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15-0695 Schweitzer SW-552 (WA) CALCS.pdf CXT, Inc. (Precast Div.) 1 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Main Wind Force Resisting System Loads (ASCE 7-10) Schweitzer SW-552 CategoryIISee Table 1.5-1: Risk Category of Buildings and Other Structures. This image cannot currently be displayed. ExposureCSee § 26.7.3: Exposure Categories, General. Velocity150 mphSee Figure 26.5A thru 26.5C: Basic Wind Speed (3 second Gust) O h.wind8.00 ftWindward wall height h.lee8.00 ftLeeward wall height h W.building10.5 ftWidth of the building L.building20 ftLength of the building H.building9.75 ftHeight of the building (to the ridge). Enter 0 if unknown. Roof Rise3Roof pitch (per foot) 14.04 degRoof Angle Kd0.85Wind directionality factor. 0.85 when using load combinations, 1.0 otherwise. This image cannot currently be displayed. 3 K0.00 3a2a 1 K0.00 2 a K0.00 See Figure 26.8-1: Multipliers for Obtaining Topographical Factor Kzt 3 This image cannot currently be displayed. Kzt1Topographic factor h8.875 ftMean roof height n8.45Natural frequency a FlexibilityRigidBuilding flexibility 1 212 h 9.5Terrain factor z900 ftTerrain factor a g 4 5 O 5 Velocity Pressure Exposure Coefficient 4 K(z)0.849at windward eave a 5 a a 5 3 Velocity Pressure (27.3.2) a 3 q41.56 psfGableType of Roof - Gable or Hip? z Partially Enclosed if the building meets both of the following conditions: 1. Total area of openings in one wall exceeds area of openings in the balance of the building by more than 10%. 2 Total area of openings in one wall exceeds 4 sq. ft. or 1% of area of that wall and the total area of openings in the balance of the building does not exceed 20% of the area in the balance of the building. ZoneOpening AreaGross AreaAgiAoiCondition 1Condition 2Condition 3Condition 4Type: Windward sidewall0 sq ft160.0 sq ft556.4 sq ft0 sq ft0.000.000.000.00Enclosed Windward endwall0 sq ft93.2 sq ft623.2 sq ft0 sq ft0.000.000.000.00Enclosed Leeward sidewall0 sq ft160.0 sq ft556.4 sq ft0 sq ft0.000.000.000.00Enclosed Leeward endwall0 sq ft93.2 sq ft623.2 sq ft0 sq ft0.000.000.000.00Enclosed Roof0 sq ft210.0 sq ft506.4 sq ft0 sq ft0.000.000.000.00Enclosed Enclosed Gust Factor - (26.9) G =0.85 External Pressure Coefficients C0.8See 27.4.4 Roof OverhangsInternal Pressures: po 0.8Windward wall (Use with qz) Fig. 27.4-1Negative:-7.48 psf -0.500Leeward wall (wind normal to ridge) (Use with qh)L/B = 0.53Positive:7.48 psf Cp -0.319Leeward wall (wind parallel to ridge) (Use with qh)L/B = 1.90 -0.7Sidewalls (Use with qh) Fig. 27.4-1 Pos. WindwardNeg. WindwardLeeward Roof Pressures Wind Perpendicular to Ridge w/ Roof Pressure Coefficients (Fig 27.4-1) Normal to -0.180-0.958-0.582 Ridge when Theta >= 10degrees >= 10 deg w/ Negative Internal1.12 psf 0 to h/2h/2 to hh to 2h> 2h-41.33 psfw/ Positive Internal Roof Pressure Coefficients (Fig 27.4-1) Normal to *WORST CASE LOADING -1.18-0.76-0.64-0.58 Ridge when Theta < 10 deg. Roof Pressure Coefficients (Fig 27.4-1) -0.90-0.90-0.50-0.30 PARALLEL to Ridge Roof Pressures: Wind Wall Pressures:Roof Pressures: Wind Parallel to w/ Negativew/ Positive Internal Windward 35.74 psf20.78 psfridge for all roof slopes:Perpendicular to ridge for < 10 Leeward (wind normal)-16.00 psf-25.14 psfLocationw/ Positive Internaldeg: Leeward (wind parallel)-16.00 psf-18.75 psf0 to h/2-39.28 psfLocationw/ Positive Internal Side Wall-17.25 psf-32.21 psfh/2 to h-39.28 psf0 to h/20.00 psf h to 2h-25.14 psfh/2 to h0.00 psf Additional Overhang Pressure:28.26 psfOver 2h-18.08 psfh to 2h0.00 psf Over 2h0.00 psf Wind Speed:150 mphRoof Slope:3.00 : 12 COMPONENTS Mean Roo f & CLADDING Height: Exposure:C8.88 ft Effective Area Zone10.0 sq ft100.0 sq ft500.0 sq ft 1-38.21 psf19.98 psf-34.05 psf11.67 psf-34.05 psf11.67 psf 2-71.45 psf19.98 psf-50.67 psf11.67 psf-50.67 psf11.67 psfHigher pressures at the ridge line only applies to roof pitches > 7 2oh-91.44 psf--91.44 psf--91.44 psf-degrees 3-108.86 psf19.98 psf-83.92 psf11.67 psf-83.92 psf11.67 psf 3oh-153.78 psf--103.90 psf--103.90 psf- 4-46.52 psf40.76 psf-38.21 psf33.70 psf-34.05 psf28.29 psf 5-58.99 psf40.76 psf-46.52 psf33.70 psf-34.05 psf28.29 psf a:3.00 ft CXT, Inc. (Precast Div.) 2 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 ASCE 7-10 SNOW LOAD CALCULATION CategoryIISee ASCE Table 1.5-1: Risk Category of Buildings and Other Structures. ExposureCSee § 26.7.3: Exposure Categories, General. Pg250 psfSee ASCE Figure 7-1: Ground Snow Load W.building10.5 ftLength of the building L.building20 ftWidth of the building H.building9.75 ftHeight of the building (to the ridge). Enter 0 if unknown. Roof Rise (per foot)3Roof pitch 14.04 degRoof Angle ASCE Table 7-3 - Thermal Condition: C t All structures except as indicated below:1.0 Structures kept just above freezing and others with cold, ventilated roofs in which the thermal resistance (R-value) between the ventilated space and the heated space exceeds 25*h (deg*sq ft/BTU).1.1 Unheated and open air structures1.2 Structures intentionally kept below freezing1.3 Continuously heated greenhouses with a roof having a thermal resistance value (R-value) less than 2.0*h (deg*sq ft/BTU).0.85 C1.2(Choose from table above) t Is1ASCE Table 1.5-2 SurfaceUnobstructedASCE § 7-4 Roof typeGable Hor. Eave to Ridge Distance - windward5.25 ft Roof ExposurePartially exposedASCE Table 7-2 C1ASCE Table 7-2 e Cs1Slope Factor from Figure 7-2 Low Sloped?:YesASCE § 7-4 P210.00 psfFlat Roof Snow Load f P210.00 psfSloped Roof Snow Load s Use unbalanced?YesASCE § 7.6.1 P0.00 psfASCE § 7.6.1 windward P250.00 psfASCE § 7.6.1 leeward1 P250.00 psfASCE § 7.6.1 leeward2 Distance from Ridge to Edge of P loading5.3 ftASCE Figure 7-5 leeward1 30.00 pcfSnow densityEq. 