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SOLAR-0769-2018TOWN OF QUEENSBURY 742 Bay Road, Queensbury, NY 12804-5904 (518) 761-8201 Community Development - Building & Codes (518) 761-8256 CERTIFICATE OF COMPLIANCE Permit Number: SOLAR-0769-2018 Date Issued: Tuesday, March 26, 2019 This is to certify that work requested to be done as shown by Permit Number has been completed. SOLAR-0769-2018 Tax Map Number: Location: Owner: 290.9-1-3 189 ROCKWELL RD MICHAEL FINKOWSKI Applicant:Solar Liberty Energy Systems Inc This structure may be occupied as a: Ground-Mounted Solar Panel Installation By Order of Town Board TOWN OF QUEENSBURY Issuance of this Certificate of Compliance DOES NOT relieve the property owner of the responsibility for compliance with Site Plan, Variance, or other issues and conditions as a result of approvals by the Planning Board or Zoning Board of Appeals. Director of Building & Code Enforcement TOWN OF QUEENSBURY 742 Bay Road,Queensbury,NY 12804-5904 (518)761-8201 Community Development- Building& Codes (518) 761-8256 BUILDING PERMIT Permit Number: SOLAR-0769-2018 Tax Map No: 290.9-1-3 Permission is hereby granted to: MICHAEL FINKOWSKI For property located at: 189 ROCKWELL RD In the Town of Queensbury,to construct or place at the above location in accordance with application together with plot plans and other information hereto filed and approved and in compliance with the NYS Uniform Building Codes and the Queensbury Zoning Ordinance Type of Construction Owner Name: MICHAEL FINKOWSKI Solar Panel-Residential $49,600.00 Owner Address: 189 Rockwell DR Total Value $49,600.00 Queensbury,NY 12804 Contractor or Builder's Name/Address Electrical Inspection Agency Solar Liberty Energy Systems Inc 6500 Sheridan DR,Suite 120 Buffalo,NY 14221 Plans& Specifications Ground-Mounted Solar Panel Installation $ 75.00 PERMIT FEE PAID -THIS PERMIT EXPIRES: Monday, February 17, 2020 (If a longer period is required,an application for an extension must be made to the code Enforcement Officer of the Town of Queensbury before the expiration date.) Dated at the Town of Queensbury; Friday, February 15,2019 SIGNED BY: r—S_Daj9 for the Town of Queensbury. Director of Building&Code Enforcement Office Use Only Permit#: 0'}(g - ZelB -�. Fee: $ .D 742 Bay Road, Queensbury, NY 12804 Invoice#: Ita P: 518-761-8256 www.queensbury.net SOLAR PANEL PERMIT APPLICATION • Property Owner(s): Name(s): Michael Finkowski Mailing Address, C/S/Z: 189 Rockwell Road Queensbury, NY 12804 Cell Phone: _( ) Land Line: _( ) 518 791 6620 Email: mfinkowski@roadrunner.com Project Address: 189 Rockwell Road Queensbury, NY 12804 Section Block Lot: Existing Use: l Single Family 0 2-4 Family 0 Commercial 0 Other: • Solar Contractor: Business Name: Solar Liberty Energy Systems, Inc. Contact Name: Kelli Wilson Mailing Address, C/S/Z: 6500 Sheridan Drive Suite 120 Buffalo, NY 14221 Cell Phone: _( ) Land Line: _( ) 716 634 3780 Email: kelli.wilson@solarliherty.com • Electrical Contractor: Business Name: D E ID E u v IE 'b•\ Contact Name: FEB 12 2019 Mailing Address, C/S/Z: L ""� Cell Phone: _( ) Land Line: _( )RY Email: Contact Person for Building & Code Compliance: Cell Phone: ( ) Land Line: ( Email: Solar Panel Application Revised December 2017 INSPECTION WORKSHEET (BINS-001600-2019) Town of Queensbury - Building and Codes - Fire Marshal 742 Bay Road - (518) 761-8256 Building (518) 761-8206 Fire Marshal Case Number:SOLAR-0769-2018 Case Module:Permit Inspection Date:Tue Mar 26, 2019 Inspection Status:Passed Inspector:Mark Smith Inspection Type:Solar Panel System Job Address:Parcel Number:189 ROCKWELL RD Queensbury, NY 12804 290.9-1-3 Contact Type Company Name Name Granted Permission FINKOWSKI, MICHAEL Contractor Solar Liberty Energy Systems Inc Applicant Solar Liberty Energy Systems Inc Primary Owner FINKOWSKI, MICHAEL Checklist Item Passed Comments Placement of Panels YES Ground mounted system in the front left side yard Building Inspector Notes YES Ground mounted system, inverters in the basement and garage. Mar 26, 2019 Page (1) Smith, Mark (Inspector) Estimated cost of construction: $ 49,600 Total System Capacity Rating (sum of all panels): Solar PV System: 21 .6 kW DC Select System Configuration: ® Supply side connection with micro inverters ❑ Supply side connection with DC optimizers ❑ Supply side connection with string inverter ❑ Load side connection with DC optimizers ❑ Load side connection with micro inverters ❑ Load side connection with string inverter Please sign below to affirm that all answers are correct and that you have met all the conditions and requirements to submit a unified solar permit. + iglibrk Nov 18,2018 w.chat Fcokowski(Nov 18,2018) Homeowner's Signature Date Solar Co. Representative Signature Date Solar Panel Application Revised December 2017 INSPECTION WORKSHEET (BINS-001600-2019) Town of Queensbury - Building and Codes - Fire Marshal 742 Bay Road - (518) 761-8256 Building (518) 761-8206 Fire Marshal Case Number:SOLAR-0769-2018 Case Module:Permit Inspection Date:Tue Mar 26, 2019 Inspection Status:Passed Inspector:Mark Smith Inspection Type:Solar Panel System Job Address:Parcel Number:189 ROCKWELL RD Queensbury, NY 12804 290.9-1-3 Contact Type Company Name Name Granted Permission FINKOWSKI, MICHAEL Contractor Solar Liberty Energy Systems Inc Applicant Solar Liberty Energy Systems Inc Primary Owner FINKOWSKI, MICHAEL Checklist Item Passed Comments Placement of Panels YES Ground mounted system in the front left side yard Building Inspector Notes YES Ground mounted system, inverters in the basement and garage. Mar 26, 2019 Page (1) Smith, Mark (Inspector) V) soIar 5EcEllwER cr. P li FEB 1 1 2019 L.L 1 Single Phase Inverter F— �OWN OF QUEENS3URY with HD-Wave Technology BUILDING&CODES OC for North America I I I SE3000H-US / SE3800H-US / SE5000H-US / > SE6000H-US / SE7600H-US / SE10000H-US '� si,i4 f, g "' ., : ?4, A "fix` i :I76+,.-.