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Home My WebLink AboutX2021-0943 - Misc (2)1 Zq7 - 20Zo X2021 •dC143 W13 CArA*b'oln Ave. JZMC LLc jzmc@shcglobal.net 300 E. 23`d St., Costa Mesa, CA92627 949-244-4423 Project: 613 Carnation Ave., Corona Del Mar, CA Project Description: Internal Remodel of the Existing 2 Story Townhouse C A L C U L A T 1 O N a x g SS/pN ZA✓yFy' _a w U _ 032946 1 m M 1 Design Criteria Scope The scope of the work includes engineering assistance for the internal remodel of the existing 2 story duplex Design Codes: California Building Code, 2019 Edition American Concrete Institute, ACI 318-14 American Institute of Steel Construction, AISC 14t" Edition American Society of Civil Engineers, ASCE 7-16 Design Parameters: Design wind speed: 94(42) mph, Exposure: C Risk Category: II Seismic data Site Class: D Fa: 1.2 Fv: N/A Ss: 1.355g Si: 0.481g SDS: 1.084g SDI: N/A Risk Category: II Soils Data: 2019 CBC Table 1806.2 Max. soil bearing: 1500 PSF (1/3 increase for seismic or wind) ( Per owner: No soil report is provided or to be used ) Materials: Concrete Foundation: f'c=3,000 psi @ 28days Cement ASTM C150, Type II -V Aggregate ASTM C33, Max. size 1-1/2" Reinforcing ASTM A615, Grade 60 Grout Non -Shrink Structural Grout, LINO Anchor Bolts ASTM F1554, Fully Threaded and Galvanized Structural Steel Simpson connectors Lumber: Douglas Fir No.2 or better Parallam: 2.OE, PSL O. ocaauuc ucatgu muga HPD S 613 Carnation Ave, Corona De! Mar, CA 92625, USA Latitude, Longitude: 33.602996,-117.87:4878 s:. d Avila's EI Ra hito Corona at Bamboo Bistro v, ? Sherman Library a G & Gardens Map data (02020 Date 7/7/2020, 8:27:36 AM Design Code Reference Document ASCE7-16 Risk Category '., II Site Class D - Default (See Section 11.4.3) Type Value Description Ss 1.355 MCER ground motion. (for 0.2 second period) S1 0.481 MCER ground motion. (for 1.09 period) Sm1s 1.626 Site -modified spectral acceleration value SM1 null -See Section 11.4.8 Site -modified spectral acceleration value SDs 1.084 Numeric seismic design value at 0.2 second SA SDt null -See Section 11.4.8. Numeric seismic design value at 1.0 second SA Type Value Description SDC null -See Sectlon 11.4.8 Seismic design category Fa 12 Site amplification factor at 0.2 second FV null -See Section 11.4.8 Site amplification factor at 1.0 second PGA 0.591 MCEG peak ground acceleration FPGA 1.2 Site amplification factor at PGA PGAM 0.71 Site modified peak ground acceleration TL 8 Long -period transition period in seconds SSRT 1.355 Probabilistic risk -targeted ground motion. (0.2 second) SsUH 1.489 Factored uniform -hazard (2% probability of exceedance In 50 years) spectral acceleration SsD 2.622 Factored deterministic acceleration value. (0.2 second) S1RT 0.481 Probabilistic risk -targeted ground motion. (1.0 second) S1UH 0.521 Factored uniform -hazard (2% probability of exceedance in 50 years) spectral acceleration. S1D 0.823 Factored deterministic acceleration value. (1.0 second) PGAd 1.057 Factored deterministic acceleration value. (Peak Ground Acceleration) of 3 7(7(2020, 8:27 AA 0. OvIbmt, lv..P. Type Value CRS 0.91 CRI 0.922 /* D 17, 's Description Mapped value of the risk coefficient at short periods Mapped value of the risk coefficient at a period of 1 a of 3 7/7/2020. 8:27 AN PROJECT: 613 Carnation Ave—CDM—,CA PROJ. NO: 20-51 CLIENT: BC Home Builders DATE: 7.6.20 SUBJECT: Seismic Calulation BY: MC site class D 1.084 Ss 1.355: Sone 0.481` Fa 1' Fv 1.82< SMS 1`.626 SM. 0.875 SDs 1.084 SDone 0.584 T 0.06' TL 12' Rf 3 le 1 Cscaia =S13s/(Rf/1) =1.084/(3/1) 0.36 seismic response coefficient Csmax1 =iF(T<=TL,SDonj/(Rt/1),SDone*TL/TA21(R1/I)) =IF(0.06<=12,0.584/0.06/(3/1),0.584*12/0.06A2/(3/1)) 3.24 Csminl 0.03 Csminl = 0.044Sdsle or Ca =MAX(MIN(Cscalc.Csmaxl),Csmint,Csmin2) =MAX(MIN(0.36,3.24),0.03,) 0.36 v =Cs*W 0.36 W seismic base shear File Name: 613 Camelia n Ave_Comns Dal Mer CA_Seismic Dale: 717202o Csminl = 0.03 clovi,c e (Fa✓�'T'OP /Cvb'c c1>M t4 4K f o 14- P— PALCA� a ; ((5-00) 2� c..