7.7-1 of ASCE 7 S4Run per rise of 1ASCE § 7.1 h10.19 ftHeight of drifting snow on leeward side d h7.00 ftHeight of balanced snow b Snow Load on Gable Structure 30 25 20 Snow depth STRUCTURE 15 Balanced Snow Unblanced Snow 10 5 0 0510152025 Structure Cross Section CXT, Inc. (Precast Div.) 3 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Seismic Loads (ASCE 7-10) Schweitzer SW-552 CategoryIISee ASCE Table 1.5-1: Risk Category of Buildings and Other Structures. Ss1.67 gMax. Earthquake Ground Motion of 0.2 sec Spectral Response AccelerationASCE Figure 22-1 S0.75 gMax. Earthquake Ground Motion of 1.0 sec Spectral Response AccelerationASCE Figure 22-2 1 Site ClassDSite classification (Use D if unknown unless jurisdiction, or geotechnical data determines Site Class E or F.)ASCE 20.1 T16.0 secLong Period Transition Period ASCE Figure 22-12 L Seismic Force Resisting SystemA.5Intermediate precast shear walls ASCE Table 12.2-1 R4.00Response Modification Factor 2.5System Over strength Factor 0 C0.02Approximate period parameterASCE Table 12.8-2 t x0.75Approximate period parameterASCE Table 12.8-2 hn9.08 ftHeight in feet from base to highest level of structure Value 1*Value 2* F1Interpolated Value ASCE Table 11.4-111*=Used for interpolation a F1.5Interpolated Value ASCE Table 11.4-21.51.5 v Sms = Fa * S1.669 gAdjusted MCE Spectral Response Acceleration at short periodsASCE 11.4-1 S S = F * S1.122 gAdjusted MCE Spectral Response Acceleration at 1 sec periodASCE 11.4-2 m1v1 (MCE = Maximum considered earthquake) S = 2/3 Sm1.113 gDesign Spectral Acceleration ParametersASCE 11.4-3 DSs S = 2/3 Sm0.748 gDesign Spectral Acceleration ParametersASCE 11.4-4 D11 I1Importance Factor ASCE Table 1.5-2 E Seismic Design CategoryD Based on SD Table 11.6-1 DS Based on SD Table 11.6-2 D1 Geotechnical Investigation Report Required?Yes per ASCE 11.8.2 and 11.8.3, IBC 1803 EQUIVALENT LATERAL FORCE PROCEDURE x T = C* hn0.10 secApproximate fundamental periodASCE 12.8-7 at T0.10 secFundamental period of the structure (can be taken as Ta per ASCE 12.8.2) C = S/(R/I)0.278ASCE 12.8-2 sDS C0.094ASCE 12.8-5 & 12.8-6 s.min C1.787ASCE 12.8-3 & 12.8-4 s.max C0.278 s k1.000ASCE 12.8.3 W63.35 kip Shear with snow load V = C * W17.62 kipASCE 12.8-1 s Overturning Moment with snow load M =157.9 k-ft o Shear without snow load V = C * W14.70 kip s Overturning Moment without snow load M =115.4 k-ft o WITH SNOW LOAD 12.8-1212.8-11;11.712.10-1 P(flat roof V (Story F fx px (diaphragm k LevelStory Heightsnow load)shear) h or hww*hCFM ixiiivxxxforce) Roof8.88 ft9.08 ft210 psf39.09 kip355.0 k-ft0.98617.37 kip17.37 kip0.0 k-ft17.37 kip Walls0.00 ft0.00 ft Floor0.21 ft0.21 ft24.26 kip5.1 k-ft0.0140.25 kip17.62 kip154.2 k-ft6.75 kip Base0 ft0.00 ftW=63.35 kip360.1 k-ftM =157.9 k-ft o WITHOUT SNOW LOAD 12.8-1212.8-11;11.712.10-1 P(flat roof V (Story F fx px (diaphragm k snow load)shear) LevelStory Heighth or hww*hCFM ixiiivxxxforce) Roof8.88 ft9.08 ft0 psf28.58 kip259.6 k-ft0.72112.70 kip12.70 kip0.0 k-ft12.70 kip Walls0.00 ft0.00 ft Floor0.21 ft0.21 ft24.26 kip5.1 k-ft0.0140.25 kip12.95 kip112.7 k-ft5.95 kip Base0 ft0.00 ftW=52.84 kip264.6 k-ftM =115.4 k-ft o CXT, Inc. (Precast Div.) 4 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Center of Mass & Rigidity Schweitzer SW-552 XY Upper Left = 0,0Lower Right143252 X RelativeY RelativeDist to CoRxDist to CoRyShear Force Wall StiffnessStiffnesslbsplfdx (IN)dy(IN) W10.00%21.33% 2,319 236 11.501164.582 W249.39%0.00% 5,370 269 61.00046.582 W30.00%20.10% 2,186 222 0.22971.418 W449.39%0.00% 5,370 269 61.00046.582 W50.00%58.57% 6,369 648 0.00035.418 W61.22%0.00% 133 50 0.00053.418 Snow/Live Left EdgeTop EdgeRight EdgeBottom EdgeLiveLiveCenter of Gravity (psf) SlabThicknessWeightXYXYXYw snoww/o snow R14.577550071.525221035.8126.0130107755 R24.5775571.50143252210107.3126.0130107755 F15111908.56134.524640071.5126.0111900 Totals2613572.0120.4 WgtWgtwgtwgt Torsional Eccentricity (w snow)(w/o snow)(w snow)(w/o snow) exey 0.5440.98 63,346 52,835 roof 39,088 28,578 Center of Gravityfloor 24,258 XY 72.0120.4 Center of Rigidty XY 71.579.4 Wall Overturning Checks Using Weight of Adjacent Walls Force Transferred by Connections Between Walls Anchorage RequiredToward Lower RightToward Upper Left Overturning status to Resist OverturningAnchor ResistanceAnchor Resistance using just connection From Design MomentMomentMoment to adjacent walls Wall(kip-ft)check(kip-ft)check(kip-ft) 12.13None Required W143.53OK43.53OK -15.99None Required W2157.95OK132.34OK 12.03None Required W335.47OK35.47OK -15.99None Required W4157.95OK132.34OK 62.27None Required W562.58OK62.58OK 0.33None Required W619.37OK11.81OK Overturning resistance considers only the weight of the wall, the weight of the roof supported by the wall, and connection to adjacent walls. Roof weight supported by other walls has not been considered. Connection to adjacent walls is taken as the connection capacity, not to exceed that portion of the adjacent wall weight that can be reasonably attributed to the connection. Wall Overturning Checks Using Base Anchors Only