- ;. .. "_ ter. _' ,.x '-� --I—Az'n . ,, r. solar= ....HD r, s 'a . 4 0 solar : ,,,, ),',, ,w e,te, f,; s -r, d Vears TEEM Wa'3""' CO JITAITE;. +aa,ana� Q -D :3 . C •••• Q CD 4 • . . . Q C o - o cogs o • — • M (n V RI ♦ Ur • • •en 0Y cG L- o) .T co O (NI LL r- V) Optimized installation with HD-Wave technology ir Specifically designed to work with power optimizers Record-breaking efficiency SW Fixed voltage inverter for longer strings SW Integrated arc fault protection and rapid shutdown for NEC 2014 and 2017,per article 690.11 and 690.12 SW UL1741 SA certified,for CPUC Rule 21 grid compliance SW Extremely small — High reliability without any electrolytic capacitors lijil,-..mil rtia — Built-in module-level monitoring III01[Itli1/ 1111160 — Outdoor and indoor installation waves • Optional:Revenue grade data,ANSI C12.20 Class 0.5(0.5%accuracy) www.solaredge.us solar - • . mIr Single Phase Inverter with HD-Wave Technology for North America SE3000H-US I SE3800H-US I SE5000H-US SE6000H-US/ SE7600H-US I SE10000H-US SE3000H-US SE3800H-US SE5000H-US SE6000H-US SE7600H-US SE10000H-US OUTPUT 3800 @ 240V 6000 @ 240V ' ; Rated AC Power Output 3000 5000 7600 10000 VA 3300 Q 208V 5000 e 208V 3800 @ 240V 1 6000 @ 240V Max.AC Power Output 3000 5000 7600 10000 VA 3300 @ 208V 1 5000 @ 208V AC Output Voltage Min.-Nom.-Max.(183-208-229) . V - I I .4 - - Vac AC Output Voltage Min.-Nom.-Max.(211-240-264) ' V V / I V V V Vac AC Frequency(Nominal) 59.3-60-60.5(" Hz Maximum Continuous Output Current 208V - 16 - I 24 - - A Maximum Continuous Output Current9240V 12.5 16 21 I 25 32 42 A GFDI Threshold 1 A Utility Monitoring,Islanding Protection,Country Configurable Thresholds Yes INPUT Maximum DC Power 4650 : 5900 I 7750 1 9300 I 11800 I 15500 W Transformer-less,Ungrounded Yes Maximum Input Voltage 480 Vdc Nominal DC Input Voltage . 380 1 400 Vdc Maximum Input Current 208V - 9 - 13.5 - I - I 1 Maximum Input Current@240V 8.5 J 10.5 13.5 16.5 i 20 27 Adc Max.Input Short Circuit Current 45 Adc Reverse-Polarity Protection . Yes Ground-Fault Isolation Detection 600ku Sensitivity Maximum Inverter Efficiency 94 99.2 % CEC Weighted Efficiency 99 % Nighttime Power Consumption <2.5 W ADDITIONAL FEATURES Supported Communication Interfaces RS485,Ethernet,ZigBee(optional),Cellular(optional) Revenue Grade Data,ANSI C12.20 Optionalm Rapid Shutdown-NEC 2014 and 2017 690.12 Automatic Rapid Shutdown upon AC Grid Disconnect STANDARD COMPLIANCE Safety UL1741,UL1741 SA,UL1699B,CSA C22.2,Canadian AFCI according to T.I.L.M-07 Grid Connection Standards IEEE1547,Rule 21,Rule 14(HI) Emissions FCC Part 15 Class B INSTALLATION SPECIFICATIONS AC Output Conduit Size/AWG Range 3/4"minimum/20-4 AWG 3/4"minimum DC Input Conduit Size/#of Strings/AWG Range 3/4"minimum/1-2 strings/14-6 AWG /1-3 strings/ 14-6 AWG 21.3 x 14.6 Dimensions with Safety Switch(HxWxD) 17.7 x 14.6 x 6.8 /450 x 370 x 174 x 7.3/540 x mm 370 x 185 Weight with Safety Switch 22/10 I 25.1/11.4 I 26.2/11.9 38.8/17.6 lb/kg Noise <25 <50 dBA Cooling Natural Convection Natural convection Operating Temperature Range -13 to+140/-25 to+600)(-40"F/-40*C option)14) 'F/'C Protection Rating NEMA 3R(Inverter with Safety Switch) (,)For other regional settings please contact SolarEdge support (2'Revenue grade inverter P/N:SExxxxH-US000NNC2 (')For power de-rating information refer to:https://www.solaredge.com/sites/default/files/se-temperature-derating-note-na.pdf W-40 version P/N:SExxxxH-US000NNU4 CD Ro HS CO SolarEdge Technologies,Inc.All rights reserved.SOLAREDGE.the SolarEdge logo.OPTIMIZED BY SOLAREDGE are trademarks or registered trademarks of SolarEdge Technologies.Inc.All other trademarks mentioned herein are trademarks of their respective owners.Date:05/2018/VO1/ENG NAM.Subject to change without notice. 1111111 SunmoduleY Plus SOLARWORLD SW 285-300 MONO (33mm frame, 5 busbar) REAL VALUE i , TUV Power controlled: _ -.---^^ '" f TUVRhNdaud i Lowest measuring tolerance in industry I ERTIFIEO 1 l [lI! Every component is tested to meet 3 times IEC requirements Rf1ABIE 0 T ,......._ , .._., _ f.,„ , Designed to withstand he v , . 1 L6 � l'J �', ♦ _ accumulations of snow an J I MAX.LOADi ow Pants pft 0 . FEB 1 1 2019 J i I Sunmodule Plus: TOWN OF OUEENBBURY O BUILDING&CODES ♦___. T. Positive performance toter nce - -0/+S Wp O ' -- - ZS10 25-year linear performance warranty and 10-year product warranty WARRANTY O ; '� Glass with anti-reflective coating Anti•ReRectireO . Coating .. World-class quality •Qualified,IEC 6121S •SafetBlowing tested,!EC si 61730 0 8 v •Blowing sand resistance,IEC 60068 2 68 \ Fully automated production lines and seamless monitoring of the process and mate- E • •Ammonia resistance,AC 62716 10.1 rial ensure the quality that the company sets as its benchmark for its sites worldwide. •PeriodicIt nspecton'1EC61p1 C us UL 1703 •Periodic controlled ion SolarWorld Plus-Sorting •Po Power Plus-Sorting guarantees highest system efficiency.SolarWorld only delivers modules ISO9001 that havegreater than or equal to the nameplate ratedpower. ( ( I,_ Li ISO 14001 q P Home Innovation G85 GREEN CERlfiED_ Certified 25-year linear performance guarantee and extension of product warranty to 10 years SolarWorld guarantees a maximum performance digression of 0.7%p.a.in the course ovE of 25 years, a significant added value compared to the two-phase warranties com- nncs (;) GS mon in the industry,along with our industry-first 10-year product warranty.* `in accordance with the applicable SolarWorld Limited Warranty at purchase. www.solarworIcI.E0m/warranty ell ■E■ MADE IN sola rworld.com IMPORTED COMPONENTS 1111111 Sunmodule Plus SOLARWORLD SW 285-300 MONO (33mm frame, 5 busbar) E '. PERFORMANCE UNDER STANDARD TEST CONDITIONS(STCr SW 285 SW 290 SW 295 SW 300 Maximum power Pm„ 285 Wp 290 Wp 295 Wp 300 Wp Open circuit voltage V„ 39.7 V 39.9 V 40.0 V 40.1 V Maximum power point voltage V,„ 31.3 V 31.4 V 31.5 V 31.6 V Short circuit current Ise 9.84 A 9.97 A 10.10 A 10.23 A Maximum power point current 1, 9.20 A 9.33 A 9.45 A 9.57 A Module efficiency q,,. 