1.6H ----- Stem Checks ----- �/ 0.497 Moment 1.75 ft-k/ft 0.87 ft-k/ft 1.2D + 1.61-+ 1.6H 0.167 Shear 3.6 k/ft 0.6 k/ft 1.2D + 1.61- + 1.6H 0.099 Max Steel 0.0403 0.0040 1.2D + 1.61- + 1.6H V 0.000 Min Steel 0.01 in2fin 0 in2fin 1.2D + 1.61-+ 1.6H v/ 0.667 Base Development 9 in 6 in 1.2D + 1.61- + 1.6H v 0.520 Lap Splice Length 30 in 15.6 in 1.2D + 1.61- + 1.6H V/ 0.000 Horz Bar Rho 0.0000 0.0000 1.2D + 1.61- + 1.6H �/ 0.556 Horz Bar Spacing 10 in 18 in 1.2D + 1.61- + 1.6H Use basic criteria from common projec...Yes Building Code IBC 2015 Concrete Load Combs IBC 2015 (Strength) Masonry Load Combs ASCE 7-10 (ASD) Stability Load Combs IBC Retaining Wall St... Apply Sds Factor to Seismic Combinat... No Restrained Against Sliding Yes Neglect Bearing At Heel Yes Use Vert. Comp. for OT Yes Use Vert. Comp. for Sliding Yes Use Vert. Comp. for Bearing Yes Use Surcharge for Sliding & OT Yes Use Surcharge for Bearing Yes Neglect Soil Over Toe No Neglect Backfill Wt. for Coulomb No Factor Soil Weight As Dead Yes Use Passive Force for OT Yes Assume Pressure To Top Yes Extend Backfill Pressure To Key Bottom No Use Toe Passive Pressure for Bearing No Required F.S. for OT 1.50 Required F.S. for Sliding 1.50 Has Different Safety Factors for Seismic No Allowable Bearing Pressure 2500 psf Req'd Bearing Location Middle third Wall Friction Angle 25° Friction Coefficent 0.35 Soil Reaction Modulus 172800 Ib/ft3 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 1 of 2 Monday 10/28/19 3:31 PM Jason Lindquist, P.E., S.E. 4ft cantilevered retaining wall EQUILIBRIA STRUCTURAL ENGINEEI DL=0.65 k/ft, LL=0.8 k/ft y= 120 Ib/ft3 � YEFP = 40 Ib/ft3 M M M M � L6 -y= 120 Ib/ft3 YEFP = 300 Ib/ft3 wales Loading Options/Assumptions Passive pressure neglects top 0 ft of soil. Load Combinations IBC 2015 (Strength) 1.2D + 1.61- + 1.61-1 1.2D + 1.61- + 0.91-1 1.2D + 0.51- + 1.61-1 1.2D+0.51-+0.91-1 1.2D + 1.61-1 1.213 + 0.91-1 0.9D + 1.61-1 0.9D + 0.91-1 1.4D QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 2 of 2 Monday 10/28/19 3:31 PM Jason Lindquist, P.E., S.E. 4ft braced retaining wall EQUILIBRIA STRUCTURAL ENGINEEI Detail Concrete f'c = 2500 psi Rebar Fy = 40000 psi Unit Weight = 150 Ib/ft3 a #4 @ 10 in (S&T) c #4@16in c m #4 @ 16 in (lapped dowels) 0 M .83 .83 �-2.33 ft--� - Check Summary Ratio Check Provided Required Combination ----- Stability Checks ----- -/ 0.660 Bearing Pressure 2500 psf 1649 lost 1.OD + 1.OL + 1.OH + 0.7E v/ 0.219 Bearing Eccentricity 1.02 in 4.65 in 1.OD + 1.01- + 1.OH + 0.7E ---- Toe Checks ----- v/ 0.043 Shear 4.8 k/ft 0.21 k/ft 1.2D + 1.61- + 