HomeMy WebLinkAboutX2020-0514 - Calcs0
Y20Z0 -mu)
2i mvine Or,
Dong Engineering, Inc.
10692 SILVER CIR, GARDEN GROVE, CA 92843
Office: (714) 204 - 2874
Email: Truongdong@gmail.com
Project:
REMODEL
STRUCTURAL CALCULATIONS FOR RESIDENCE AT:
21 STONE PINE DR,
NEWPORT COAST, CA 92657
DATE: 03/03/2020
CLIENT:
JOB NO.: 19069
Page 1 of 18
BUILDING DIVISION
r,
BY: M.K.
DONG ENGINEER, INC.
#Fnlalt I n 9 "7 a N111 r x o-3 Flit
LOADING CONDITIONS
PAGE
DATE: 08101119
Project # I,t t8 Si
ROOF.
TILE
FLOOR:
Without Lt. Wt. CONC.
Slope
4:12
2 Sheets:
Date:
Live Load
20 psf
Live Load
40 psf
Roof Material
10 psf
Floor Material
3.0 psf
Sheathing
1.5 psf
Sheathing
2.5 psf
Trusses / Rafters
2.5 psf
Floor Joists
2.5 psf
Ceiling Joists
2.0 psf
Ceiling Joists
0.0 psf
Drywall
2.5 psf
Drywall
3.0 psf
Sprinkler
0.5 psf
Sprinkler
0.5 psf
Miscellaneous
1.0 psf
Miscellaneous
1.5 psf
Total D.L.
20 psf
Total D.L.
13.0 psf
Total Load
40 psf
Total Load
53 psf
EXTERIOR WALL:
INTERIOR WALL:
EXTERIOR:
9
DRYWALL:
3
DRYWALL:
3.0
DRYWALL:
3.0
STUDS:
2.0
STUDS:
2.0
MISC.:
1.0
MISC.:
2.0
DL=
15.0 PSF
DL=
10.0 PSF
REVISIONS:
1 Sheets:
Date:
Init:
Remark:
2 Sheets:
Date:
Init:
Remark:
3 Sheets:
Date:
fnit:
Remark:
4 Sheets:
Date:
Init:
Remark:
5 Sheets:
Date:
[nit:
Remark:
6 Sheets:
Date:
Init:
Remark:
Page 2 of 18
LOADS -2013 NEWAs
I
21 Stone Pine Dr, Newport Coast, CA 92657, USA
Latitude, Longitude: 33.604652, -117.83289100000002
OSP
rype
varue
uescripuon
Ss
1.612
MCER ground motion. (for 0.2 second period)
St
0.584
MCER ground motion. (for 1.0s period)
SMs
1.612
Site -modified spectral acceleration value
SMI
0.877
Site -modified spectral acceleration value
SDS
1.075
Numeric seismic design value at 0.2 second SA
SDI
0.584
Numeric seismic design value at 1.0 second SA
Type
Value
Description
SDC
D
Seismic design category
Fa
I
Site amplification factor at 0.2 second
Fv
1.5
Site amplification factor at 1.0 second
PGA
0.645
MCEG peak ground acceleration
FpGA
1
Site amplification factor at PGA
PGAM
0.645
Site modified peak ground acceleration
TL
8
Long -period transition period in seconds
SsRT
1.612
Probabilistic risk -targeted ground motion. (0.2 second)
SsUH
1.742
Factored uniform -hazard (2% probability of exceedance in 50 years) spectral acceleration
SsD
3.323
Factored deterministic acceleration value. (0.2 second)
S1RT
0.584
Probabilistic risk -targeted ground motion. (1.0 second)
S1UH
0.612
Factored uniform -hazard (2% probability of exceedance in 50 years) spectral acceleration.