17.00% 17.30% 17.59% 17.89 •STC:1000W/m,25'C,AM 1.5 PERFORMANCE AT 800 W/M2,NOCT,AM 1.5 SW 285 SW 290 SW 295 SW 300' Maximum power P, 213.1 Wp 217.1 Wp 220.5 Wp 224.1 Wp Open circuit voltage V, 36.4 V 36.6 V 36.7 V 36.9 V I Maximum power point voltage Vop 28.7 V 28.8 V 28.9 V 31.1 V Short circuit current 1„ 7.96 A 8.06 A 8.17 A 8.27 A Maximum power point current I oP 7.43 A 7.54 A 7.64 A 7.75 A Minor reduction in efficiency under partial load conditions at 25°C:at 200 W/m2,100%of the STC efficiency(1000 W/m')is achieved. *Preliminary values,subject to change. COMPONENT MATERIALS I loon w/m' Cells per module 60 Front Low iron tempered glass 800 W/rn' with ARC(EN 12150) a I - 60oW m' Cell type Mono crystalline Frame Clear anodized aluminum / 5 bus bar aoo W/m' 6.17 in x 6.17 in Cell dimensions (156.75 x156.75 mm) Weight 39.7 lbs(18.0 kg) zoo w/mr THERMAL CHARACTERISTICS ADDITIONAL DATA too W/m' NOCT 46*C Power sorting -0 Wp/+5 Wp Module voltage[VI V TCI,, 0.04%/K 1-Box IP65 37.8(961) TCV, -0.30%/K Connector PV wire per UL4703 with H4 connectors 1 u - TCP, -0.41%/K 4.20 (t405) ,-'-o%H Module fire performance (UL 1703)Type 1 i 4x - Operating temp -40'C to+85'C _ T - _ 7.12 00.26(6.6) (180.85) PARAMETERS FOR OPTIMAL SYSTEM INTEGRATION - ' 00.35(9) o o Maximum system voltage SC Il/NEC 1000 V 0 o Maximum reverse current 25 A Number of bypass diodes 3 o ° Design loads' Two rail system 113 psf downward,64 psf upward 0 a _J V Design loads' Three rail system 178 psf downward,64 psf upward Design loads' Edge mounting 178 psf downward,41 psf upward Please refer to the Sunmodule installation instructions for the details associated with these load cases. 0 o D4310I •Compatible with both"Top-Down" - e 00.35(9) and"Bottom"mounting methods oo0o0 1 11.32 •-'-Groundin g Locations: (287.50) I ,, -4locations along the length of the module in the extended flange. 1 39.4(1001) I y 1.30(33) All units provided are imperial.SI units provided in parentheses. ``' 5olarworld AG reserves the right to make specification changes without notice. S W-01-7510 US 07-2015 t P E P E STRUCTURAL CALCULATIONS FOR GROUND-MOUNTED SOLAR PANEL INSTALLATION CLIENT PV Racking Inc. 505 Keystone Road rr '1) >- E Southampton, PA 18966 Ste' 00 = N f o 1 PROJECT OWNER o irl Finkowski Residence N c CO Q- 189 Rockwell Road co 2 Li- z_' Queensbury, NY 12804 9 11 1,-- n 0 ,---- , ix c STRUCTURAL ENGINEER N a Richard Grow, P.E. v Ce N 1508 Devereaux Avenue g as c Philadelphia, PA 19149 M Y = nt WI o, oI° a DATE O c v) 2February 6, 2019 N ii °r-° V) ��ofNEWYO, k p 0,fok IL Fi v., alit F.R r1 !./� ice, 2 0878 P 4 PPOFESSO P E P E I 3 February 6, 2019 P E Richard Grow, P.E. 1508 Devereaux Avenue Philadelphia, PA 19149 Telephone: (267) 423-7099 /Email:richgrowpe@gmail.com To: Town of Queensbury Department of Buildings & Codes 742 Bay Road Queensbury, NY 12804 Re: Structural Evaluation and Verification for Installing Ground Mounted Solar Panel Array System Project Name: Finkowski Residence Project Location: 189 Rockwell Road Queensbury, NY 12804 I have reviewed the PV Racking Ground Mount System Installation Guide instructions which shall be applied for the solar module installation at the above-referenced residential property. The Installation Guide consists of the racking components and installation guidelines for mounting the solar photovoltaic (PV) modules in the configuration drawings illustrated by PV Racking Inc. All applicable load cases were evaluated in determining the governing load case. Maximum post (leg) reaction forces represent the highest load condition seen by any post (leg) in the structure. All posts (legs), diagonal members (bracing), horizontal beams, and sloped beams use the allowable stress method where the design verification is based on: I. ASCE 7-16, Minimum Design Loads for Buildings and Other Structures American Society of Civil Engineers/Structural Engineering Institute (ASCE/SEI)—2016 II. Steel Design Manual, 15th Edition, American Institute of Steel Construction (AISC) - 2017 III. New York State Building Code with 2017 Supplement—International Council of Building Officials—2018 All structural elements analyzed in the ground-mounted solar panel structure use the allowable stress design method. Load criteria is established in the structural calculations and are summarized below: Risk Category I Design Wind Speed = 105 mph Exposure Category B Importance Factor= 1 (Category II) Ground Snow Load = 50 psf Design Dead Load= 5.40 psf(based on total weight) Governing Load Cases: dead load+ snow load and 60% dead load+ 60% wind load 1 Net design wind pressures were calculated in accordance with ASCE 7-16, Figure 30.7-1, "Net Wind Pressure Coefficients on Open Buildings with Monoslope, Free Roofs—Open Buildings". All applicable load cases were evaluated in determining the governing load case; here it is shown that 60% dead load+ 60% wind load (uplift) and dead load plus snow load (downward) governs the structural design. Soil data obtained from Web Soil Survey (http://websoilsurvey.sc.egov.usda.gov) describes the in-situ subgrade as Oakville loamy fine sand, 3%-8% slopes. A typical profile consists of 8 inches of loamy fine sand, and then followed by a stratum of sand from 8 inches to 60 inches below grade. The soil designation for the Oakville loamy fine sand as per Soil Classification System is SM (sandy loam) for all strata and SP (sandy gravel) for all strata except the top stratum. The parent material is made of sandy eolian, beach ridge or glaciofluvial deposits. On average, the Oakville loamy fine sand composition is 91% sand, 7% silt, and 2% clay. The Oakville loamy fine sand is well-drained and the water table is more than 80 inches below ground. Frost action is low and the soil exhibits a low risk of corrosion to uncoated steel, and a moderate risk of corrosion to concrete, so