Must investigate ONLY if connection to adjacent walls is insufficient Combined Toward Lower RightToward Upper Left DesignRequired Tension Loading Anchor ResistanceAnchor Resistance MomentCapacity per Unity MomentMoment (kip-ft)Base Anchor (lb) Wall(kip-ft)check(kip-ft)checkCheck (1427) W112.1346.31OK58.14OKOK (2967) W2-15.9989.74OK89.74OKOK (1554) W312.0343.75OK42.06OKOK (2967) W4-15.9989.74OK89.74OKOK (16) W562.2752.33Try Both52.33Try BothTry Both (4303) W60.337.24OK7.24OKOK Wall Overturning Checks Using Base Anchors and Connection to Adjacent Walls Must investigate ONLY if both base anchor alone and adjacent walls alone are insufficient Base Anchor Base AnchorAvailable OverturningOverturning ShearTensionResistance (kip-ft)Unity Check of RequiredAvailableFrom Base AnchorsBase Anchors Wall(% Capacity)(% Capacity)Lower RightUpper LeftLower RightUpper Left W114.4%100.0%89.85101.68OKOK W223.8%96.2%238.16213.53OKOK W318.2%100.0%79.2277.53OKOK W423.8%96.2%238.16213.53OKOK W536.8%83.2%95.6295.62OKOK W63.3%100.0%26.6219.05OKOK CXT, Inc. (Precast Div.) 5 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 0.00 ki p 10 f t 0.00 ki p 2.71 ki Bs p 5.382 f t TWO-WAY SLAB 2.71 ki Bs wB p Ls wL ONE-WAY SLAB wB h Ls dt steel bottomSECTION PROPERTIES steel to p wb rd db 0.00 ki 0.00 ki p p ct cb 10 f10 f ACI 10.2.7.3 ACI 9.5.2.3ACI 9.5.2.3 0.00 ki tt 0.00 ki p p 1.71 ki0.58 ki pp 5.382 f 5.382 f t t providedprovidedprovided 1.71 ki0.58 ki pp {walls that support one or more roof panels in the short direction} {walls that support one or more roof panels in the long direction} {qty of overhangs in Bs direction} {qty of overhangs in ls direction} ASCE7-05 eq CC1b ACI eq. 9-3 {from seismic analysis} (typically 12 inches) (if centered enter 0) ACI 10.3.3ACI 7.12.2ACI 10.5.1 ACI 8.5.1 ACI 14.0 temp trialtrial min d t CXT, Inc. (Precast Div.) 6 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Bs TWO-WAY SLAB Bs wB Ls wL ONE-WAY SLAB wB h Ls dt steel bottomSECTION PROPERTIES steel to p wb rd db ct cb ACI 10.2.7.3 ACI 9.5.2.3ACI 9.5.2.3 com p providedprovidedprovided TensionTension 0.550.550.550.55 {walls that support one or more roof panels in the short direction} {walls that support one or more roof panels in the long direction} {qty of overhangs in Bs direction} {qty of overhangs in ls direction} {from seismic analysis} (typically 12 inches) (if centered enter 0) ACI 8.5.1 ACI 14.0 d CXT, Inc. (Precast Div.) 7 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID:ACI's Alternate Design of Slender Walls ACI 14.8 DESIGN OF WALL MARKED W1 Assumptions from this methodology: Wall panel shall be simply supported, axially loaded, and subject to out-of-plane uniform lateral loading where maximum ACI 14.8.2.1 moments and deflections occur at mid-height of the wall. NotesThe cross section is constant over the height of the wall panel. ACI 14.8.2.2 The wall cross sections shall be tension controlled. ACI 14.8.2.3 Phi*Mn >= Mcr ACI 14.8.2.4 Concentrated gravity loads are distributed over the wall length ACI 14.8.2.5 The vertical stress Pu/Ag at mid-height shall not exceed 0.06*f'c ACI 14.8.2.6 Material Properties f`c5000 psiGeometric Properties Steel ReinforcementPlain WWF >= W1.2-A185 X Corridinate12.5 Fy wire mesh65000 psi Y Corridinate244 Fy rebar60000 pcf Direction of WallX Lightweight?No Center of gravity X83.001 Concrete density150 pcf O.K.Center of gravity Y244.000 E (Steel)29000000 psiWall Weight 2918.000 lbs. E (Concrete)4290000 psiCentral wall?Yes ACI 8.5.1 n (modular ratio)6.76Yes Wall that supports 2 roof panels? 0 ft lop (length of opening on wall) Shear ParametersH (height of wall)103.37 in Phi.v0.85Lh (length of wall)9.833 ft ACI 9.3.2.3 Vc3.123 kipTwo-way slab Analyisis will be performed as : ACI 11.3.1.1 & 11.2.1.2 Phi*Vc2.654 kipb (section width)12 in ACI 11.1.1 h (section thickness)4 in Minimum Wall Reinforcement Requirementsct (cover top)2 in roe.min.vert0.0012cb (cover bottom)2 in ACI 14.3.2 roe.min.hor0.0020.319 in rd (assumed reinf. diameter) ACI 14.3.3 Max Vertical spacing18 indt (effective depth top)1.84 in ACI 14.3.5 Max Horizontal spacing18 in1.84 in db (effective depth bottom) ACI 14.3.5 0.278 Cs (% of DL used for Seismic) LoadingEccentricity - Axial Load1 in Axial Design Loads (pressure from roof)Lateral Design Loads (pressure on wall)Is wall SplitNo D (Dead load) + Ww ( Wall weight)110.94 psfDead Load (DL.lat)0 psf S (Snow Load)250 psfSnow Load (SL.lat)0 psf L (Live Load)0 psfLive Load (LL.lat)0 psfWire Mesh Lr (Live Roof Load)30 psfLive Roof Load (LLr.lat)0 psfWire SizeW8 W (Wind Load)108.86 psfWind Load (WL.lat)58.99 psfspacing4 in E (Earthquake Load)16.95 psfEarthquake Load (EL.lat)13.91 psfMesh Area0.24 in^2 = As Factored Axially Applied LoadsFactored Laterally Applied Loads Factored Loading per ACIACI eq. 9-3Factored Loading per ACI ACI eq. 9-4 Factored Pressure on Roof Wr560.21394.38 psf Factored Pressure on Wall Ww Axial Pressure on SectionLateral Pressure on Section PuB2.15 kip0.03 klf Lw = W*(L^4 / L^4 + H^4) 0.06 klf Hw = W*(H^4 / H^4 + L^4) Assumption check Pu/Ag44.792 psiUnfactored Laterally Applied Loads 0.06*f`c300 psi58.99 psf Unfactored Pressure on Wall uWw O.K. Check ACI 14.8.2.6 Lateral Pressure on Section Unfactored Axially Applied Loads0.02 klf Lw = W*(L^4 / L^4 + H^4) Unfactored Pressure on Roof uWr330.0825 psf0.04 klf Hw = W*(H^4 / H^4 + L^4) Axial Pressure on Section PB1.35 kip ShearDeflection