-, 4';?C� SA"t, S12!r tout)"—Ar- L.I r'�" /I CA P -PAT A 4-( 4c-2 "A L, -7 1 6 3 1 f -71 - -r7% 3 'N l C 'T�\( Ar- Ay. Z, N'l - o- 4-4_ 1 4 0 2 4v Li 115% 4 if GUNDA�'-�( Ci al UCJCaLo r >f M s Tr—,4 $ V-, "_To 5o To � fir` I - .S ttC% P-".. KAV- ?. Ac, :Yt� S,H E�A p (/ /(-L 6,C h 5� os qt 1 t, 6fi�Ap— P')' 4 r�\p (5,- T,., r02 A2 N1> F -c LPS X5'7 L-A C:8 ROJECT• JOB No COMPUTER TG S DATE 2- l 4- 7 1 SHEET bN Lo �, ---- ----- NN_ NNN' �w n N � � N h ech D t NVIs� Jt MSD\ BHN NG�� NN� ta. dh NV�O 6�thM �QO; tN��D NNN � Q= o.ao� '� o M � p X041 rN� w d erd•— D,m� I11C, oi`ey r►atN NNN �¢ Q/�v7 N ehM� M�pd Oct M QNN tl•tn_ q.r� QNm Qr- .►-� N N. MN N 40 a Q -� 0 4 N N 014 1 t 1 4%— t I l NNM 1 1 `fitNN ttI,; N�14 th-- rooms adr osa0 d 2 •t M m 'rer d-tv aD o �6 N }-..-+ -- + NN.. MNN Q a o cc a (3,* 0 ct-M1n = OQ N �y V s_tN cp.Dej- rtn 01� h Q W_ - NN-- NNN Q6. .� Q O eg 40rt 43 ett•'e�O �itl t�il� t t� NN -NN e 6�Qa �0 N o 41 ?I�d' N6,tr �h Q- Q CK qNa�a�O N2p 04? _=O aN1 m-4-4. JN o .tOtO� 00 43 Opa J10 crt�lil NIVN 1N'vNN rJNI+'�'S Na9N tJ2►N N�1d Nie► 3it'(S 9x2 StZ Gl x Z ZI nZ Table'3.22A1 Laterally Unsuppi Exterior Loadbea l'Supporting d Root and C Dead Load As RMW I On 5: I (Dropped) Header Spans for Walls "Ceding 4spol71ly = 20 psf,L,,' %,,-_240 Exterior 12 1 24 1 36 1 12 1 24 1 36 1 12 1 24 1 36 1 12 1 24 1 36 Headers Sizc Maximurn Heador/Girder Spans (ft -in.) for Common Lumber Spel Ise I -2x6 4.4 3A 2.9 3.11 3-0 2-7 3.4 2-7 2-2 3.0 2-4 2-0 Ceiling I -W 5.3 4 - 1 3-6 4-10 3-9 3-3 4-2 3-3 2.9 3.9 2.11 2.6 I.ZxI0 b.0 4.9 4.0 5 - / 4.5 3-9 4.10 3-10 3-'3 4.4 1 - 11 2-11 1-202 6.6 S.a 4-7 6.2 5.0 4-4 5.5 1- 5 3-9 4-11 4-0 3-4 2.21" 4.4 3.3 2.9 Y 3.12 3-0 2.7 3.4 i.7 2-2 3-0 2.4 1.11. 2-24 6-2 4-10 4-1 5.8 4-5 3.9 4-11 3710 3-3 4-S 3-5 2-11 2-24 7-2 i-9 4-11 6-9 S.5 4-8 i-11 4-8 4-0 S-4 4 -ii 3.7 Z-ZxIQ 1.10 6-4 5 - h I-6 6- 1 1 6.1 ii -4 4-8 6.0 4.10 4.2 2-202 H - 5 6-101 0.0 8-1 b - 1 i 10 1-2 " - 11 S - Z 0,6 '.' - 1, 4.9 3-2118 8.-5 6.10 5-21 8-0 6-6 5-7 1'.1 5-8 4.11 6-5 5-2 4-5 3-2X10 9-2 7.S 6-6 8-9 7-2 6-3 7-9 6-4 5-6 7-1 5.9 5-04. 3-2x1'2 9-9 8-0 7.0 9.4 7-8 6.9 8-4, 6-10 6-1 1 7-11 fi-3 5-7 4-2K8 9.4 1 7I 6 8 8-11 1,3 6-4 /•11 6,', !ii - 1 1.2 5,10 `,.0 4-2x10 10-2 8-3 7.3 9-8 8-0 7.0 9.8 1.1 6.3 1.11 6-6 8 4-242 10.10 8.10 7.9 10-4 . 8-7 7. 6 L9-3 7.8 6-9 8-6 1 7-0 6.2 Size Max "um Header/Girders ans (ft4n.1 for Lil 8.5 6.10 5.9 8.1 6.3 5-3 17-0 5-4 4-6 6-2 4-9 4.0 3.125K6475 10-7 R -S 7-1 10-1 7-9 6.7 8-0 61.8 5.7 1.8 5-11 5-0 3.125xill 12.8 10.1 8.5 12.0 9.3 7.10 (:10.3 8.0 6.9 9.2 7.1 64 3.125K9.625 14-9 11 6 9-9 13 8 10.11 9-0 11110 `)-2 /-9 10-I 8 - 3 6.11 112SM.OW 16 1 12.10 10.11 15-1 12.0 10-2 13.2 10-4 8.10 11.10 9,3 1 10 3.12542.375 17.1 13.9 11 -11 16-2 13.1 11-3 14.3 11.5 9-9 12-11 10-3 8-9 3.12$x13.750 17-10 14-7 12.8 17-0 0-11 12-1 15-1 32-3 10-7 13.9 11-1 9-6 3.125x15.12111 18-7 IS -21 13.3 17-9 14-7 32.9 15.9 12.11 11.3 14-$ 11.9 10.2 3.125Xj6.S00 10.2 15.8 13.9 :19.4 15-1 13-3 16.4. 13.5 11.9.15.0 12-3 10.9 3.125x17,875 19.8 16.2 14.2 18.10 15.1 13.8 16.10 13.11 12-2 15-5 12 ' 9 11'2 3.125*19.250 20.Ot 16.7 14 - fi 19-4 16.0 14-1 17.3 14-3 12.7 15.10 13-1 11-6 3.125x20.625 20 -Of 16. 11, till. 11 14-9 lb -4 14-5 1/.H 14,/ 12-11 lb. 3 13-!i 11-10 -2 ":� -2W 16-8 14-9 18.1 14.11 13-2 26.1 13.9 12.1 3.12SX23.375 IT: 1 is 6 20'Dt 17.0 is.0 :18 .5 IS -3 23.5. 16-11 14-0 12-5 3.1294IL750 XW a 17-1 f 15-9 204f 17-4 15-4 18=9 U1 IS -65 13-9 17-2 14,3 12'8 5.125X5.500 10-0 8.1 1 7.4 9-7 810 fi•9 8 - -j` 6.11 11-9 7.11 6-1 5.1 5.1250.875 12-5 10,4: 9.2 12-0 Ill -0 8-1 10.9 8-/ /-j 9- 11 /-8 ti -S 5,125x5.250 14,11 12 - -, 10. 