SID
1.137
Factored deterministic acceleration value. (1.0 second)
PGAd
1.223
Factored deterministic acceleration value. (Peak Ground Accelerator)
CRs
0.925
Mapped value of the risk coefficient at short periods
CRI
0.955
Mapped value of the risk coefficient at a period of 1 s
Page 3 of 18
2.0
1.5
A 1.0
m
rn
0.5
0.0
0.0
MCER Response Spectrum
1.5
1.0
Cn0
m
0.5
0.0
0.0
2.5 5.0 T5
Period, T (sec)
— Sa(g)
Design Response Spectrum
2.5 5.0 7.5
Period, T (sec)
— Sa(g)
IIKIJ MAV
While the information presented on this website is believed to be correct, SEAOC /OSHPD and its sponsors and contributors assume no responsibility or
liability for its accuracy. The material presented in this web application should not be used or relied upon for any specific application without competent
examination and verification of its accuracy, suitability and applicability by engineers or other licensed professionals, SEAOC / OSHPD do not intend that the
use of this information replace the sound judgment of such competent professionals, having experience and knowledge in the field of practice, nor to substitute
for the standard of care required of such professionals in interpreting and applying the results of the seismic data provided by this website. Users of the
information from this website assume all liability arising from such use. Use of the output of this website does not imply approval by the governing building code
bodies responsible for building code approval and interpretation for the building site described by IatitudeAongitude location in the search results of this
webstie.
Page 4 of 18
Title Block Line 1 Project Title:
You �can change this area Engineer: Project ID:
using the "Settings" menu item Protect Descr:
and then using the "Printing &
Title Block" selection.
G.T.#1, G.T.#2, Bfv11
Using Allowable Stress Design with ASCE 7-10 Load Combinations, Major Axis Bending
Wood Species: Trus Joist Wood Grade: Parallam PSL 2.0E
Fb - Tension 2,900.0 psi Fc - PHI 2,900.0 psi Fv 290.0 psi Ebend- xx 2,000.0 ksi Density 45.050 pcf
Fb - Compr 2,900.0 psi Fc - Perp 625.0 psi Ft 2,025.0 psi Eminbend - xx 1,016.54 ksi
Applied Loads
1,372.73 psi
Beam self weight calculated and added to loads
Unif Load: D=0.020, Lr = 0.020 Wit, Tdb=13.0 it
Design Summary
1,375.00 psi
Max fb/Fb Ratio
= 0.639. 1
fb : Actual:
2,275.54 psi at 9.000 It in Span # 1
Fb: Allowable:
3,563.50 psi
Load Comb:
+D+Lr+H
Max fv/FvRatio =
0.355: 1
fv : Actual:
128.81 psi at 0.000 ft in Span # 1
Fv: Allowable:
362.50 psi
Load Comb:
+D+Lr+H
Max Reactions (k)
D 6 Id s W €
Left Support
2.48 2.34
Right Support
2.48 2.34
D(O.2601 Lr 0.260
18.0% 3.5x74.0
H Downward L+Lr+S 0.386 in Downward Total 0.794 in
Upward L+Lr+S 0.000 in Upward Total 0.000 in