ACI 14.8.4 Factored Loading per ACIACI eq. 9-3Service Loads Vu = wuB*(Bw-2db) / 20.09Axial1.35 kip Phi*Vc/21.33Lateral0.02 klf Check Shear ACI 11.5.5.1O.K.Allowed service deflection0.69 in Msa2.901 kip-in M2.917 kip-in Ds0.012 in Check deflectionO.K. Allowable CapacityFlexure Ig = (b*h^3)/1264 in^4Assumption check Ag = (b*h)48 in^2SpanHwLw Yt = h/22net Tensile Strain0.0110.011 fr (rupture modulus)530.330 psiCheck ACI 14.8.2.3 TensionTension Mcr16.971 kip-inMua0.650 kip-ft Beta_10.8 Trial Ast req'd0.073 in^2ACI eq. (14-6) BMu0.790 kip-ft0.360 kip-ft 7.403686795 kd 0.583 in I.crACI 9.3.2 3.35 in^4 efb 0.90.9 0.003 c e1.960 kip-ft1.960 kip-ft fMn trial = AsFy(dt - a/2) 0.005 s a0.000 kip-ft0.000 kip-ft 0.32469 psiDM =Mpos - M cAs Add'l req'd0.00 in^20.00 in^2 0.406 in AseAdditional reinf req`d0.00 in^20.00 in^2 0.27 in^2 IcrdeflectionAdd'l bar size:33 4.21 in^4 Ieqty req`d00 64.00 in^4 deltaor spacing of:00 150 r(maximum tensile reinforcement)0.02250.000 kip-ft0.000 kip-ft t As add'l = r(min. temperature reinforcement)0.0017 temp r(minimum tensile reinforcement)0.0033Ast = As + As add'l0.24 in^20.24 in^2 min r(trial reinforcement ratio bottom)0.00331.961 kip-ft1.961 kip-ft fMn = AsFy(db - a/2) trial 0.0110O.K.O.K. (reinforcement ratio provided) provided CheckMn > Mu % allowed40.29%18.36% CXT, Inc. (Precast Div.) 8 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Entire WallDoor 1 REINFORCEMENT AT OPENINGS LoadingMaterial Properties Pu (factorized load from roof)0.56 klfdb (effective depth bottom)1.84 in Ww (weight of panel per sq ft)0.05 ksfa (block of strain)0.32469 psi a=As * fy / (0.85 * f`c *b) Factorized Moment H height above (-) Weight of Pw total factorized wu total Mu OpeningHorizontal LocationVertical LocationL length of opening openingOpening (LBS)panel loadfactorized load(wu*L^2)/12 Door 11.83 ft0 ft3.84 ft1.76 ft1316.000.09 klf0.65 klf0.8 kip-ft Flexure Check Mn = OpeningAs req'dBar sizeqty req'd: b Mn > Mu AsFy(db - a/2) Door 1 0.90.009 in^2No. 319.67 kip-ftO.K. CONNECTIONS Full Resistance Value Overturning Base AnchorsBase AnchorsWall-Wall ConnectionLateral QuantityMaximumMaximumShearMoment +Moment -Moment +Moment - in ShearR - DistanceL - Distancekipkip - ftkip - ftkip - ftkip - ft 411311328.37246.3158.1443.5343.53 Base Anchors Total Tension DistTension (kip)ShearL - DistMoment +Moment - 12.622 5 in 3.886.05 113 in0.072 kip*ft36.574 kip*ft Base Anchor 1 19 in 2.438.14 99 in0.646 kip*ft17.542 kip*ft Base Anchor 2 71 in 2.438.14 47 in9.022 kip*ft3.954 kip*ft Base Anchor 3 113 in 3.886.05 5 in36.574 kip*ft0.072 kip*ft Base Anchor 4 Wall Connections CapacityCountering Dead % of Overturning Moment QuantityDistAllowable Adjoining L - Dist of eachLoad from wall to Resistance(kip-ft) of Anchors Wall(inches)Force Up LeftLow Right use AnchorAdjoining Wall 31.4768.51742.50%W2 0118.0004.4270.00043.534 Wall Connection 1 31.4768.51742.50%W4 1180.0004.42743.5340.000 Wall Connection 2 Wall Shear Checks Shear Connections at BaseWall Shear Capacity Required Shear Capacity (lb) per DesignCapacityReserveDesignResistanceReserve Base Connector Force(lb)(lb)Capacity(PLF)(PLF)checkCapacity 40872837224285 2367415OK1022(24285)OK RIGIDITY CALCULATED VALUES36%Final 2.206554309 PierLengthHeightFixed Top?Useable?Stiffness (k)Deflection Label(inches)(inches)(Y/N)(Y/N)(1000 kip / IN)(in / 1000 kip) Entire Wall118103.37YY6.0600.165 A'11882.25YY8.2310.121 Door 1 A21.9682.25YY0.3143.189 B49.9682.25YY2.1270.470 Combine Logic First SegmentSecond SegmentRe-NameCombine/SubtractMethodCombined Entire WallA'A'a-Deflection0.044 Door 1 ABAB+Stiffness2.441 A'aABFinal+Deflection0.453 CXT, Inc. (Precast Div.) 9 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID:ACI's Alternate Design of Slender Walls ACI 14.8 DESIGN OF WALL MARKED W2 Assumptions from this methodology: Wall panel shall be simply supported, axially loaded, and subject to out-of-plane uniform lateral loading where maximum ACI 14.8.2.1 moments and deflections occur at mid-height of the wall. NotesThe cross section is constant over the height of the wall panel. ACI 14.8.2.2 The wall cross sections shall be tension controlled. ACI 14.8.2.3 Phi*Mn >= Mcr ACI 14.8.2.4 Concentrated gravity loads are distributed over the wall length ACI 14.8.2.5 The vertical stress Pu/Ag at mid-height shall not exceed 0.06*f'c ACI 14.8.2.6 Material Properties f`c5000 psiGeometric Properties Steel ReinforcementPlain WWF >= W1.2-A185 X Corridinate10.5 Fy wire mesh65000 psi Y Corridinate6 Fy rebar60000 pcf Direction of WallY Lightweight?No Center of gravity X10.500 Concrete density150 pcf O.K.Center of gravity Y126.000 E (Steel)29000000 psiWall Weight 7905.000 lbs. E (Concrete)4290000 psiCentral wall?Yes ACI 8.5.1 n (modular ratio)6.76No Wall that supports 2 roof panels? 