using drilled concrete shafts or steel helical piles are permissible to support the ground mounted solar panel system framing. I hereby certify that Solarworld DC 300 solar panel modules—model SW DC300, and the PV Racking ground-mounted racking system assembly, when installed correctly with their respective product specifications, resist the dead load, snow load and wind uplift load. From the structural analysis performed based on dead load plus snow load and then dead load plus wind load, it is determined that the structural framing is designed to carry to support the solar PV panels attached to the ground mounted steel frame structure based on the applicable structural design codes adopted by the State of New York. oaf NEW yo', cerely, �Q'� Aµ0 C Gip0 4- r ' %-ocililit a el Y 0 . PFO B :24 • PA'OFESS% 2 loads summary Dead Load Parameters length of one solar panel module 1= 5.50 ft Solarworld DC 300 solar modules(length=65.95 in) width of one solar panel module w= 3.28 ft Solarworld DC 300 solar modules(width=39.37 in) length of solar panel array L= 39.37 ft L=12w width of solar panel array B= 10.99 ft B=2 xl solar panel installation area A= 433 ft2 A=B x L weight of each solar panel module P= 39.69 lbf Solarworld DC 300 solar modules(weight=23.0 kg) number of solar panels N= 24 see structural drawings total weight of solar panels on structure Wp= 952 lbf Wp=N x P number of"north side"posts NN= 4 see design drawings number of"south side"posts Ns= 4 see design drawings height of"north side"posts HN= 6.83 ft see structural drawings(82 in) height of"south side"posts Hs= 4.00 ft see structural drawings(48 in) number of diagonal bracing in N-S direction NDB= 4 see structural drawings spacing of posts in N-S direction SNs= 4.83 ft see structural drawings(58 in) length of diagonal bracing in N-S direction LDB= 8.37 ft LDB=(SNs2+HNZ)u2 number of inclined beams(span in N-S direction) NIB= 13 see structural drawings pitch angle of solar array 9= 30° see structural drawings supported span/center span of inclined beam Les= 5.58 ft see structural drawings(SNs/cos 9) cantilevered span/overhang span of inclined beam Los= 2.80 ft see structural drawings(33.51 in) span of inclined beams LIB= 11.18 ft LIB=Los+Los number of horizontal beams(span in E-W direction) NHB= 2 see structural drawings span of horizontal beams LHB= 39.37 ft same as length of solar panel area weight of horizontal members per linear foot wi= 7.31 plf AISC Table 1-11(HSS 5x4x1/8) weight of inclined members per linear foot w2= 4.75 plf AISC Table 1-11(HSS 4x2x1/8) weight of steel posts per linear foot w3= 2.72 plf HSS 1-1/2 x 1/8"pipe members weight of diagonal bracng per linear foot w4= 2.27 plf HSS 1-1/4 x 1/8"pipe members total weight of aluminum horizontal members WI= 576 lbf WI=wl x NHB x LHB total weight of aluminum inclined members W2= 691 lbf W2=w2 x NIB x LIB total weight of steel posts W3= 118 lbf W3=W3 x (NN HN+Ns Hs) total weight of diagonal bracing W4= 76 lbf W4=w4 x NDB x LDB total dead load of solar panels and framing D= 2336 lbf D=W f+W2+W3+W4+WP design dead load for entire ground mount array PDT= 5.40 psf pm= D/A Wind Load Parameters: wind exposure category B refer to ASCE-7,sections 26.7-2&26.7-3 design wind speed v= 105 mph ASCE 7-16,Figure 26.5.1A,u.n.o.(category I structure) elevation factor Kt,= 0.70 ASCE 7-16,Table 30.3-1(height<30 ft) topographic factor K,,,= 1.00 ASCE 7-16,Figure 26.8-1 directionality factor Ka= 0.85 ASCE 7-16,Table 30.3-1 design wind pressure q,= 16.79 psf q,=0.00256 K1,Kn Kd v2(ASCE 7-16,Equation 30.3-1) mean roof height h= 5.42 ft from structural drawing,average of 56"&105" roof dimension parameter a= 3 ft ASCE 7-16,Figure 30.7-1(monosloped roof) tilt angle/pitch 6= 30° see structural drawings external net wind pressure coefficient GCN= -2.125 ASCE 7-16,Figure 30.7-1(monosloped roof&G=0.85) horizontal wind pressure qn= -35.69 psf q,=q,GCN importance factor Iw= 1.00 Occupancy Category II(wind) vertical wind pressure(uplift) U= -35.69 psf U=qi,GCN Iw vertical wind force(uplift) W= -15443 lbf W=U x A Snow Load Parameters: snow importance factor I,= 1 ASCE 7-16,Table 1.5.1(Category II) ground snow load pg= 50 psf ASCE 7-16,Figure 7.2-1,u.n.o. exposure factor C"= 0.9 ASCE 7-16,Table 7.3-1 thermal factor C,= 1 ASCE 7.16,Table 7.3-2 flat roof snow load pf= 31.5 psf ASCE 7-16,Equation 7.4.1 slope factor C.= 1 ASCE 7-16,Figure 7.4-1(pitch=30°) design snow load p,= 31.50 psf ASCE 7-16,Equation 7.3-1 (set S=p,for load cases below) solar panel installation area A= 433 ft2 A=BxL obtained from wind load calculations weight of snow from design snow load S= 13631 lbf S=p,x A Allowable Stress Design Load Cases dead load D 2336 lbf ASD load case 1 dead load+snow load D+S 15968 lbf ASD load case 3(governs) dead load+45%of wind load+75%of snow load D+0.45W+0.75S 5611 lbf ASD load case 6a 60%dead load+60%of wind uplift 0.6D+0.6W -7864 lbf ASD load case 7 3 PV inclined rail (DL + SL) uniform dead load-snow load L2 Li L2 .\ 12 12 7 RA Rs 7 Inclined Beam/Rail Span Applied Loads on Inclined Beam/Rail total inclined beam span L= 11.17 ft sheet 2 of 6 tributary width t= 3.30 ft see sheet 5 of 6 of structural layouts main span L1= 5.58 ft center span=98.15" design dead load DL= 5.40 psf obtained from loads layout cantilevered span L2= 2.79 ft L2=(L-LI)/2 design snow load SL= 31.50 psf obtained from loads layout slope/pitch 0= 30° sheet 2 of 6 Design Uniform Load uniform dead+snow load WDL+sL= 73.12 plf wDL+sL=(DL+SL)x t design uniform dead+snow load w= 84.43 plf w=wDL+sL/cos 0 Actual versus Allowable Shear inclined beam span L= 11.17 ft L=21,+L1 reaction @ short post R1= 471 lbf R1=wL/2 reaction @ tall post R2= 471 lbf R2=wL/2 axial force carried by short post R'1= 408 lbf R'1=RI cos 0 compression axial force carried by tall post R'2= 408 lbf R'2=R2 cos 0 compression maximum shear Vma,= 408 lbf Vma:=maximum absolute value obtained at supports depth of inclined beam/rail d= 4.00 in HSS4x2x1/8 web thickness of inclined beam/rail tw= 0.125 in HSS4x2x1/8 area of web Aw= 1.00in2 Aw=2dxt elastic modulus E= 29000 ksi steel yield strength Fy= 50.00 ksi steel web shear plate buckling factor k„= 5.34 AISC Steel Construction Manual,Section G2(b) web depth to thickness ratio h/t= 31.50 AISC Steel Construction Manual,Table 1-11 limiting web depth to thickness ratio h/t.