11 14.4 12.0 10-1 12.11 10.3 8.8 11.10 9 2 1 8 5.12Sa9.625 11-524-1 12-9 16.9 13-11 11-9 tS- 1 12-0 10-1-'13-9 10-8 9.0 SillIftlIAM 19-11 16.6 14.6 10-2 15.10 13-5 17.3 13.8 11.6 15.8 12.2 5.12542373 2"1 18.7 16.2 20.01 17-9 15.0 10.5 IS -3 12.11 17-7 13-7 11.6 5.125X13.750 ZOLOT 20-(Jf, 17.10 20'01 19.7 lb- 7 20,01 16'-10 14.3 19.4 15.1 12,9 5.125x15.125 20.Ot 20-01:i 19.1 20V 200+ 18. 1 2041 18-5 15-7 20 -Of 16. 5 13 -11 SAMMSOO MOf 20.0 20.Ot 20-01 20-0t 19-6 20-01 19.10 16-17 20 Ot 17.9 15-I $.Uglixil7l 2().Of 2"t 2"1 2"11 20-011 2"1 20 -Of 2"t 18.1 20 -Of 19.0 16-3 S.125119.250 20-00 2W Mf 20-Ot 20 -Of 20*f 2"1 2"t 19,3 2"t 204t 17.3 9.t;HbiU.6Z5 2"t 2"t 204of 20,& 204* 2"t 20�()* " 20401 20-Ot 20-01 U- 3 S.12SX22.0w 20.01 20-01 �: 20.of zo.of zo-Ot zo-ut 20-0' 20-01 zo,oi 20-01 20.0t 19-1 5.125x23.375 20-0' 20-01 20-Oli 20-01 20-01 20-01 20-01 2(�Ot 20-01 20.01 20-W 113-10 5.12W4.750 20-Ot 20-0 1, 20-01 . 20�01 Ot 20-M 2"1 241-01 20 -Of 20-41t 20-01 20�0 t . 2 0-0t 1, 7 :1 r :Irl j-1 o li'li Ill, ii it I I l !"11 j"ll ..... .. j il"", 1j" .1 �A AMIM(All •2.01' Parallam® PSL Headers and Beams Allowable Design Stresses (100% Load Duration) Shear modulus of elasticity G = 125;000 psi Modulus. of elasticity E - 2.0 x 10,6 psi Flexural stress Fb = 2,900 psi(') Tension stress Fs = 2,025(2); psi Compression perpendicular to groin F, - 750 psi"') Compression parallel to grain Fds = Z,900 pili Nosiwit al shear parallel to gain f 290 psi L7ant (1) l,or 12" depth. For others, multiply by { a J (2) Fr has been reduced to reflect the volume effect] of length, width, and thickness for a range of common application conditions. (3) Fu shall not be increased for duration of load. Allowable DesUp Propertles (100% Load Duration) 13/4" 2.0E Parallam® PSL 'Z10 6,530 1 8,985 1 9,950 13,380 ,130 Ss215 - 0,605 '.+1)0249 4:135 115 125 208 244 4100 K1 59 _ i9 X'L 99. ;� 211/is" 2.0E Parallam® PSL v , ,A* n a #•grftr 9,535 10,025 13,800 15,280 120,855 26,840 33,530 , ;a� 9,801 4,935 5,845 6.170 �, T,275 8,315 9,350 1T5 142' 3f9 STS � 615 91'T 1,305 .19,900 1,27,160 34,955 43,665 31/2" 2.0E Parallam® PSL 51/a" 2.0E Paraliamo PSL 346 1 375 1 623 1 733 7" 2 AE ParallamD PSL 4;ZSa., 14240 18�Z1a 1,201 1,792 2,552. 23.0 26.3 29.5 P#,830 , 26,195 35,940 39,805 '54,325 69,905 87,32'§ 12,415 13,055 1.7,979 .19,900 1,27,160 34,955 43,665 t67.60 44301,.. 7,615" �; IABLE.KSU2.S(2) GIKUEK SPANS- AND HEAUER SPANS' FOR INTERIOR BEARING WALLS (Maximum spans for Douglas fir -larch, hem -fir, southern pine and spruce-pine-firb and requieed number of jack studs) HEADERS AND GIRDERS SUPPORTING SIZE', 20 Span BUILDING Width` 28 NjdSpan Njd (feet) 36 Span Njd One floor only 2-2x4'. 3-1 1 2-8 1 2-5 1 2-2x61 4-6 1 3-11 1 3-6 1 2-2x8' 5-9 1 5-0 2 4-5 2 2-2x10 7-0 2 6-1 2 5-5 2 2-2x1 8-1 2 7-0 2 6-3 2 3-2x8! 7-2 1 6-3 1 5-7 2 3-2x10 8-9 1 7-7 2 6-9 2 3-2x12 10-2 2 8-10 2 7-10 2 4-2x8' 9-0 1 7-8 1 6-9 1 4-2x10 10-1 1 8-9 1 7-10 2 4-2x12 11-9 1 10-2 2 9-1 2 Two floors 2-2x41 2-2 1 1-10 1 1-7 1 2-2x61 3-2 2 2-9 2 2-5 2 2-2x81 4-1 2 3-6 2 3-2 2 2-2x10 4-11 2 4-3 2 3-10 3 2-2x12 5-9 2 5-0 3 4-5 3 3-2x8, 5-1 2 4-5 2 3-11 2 3-2x16 6-2 2 5-4 2 4-10 2 3-2x12 7-2 2 6-3 2 5-7 3 4-2x81 6-1 1 5-3 2 4-8 2 4-2x 10 7-2 2 6-2 2 5-6 2 4-2x12 8-4 2 7 2 2 6-5 2 For 51: I inch = 25.4 mm, 1 foot = 304.8 mm. a. Spans are given in feet and inches. b. Tabulated values assume =2 grade lumber. c. Building width is measured perpendicular to the ridge. For widths between those shown, spans are permitted to be interpolated. d. NJ - Number of jack studs required to support each end. Where the number of required jack studs equals one, the header is permitted to be supported by an approved framing anchor attached to the full -height wall stud and to the header. AV�'C'KQLW1A ESI/FME INC. STRUCTURAL ENGINEERS ca Hoffineyer BUILDING DIVISION AUG 