0 ft lop (length of opening on wall) Shear ParametersH (height of wall)96 in Phi.v0.85Lh (length of wall)20.000 ft ACI 9.3.2.3 Vc3.123 kipOne-way slab Analyisis will be performed as : ACI 11.3.1.1 & 11.2.1.2 Phi*Vc2.654 kipb (section width)12 in ACI 11.1.1 h (section thickness)4 in Minimum Wall Reinforcement Requirementsct (cover top)2 in roe.min.vert0.0012cb (cover bottom)2 in ACI 14.3.2 roe.min.hor0.0020.319 in rd (assumed reinf. diameter) ACI 14.3.3 Max Vertical spacing18 indt (effective depth top)1.84 in ACI 14.3.5 Max Horizontal spacing18 in1.84 in db (effective depth bottom) ACI 14.3.5 0.278 Cs (% of DL used for Seismic) LoadingEccentricity - Axial Load1 in Axial Design Loads (pressure from roof)Lateral Design Loads (pressure on wall)Is wall SplitNo D (Dead load) + Ww ( Wall weight)110.94 psfDead Load (DL.lat)0 psf S (Snow Load)250 psfSnow Load (SL.lat)0 psf L (Live Load)0 psfLive Load (LL.lat)0 psfWire Mesh Lr (Live Roof Load)30 psfLive Roof Load (LLr.lat)0 psfWire SizeW8 W (Wind Load)108.86 psfWind Load (WL.lat)58.99 psfspacing4 in E (Earthquake Load)16.95 psfEarthquake Load (EL.lat)13.91 psfMesh Area0.24 in^2 = As Factored Axially Applied LoadsFactored Laterally Applied Loads Factored Loading per ACIACI eq. 9-3Factored Loading per ACI ACI eq. 9-4 Factored Pressure on Roof Wr560.21394.38 psf Factored Pressure on Wall Ww Axial Pressure on SectionLateral Pressure on Section PuB2.22 kip0 klf Lw = W*(L^4 / H^4 + L^4) 0.09 klf Hw = W*(L^4 / H^4 + L^4) Assumption check Pu/Ag46.250 psiUnfactored Laterally Applied Loads 0.06*f`c300 psi58.99 psf Unfactored Pressure on Wall uWw O.K. Check ACI 14.8.2.6 Lateral Pressure on Section Unfactored Axially Applied Loads0 klf Lw = W*(L^4 / H^4 + L^4) Unfactored Pressure on Roof uWr330.0825 psf0.06 klf Hw = W*(L^4 / H^4 + L^4) Axial Pressure on Section PB1.42 kip ShearDeflection ACI 14.8.4 Factored Loading per ACIACI eq. 9-3Service Loads Vu = wuB*(Bw-2db) / 20Axial1.42 kip Phi*Vc/21.33Lateral0 klf Check Shear ACI 11.5.5.1O.K.Allowed service deflection0.64 in Msa0.710 kip-in M0.714 kip-in Ds0.002 in Check deflectionO.K. Allowable CapacityFlexure Ig = (b*h^3)/1264 in^4Assumption check Ag = (b*h)48 in^2SpanHwLw Yt = h/22net Tensile Strain0.0110.011 fr (rupture modulus)530.330 psiCheck ACI 14.8.2.3 TensionTension Mcr16.971 kip-inMua0.813 kip-ft Beta_10.8 Trial Ast req'd0.073 in^2ACI eq. (14-6) BMu0.960 kip-ft0.000 kip-ft 7.403686795 kd 0.583 in I.crACI 9.3.2 3.35 in^4 efb 0.90.9 0.003 c e1.960 kip-ft1.960 kip-ft fMn trial = AsFy(dt - a/2) 0.005 s a0.000 kip-ft0.000 kip-ft 0.32469 psiDM =Mpos - M cAs Add'l req'd0.00 in^20.00 in^2 0.406 in AseAdditional reinf req`d0.00 in^20.00 in^2 0.27 in^2 IcrdeflectionAdd'l bar size:33 4.21 in^4 Ieqty req`d00 64.00 in^4 deltaor spacing of:00 150 r(maximum tensile reinforcement)0.02250.000 kip-ft0.000 kip-ft t As add'l = r(min. temperature reinforcement)0.0017 temp r(minimum tensile reinforcement)0.0033Ast = As + As add'l0.24 in^20.24 in^2 min r(trial reinforcement ratio bottom)0.00331.961 kip-ft1.961 kip-ft fMn = AsFy(db - a/2) trial 0.0110O.K.O.K. (reinforcement ratio provided) provided CheckMn > Mu % allowed48.95%0.00% CXT, Inc. (Precast Div.) 10 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Entire WallVent 1 Vent 2 REINFORCEMENT AT OPENINGS LoadingMaterial Properties Pu (factorized load from roof)0.56 klfdb (effective depth bottom)1.84 in Ww (weight of panel per sq ft)0.05 ksfa (block of strain)0.32469 psi a=As * fy / (0.85 * f`c *b) Factorized Moment H height above (-) Weight of Pw total factorized wu total Mu OpeningHorizontal LocationVertical LocationL length of opening openingOpening (LBS)panel loadfactorized load(wu*L^2)/12 Vent 11.5 ft1 ft1 ft6 ft50.000.3 klf0.86 klf0.07 kip-ft Vent 217.5 ft1 ft1 ft6 ft50.000.3 klf0.86 klf0.07 kip-ft Flexure Check Mn = OpeningAs req'dBar sizeqty req'd: b Mn > Mu AsFy(db - a/2) Vent 1 0.90 in^2No. 300 kip-ftO.K. Vent 2 0.90 in^2No. 300 kip-ftO.K. CONNECTIONS Full Resistance Value Overturning Base AnchorsBase AnchorsWall-Wall ConnectionLateral QuantityMaximumMaximumShearMoment +Moment -Moment +Moment - in ShearR - DistanceL - Distancekipkip - ftkip - ftkip - ftkip - ft 522822840.69589.7489.74157.95132.34 Base Anchors Total Tension DistTension (kip)ShearL - DistMoment +Moment - 12.135 12 in 2.438.14 228 in0.128 kip*ft46.113 kip*ft Base Anchor 1 66 in 2.438.14 174 in3.864 kip*ft26.857 kip*ft Base Anchor 2 120 in 2.438.14 120 in12.774 kip*ft12.774 kip*ft Base Anchor 3 174 in 2.438.14 66 in26.857 kip*ft3.864 kip*ft Base Anchor 4 228 in 2.438.14 12 in46.113 kip*ft0.128 kip*ft Base Anchor 5 Wall Connections CapacityCountering Dead % of Overturning Moment QuantityDistAllowable Adjoining L - Dist of eachLoad from wall to Resistance(kip-ft) of Anchors Wall(inches)Force Up LeftLow Right use AnchorAdjoining Wall 32.4223.03525.00%W3 2238.0003.0350.50660.189 Wall Connection 1 32.4224.21425.00%W5 38202.0004.21413.34570.940 Wall Connection 2 32.4227.77050.00%W1 2382.0007.266144.1011.211 Wall Connection 3 Wall Shear Checks Shear Connections at BaseWall Shear Capacity Required Shear Capacity (lb) per DesignCapacityReserveDesignResistanceReserve Base Connector Force(lb)(lb)Capacity(PLF)(PLF)checkCapacity 97044069530991 26920061OK1941(30991)OK RIGIDITY CALCULATED VALUES99%Final 15.58709708 PierLengthHeightFixed Top?Useable?Stiffness (k)Deflection Label(inches)(inches)(Y/N)(Y/N)(1000 kip / IN)(in / 1000 kip) Entire Wall24096YY15.8230.063 A'24012YY133.2220.008 Vent 1 A1812YY8.7100.115 B21012YY116.5400.009 B'24012YY133.2220.008 Vent 2 C21012YY116.5400.009 D1812YY8.7100.115 Combine Logic First SegmentSecond SegmentRe-NameCombine/SubtractMethodCombined Entire WallA'A'a-Deflection0.056 Vent 1 ABAB+Stiffness125.249 A'aABA'b+Deflection0.064 A'bB'B'a-Deflection0.056 Vent 2 CDCD+Stiffness125.249 B'aCDFinal+Deflection0.064 CXT, Inc. (Precast Div.) 11 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID:ACI's Alternate Design of Slender Walls ACI 14.8 DESIGN OF WALL MARKED W3 Assumptions from this methodology: Wall panel shall be simply supported, axially