= 61.22 AISC Steel Construction Manual,Section G2(b) web shear correction coefficient Cv1= 1.00 AISC Steel Construction Manual,Equation G2-3 nominal shear load capacity V,= 30.00 k AISC Steel Construction Manual,Equation G2-1 factor of safety ll = 1.67 shear allowable shear Vanow= 17964 lbf Ve11oµ,=V./52„ OK Actual versus Allowable Flexural Moment maximum flexure moment for supported span Mm'xi= -7 lbf-in Mma,l=wL12/8-wL22/2 maximum flexure moment for cantilever span Mma,,2= 3951 lbf-in Maxi=wL22/2 maximum flexural moment Mma,,= 3951 lbfin Mmax=max{Mma:i,Mmax2} plastic modulus @ x-axis Z„= 1.66 in' AISC Steel Construction Manual,Table 1--11 plastic moment by yielding Mp= 83.00 k-in AISC Steel Construction Manual,Equation F7-1 section modulus @ x-axis S„= 1.32 in3 AISC Steel Construction Manual,Table 1--11 flange width b= 2.000 in HSS4x2x1/8 flange thickness tf= 0.125 in HSS4x2x1/8 flange width to thickness ratio b/tf= 14.20 AISC Steel Construction Manual,Table 1--11 flexural moment for flange local buckling M„1= 115.22 k-in AISC Steel Construction Manual,Equation F7-2 flexural moment for web local buckling M„2= 88.76 k-in AISC Steel Construction Manual,Equation F7-6 supported span of inclined beam Lb= 5.58 ft design(same as L1) radius of gyration @ y-axis ry= 0.83 in AISC Steel Construction Manual,Table 1--11 polar moment of inertia J= 2.200 in' AISC Steel Construction Manual,Table 1--11 gross cross section area Ag= 1.300 in2 AISC Steel Construction Manual,Table 1--11 limiting unbraced length for yielding L5= 5.31 ft AISC Steel Construction Manual,Equation F7-12 limiting unbraced length for lateral torsional buckling Lr= 146.85 ft AISC Steel Construction Manual,Equation F7-13 flexural moment for lateral torsional buckling M„3= 82.93 k-in AISC Steel Construction Manual,Equation F7-10 nominal flexural moment(local buckling) M„= 82.93 k-in M„=min{M„1,Mn2,Mn3} factor of safety (lb= 1.67 flexure allowable flexural moment Mao.= 49659 lbf-in Marrow=M./11, OK Actual versus Allowable Deflection moment of inertia @ x-axis Ia= 2.65 in' AISC Steel Construction Manual,Table 1--11 flexural rigidity EI= 76850 k-in' based on values for E and Ix above maximum supported deflection Am,=i= -0.027 in Ama,l=wL22(5L22-24L12)/384EI allowable supported deflection Aauow1= 0.279 in Aanowi=Li/240(dead load+snow load) OK maximum cantilever deflection Ama:2= 0.014 in Ama:2=wL14/8El allowable cantilever deflection Aallow2= 0.140 in Ae11ow2=L1/240(dead load+snow load) OK 4 horiz beam analysis (DL+ SL) uniform distributed dead load+snow load A B C D angle 0= 30 deg Alt rI SNs= 4.83 ft L2 L, 1 I., I,, L2 I Los= 2.79 ft ft, It,; beam subspan L,= 12.19 ft sheet 2 of 6 design dead load DL= 5.40 psf cantilever span L2= 2.00 ft sheet 2 of 6 design snow load SL= 31.5 psf number of subspans n= 3 sheet 2 of 6 tributary width t= 4.84 ft t=SNs/2+Los cos 9 total horizontal beam span L= 40.57 ft L=nL,+21.2 uniform distributed load w= 178.41 plf w=(DL+SL)x t reactions at supports Rq= 1227 lbf Ri,=2wLi/5+w12 locations where shear is zero xi= 4.876 ft x,=2L45 Re= 2392 lbf Rs= 11wLi110 (measured from left-right x2= 6.095 ft x2=Lil2 Re= 2392 lbf Re=I1wLi/10 for each subspan) xs= 7.314 ft x2=3L,/5 Ro= 1227 lbf Ro=2wL1/5+wL2 SHEAR DISTRIBUTION xl x xs I. L, I., Li L2 FLEXURE DISTRIBUTION M',na„ M'max2 Woo.F_1IIIIlI' L, L, M maul m.x M ma. Mma.l flexural momenta A each rapport flexural moments A each subspan M max,= 356.83 lbf-ft M„.i=wL22/2 • M'.„.= 1764.09 lbf ft M'max,=2wL,2/25•wL22/2 Mm..x= 3007.97 lbf-ft M, =wL,2/10+wLt2/2 M{ma.x= 305.96 lbf-ft M`m.ix=wLi2140-wL22/2 M,,,,,,,,= 3007.97 lbf-ft M m..a=wL,2I10+wL22/2 M`ma.s= 1764.09 lbf-ft M'm,xa=2wL,2/25-wL22/2 M-m..r= 356.83 lbf-ft M-„,,=wL22/2 Allowable Shear in Horizontal Beam maximum transverse shear in horizontal beam Vm..= 2392 lbf obtained from shear distribution and beam reactions from above depth of horizontal beam d= 5 in HSS5x4x1/8 web thickness of rectangular beam member t„= 0.125 in HSS5x4x118 area of web A„= 1 25 in2 A„=2d x t elastic modulus E= 29000 ksi steel yield strength of horizontal beam member Fy= 50.00 ksi steel web plate buckling coefficient It,= 5.00 AISC Steel Construction Manual.Section G2.2(b) web depth to thickness ratio hit= 40.10 AISC Steel Construction Manual,Table 1--11 limiting web depth to thickness ratio hit„= 59.24 AISC Steel Construction Manual.Section G2(a) web shear correction coefficient C,1= 1 AISC Steel Construction Manual.Equation G2-3 nominal shear load capacity V„= 37.50 k AISC Steel Construction Manual.Equation G2-6 factor of safety Sl,= 1.50 shear allowable shear V,,,,,,.= 25000 lbf V.j,o„=V„I Cl, OK Allowable Flexural Moment in Horizontal Beam maximum flexural moment @ subspan M,,,xl= 306 lbf-ft obtained from moment distribution from beam reactions from above maximum flexural moment @ supports Mm,x2= 3008 lbf-ft obtained from moment distribution from beam reactions from above plastic modulus @ x-axis Z.= 3.50 in' AISC Steel Construction Manual,Table 1--11 plastic moment by yielding Ms= 175.00 k•in AISC Steel Construction Manual,Equation F7.1 section modulus @ x-axis S,= 2.97 in' AISC Steel Construction Manual.Table 1-11 flange width b= 4.000 in HSS5x4x1/8 flange thickness tr= 0.125 in HSS5x4x1/8 flange width to thickness ratio b/tr= 32.00 AISC Steel Construction Manual,Table 1--11 flexural moment for flange local buckling M„,= 155.30 k-in AISC Steel Construction Manual.Equation F7-2 flexural moment for web local buckling M„a= 181.10 k-in AISC Steel Construction Manual.Equation F7-6 supported span of horizontal beam L.