1.6H v/ 0.252 Moment 2.5 ft.k/ft 0.63 ft.k/ft 1.2D + 1.61-+ 1.6H ---- Heel Checks ----- ,/ 0.162 Shear 4.8 k/ft 0.78 k/ft 1.4D v/ 0.129 Moment 2.5 ft.k/ft 0.32 ft.k/ft 1.4D ----- Stem Checks ----- v 0.572 Moment 1.75 ft-k/ft 1 ft-k/ft 1.2D + 0.51- + 1.6H + 1.0E v/ 0.236 Shear 3.6 k/ft 0.85 k/ft 1.2D + 0.51- + 1.6H + 1.0E �/ 0.099 Max Steel 0.0403 0.0040 1.2D + 1.61- + 1.6H V 0.000 Min Steel 0.01 in2fin 0 in2fin 1.2D + 1.61-+ 1.6H v/ 0.667 Base Development 9 in 6 in 1.2D + 1.61- + 1.6H v 0.520 Lap Splice Length 30 in 15.6 in 1.2D + 1.61- + 1.6H V/ 0.000 Herz Bar Rho 0.0000 0.0000 1.2D + 1.61- + 1.6H v 0.556 Herz Bar Spacing 10 in 18 in 1.2D + 1.61- + 1.6H Use basic criteria from common projec...Yes Building Code IBC 2015 Concrete Load Combs IBC 2015 (Strength) Masonry Load Combs ASCE 7-10 (ASD) Stability Load Combs IBC Retaining Wall St... Apply Sds Factor to Seismic Combinat... No Restrained Against Sliding Yes Neglect Bearing At Heel Yes Use Vert. Comp. for OT Yes Use Vert. Comp. for Sliding Yes Use Vert. Comp. for Bearing Yes Use Surcharge for Sliding & OT Yes Use Surcharge for Bearing Yes Neglect Soil Over Toe No Neglect Backfill Wt. for Coulomb No Factor Soil Weight As Dead Yes Use Passive Force for OT Yes Assume Pressure To Top Yes Extend Backfill Pressure To Key Bottom No Use Toe Passive Pressure for Bearing No Required F.S. for OT 1.50 Required F.S. for Sliding 1.50 Has Different Safety Factors for Seismic No Allowable Bearing Pressure 2500 psf Req'd Bearing Location Middle third Wall Friction Angle 25° Friction Coefficent 0.35 Soil Reaction Modulus 172800 Ib/ft3 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 1 of 2 Monday 10/28/19 3:31 PM Jason Lindquist, P.E., S.E. 4ft braced retaining wall EQUILIBRIA STRUCTURAL ENGINEEI DL=0.65 k/ft, LL=0.8 k/ft Loading Options/Assumptions Passive pressure neglects top 0 ft of soil. i I� i 1 y= 120 Ib/ft3 -A2 psf CJ C� YEFP = 60 Ib/ft3 M } -y = 120 Ib/ft3 7EFP = 200 Ib/ft3 F-- Notes Load Combinations IBC 2015 (Strength) 1.2D + 1.61- + 1.61-1 1.213 + 1.61- + 0.91-1 1.2D+0.51-+1.61-1+1 1.2D + 0.51- + 1.61-1 1.213+0.51-+0.91-1+1 1.2D+0.51-+0.91-1 1.2D + 1.61-1 + 1.0E 1.213 + 1.61-1 1.213+0.91-1+1.0E 1.2D + 0.91-1 0.913 + 1.61-1 + 1.0E 0.913 + 1.61-1 0.9D+0.91-1+1.0E 0.9D + 0.91-1 1.413 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 2 of 2 Monday 10/28/19 3:31 PM Jason Lindquist, P.E., S.E. Site Retaining Wall EQUILIBRIA STRUCTURAL ENGINEEI Detail P [-1.5 ft-� [-1.5 ft-� �--3.67 ft- Check Summary Concrete f'c = 2500 psi Rebar Fy = 60000 psi Unit Weight = 150 Ib/ft3 #5 @ 18 in (S&T) #5@18in #5 @ 18 in (lapped dowels) Ratio Check Provided Required Combination ----- Stability Checks ----- _ �/ 0.663 Overturning 2.26 1.50 1.OD + 1.OL+ 1.OH 0.520 Bearing Pressure 2500 psf 1300 psf 1.013 + 1.01- + 1.OH 0.899 Bearing Eccentricity 6.59 in 7.33 in 1.OD + 1.01- + 1.OH ----- Toe Checks ----- v/ 0.215 Shear 4.8 k/ft 1.03 k/ft 1.4D v/ 0.514 Moment 2.5 ft-k/ft 1.28 ft-k/ft 1.213 + 1.61-+ 1.6H ----- Heel Checks ----- �/ 0.398 Shear 4.8 k/ft 1.91 k/ft 1.4D 0.520 Moment 2.5 ft-k/ft 1.3 ft-k/ft 1.2D + 1.61-+ 1.6H ----- Stem Checks ----- �/ 0.786 Moment 3.49 ft.k/ft 2.74 ft-k/ft 1.2D + 1.61-+ 1.6H 0.345 Shear 3.6 k/ft 1.24 k/ft 1.2D + 1.61- + 1.6H v 0.223 Max Steel 0.0180 0.0040 1.2D + 1.61- + 1.6H v/ 0.774 Min Steel 0.02 in2fin 0.01 in2fin 1.2D + 1.61-+ 1.6H v 0.917 Base Development 9 in 8.25 in 1.2D + 1.61- + 1.6H v/ 0.780 Lap Splice Length 30 in 23.4 in 1.2D + 1.61- + 1.6H V 0.000 Horz Bar Rho 0.0000 0.0000 1.2D + 1.61- + 1.6H V/ 1.000 Horz Bar Spacing 18 in 18 in 1.2D + 1.61- + 1.6H Use basic criteria from common projec...Yes Building Code IBC 2015 Concrete Load Combs IBC 2015 (Strength) Masonry Load Combs ASCE 7-10 (ASD) Stability Load Combs IBC Retaining Wall St... Apply Sds Factor to Seismic Combinat... No Restrained Against Sliding Yes Neglect Bearing At Heel Yes Use Vert. Comp. for OT Yes Use Vert. Comp. for Sliding Yes Use Vert. Comp. for Bearing Yes Use Surcharge for Sliding & OT Yes Use Surcharge for Bearing Yes Neglect Soil Over Toe No Neglect Backfill Wt. for Coulomb No Factor Soil Weight As Dead Yes Use Passive Force for OT Yes Assume Pressure To Top Yes Extend Backfill Pressure To Key Bottom No Use Toe Passive Pressure for Bearing No Required F.S. for OT 1.50 Required F.S. for Sliding 1.50 Has Different Safety Factors for Seismic No Allowable Bearing Pressure 2500 psf Req'd Bearing Location Middle third Wall Friction Angle 25° Friction Coefficent 0.35 Soil Reaction Modulus 172800 Ib/ft3 QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 1 of 2 Monday 10/28/19 3:32 PM Jason Lindquist, P.E., S.E. Site Retaining Wall EQUILIBRIA STRUCTURAL ENGINEEI Loads 40 psf �� 1111 y= 120 Ib/ft3 YEFP = 35 Ib/ft3 M � M CM p r; M y = 120 Ib/ft3 7EFP = 200 Ib/ft3 Notes Loading Options/Assumptions Passive pressure neglects top 0 ft of soil. Load Combinations IBC 2015 (Strength) 1.2D + 1.61- + 1.61-1 1.2D + 1.61- + 0.91-1 1.2D + 0.51- + 1.61-1 1.2D+0.51-+0.91-1 1.2D + 1.61-1 1.213 + 0.91-1 0.9D + 1.61-1 0.9D + 0.91-1 1.4D QuickRWall 5.0 (iesweb.com) P:\E1396 Pickering Ed ... \E1396 Retaing Wall Calculations. rwd Page 2 of 2 Monday 10/28/19 3:32 PM