loaded, and subject to out-of-plane uniform lateral loading where maximum ACI 14.8.2.1 moments and deflections occur at mid-height of the wall. NotesThe cross section is constant over the height of the wall panel. ACI 14.8.2.2 The wall cross sections shall be tension controlled. ACI 14.8.2.3 Phi*Mn >= Mcr ACI 14.8.2.4 Concentrated gravity loads are distributed over the wall length ACI 14.8.2.5 The vertical stress Pu/Ag at mid-height shall not exceed 0.06*f'c ACI 14.8.2.6 Material Properties f`c5000 psiGeometric Properties Steel ReinforcementPlain WWF >= W1.2-A185 X Corridinate12.5 Fy wire mesh65000 psi Y Corridinate8 Fy rebar60000 pcf Direction of WallX Lightweight?No Center of gravity X71.729 Concrete density150 pcf O.K.Center of gravity Y8.000 E (Steel)29000000 psiWall Weight 1944.000 lbs. E (Concrete)4290000 psiCentral wall?Yes ACI 8.5.1 n (modular ratio)6.76Yes Wall that supports 2 roof panels? 0 ft lop (length of opening on wall) Shear ParametersH (height of wall)103.37 in Phi.v0.85Lh (length of wall)9.833 ft ACI 9.3.2.3 Vc3.123 kipTwo-way slab Analyisis will be performed as : ACI 11.3.1.1 & 11.2.1.2 Phi*Vc2.654 kipb (section width)12 in ACI 11.1.1 h (section thickness)4 in Minimum Wall Reinforcement Requirementsct (cover top)2 in roe.min.vert0.0012cb (cover bottom)2 in ACI 14.3.2 roe.min.hor0.0020.319 in rd (assumed reinf. diameter) ACI 14.3.3 Max Vertical spacing18 indt (effective depth top)1.84 in ACI 14.3.5 Max Horizontal spacing18 in1.84 in db (effective depth bottom) ACI 14.3.5 0.278 Cs (% of DL used for Seismic) LoadingEccentricity - Axial Load1 in Axial Design Loads (pressure from roof)Lateral Design Loads (pressure on wall)Is wall SplitNo D (Dead load) + Ww ( Wall weight)110.94 psfDead Load (DL.lat)0 psf S (Snow Load)250 psfSnow Load (SL.lat)0 psf L (Live Load)0 psfLive Load (LL.lat)0 psfWire Mesh Lr (Live Roof Load)30 psfLive Roof Load (LLr.lat)0 psfWire SizeW8 W (Wind Load)108.86 psfWind Load (WL.lat)58.99 psfspacing4 in E (Earthquake Load)16.95 psfEarthquake Load (EL.lat)13.91 psfMesh Area0.24 in^2 = As Factored Axially Applied LoadsFactored Laterally Applied Loads Factored Loading per ACIACI eq. 9-3Factored Loading per ACI ACI eq. 9-4 Factored Pressure on Roof Wr560.21394.38 psf Factored Pressure on Wall Ww Axial Pressure on SectionLateral Pressure on Section PuB2.08 kip0.03 klf Lw = W*(L^4 / L^4 + H^4) 0.06 klf Hw = W*(H^4 / H^4 + L^4) Assumption check Pu/Ag43.333 psiUnfactored Laterally Applied Loads 0.06*f`c300 psi58.99 psf Unfactored Pressure on Wall uWw O.K. Check ACI 14.8.2.6 Lateral Pressure on Section Unfactored Axially Applied Loads0.02 klf Lw = W*(L^4 / L^4 + H^4) Unfactored Pressure on Roof uWr330.0825 psf0.04 klf Hw = W*(H^4 / H^4 + L^4) Axial Pressure on Section PB1.28 kip ShearDeflection ACI 14.8.4 Factored Loading per ACIACI eq. 9-3Service Loads Vu = wuB*(Bw-2db) / 20.09Axial1.28 kip Phi*Vc/21.33Lateral0.02 klf Check Shear ACI 11.5.5.1O.K.Allowed service deflection0.69 in Msa2.866 kip-in M2.881 kip-in Ds0.012 in Check deflectionO.K. Allowable CapacityFlexure Ig = (b*h^3)/1264 in^4Assumption check Ag = (b*h)48 in^2SpanHwLw Yt = h/22net Tensile Strain0.0110.011 fr (rupture modulus)530.330 psiCheck ACI 14.8.2.3 TensionTension Mcr16.971 kip-inMua0.647 kip-ft Beta_10.8 Trial Ast req'd0.073 in^2ACI eq. (14-6) BMu0.780 kip-ft0.360 kip-ft 7.403686795 kd 0.583 in I.crACI 9.3.2 3.35 in^4 efb 0.90.9 0.003 c e1.960 kip-ft1.960 kip-ft fMn trial = AsFy(dt - a/2) 0.005 s a0.000 kip-ft0.000 kip-ft 0.32469 psiDM =Mpos - M cAs Add'l req'd0.00 in^20.00 in^2 0.406 in AseAdditional reinf req`d0.00 in^20.00 in^2 0.27 in^2 IcrdeflectionAdd'l bar size:33 4.21 in^4 Ieqty req`d00 64.00 in^4 deltaor spacing of:00 150 r(maximum tensile reinforcement)0.02250.000 kip-ft0.000 kip-ft t As add'l = r(min. temperature reinforcement)0.0017 temp r(minimum tensile reinforcement)0.0033Ast = As + As add'l0.24 in^20.24 in^2 min r(trial reinforcement ratio bottom)0.00331.961 kip-ft1.961 kip-ft fMn = AsFy(db - a/2) trial 0.0110O.K.O.K. (reinforcement ratio provided) provided CheckMn > Mu % allowed39.78%18.36% CXT, Inc. (Precast Div.) 12 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Entire WallDoor 1 Door 2 REINFORCEMENT AT OPENINGS LoadingMaterial Properties Pu (factorized load from roof)0.56 klfdb (effective depth bottom)1.84 in Ww (weight of panel per sq ft)0.05 ksfa (block of strain)0.32469 psi a=As * fy / (0.85 * f`c *b) Factorized Moment H height above (-) Weight of Pw total factorized wu total Mu OpeningHorizontal LocationVertical LocationL length of opening openingOpening (LBS)panel loadfactorized load(wu*L^2)/12 Door 10.99 ft0 ft3.34 ft1.76 ft1144.650.09 klf0.65 klf0.6 kip-ft Door 25.49 ft0 ft3.34 ft1.76 ft1144.650.09 klf0.65 klf0.6 kip-ft Flexure Check Mn = OpeningAs req'dBar sizeqty req'd: b Mn > Mu AsFy(db - a/2) Door 1 0.90.007 in^2No. 319.67 kip-ftO.K. Door 2 0.90.007 in^2No. 319.67 kip-ftO.K. CONNECTIONS Full Resistance Value Overturning Base AnchorsBase AnchorsWall-Wall ConnectionLateral QuantityMaximumMaximumShearMoment +Moment -Moment +Moment - in ShearR - DistanceL - Distancekipkip - ftkip - ftkip - ftkip - ft 311311320.23343.7542.0635.4735.47 Base Anchors Total Tension DistTension (kip)ShearL - DistMoment +Moment - 10.195 5 in 3.886.05 113 in0.072 kip*ft36.574 kip*ft Base Anchor 1 63 in 2.438.14 55 in7.104 kip*ft5.414 kip*ft Base Anchor 2 113 in 3.886.05 5 in36.574 kip*ft0.072 kip*ft Base