= 10.50 ft design radius of gyration @ y-axis ry= 1.62 in AISC Steel Construction Manual,Table 1--11 polar moment of inertia J= 9.66 in' AISC Steel Construction Manual,Table 1-11 gross cross section area A,= 2.00 in2 AISC Steel Construction Manual Table 1-11 limiting unbraced length for yielding Li,= 12.78 ft AISC Steel Construction Manual.Equation F7-12 limiting unbraced length for lateral torsional buckling L,= 331.09 ft AISC Steel Construction Manual Equation F7.13 nominal flexural moment(local buckling) M,= 155.30 k-in M„=min(M„i,M,2) factor of safety Sly= 1.67 flexure allowable flexural moment Mayo„= 7749 lbf-ft M,a,„=M.I Wb OK Allowable Deflection in Horizontal Beam moment of inertia @ x-axis I,= 7.42 iu' AISC Steel Construction Manual.Table 1--11 flexural rigidity El= 215180 k-in2 based on values for E and Ix above maximum supported deflection in first subspan 4„,.„.= 0.000 in q,,.an=5wxi'/24EI-wL22xi2/4E1 (take absolute value if the result is negative) maximum supported deflection in second subspan A.m.= 0.029 in Am„g=5wx24/24EI-wL22x22I4E1 (take absolute value if the result is negative) maximum supported deflection in third subspan A„,,xc= 0.094 in Am„c=5wx,'/24EI-wL22x22/4EI (take absolute value if the result is negative) maximum supported deflection Amax,= 0.094 in 4.a.i=max(q,,,,,,,Ama,s.Ama,c) allowable supported deflection A,a,„t= 0.610 in A,it,,,,=Li/240(dead load+snow load) OK maximum cantilever deflection Am„2= 0.003 in 4m„2=wL2°/8E1 (take absolute value if the result is negative) allowable cantilever deflection Ay,o„2= 0.100 in 5.a,w2=L2I240(dead load+snow load) OK 5 brace&post analysis (DL+SL) Forces and Moments Transferred to Structural Elements reaction force transferred from inclined beam/rails Pi= 408 lbf obtained from analysis of inclined beam flexural moment transferred from inclined beam/rails M1= 329 lbf-ft obtained from analysis of inclined beam angle of inclination for sloped beam/rails 0= 30° see design layout height of south side posts hs= 4.00 ft see design layout("south post height"=48.00 in) spacing between north and south posts 11= 4.83 ft see design layout(spacing=58.00 in) orientation of diagonal brace a= 39.61° a=tan 1(hi11) maximum reaction force transferred from horizontal beam P2= 2061 lbf obtained from analysis of horizontal beam flexural moment transferred from horizontal beam to post M2= 3345 lbf-ft obtained from analysis of horizontal beam height of north side posts hN= 6.83 ft see design layout("north post height"=82.00 in) spacing between each post along east-west direction 12= 12.19 ft see design layout(sheet 2 of 6) orientation of diagonal brace R= 29.27° R=tan 1(hN/12) Vertical Post Design(north side posts) total axial load applied to north side post PN= 2469 lbf PN=P1+P2 cross sectional area for each post/column A= 0.75 in2 1 1/2"diameter,Schedule 40 pipe yield stength Fy= 35.00 ksi AISC,Table 2-4 elastic modulus E= 29000 ksi steel end fixity factor K= 0.70 top end fixed and bottom end pinned north side column height L1= 82.00 in see design layout(sheet 2 of 6) effective length of diagnal brace KL= 57.40 in KL=KL1 radius of gyration r= 0.625 in 1 1/2"diameter,Sched 40 pipe effective slenderness ratio KIJr= 91.84 for use in computing buckling capacity slenderness ratio threshold 4.71(E/F)112= 135.58 AISC,Section E3(a) Euler buckling stress Fe= 33.93 ksi AISC,Equation E3-4 critical buckling stress F°,.= 29.76 ksi AISC,Equation E3-3 nominal compression load P„= 22290 lbf P„=F°r A factor of safety S2°= 1.67 compression allowable compression load Can°w= 13347 lbf Ca11°w=P„/S2° OK Vertical Post Design(south side posts) total axial load applied to south side post Ps= 2469 lbf Ps=Pi+P2 cross sectional area for each post/column A= 0.75 in2 1 1/2"diameter,Schedule 40 pipe yield stength Fy= 35 ksi AISC,Table 2-4 elastic modulus E= 29000 ksi steel end fixity factor K= 0.70 top end fixed and bottom end pinned south side column height L2= 48.00 in see design layout(sheet 2 of 6) effective length of diagnal brace KL= 33.60 in KL=KL2 radius of gyration r= 0.952 in 2 7/8"outer diameter,RISC Table 1-14 effective slenderness ratio KL/r= 35.29 for use in computing buckling capacity slenderness ratio threshold 4.71(E/Fy)1'2= 135.58 AISC,Section E3(a) Euler buckling stress Fa= 229.77 ksi AISC,Equation E3-4 critical buckling stress F„r= 32.84 ksi AISC,Equation E3-2 nominal compression load P„= 24596 lbf P„=For A factor of safety 0°= 1.67 compression allowable compression load Callow= 14728 lbf Callow=P„/S2° OK Diagonal Brace Design(member spans along north-south direction) length of diagonal brace L1= 6.27 ft L1=(hs2+112)112 tension carried by diagonal brace Ti= 308 lbf T1= RN sin 0/cos a+ (Ml/L1)tan a cross sectional area A= 0.469 in2 1 1/4"outer diameter,AISC Table 1-14 yield stength Fy= 35.00 ksi AISC,Table 2-4 nominal tension load P„= 16415 lbf P„=Fy A factor of safety S2t= 2.00 tension allowable tension load Tallow= 8208 lbf Tallow=P„/S2t OK Diagonal Brace Design(member spans along east-west direction) length of diagonal brace L2= 13.97 ft L2=(hN2+122)112 tension carried by diagonal brace T2= 154 lbf T2= M2/L2 tan R cross sectional area A= 0.469 in2 1 1/4"outer diameter,MSC Table 1-14 yield stength Fy= 35.00 ksi AISC,Table 2-4 nominal tension load P„= 16415 lbf P„=Fy A factor of safety S2t= 2.00 tension allowable tension load Tallow= 8208 lbf Tallow=P„/S2t OK 6 • PV inclined rail--0.6(DL+WL) uniform 60%dead load+60%wind load L2 Li L2 12 12 ' 0 RA Rr1 0 Inclined Beam/Rail Spans Applied Loads on Inclined Beam/Rail total inclined beam span L= 11.17 ft sheet 2 of 6 tributary width t= 3.30 ft see sheet 5 of 6 of structural layouts main span Li= 5.58 ft center span=98.15" design dead load DL= 5.40 psf obtained from loads layout cantilevered span L2= 2.79 ft L2=(L-L1)/2 design wind load WL= -35.69 psf obtained from loads layout slope/pitch 0= 30° sheet 2 of 6 Design Uniform Load uniform dead+wind load wDL+wL= -60.02 plf wDL+wL=0.6x(DL+WL)x t design uniform dead+wind load w= -69.30 plf w=wDL+wL/cos 0 Actual versus Allowable Shear inclined beam span L= 11.17 ft L=2L2+L1 reaction @ short post R1= -387 lbf R1=wL/2 reaction @ tall post R2= -387 lbf R2=wL/2 axial force carried by short post R'1= -335 lbf R'1=R1 cos 0 tension axial force carried by tall post R'2= -335 lbf R'2=R2 cos 0 tension maximum shear V,,,,,,= 335 lbf Vm„x=maximum absolute value obtained at supports depth of inclined beam/rail d= 4.00 in HSS4x2x1/8 web thickness of inclined beam/rail t,,.