3 1 2020 BY: M.K to be built at 343 62nd St., Newport Beach, Ca. 92663 July 20, 2020 Sipped: CBC 2014 1800 E. 16th Street, Unit B, Santa Ana, CA 92701 Hopkins am Job No. L201 Tel: (714) 835-2800 Fax: (714) 835-2819 Page: 2 _ ESI/FME INC Date: 7/20/2020 STRUCTURAL ENGINEERS Jab W: L201 Client: Hopkins Project Name: Hoffineyer Plan No: Load Conditions Seismic Design Summitry Analysis Used: Equivalent Lateral Force Procedure(12.2) Floor(psf) VROCII(psfJ w/o LW S.S Lw Ss = Y393 S, =.0.499 Soil Site Class = D I = 19 R = 6.5 p• Tile Deck Cones Conc. Or I" Gyperete F. = 1.0 F„ =1.5 Seismic Design Catergory = D P =1.0 D = 2.5 20.0 40.0 40.0 Ove Load Situ = 1.393 Sul = 0.749 545 = 0.929 Sot - 8.499 Base Sbedr = 0.1Z0 W Dead Load 4.0 4.0 14.0 Sheathing 1.5 2.5 2.5 L/fllIn Desi n Summa eeker/Joists 1.5 2.0 2.0 sprinklers 2.0 2.0 2.0 Wind Velocity = 100 M.P.N. Wind Exposure Ceiling Joists 1.S 0.0 0.0 Governing Codes Dull 2.5 2.S 2.5 IBC2018 ASCE72016 Nos 2018 TMS 40Z2016 isaSolar Pv 2A. 1.0 1.0 Tot4I i0Ll i5.p 14.0 24.0 CaC:2019 AC1318.2014 SORVJS 2025 AlSC3fi0.10 Votal(DLAL) 35,0 1 54.0 1 64:0 Emkct Info SOils Report Initials Date Address By: 2019 CBC Engineer of Record: DF 7/23/2020 Street 349 62nd St. Job No: Project Engineer: DIF 7/23/2020 City Newport Beach. Date: Back Check: State, Zip Co.,92063 Allowable Soil Bearing Pressure l.SOO psf Roof truss Review: For Addition! Information: Refer to Soils Report Floor Truss Review:. structural Observation/Special InspectiOn PT Foundation Review: Structural Observation Required:. Yes Plan Check 1:. Special Inspection Required: No Plan Check 2: Revisions Table of Contents Revision Revised Sheets. initials Date Description Pg. No. Notes 2`5 Reductions R1 -R3 Beams 6- LateralAnilysis 7-9 ESI/FME, Inc. - Structural Engineers (This Signature is to be a wet signature, not a copy.l r{ gaf ION i •r�y w�psv 7 tut .i ( / Date: s ESi/FME INC STRUCTURAL ENGINEERS Project Name:. IBC2018 CBC 2019 ASCE72016 In.all cases calculations will supersede this design criteria sheet Doug Fir - Larch #11 Doug Fir - Larch #2 Size Fb(Psi) F"(psi) Fb(psi) F„ (psi) E(psi) 254, 2x6, 2x8, 2x10, 2x12, 1000 180 900 180 1.60E+06 2x14 2600 285 1.90E+06 Timberstrand (LSL) 1700 4x4, 4x6, 4x8, 4x10, 4x12, 1000 180 900 180 1.60E+06 414 6x6, 6x8, 8x8, $%10 1200 170 750 170 1.60E+06 6x10, 6x12, 6x14, 8X12,81141 13S0 170 875 170 1.60E+06 uoug Fir -tern-ia max moature concern. it oe tree of neartcenter Page: 3 Date: 7/20/2020 Job No: L201 Client: Hopkins Pian No: Grade Pb (psi) F� (psi) E (psi). Parallam 2.0 PSL) 2900 290 2.00E+06 Parallam 2.2 (PSL) 2900 290 2.20E+06 Microllam (LVL) 2600 285 1.90E+06 Timberstrand (LSL) 1700 425 130E+06 Glulam (24r -V4) 2400 240 1.80E+06 1 Drypack shall be composed of one part Portland Cement -to not more than three parts sand. 2 All structural concrete f,= 3000 psi Special Inspection Required All slab-ongrade, continous footings, pad footings f ,= 2500 psi Special Inspection Not Required 1 All reinforcing shall be.A.ST,M.A-616-40 for #4 bars and smaller, & A615.60 for#5 bars and larger. Welded wire fabric to be A.S.T.M. A-185, lap 1-1/2 spaces, 9" min. 2 Development length of Tension Bars shall be calculated. per AC1318-14 Section 12.2.2 Class B Splice=1.3x1a Splice length for 2500 psi concrete is: #4 Bars (400 = 21",#5 Bars (60K) = 39", #6 Bars (60K) = 47" (30 dia. for compression) Masonry reinforcement shall have lapping of 48 dia. Or 2'-0". This is in all cases U.N.O. 3 All reinforcing bars shall be accurately and securely placed before pouring concrete, or grouting masonry. 4 Concrete protection for reinforcement shall be at least eaqual to the diameter of the bars. Cover for cast -in-place concrete shall be as follows, U.N.O. A. Concrete cast against & permenently exposed to earth ........... 3" B. Concrete exposed to earth or weather <#5 Bars .... 