Anchor 3 Wall Connections CapacityCountering Dead % of Overturning Moment QuantityDistAllowable Adjoining L - Dist of eachLoad from wall to Resistance(kip-ft) of Anchors Wall(inches)Force Up LeftLow Right use AnchorAdjoining Wall 31.4761.6708.33%W2 0118.0001.6700.00016.422 Wall Connection 1 32.4223.87450.00%W6 5959.0003.87419.04519.045 Wall Connection 2 31.4761.6708.33%W4 1180.0001.67016.4220.000 Wall Connection 3 Wall Shear Checks Shear Connections at BaseWall Shear Capacity Required Shear Capacity (lb) per DesignCapacityReserveDesignResistanceReserve Base Connector Force(lb)(lb)Capacity(PLF)(PLF)checkCapacity 36842023316549 2226989OK1228(16549)OK RIGIDITY CALCULATED VALUES34%Final 2.079656943 PierLengthHeightFixed Top?Useable?Stiffness (k)Deflection Label(inches)(inches)(Y/N)(Y/N)(1000 kip / IN)(in / 1000 kip) Entire Wall118103.37YY6.0600.165 A'11882.25YY8.2310.121 Door 1 A11.8882.25YY0.05717.632 B66.0482.25YY3.5280.283 B'11882.25YY8.2310.121 Door 2 C65.8882.25YY3.5140.285 D12.0482.25YY0.05916.965 Combine Logic First SegmentSecond SegmentRe-NameCombine/SubtractMethodCombined Entire WallA'A'a-Deflection0.044 Door 1 ABAB+Stiffness3.585 A'aABA'b+Deflection0.322 A'bB'B'a-Deflection0.201 Door 2 CDCD+Stiffness3.573 B'aCDFinal+Deflection0.481 CXT, Inc. (Precast Div.) 13 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID:ACI's Alternate Design of Slender Walls ACI 14.8 DESIGN OF WALL MARKED W4 Assumptions from this methodology: Wall panel shall be simply supported, axially loaded, and subject to out-of-plane uniform lateral loading where maximum ACI 14.8.2.1 moments and deflections occur at mid-height of the wall. NotesThe cross section is constant over the height of the wall panel. ACI 14.8.2.2 The wall cross sections shall be tension controlled. ACI 14.8.2.3 Phi*Mn >= Mcr ACI 14.8.2.4 Concentrated gravity loads are distributed over the wall length ACI 14.8.2.5 The vertical stress Pu/Ag at mid-height shall not exceed 0.06*f'c ACI 14.8.2.6 Material Properties f`c5000 psiGeometric Properties Steel ReinforcementPlain WWF >= W1.2-A185 X Corridinate132.5 Fy wire mesh65000 psi Y Corridinate6 Fy rebar60000 pcf Direction of WallY Lightweight?No Center of gravity X132.500 Concrete density150 pcf O.K.Center of gravity Y126.000 E (Steel)29000000 psiWall Weight 7905.000 lbs. E (Concrete)4290000 psiCentral wall?Yes ACI 8.5.1 n (modular ratio)6.76No Wall that supports 2 roof panels? 0 ft lop (length of opening on wall) Shear ParametersH (height of wall)96 in Phi.v0.85Lh (length of wall)20.000 ft ACI 9.3.2.3 Vc3.123 kipOne-way slab Analyisis will be performed as : ACI 11.3.1.1 & 11.2.1.2 Phi*Vc2.654 kipb (section width)12 in ACI 11.1.1 h (section thickness)4 in Minimum Wall Reinforcement Requirementsct (cover top)2 in roe.min.vert0.0012cb (cover bottom)2 in ACI 14.3.2 roe.min.hor0.0020.319 in rd (assumed reinf. diameter) ACI 14.3.3 Max Vertical spacing18 indt (effective depth top)1.84 in ACI 14.3.5 Max Horizontal spacing18 in1.84 in db (effective depth bottom) ACI 14.3.5 0.278 Cs (% of DL used for Seismic) LoadingEccentricity - Axial Load1 in Axial Design Loads (pressure from roof)Lateral Design Loads (pressure on wall)Is wall SplitNo D (Dead load) + Ww ( Wall weight)110.94 psfDead Load (DL.lat)0 psf S (Snow Load)250 psfSnow Load (SL.lat)0 psf L (Live Load)0 psfLive Load (LL.lat)0 psfWire Mesh Lr (Live Roof Load)30 psfLive Roof Load (LLr.lat)0 psfWire SizeW8 W (Wind Load)108.86 psfWind Load (WL.lat)58.99 psfspacing4 in E (Earthquake Load)16.95 psfEarthquake Load (EL.lat)13.91 psfMesh Area0.24 in^2 = As Factored Axially Applied LoadsFactored Laterally Applied Loads Factored Loading per ACIACI eq. 9-3Factored Loading per ACI ACI eq. 9-4 Factored Pressure on Roof Wr560.21394.38 psf Factored Pressure on Wall Ww Axial Pressure on SectionLateral Pressure on Section PuB2.22 kip0 klf Lw = W*(L^4 / H^4 + L^4) 0.09 klf Hw = W*(L^4 / H^4 + L^4) Assumption check Pu/Ag46.250 psiUnfactored Laterally Applied Loads 0.06*f`c300 psi58.99 psf Unfactored Pressure on Wall uWw O.K. Check ACI 14.8.2.6 Lateral Pressure on Section Unfactored Axially Applied Loads0 klf Lw = W*(L^4 / H^4 + L^4) Unfactored Pressure on Roof uWr330.0825 psf0.06 klf Hw = W*(L^4 / H^4 + L^4) Axial Pressure on Section PB1.42 kip ShearDeflection ACI 14.8.4 Factored Loading per ACIACI eq. 9-3Service Loads Vu = wuB*(Bw-2db) / 20Axial1.42 kip Phi*Vc/21.33Lateral0 klf Check Shear ACI 11.5.5.1O.K.Allowed service deflection0.64 in Msa0.710 kip-in M0.714 kip-in Ds0.002 in Check deflectionO.K. Allowable CapacityFlexure Ig = (b*h^3)/1264 in^4Assumption check Ag = (b*h)48 in^2SpanHwLw Yt = h/22net Tensile Strain0.0110.011 fr (rupture modulus)530.330 psiCheck ACI 14.8.2.3 TensionTension Mcr16.971 kip-inMua0.813 kip-ft Beta_10.8 Trial Ast req'd0.073 in^2ACI eq. (14-6) BMu0.960 kip-ft0.000 kip-ft 7.403686795 kd 0.583 in I.crACI 9.3.2 3.35 in^4 efb 0.90.9 0.003 c e1.960 kip-ft1.960 kip-ft fMn trial = AsFy(dt - a/2) 0.005 s a0.000 kip-ft0.000 kip-ft 0.32469 psiDM =Mpos - M cAs Add'l req'd0.00 in^20.00 in^2 0.406 in AseAdditional reinf req`d0.00 in^20.00 in^2 0.27 in^2 IcrdeflectionAdd'l bar size:33 4.21 in^4 Ieqty req`d00 64.00 in^4 deltaor spacing of:00 150 r(maximum tensile reinforcement)0.02250.000 kip-ft0.000 kip-ft t As add'l = r(min. temperature reinforcement)0.0017 temp r(minimum tensile reinforcement)0.0033Ast = As + As add'l0.24 in^20.24 in^2 min r(trial reinforcement ratio bottom)0.00331.961 