= 0.125 in HSS4x2x1/8 area of web Aw= 1.00 in2 A,,.=2dxt elastic modulus E= 29000 ksi steel yield strength Fy= 50.00 ksi steel web shear plate buckling factor k,.= 5.34 AISC Steel Construction Manual,Section G2(b) web depth to thickness ratio h/t= 14.20 AISC Steel Construction Manual,Table 1--11 limtiing web depth to thickness ratio h/t,,,= 61.22 AISC Steel Construction Manual,Section G2(b) web shear correction coefficient C,.1= 4.311 AISC Steel Construction Manual,Equation G2-4 nominal shear load capacity V„= 129.33 k AISC Steel Construction Manual,Equation G2-1 factor of safety 52,.= 1.67 shear allowable shear Va11ow= 77445 lbf V„11ow=V„/fl OK Actual versus Allowable Flexural Moment maximum flexure moment for supported span Mm„1= 6 lbf-in Mmo,1=wL12/8-wL22/2 maximum flexure moment for cantilever span Mm„,2= -3244 lbf-in Mmax2=wL22/2 maximum flexural moment Mm„,= 3244 lbf-in M,,,a,=min{Mm„,1,Mm„z2} plastic modulus @ x-axis Z,= 1.66 in' AISC Steel Construction Manual,Table 1--11 plastic moment by yielding Mp= 83.00 k-in AISC Steel Construction Manual,Equation F7-1 section modulus @ x-axis S,= 1.32 in' AISC Steel Construction Manual,Table 1--11 flange width b= 2.000 in HSS4x2x1/8 flange thickness t1= 0.125 in HSS4x2x1/8 flange width to thickness ratio b/t1= 14.20 AISC Steel Construction Manual,Table 1--11 flexural moment for flange local buckling M„1= 115.22 k-in AISC Steel Construction Manual,Equation F7-2 flexural moment for web local buckling Mn2= 92.49 k-in AISC Steel Construction Manual,Equation F7-6 supported span of inclined beam Lb= 5.58 ft design(same as L1) radius of gyration @ y-axis ry= 0.83 in AISC Steel Construction Manual,Table 1--11 polar moment of inertia J= 2.200 in4 AISC Steel Construction Manual,Table 1--11 gross cross section area A2= 1.300 in2 AISC Steel Construction Manual,Table 1--11 limiting unbraced length for yielding L,,= 5.31 ft AISC Steel Construction Manual,Equation F7-12 limiting unbraced length for lateral torsional buckling L,.= 146.85 ft AISC Steel Construction Manual,Equation F7-13 flexural moment for lateral torsional buckling M„3= 82.93 k-in AISC Steel Construction Manual,Equation F7-10 nominal flexural moment(local buckling) Mn= 82.93 k-in M„=min{Mi1,Mi2,Nina) factor of safety Oh= 1.67 flexure allowable flexural moment M,11°„,= 49659 lbf-in Mellow=M„/flb OK Actual versus Allowable Deflection moment of inertia @ x-axis Ix= 2.65 in4 MSC Steel Construction Manual,Table 1--11 flexural rigidity EI= 76850 k-in2 based on values for E and Ix above maximum supported deflection Ama1= 0.022 in Am,,1=wL22(5L22-24L12)/384EI allowable supported deflection Ax11ow1= 0.372 in A,11°w1=L1/180(dead load+wind load) OK maximum cantilever deflection Ame,2= -0.012 in Amx,2=wL14/8EI allowable cantilever deflection Ae11ow2= 0.140 in A,,11ow2=L1/180(dead load+wind load) OK 7 a , 4 horiz beam analysis 0.6(DL+WL) uniform dist Halted 60%dead load+60%wind load A B C D angle 0= 30 deg L, 4111 LZ4r L, , LL t L, I r SNs= 4.83 ft Los= 2.79 ft It., ft, beam subspan Li= 12.19 ft sheet 2 of 6 design dead load DL= 5.40 psf cantilever span L2= 2.00 ft sheet 2 of 6 design wind load WL= -35.69 psf number of subspans n= 3 sheet 2 of 6 tributary width t= 4.84 ft t=SNs/2+Los cos 0 total horizontal beam span L= 40.57 ft L=nL,+2L2 uniform distributed load w= .87.87 plf w=0.6(DL+WL)x t reactions at supports RA= -604 lbf RA=2wL,/5+wL2 locations where shear is zero xi= 4.876 ft xi=2Lu/5 Re= -1178 lbf Rs= 11wL,/10 (measured from left-right x2= 6.095 ft x2=Li/2 Re= •1178 lbf Re=11wLi/10 for each subspan) xs= 7.314 ft x3=3L1/5 RD= •604 lbf RD=2wLi15+wL2 SHEAR DISTRIBUTION x...iiill � x2 .....00111111111119 L2 Li Li Li L2 FLEXURE DISTRIBUTION M'ma. M`maxz M'ma.s Mrmaxa L L L Lz max, Mmax2 M ma. L2 flexural moments 0 each support flexural moments 0 each subspan M'ma.1_ •175.74 lbf-ft M„,„,=wL22/2 M m,xi= .868.85 lbf-ft M max1=2wL,2/25-wL22/2 M`m..2= .1481.491bfft Wm...=wLi2/10+wL22/2 M'm„2= .150.69 lbf-ft M'm„2=wLi2/40-wL22/2 M+ma.s= '1481.49 lbf•ft M'ma.s=wLi2/10+wL22/2 M'max3= .868.85 lbf-ft Mm„3=2w1u2/25-wL22/2 M.maxa= -175.74 lbf-ft M'.,....=wL22/2 Allowable Shear in Horizontal Beam maximum transverse shear in horizontal beam Vm„= 1178 lbf obtained from shear distribution and beam reactions from above depth of horizontal beam d= 5 in HSS5x4x1/8 web thickness of rectangular beam member t.= 0.125 in HSS5x4x1/8 area of web A.= 1.25 in2 A.,=2d x t elastic modulus E= 29000 ksi steel yield strength of horizontal beam member Fr= 50.00 ksi steel web depth to thickness ratio d/t= 40.00 AISC Steel Construction Manual,Table 1--11 limtiing web depth to thickness ratio hit.= 53.95 RISC Steel Construction Manual,Section G2(a) web shear correction coefficient Co= 1 AISC Steel Construction Manual,Equation G2.2 nominal shear load capacity V„= 37.50 k AISC Steel Construction Manual,Equation G2.1 factor of safety S4= 1.67 shear allowable shear V.aa.= 22455 lbf Vs„.=V„I W, 0K Allowable Flexural Moment in Horizontal Beam maximum feuxral moment 0.subspan Mm..i= 869 Ibf-ft obtained from moment distribution from beam reactions from above maximum flexural moment @ supports Mm..2= 1481 Ibf-ft obtained from moment distribution from beam reactions from above plastic modulus @ x-axis Z.= 3.50 ins AISC Steel Construction Manual,Table 1-11 plastic moment by yielding Me= 175.00 k-in AISC Steel Construction Manual,Equation F7-1 section modulus @ x-axis S.