11/2" 2 #6 Bars ......... 2" C. Concrete no exposed to weather or in contact with ground Slabs, Walls, Joistsi5 45 Bars :.................:... 3/4" Reams R Columns: Primary reinforcement. Ties. Stiruos. Spirals .. 11/2" 1 Fabrication and erection of structural steel shall be In accordance with "Specification forthe Design, Fabrication and Erection of Structural Steel Buildings", AISC,,current edition. Steel to conform to ASTM A992. Round pipe columns shall conform to ASTM A53, Grade B. Square/Rectangular steel tubes ASTM A500, Grade B. 2 All welding shall be performed by certified welders, using the Electric Shielded Are Process at licensed shopsoratherwise approved by the. Building Department. Continuous inspection is required for all field welding. 3 All Steel exposed to weather shall be hot -dip galvanized after fabrication, or other approved weatherproofing method. 4 Where finish is attached to structural steel. Provide 1/2" dia. bolt holes -@ 4'-0" o.c. for attachment of nailer, U.N.O. See architectural drawings for finishes (Nelson studs 1/2"x 3" CPL may replace bolts) 1 Concreteblock shall be of sizes shown on architectural drawings and/or called for in specifications and conform to ASTM G90-09, Grade A normal weight units with max linear shrinkage of 0.06% 2 All vertical reinforcing In masonry walls not retaining earth shall be located In the center of the wall U.N.O. Retaining walls are to be as shown in details. 3 All cells with steel are to be solid grouted (except retaining walls where all cells.are to besolid grouted) ESI/FME INC STRUCTURAL ENGINEERS Project Name: Page: 4 Date: 7/20/2020 Job No: L201 Client: Hopkins Plan No: CODES: IBC2018 CBC 2019 ASCE72016 NDS 2018 SDPWS 2015 A. All beams #o be supported with full bearing unless noted otherwise. B. All Isolated posts and beams to have Simpson PB's, PC's and/or BCs minimum, U.N.O. C. All bearing walls on wood floors are to be supported with double joists or solid blocking, U.N.O. D. Provide 4X or 2-2x members under sole plate nailing less than 6" o/c. E. All Simpson HTT, HDU, HDQ and CS holdowns to be fastened to 4x4 post min.. U.N.O. F. All hardware is to be Simpson Strong-Tie.or approved equal. Install per mfr.'s specifications. G. All shop drawings are to be reviewed by the contractor and the architect prior to submittal for engineers review. H. All exterior walls are to be secured with 1/2" diameter x 10" anchor bolts or MASA anchors.@ 72" o.c., U.N.O. (Please call structural engineer for a fix.) L All interior walls to be secured with shot pins per manufacturer's recommendations, U.N.O. Calculations govern in all cases. Recommend Simpson 0.145" dia.,3" long PDP Powder Actuated Anchors @ 24" o.c. (ICGESR#2138) or equal. J. All conventional framed portions of structure are to be constructed per section 2308 of the CBC 2019 or IBC 2018 U.N.O. K. All nailing is to be per table 2304.10.1 of the IBC or California Building Code, U.N.O. L. All nails to be "common", U.N.O. FOUNDATION HARDWARE LEGEND SOLE PLATE NAILING SPN16: 16d Sole Plate Nailing @ 16" O.C. SCR10: 1/4" x 4.1/2" SDS Screws @ 10" O.C. SPN12: 16d Sole Plate Nailing @ 12" O.C. SCR8: 1/4" x 41/2" SDS Screws @ 8" O.C. SPN30: 16d Sole Plate Nailing @ 10" O.C. SCR6: 1/4"'x41/X' SDS Screws @ 6" O.C. SPN8: 16d Sole Plate Nailing @ 8" D.C. SCR4: 114" x41/2" SDS Screws @ 4" O.C. SPN6: 16d Sole Plate Nailing @ 6" D.C. SCR2: 1/4" x 4 1/2".505 Screws @ 2" D.C. SPN4: 16d Sole Plate Nailing :@ 4" O.C. AB32: 1/2" Dia. X 10" Anchor Bolts @ 32" O.C. or MASA Anchors @ 32" O.C. SPN2: 16d Sole Plate Nailing @ 2" O.C. HDU5 : (1) Simpson HOU5 per post FOUNDATION HARDWARE LEGEND A872: 1/2" Dia. X 10" Anchor Bolts @ 72" O.C. or MASA Anchors @ 72" O.C. 244 : Provide a total of 2-44 at top 244 at bottom of footing; 3' past post