Live Load Deb Ratio 560 >360 Total Defl Ratio 271 >180
Using Allowable Stress Design with ASCE 7-10 Load Combinations, Major Axis Bending
Wood Species: Douglas Fir - Larch Wood Grade: NO
Fb - Tension 1,000.0 psi Fc - PHI 1,500.0 psi Fv 180.0 psi Ebend- xx 1,700.0 ksi Density 31.20 pcf
Fb - Compr 1,000.0 psi Fc - Perp 625.0 psi Ft 675.0 psi Eminbend - xx 620.0 ksi
Applied Loads
Beam self weight calculated and added to loads
Unif Load: D = 0.020, Lr = 0.020 klft, Trib= 5.0 ft
Desian Summary
Max fb/Fb Ratio = 0.998; 1
fb : Actual:
1,372.73 psi
at
9.000 It in Span # 1
Fb: Allowable:
1,375.00 psi
Load Comb:
+D+Lr+H
Max fv/FvRatio =
0.286:
1
tv : Actual :
64.35 psi
at
0.000 ft in Span # 1
Fv: Allowable:
225.00 psi
Load Comb:
+D+Lr+H
Max Reactions (k)
D 6
Lr
s W E
Left Support
0.98
0.90
Right Support
0.98
0.90
1)(0.10) 10 .101
18.Oft, 412
H Downward L+Lr+S 0.336 in Downward Total 0.701 in
Upward L+Lr+S 0.000 in Upward Total 0.000 in
Live Load Dan Ratio 642 >360 Total Defl Ratio 307 >180
Using Allowable Stress Design with ASCE 7-10 Load Combinations, Major Axis Bending
Wood Species: Trus Joist Wood Grade: Parallam PSL 2.0E
Fb - Tension 2,900.0 psi Fc - PHI 2,900.0 psi Fv 290.0 psi Ebend- xx 2,000.0 ksi
Fb - Compr 2,900.0 psi Fc - Perp 625.0 psi Ft 2,025.0 psi Eminbend - xx 1,016.54 ksi
Applied Loads
Beam self weight calculated and added to loads
Unif Load: D = 0.010 Wft, Trib= 9.0 ft
Unif Load: D = 0.0130, L = 0.040 Wft, Trib=12.250 ft
Point: D = 2.480, Lr = 2.340 k @ 10.0 ft
Point: D = 0.980, Lr = 0.90 k @ 11.0 ft
Point: E = 4.290 k @ 5.750 ft
Point: E = -4.290 k @ 17.750 ft
Page 5 of 18
Density 45.050 pcf
Title Block Line 1 Project Title:
You can change this area Engineer: Project ID:
using the "Settings" menu item Project Descr:
and then using the "Printing &
Title Block" selection.
Design Summary
Max tb/Fb Ratio
= 0.862; 1
fb : Actual :
2,458.24 psi at
9.977 ft in Span # 1
Fb : Allowable :
2,850.80 psi
Load Comb:
+D+L+H
Max fv/FvRatio =
0.427: 1
fv : Actual :
123.75 psi at 17.094
ft in Span # 1
Fv : Allowable:
290.00 psi
Load Comb:
+D+L+H
Max Reactions (k)
o L I r
a w 9
Left Support
4.06 4.47 1.42
2.82
Right Support
4.50 4.47 1.82
-2.82
H
Page 6 of 18
r
nward L+Lr+S 0.384 in Downward Total 0.902 in
and L+Lr+S 0.000 in Upward Total 0.000 in
Load Dell Ratio 570 >360 Total Dell Ratio 242 >180
o � u
d o o d
XI
,�m r
Number of Story: 2 Section width: 38.5(ft) Section length: 34(ft)
Base height: (ft) Slope roof height: 24(ft) Gable mean roof height: 23(ft)
Plate height: ROOF = 21 (ft); FIRST FLOOR = 11(ft)
WIND PARAMETERS:
Wind speed = 110, Wind exposure = C, Wind importance factor Iw= 1
Coefficients: Kd = 0.85, Kzt = 1, G=0.85, Gcpi = +/-0.18, omega = 1