= 2.97 in3 AISC Steel Construction Manual,Table 1-•11 flange width b= 4.000 in HSS5x4xt18 flange thickness tr= 0.125 in HSS5x4x1/8 flange width to thickness ratio bit,= 32.00 AISC Steel Construction Manual,Table 1••11 flexural moment for flange local buckling M.,= 155.30 k-in AISC Steel Construction Manual,Equation F7-2 flexural moment for web local buckling M„2= 181.13 k-in AISC Steel Construction Manual,Equation F7.6 supported span of horizontal beam Lb= 10.60 ft design radius of gyration @ y-axis rr= 1.62 in AISC Steel Construction Manual,Table 1--11 polar moment of inertia J= 9.66 in' AISC Steel Construction Manual,Table 1--11 gross cross section area A.= 2.00 ill' AISC Steel Construction Manual,Table 1--11 limiting unbraced length for yielding Iq= 12.78 ft AISC Steel Construction Manual,Equation F7.12 limiting unbraced length for lateral torsional buckling La= 331.09 ft AISC Steel Construction Manual,Equation F7.13 nominal flexural moment(local buckling) M„= 155.30 k-in M.=min(M„,,Mae) factor of safety D = 1.67 flexure allowable flexural moment M.s.„= 7749 lbf-ft M.s.„=M.I0, OK Allowable Deflection in Horizontal Beam moment of inertia @ x-axis I.= 7.42 in" AISC Steel Construction Manual,Table 1••11 flexural rigidity El= 215180 k-in2 based on values for E and I.above maximum supported deflection in first subspan amaxA= 0.0002 in q„.xs=5wxi3/24E1-wL22xi3/4EI (take absolute value if the result is negative) maximum supported deflection in second subspan AmazB= 0.0144 in Amass=5wx2424EI•wL22x2214EI (take absolute value if the result is negative) maximum supported deflection in third subspan Ama.c= 0.0464 in Am„c=5wxs"/24EI-wL22xs2/4EI (take absolute value if the result is negative) maximum supported deflection in any subspan Amax]= 0.0464 in Am„1=max(Am..,,Amaxs,Am„c) allowable supported deflection in any subspan A.,i„.1= 0.8127 in a.m.,=Li/180(dead load+wind load) OK maximum cantilever deflection Ama.= -0.0014 in Am„2=w1.2'/8EI (take absolute value if the result is negative) allowable cantilever deflection a.aa.2= 0.1333 in Amo.2=L2I180(dead load+wind load) OK 8 • brace&post analysis O.6(DL+WL) Forces and Moments Transferred to Structural Elements reaction force transferred from inclined beam P1= 335 lbf obtained from analysis of inclined beam flexural moment transferred from inclined beam M1= 270 lbf-ft obtained from analysis of inclined beam angle of inclination for sloped beam 0= 30° see design layout height of south side posts hs= 4.00 ft see design layout("south post height"=48.00 in) spacing between north and south posts 11= 4.83 ft see design layout(spacing=58.00 in) orientation of diagonal brace a= 39.61° cc=tan 1(ha/11) maximum reaction force transferred from horizontal beam P2= 1178 lbf obtained from analysis of horizontal beam flexural moment transferred from horizontal beam to post M2= 1481 lbf-ft obtained from analysis of horizontal beam height of north side posts hN= 6.83 ft see design layout("north post height"=82.00 in) spacing between each post along east-west direction 12= 12.19 ft see design layout(12'-2") orientation of diagonal brace R= 29.27° 13=tan 1(hN/12) Vertical Post Design(north side posts)) total axial load applied to north side post PN= 1513 lbf PN=P1+P2 cross sectional area for each post/column A= 0.75 in2 1 1/2"diameter,Schedule 40 pipe yield stength Fy= 40.00 ksi Schedule 40 pipe nominal tension load Tn= 29960 lbf T.=Fy A factor of safety nc= 2.00 tension allowable tension load Tallow= 14980 lbf Tauaw=P004 OK Vertical Post Design(south side posts) total axial load applied to south side post Ps= 1513 lbf Ps=Pi+P2 cross sectional area for each post/column A= 0.75 in2 1 1/2"diameter,Schedule 40 pipe yield stength Fy= 40.00 ksi Schedule 40 pipe nominal tension load Pn= 29960 lbf P.=Fy A factor of safety flt= 2.00 tension allowable tension load Tauow= 14980 lbf TP/S21 OK allow= n Diagonal Brace Design(member spans along north-south direction) length of diagonal brace L1= 6.27 ft L1=(hs2+112)1/2 compression carried by diagonal brace C1= 182 lbf C1= RN sin 0/cos a- (MI/L1)tan a cross sectional area A= 0.625 in2 1 1/4"diameter,Sched 40 pipe yield stength Fy= 40.00 ksi Schedule 40 pipe elastic modulus E= 29000 ksi steel end fixity factor K= 0.70 top end fixed and bottom end pinned effective length of diagonal brace KL= 52.70 in KL=KL1 radius of gyration r= 0.543 in 1 1/4"diameter,Schedule 40 pipe effective slenderness ratio Mir= 97.05 for use in computing buckling capacity slenderness ratio threshold 4.71(E/F)1/2= 126.82 AISC,Section E3(a) Euler buckling stress Fe= 30.39 ksi AISC,Equation E3-4 critical buckling stress F,= 26.65 ksi AISC,Equation E3-3 nominal compression load Pn= 16655 lbf Pn=For A factor of safety Sl°= 1.67 compression allowable compression load Callow= 9973 lbf C.o.,'=Pn/Se OK Diagonal Brace Design(member spans along east-west direction) length of diagonal brace L2= 13.97 ft L2=(hN2+122)112 compression carried by diagonal brace C2= 68 lbf C2= M2/L2 tan 13 cross sectional area A= 0.625 in2 1 1/4"diameter,Schedule 40 pipe yield stength Fy= 40.00 ksi Schedule 40 pipe elastic modulus E= 29000 Kksi steel end fixity factor K= 0.70 top end fixed and bottom end pinned effective length of diagonal brace KL= 117.39 in KL=KL2 radius of gyration r= 0.543 in 1 1/4"diameter,Schedule 40 pipe effective slenderness ratio KL/r= 216.18 for use in computing buckling capacity slenderness ratio threshold 4.71(E/Fy)1/2= 126.82 AISC,Section E3(a) Euler buckling stress Fe= 6.12 ksi AISC,Equation E3.4 critical buckling stress F,= 5.37 ksi RISC,Equation E3.3 nominal compression load Pn= 3357 lbf P.=F°,.A factor of safety 4= 1.67 compression allowable compression load in member Callow= 2010 lbf Cal.,=Pn4 OK 9 To: Page 1 of 1 2019-03-22 13:55:11 (GMT) 15183146044 From: Joseph Holmes pi ;. .[74 .VC.: ewE:.i:�.._ _. ........ 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