AB64: 1/2' Dia. X 10" Anchor Bolts @ "' O:C. or MASA Anchors @ 64" O.C. 344 : Provide a total of 344 at top 344 at bottom of footing, 3' past post A656: 1/2" Dia. X"10" Anchor Bolts @ 56" O.C. or MASA Anchors @ 56" O.C. 444 : Provide a.total of 444 at tap 4-#4 at bottom of footing, 3'past post AB48: 1/2" Dia. X 30" Anchor Bolts @ 48" O.C. or MASA Anchors @ 48" O.C. -HTT4 : (1) Simpson HTT4 per post A840: 112" Dia. X 10" Anchor Bolts @40" O.C. or MASA Anchors @ 40" O.C. HITS : 1) Simpson HTTS per post HDU2: (1)Simpson HDU2 per post AB32: 1/2" Dia. X 10" Anchor Bolts @ 32" O.C. or MASA Anchors @ 32" O.C. HDU4: (1) Simpson HDU4 per post. HDU5 : (1) Simpson HOU5 per post AB24: 1/2" Dia, X 10" Anchor Bolts @ 24" O,C. or MASA Anchors @ 24" O.C. HOUS : (1) Simpson HDUB per post HDQ8: (1) Simpson HDQ8 per post A816: 1/2" Die. X 10" Anchor Bolts @ 16" O.C. or MASA Anchors @ 16" O.C. HDU11.: (1) Simpson HDU11 per post 14DU14 : (1) Simpson HDU14 per post ABB: 1/2" Dia, X 10" Anchor Bolts @ a" O.C. or MASA Anchors @ 8" O.C. 11036 i (1) Simpson HD36 per post H019 s (1) Simpson HD19 per post Nate: When anchor bolts are used, provide V s4; x..229" thick plate washer for all sill plate A.B.'s atshear walls only. Project Name:. Vertical STRUCTURAL ENGI ESI FME 1 C NEE'RS Lateral Shear Nates (IBC 2018, CBC 2019, SDPWS 2015) Seismic Design Category D & E Table 4.3A, AFPA SDPWS 2015 Page: 5 Date: 7/20/2020 Job No: L201 Client: Hopkins Plan No: Framing Members: Douglas Fir -Larch @ 16" O.C. Wind Seismic 3/8" Wood Structural Panel w/ 8d Common Nails @ 6" O.C. @ Edges & 12" 0-.C. @ Field 3/8" Wood Structural Panel w/Sd Common Nails @ 4" O.C. @ Edges & 12" O.C. @ Field 3/8" Wood Structural Panel w/ ad Common Nails @ 3" D.C. @ Edges at 12" OX..@ -Field 3/8" Wood Structural Panel w/ 8o Common Nails @ 2" O.C. @ Edges & 12" C.C.. @ Field 1/2" (or 15132") Wood Structural Panel w/ 10d Common Nails @ 2" O.C. @ Edges & 12" O.C. @ Field 112" (or 15/32") Structural 1 Wood.Panel w/ 10d Common Nails @ 2" O.C. @Edges& 12" O.C. @ Field Double Sided (3x Vertical Studs @ Abutting Panels and Nails Staggered On Each Side) 318" Wood Structural.Panel w/ ad Common, Nails @ 3" O.C. @ Edges 8,12" OX. @ Field Double Sided (3x Vertical Studs @ Abutting Panels and Nails Staggered On Each Side) 12 3/8" Wood Structural Panel w/ -8d Common Nails @.2" D.C. @ Edges & 12" O.C. @ Field DBL 365 PLF 260 PLF -532. PLF 350 PLF 685 PLF 490 PLF 895 PLF 640 PLF 1077 PLF 770 PLF 1215 PLF 870 PLF 1370 PLF 980 PLF 1790PLF 1280PLF Notes a. Wood Structural Panel: Material approved by APA,PPS/TECO or Pittsburgh Testing laboratories. These values are for Doug -Fir Larch or Southern Pine, other lumber species may differ in shear capacities. b. Where. plywood Is applied on both faces of wall and nail spacing is less than 6" o.c., panel joints shall be offset to fall on different framing members or framing shall be 3x or wider and nails staggered on each side, C For allowable shearvalues greater than 350plf, provide a min. of a single 3x member at all framing members- receiving edge nailing from abutdngpanels. d. Where anchor bolts are provided at shear walls a 3"x3"x0.229"steel plate washers are required on each bolt. The washer shall be Installed within 1/2" from the sheathed side of the plate. (SDPWS sect. 4.3.6.43) Horizontal Roof: Jolst.Spacing <24" ox,: 15/32" Wood Struct. Panel PII 24/0, with Sd's @ 6" o.c. at edges & boundaries, 12" o.c. field. Floor: Joist Spacing < 16" o.c.: 19/32" Wood Struct. Panel T&G*, PI 32/16, w/10d's @';6" ox. at edges & bound, 10" o.c, field. Joist Spacing <20" o.c.: 19/32" Wood Struct. Panel T&G",PI 40/20, W/10d'3 @ G" ox. at edges &bound., 10" o.c, field. Joist Spacing <24" o.c.: 23/32" Wood Panel T&G* shtg., Pi 48/24,.w/10d's @ 6" o.c.. at edges & boundaries, 10" o.c. field. Notes a. Panel