B = 96(ft), L = 36(ft), H = 24(ft)-->L/B = 0.38, H/L = 0.67
Wall coefficient: Cpw = 0.8, Cpl= -0.5, Roof coefficient: Cpw = (-0.18;-0.84), Cpl= -0.54
Wind exposure = C-->anpha = 9.5, zg = 900
Kz = 2.01*(15/zg)A(2/anpha) qz = 0.00256*Kz*Kzt*Kd*VA2*lw P = G(Cpw*qz+Cpl*qh)
(z, Kz, qz, P): (24, 0.94, 24.68, 27.27); (21, 0.91, 23.99, 26.8); (16.5, 0.87, 22.8, 25.99)
(15, 0.85, 22.35, 25.69)
WIND LOAD:
SHEAR ROOF = 90.36(plf)
SHEAR FIRST FLOOR = 170.54(plf)
SEISMIC PARAMETERS:
Light frame wood -->Ry = 6.5, Site class :D, SDS = 2FaSs/3 =1.075, SD1 = 2FvS1/3 =0.584,
Seismic design category: D, 1 = 1, V = SDS*I*W/(1.4*Ry) = 1.075*1*W/(1.4*6.5) = 0.1181*W
ROOF
Roof = 20*37 = 740 PLF
Wall = 15*3*4.5 + 10*2*4.5 = 292.5 PLF
Shear = 0.1181(740+292.5) = 0.1181 *1032.5 = 121.94 PLF
FIRST FLOOR
Floor = 13*34 = 442 PLF
Wall = 15*3*4.5 + 15*3*5.5 + 10*2*4.5 + 10*2*5.5 = 650 PLF
Shear = 0.1181(442+650) = 0.1181 *1092 = 128.97 PLF
Total Seismic Load = 121.97 + 129 = 250.97 PLF
Redistrib: 1032.5*21 + 1092*11 = 33694.5 PLFxFT
SHEAR ROOF = 250.97*1032.5*21/33694.5 = 161.5 PLF
SHEAR FIRST FLOOR = 250.97*1092*11/33694.5 = 89.47 PLF
ROOF 161.5 PLF SEISMIC GOVERN
FIRST FLOOR 170.54 PLF WIND GOVERN
ROOF DIAPHRAGM
Max shear = 161.5 x 19.25 / (2 x 34) = 45.72 PLF
Use: 15/32" spa rated unblock 32/16 w/8d common nails at 6", 6", 12" o.c.
Chord force = 161.5 x 19.2512 / (8 x 34) = 220.02 LBS
Splice w/ min. (2) 16d sinker nails each side of splice at 8" o.c. (standard construction)
FIRST FLOOR DIAPHRAGM
Max shear = 170.54 x 19.25 / (2 x 34) = 48.28 PLF
Use: 23/32" ape rated unblock w/10d common nails at 6", 6", 12" o.c.
Chord force = 170.54 x 19.2512 / (8 x 34) = 232.34 LBS
Splice w/ min. (2) 16d sinker nails each side of splice at 8" o.c. (standard construction)
Page 8 of 18
Lateral
V—(Ib)=v_(plf)'Span•Span/2/(Span+Offset)
D Factor: X Direction: 0=0: Y Direction: n=1.3
Wall Sec.
Sto.
Wind
Seismic
Span, Offset
Wind
Seismic
L
Description
# #
# v_ I v I
ft ft
V Ib
V_ lb
1
:Wind -5022.331b
Seismic =6280.531b
1
1Y
2
90.4
181.5 38.5
1739.4
3108.9----------38.5(ft)-----------I
1
1Y
1 1
170.51
89.51 38.51
1 3282.91
1722.3--------38.5(R)----------I
Page 9 of 18
Line shear V = Maximum(V1;V2)
V1 = Wind*Span/2 + Added Vwind
V2 = Seismic*Span/2 + Added Vseismic
v(plf) = V/L
Shear Wall (X -X Direction)
Line Story Section Span Wind I Seismic Kdded V (Ib) H L v Type
# # # ft If If Wind Seismic ftft If
Page 10 of 18
Line shear V = Maximum(V1;V2)
V1 = Wind*Span/2 + Added Vwind
V2 = Seismic*Span/2 + Added Vseismic
v(pif) = V/L
Shear Wall (Y -Y Direction)
Line Story Section Span
Wind
Seismic
dded V (Ib) H L v Type
# # # (ft)
(plf)
(plf)
Wind Seismic (ft) (ft) (plf)
1 1 1Y 38.5
90.36
161.5
3282.9 1722.3 11 12 523.38 D