edges shall have approved T&G joints or shall be supported with blocking. Not required when lightweight concrete is placed over sub0eor. b, All roof and floor shearingto he Exposre for Exterior. ON -Caw 7c+� X09_ FOR BARS II PER GEral ODNMC R TD VMY I 12x24 M..w/(2)15 ttm I 1 1 i } I I I I I I I F0011NG LEGEND NEW 5' cave, m W/!s 0 16' O.C. Ew, OVER 2• WO W/6 0- VPPOR r-- RAMER OYER 1 BMS INTO (k7 /� WRD RE&OtS FRON' fiD 8" P6R ETAIL E 60 A FN M j� 3'-0" WN; C0.MMOR TO vam fir. marns6' �` CON=OR TO'VEIM I fitR NEW TO a tks am \�F � (� 12x2+ T&B 2150 I OR NEN TO ��aEEO i 1` I i I (Ey 4' WAC. SA 1 I I I I 1 L-----------------------------' I' 1 I i I I I I I 1 I 1 i I 1 1 I I I 1 -- (E) POOTRR. TO REUMN lf 7RWT/ (2) 15 T&S 00NCRERC i5 TYPE V. Te - 45M P51 W/fUilO , r---------- SEND I 1 I 1 f 7YP. d�-� ,��✓ e a�.�a _a -ey L?OJ Q _ Page: (t ESI/FMEINC .__ Date: 7/20/2020 [STRUCTURAL ENGINEERS Job No: L201 Client: Hopkins Project Name: Hoffmeyer Plan No: Beam ( 1 } bm at frt porch Member Span= 7.5 FT DL LL RL Total fib) X ift) Sour P1=( + + 651 lb 1223 ft -lb 7t R,(ib) R2(lb) Design: 0p.751.+-75RL 125 Total x" 651 m; 17657:` S, = M,,,,,/Fb = 14.80 Me Mm,x = 1221 ft -Ib DL 145 145 A., = S.SVR,e,/Fv= 5.43 int V,, = 651 Ib DL LL 506 RL Trib (ft) Total { Roof = ( is + + 20 ) x ( + ) _. 0 Wall =( to + + )x( + )= 0 Floor = ( 14 + 40 + ) x { + ) = 0 Deck = ( 14 + 60 + ) x ( 0.75. + 1.5 ) = 167 Floor Live Load Reduction Factor,81.00;; Self Weight = 7.2 Roof Live Load Reduction Factor 5z3 OQ4 Total = 174 MEMBER SIZE _ ( 1 ) 4 x 10 P X R, R2 Size Factor, CF =1.10 Rep. Factor, Ci = No =1 F,; = 180 PSI Fp = 900 x CF x C, = 990 PSI E = 1.60E+06 PSI W 3.501, LC Cd V/Cd M/cd Comments: 1.00 651 lb 1223 ft -lb WRL R,(ib) R2(lb) Design: 0p.751.+-75RL 125 Total x" 651 m; 17657:` S, = M,,,,,/Fb = 14.80 Me Mm,x = 1221 ft -Ib DL 145 145 A., = S.SVR,e,/Fv= 5.43 int V,, = 651 Ib LL 506 506 A, l = L/ 360 = 0.25 in 0.03 RL 0 0 AIL = 0.01 in GL6 Camber = 1.5 x dot = Ool in IN D+LL 1.00 651 lb 1223 ft -lb WRL 1.25 11616 218 ft -lb 0p.751.+-75RL 125 420 lb 787 ft -ib Stress Ratio Sp 0.d = 49.91 in' 29.7% OK AFm„aed = 32.38 int 16.8% OK A,,, = 0.03 in 13.4% OK 1.00 1.25 125 M 7/2112020 U.S. Seismic Design Maps V J H 1 V 1, ZO) 343 62nd St, Newport Beach, GA 92663, USA Latitude, Longitude; 33.628827, -117.9478514 data 02020 Type Value Description SDC. null See Section IIA.8 Seismic design category Fa 12. Site amplification factor at 0.2 second Fv. null See Section 11.4.8 Site amplification factor at 1.0 second PGA 0.688. MCEG peak ground acceleration FpeA 1.2 Site amplification factor at PGA PGApt 0.73 Site modified peak ground acceleration T11 3 Long -period transition period in seconds SsRT 1.393 Probabilistic risk-targotedground motion. (0.2 second) SsUH 1,538 Factored uniform -hazard (2% probability of exceedance in 50 years) spectral acceleration SO 2.591 Factored determimsticacceleration value. (0.2 second) S1RT OA99 Probabilistic risk -targeted ground .motion. (1.0 second) S1UH 0.543 Factored onifonn-hazard(2% probability of exceedance in 50 years) spectral acceleration. SID 0.828 Factored deterministic accoleration value. (1A second) PGAd 1.05 Factored datemiinistic acceleration value. (Peak Ground Acceleration) Cgs 0.906 Mapped value of the risk coefficient at short periods https,J/soismicmaps.org S. 113 ESI FME INC STRUCTURAL ENGINEERS Name: Hr C0 ft 8.4 65,% Zone C psf 35l Zone H, 11.0 ft 11.4 zone C I psf 1.2 ft Hy 10.0 ft 11 11.4 ZoneC psf' CE 7-16 Equivalent Lateral Force Method SS = 1.393 S1 = 0.499 Fa=1.2. Fv=1.8 SMS = Ssxpa = 1.672 Sly, = SSxF, = 0.899 $py = (2/3)xSMs = 1:114 So, _ (2/3)xSMS re 0.599 SS, Csimhf RA- 0.03$ Oa = CW Page: Date: 7/20/2020 Job No: L201 Client: Hopkins Plan No: Location 2nd5tory Weight Trib.