Page 11 of 18
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Page 13 of 18
EMMAnchor DesignerTm
Software
Version 2.6.6703.1
1.Prolect i
Customer company:
Customer contact name:
Customer e-mail:
Comment:
2. Input Data & Anchor Parameters
General
Design method:AC1318-14
Units: Imperial units
Anchor Information:
Anchor type: Bonded anchor
Material: F1554 Grade 36
Diameter (inch): 0.500
Effective Embedment depth, he (inch): 10.000
Code report: ICC -ES ESR -4057
Anchor category: -
Anchor ductility: Yes
hmon (inch): 11.25
ca. (inch): 23.34
Cmm (inch): 1.75
Smm (inch): 3.00
Recommended Anchor
Anchor Name: SET -3G - SET -3G w/ 1/2"0 F1554 Gr. 36
Code Report: ICC -ES ESR -4057
i
Project description:
Location:
Fastening description:
Base Material
Concrete: Normal -weight
Concrete thickness, h (inch): 18.00
Stale: Cracked
Compressive strength, r. (psi): 3000
WqV: 1.0
Reinforcement condition: A tension, A shear
Supplemental reinforcement: Not applicable
Reinforcement provided at corners: No
Ignore concrete breakout in tension: No
Ignore concrete breakout in shear: No
Hole condition: Dry concrete
Inspection: Periodic
Temperature range, Short/Long: 150/110°F
Ignore Edo requirement: Not applicable
Build-up grout pad: No
Input data and results must be checked for agreement with the existing circumstances, the standards and guidelines must be checked for plausibility.
Simpson Strong -Tie Company Inc. 5956 W. Las Positas Boulevard Pleasanton, CA 94588 Phone: 925.560.9000 Fax: 925.847.3871 www.strongtie.com
Page 14 of 18
Anchor DesignerM
Software
Version 2.6.6703.1
Company: Date: 2/28/2020
Engineer: Page: 2/5
Project:
Address:
Phone:
E-mail:
Load and Geometry
Load factor source: ACI 318 Section 5.3
Load combination: not set
Seismic design: Yes
Anchors subjected to sustained tension: No
Ductility section for tension: 17.2.3.4.3 (a) (iii) -(vi) is satisfied
Ductility section for shear: 17.2.3.5.3 (a) is satisfied
Do factor: not set
Apply entire shear load at front row: No
Anchors only resisting wind and/or seismic loads: Yes
Strength level loads:
Nu. [Ib]: 5100
W. [lb]: 0
Vu, [lb]: 0
<Figure 1>
7 -
Input data and results must be checked for agreement with the existing circumstances, the standards and guidelines must be checked for plausibility.
Simpson Strong -Tie Company Inc. 5956 W. Las Positas Boulevard Pleasanton, CA 94588 Phone: 925.560.9600 Fax: 925.847.3871 www.sbongtie.com
Page 15 of 18
Anchor Designer TIM
Software
Version 2.6.6703.1
<Figure 2>
Company:
Date:
212 8/2020
Engineer:
Page:
315
Project:
Address:
Phone:
E-mail:
Input data and results must be checked for agreement with the existing circumstances, the standards and guidelines must be checked for plausibility.