(it) Site Information Roof = 35 psf x 30 =450 pff Zip = Floor = 14 psf x 0 = 0 pif Lattitude = 33.628827 Weight Trib: (ft) qty. Longitude = -117.9479-i-Ext. Wali = 14 psf x 5.5 x 2 =154 pif Occupancy Category = II y Int. Wall = 10 psf x. 5.5 x 2.5 =138 pif II Ext. Wall = 14 psf x S.5 x 0 = 0 plf II Int. Wall = 10 psf x 5.5 x D =0 pif 194 plf Total=742plf 1st Story Weight Trib.(ft) 1615 pif Roof = 15 psf x = 0 pif Floor = 14 psf x 28 =392 pif Weight Trlb. (ft) CRy. Trib. (ft) City. -Ext. Wali = 14 psf x ( 5.5 x 2 + 5 x 2 ) =294 pif -I-Int-Wall = 10 psf x{ 5.S 'x 2.5 + 5 x 1 )=188pff If Ext. Wall = 14 psf x { 5.5 x 0 + 5 x 0 ) = 0 plf 11 Int. Wail = 10 psf x { 5.5 x 0 + 5 x 0 ) = 0 plf 2nd Story ISt5tory Total=874pff R = 6.5 Soll Site Class = D Per ASCE7.1611.4.3 I =1.0 Seismic Design Category= D p=1.0 h„=24.2ft T = 0.218 for All OtherStmctural Systems Cs = 0.171 <-Governs EI, = .7pDs =0.120W R/L Csimaa) = sox. = 0.423. '�y,t0,120W TxR/I ASCE 7.16 Simglified Wind Design Roof Slope z: 4:12=18.4 Degrees xae=1.0 Wind Velocity =.100 mph It, = 24.2 ft Exposure = C A =1.34- „„,,.,.,..,_,.,_,.,.,_,,.,.,,._ Wind _ Level Z(P,xTrib) Fe Story Shear Wind Roof 4ftx 8.4psf+S.5ft x11.4 sf) 96 ff 96 If Leven (6.7ft x 11.4psf+Sft x SL4psf) 133 plf 229 plf23%133zRf Holitanal Pressures Veftical Preswes 107erhangsl Zone A 8 C D E F G H Eon Gan psao 21.3 -6.1 14.2 -41-19.11-13-01-13.31491-26.3 7 .20.9 Ps 17.2 -4.9 114 -2.71-15,41-10. •10.7 •6.e -23.5 •16.6 Wind at Corner Level Bld. Width a Fa Roof 45 ft 4,4 ft 67 pIf Leven 45ft 14:Oft 67p1f Comerwlnds the addltleml Wassum oppiled at wmerahearwalis: Pressore'p,' isto 6e Included for a distance'a' away fmm the comer Governing Load Level story SheNWind Roof ti127 pifSeismic Level l s��'229%133 Seismic �. WI h, Wixhl Fx. StoryShea Seismic 742 pff 22 16436.6 127 pif 127 pifIE 874 pif 10 8735 67 plf 194 plf ;x'194/67 psf Total 1615 pif 25172 „„,,.,.,..,_,.,_,.,.,_,,.,.,,._ Wind _ Level Z(P,xTrib) Fe Story Shear Wind Roof 4ftx 8.4psf+S.5ft x11.4 sf) 96 ff 96 If Leven (6.7ft x 11.4psf+Sft x SL4psf) 133 plf 229 plf23%133zRf Holitanal Pressures Veftical Preswes 107erhangsl Zone A 8 C D E F G H Eon Gan psao 21.3 -6.1 14.2 -41-19.11-13-01-13.31491-26.3 7 .20.9 Ps 17.2 -4.9 114 -2.71-15,41-10. •10.7 •6.e -23.5 •16.6 Wind at Corner Level Bld. Width a Fa Roof 45 ft 4,4 ft 67 pIf Leven 45ft 14:Oft 67p1f Comerwlnds the addltleml Wassum oppiled at wmerahearwalis: Pressore'p,' isto 6e Included for a distance'a' away fmm the comer Governing Load Level story SheNWind Roof ti127 pifSeismic Level l s��'229%133 ESI/FME INC STRUCTURAL ENGINEERS Project: Name: Page:. Date: 7/20/2020 Job No: L201 Client: Hopkins Plan No: Shearwall Design (IBC 2018, CBC 2019, SDPWS 2018) wall at front entry. Plate Height{H)=8.0ftNet Lateral Load I I Shearwall Design Length Opening Length Source WWI(plf Seismic (PIG Tributary (ft) Wind Seismic Demand Capacity Ratio Wall 1= 3.0 ft - _- 3.Oft 229 194 (2012 +2:0) =. 2748 lb 2328 lb Wind 289 plf 489 OF 0.59 Wall = 3.0 ft - 3.0 it x + = 0 l 01b Seismic 245 pH 322 pif 0.76 Wall 3= 3.5 ft - = 3.5 ft + = 016 Olb Aspect Bad WA14= - 0.Oft + _. 016 0 l 11 h(b, ` 2.7> 2.0 Wd115 = - = Q0ft + = 016 016' Aspect Ratio Factor Total Length= 9.5 ft Gamer Wind KH, �'.x _ Gib Total Load= 2748 lb 23281b 1.25-.125hfbp 0.82 Diaphragm Unit Shear (V) = Load/Length = 289 plf 245 plf 1/2 "A.B. @ 40"D.C. A840 L = 28 ft Provide A35/LTP4 @ 48" O.C. - V=98 ptf V,=168 p1f w/ 4x4 w/HDU2 Vertical load Load Trib(ft). Load Uplift Calculation Roof = 15 psf x 6.0 = 9p pif Stacking Addn'I Waif - 14 pSf x 21.0 = 294 pif Mo = VLH L=311 M"(ft-#) M Jft-#) Ma(ft-#) Ma(ft-#) UPlift(lb) NO Capacity(lb) Floor =14 psf x- 2.0 = 28 pif WLa Wind 6942 0 1854ra 0 a; 19¢3 3075 Ok Total Load (W) = 412 pit M 06 ary4 = 2 Seismic 5881 0 1854z " "' ;,0? 1670 3075 Ok Sas = 0.929 L = 3.0 ft W LZ Ma61 = 0A7 E Z E E (.6-.145as) =. 0.47 u° R E