Simpson Strong -Tie Company Inc. 5956 W. Las Positas Boulevard Pleasanton, CA 94588 Phone: 925.560.9000 Fax: 925.847.3871 www.strongtie.com
Page 16 of 18
Anchor DesignerTIM compan
Engineer
Software Project:
Version 2.6.6703.1 Address:
3. Resulting
Anchor Forces
w,.=.=rx,arf han�.,mK.ar(f./2,500)"2'Naaia
Anchor
Tension load,
Shear load x,
Shear load y,
Shear load combined,
3000 0.24 1226
W„ (lb)
W.. (lb)
V..y (lb)
J(V.a.)2+(V.ay)2 (Ib)
1
5100.0
0.0
0.0
0.0
Sum
5100.0
0.0
0.0
0.0
Maximum concrete compression strain (%a): 0.00
Maximum concrete compression stress (psi): 0
Resultant tension force (lb): 5100
Resultant compression force (lb): 0
Eccentricity of resultant tension forces in x-axis, e'N. (inch): 0.00
Eccentricity of resultant tension forces in y-axis, e'Ny (inch): 0.00
4. Steel Strenath of Anchor in Tension (Sec. 17.4.11
N.. (lb) d ON.. (lb)
8235 0.75 6176
5. Concrete Breakout Strength of Anchor in Tension (Sec. 17.4.2)
Ne = k.Aa4fchad s (Eq. 17.4.2.2a)
ka A. f" (psi) he (in) Nb (lb)
17.0 1.00 3000 10.000 29445
0.750Nch = 0.750 (ANc/AN"a)Tad,N%NY4p,NNn (Sec. 17.3.1 & Eq. 17.4.2.1a)
ANc (Ind) AN. (In2 ca,mm (In) 44dN Y",N Y.p,N Nb (Ib) 0 0.75^h (lb)
450.00 900.00 7.50 0.850 1.00 1.000 29445 0.75 7039
6. Adhesive Strength of Anchor in Tension (Sec. 17.4.5)
w,.=.=rx,arf han�.,mK.ar(f./2,500)"2'Naaia
rks, (psi) f.hod-. Kw
aN...I.
f� (psi) n rice (psi)
1304 1.00 1.00
0.90
3000 0.24 1226
Nn. = Aa wzdah.f (Eq. 17.4.5.2)
A r (psi) d. (in)
he (in)
Nha(lb)
1.00 1226 0.50
10.000
19259
0.75ONa = 0.750 (ANa/ ANao)TBdNe Pop,NaNha (Sec. 17.3.1 & Eq. 17.4.5.1 a)
ANa (int) ANao (int) cNa (in) camm (in) %d,N. 'Yp,N. Nao (lb) d 0.750Na (lb)
191.09 191.09 6.91 7.50 1.000 1.000 19259 0.55 7945
Input data and results must be checked for agreementwith the existing circumstances, the standards and guidelines must be checked for plausibility.
Simpson Strong -Tie Company Inc. 5956 W. Las Positas Boulevard Pleasanton, CA 94588Phone: 925.560.9000 Fax: 925.847.3871 w .strongtie.com
Page 17 of 18
EEMAnchor DesignerTM
Software
Version 2.6.6703.1
ASD Level tensile demand load
= 6,176 x 0.7 = 4,323 Ib.
11. Results
11. Interaction of Tensile and Shear Forces (Sec. D.717
Tension Factored Load, N.. (Ib)
Concrete breakout 5100
Adhesive 5100
7945
o% (lb) Ratio
Status
u.as Vass
0.72 Pass
0.64 Pass
SET -313 wl 1/2"0 F1554 Gr. 36 with hef = 10.000 inch meets the selected design criteria.
ACI 318-14 Section 17.2.3.4.3(al (I) & (ii) Calculations for Ductility requirement for tension load
Steel Factored Load, Nu. (lb) 1.2 x Nominal Strength, W (Ib) Ratio
Steel 5100 9882 51.6% Governs
Concrete Factored Load, Nn. (lb) Nominal Strength, Nn (lb) Ratio
Concrete breakout 5100 12514 40.8%
Adhesive 5100
19259
26.5%
ACI 318-14 Section 17.2.3.4.3(a) (i) & (ii) satisfied since steel ratio governs and the steel element is ductile.
12. Warnings
- Per designer input, ductility requirements for shear have been determined to be satisfied — designer to verify.
- Designer must exercise own judgement to determine if this design is suitable.
- Refer to manufacturer's product literature for hole cleaning and installation instructions.
Input data and results must be checked for agreement with the existing circumstances, the standards and guidelines must be checked for plausibility.
Simpson Strong -Tie Company Inc. 5956 W. Las Pashas Boulevard Pleasanton, CA 94588 Phone: 925.560.9000 Fax: 925.847.3871 www.atronglle.com
Page 18 of 18