kip-ft1.961 kip-ft fMn = AsFy(db - a/2) trial 0.0110O.K.O.K. (reinforcement ratio provided) provided CheckMn > Mu % allowed48.95%0.00% CXT, Inc. (Precast Div.) 14 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Entire WallVent 1 Vent 2 REINFORCEMENT AT OPENINGS LoadingMaterial Properties Pu (factorized load from roof)0.56 klfdb (effective depth bottom)1.84 in Ww (weight of panel per sq ft)0.05 ksfa (block of strain)0.32469 psi a=As * fy / (0.85 * f`c *b) Factorized Moment H height above (-) Weight of Pw total factorized wu total Mu OpeningHorizontal LocationVertical LocationL length of opening openingOpening (LBS)panel loadfactorized load(wu*L^2)/12 Vent 11.5 ft1 ft1 ft6 ft50.000.3 klf0.86 klf0.07 kip-ft Vent 217.5 ft1 ft1 ft6 ft50.000.3 klf0.86 klf0.07 kip-ft Flexure Check Mn = OpeningAs req'dBar sizeqty req'd: b Mn > Mu AsFy(db - a/2) Vent 1 0.90 in^2No. 300 kip-ftO.K. Vent 2 0.90 in^2No. 300 kip-ftO.K. CONNECTIONS Full Resistance Value Overturning Base AnchorsBase AnchorsWall-Wall ConnectionLateral QuantityMaximumMaximumShearMoment +Moment -Moment +Moment - in ShearR - DistanceL - Distancekipkip - ftkip - ftkip - ftkip - ft 522822840.69589.7489.74157.95132.34 Base Anchors Total Tension DistTension (kip)ShearL - DistMoment +Moment - 12.135 12 in 2.438.14 228 in0.128 kip*ft46.113 kip*ft Base Anchor 1 66 in 2.438.14 174 in3.864 kip*ft26.857 kip*ft Base Anchor 2 120 in 2.438.14 120 in12.774 kip*ft12.774 kip*ft Base Anchor 3 174 in 2.438.14 66 in26.857 kip*ft3.864 kip*ft Base Anchor 4 228 in 2.438.14 12 in46.113 kip*ft0.128 kip*ft Base Anchor 5 Wall Connections CapacityCountering Dead % of Overturning Moment QuantityDistAllowable Adjoining L - Dist of eachLoad from wall to Resistance(kip-ft) of Anchors Wall(inches)Force Up LeftLow Right use AnchorAdjoining Wall 32.4223.03525.00%W3 2238.0003.0350.50660.189 Wall Connection 1 32.4224.21425.00%W5 38202.0004.21413.34570.940 Wall Connection 2 32.4227.77050.00%W1 2382.0007.266144.1011.211 Wall Connection 3 Wall Shear Checks Shear Connections at BaseWall Shear Capacity Required Shear Capacity (lb) per DesignCapacityReserveDesignResistanceReserve Base Connector Force(lb)(lb)Capacity(PLF)(PLF)checkCapacity 97044069530991 26920061OK1941(30991)OK RIGIDITY CALCULATED VALUES99%Final 15.58709708 PierLengthHeightFixed Top?Useable?Stiffness (k)Deflection Label(inches)(inches)(Y/N)(Y/N)(1000 kip / IN)(in / 1000 kip) Entire Wall24096YY15.8230.063 A'24012YY133.2220.008 Vent 1 A1812YY8.7100.115 B21012YY116.5400.009 B'24012YY133.2220.008 Vent 2 C21012YY116.5400.009 D1812YY8.7100.115 Combine Logic First SegmentSecond SegmentRe-NameCombine/SubtractMethodCombined Entire WallA'A'a-Deflection0.056 Vent 1 ABAB+Stiffness125.249 A'aABA'b+Deflection0.064 A'bB'B'a-Deflection0.056 Vent 2 CDCD+Stiffness125.249 B'aCDFinal+Deflection0.064 CXT, Inc. (Precast Div.) 15 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID:ACI's Alternate Design of Slender Walls ACI 14.8 DESIGN OF WALL MARKED W5 Assumptions from this methodology: Wall panel shall be simply supported, axially loaded, and subject to out-of-plane uniform lateral loading where maximum ACI 14.8.2.1 moments and deflections occur at mid-height of the wall. NotesThe cross section is constant over the height of the wall panel. ACI 14.8.2.2 The wall cross sections shall be tension controlled. ACI 14.8.2.3 Phi*Mn >= Mcr ACI 14.8.2.4 Concentrated gravity loads are distributed over the wall length ACI 14.8.2.5 The vertical stress Pu/Ag at mid-height shall not exceed 0.06*f'c ACI 14.8.2.6 Material Properties f`c5000 psiGeometric Properties Steel ReinforcementPlain WWF >= W1.2-A185 X Corridinate12.5 Fy wire mesh65000 psi Y Corridinate44 Fy rebar60000 pcf Direction of WallX Lightweight?No Center of gravity X71.500 Concrete density150 pcf O.K.Center of gravity Y44.000 E (Steel)29000000 psiWall Weight 4235.000 lbs. E (Concrete)4290000 psiCentral wall?Yes ACI 8.5.1 n (modular ratio)6.76Yes Wall that supports 2 roof panels? 0 ft lop (length of opening on wall) Shear ParametersH (height of wall)103.37 in Phi.v0.85Lh (length of wall)9.833 ft ACI 9.3.2.3 Vc3.123 kipTwo-way slab Analyisis will be performed as : ACI 11.3.1.1 & 11.2.1.2 Phi*Vc2.654 kipb (section width)12 in ACI 11.1.1 h (section thickness)4 in Minimum Wall Reinforcement Requirementsct (cover top)2 in roe.min.vert0.0012cb (cover bottom)2 in ACI 14.3.2 roe.min.hor0.0020.319 in rd (assumed reinf. diameter) ACI 14.3.3 Max Vertical spacing18 indt (effective depth top)1.84 in ACI 14.3.5 Max Horizontal spacing18 in1.84 in db (effective depth bottom) ACI 14.3.5 0.278 Cs (% of DL used for Seismic) LoadingEccentricity - Axial Load1 in Axial Design Loads (pressure from roof)Lateral Design Loads (pressure on wall)Is wall SplitNo D (Dead load) + Ww ( Wall weight)110.94 psfDead Load (DL.lat)0 psf S (Snow Load)250 psfSnow Load (SL.lat)0 psf L (Live Load)0 psfLive Load (LL.lat)0 psfWire Mesh Lr (Live Roof Load)30 psfLive Roof Load (LLr.lat)0 psfWire SizeW8 W (Wind Load)108.86 psfWind Load (WL.lat)58.99 psfspacing4 in E (Earthquake Load)16.95 psfEarthquake Load (EL.lat)13.91 psfMesh Area0.24 in^2 = As Factored Axially Applied LoadsFactored Laterally Applied Loads Factored Loading per ACIACI eq. 9-3Factored Loading per ACI ACI eq. 9-4 Factored Pressure on Roof Wr560.21394.38 psf Factored Pressure on Wall Ww Axial Pressure on SectionLateral Pressure on Section PuB2.24 kip0.03 klf Lw = W*(L^4 / L^4 + H^4) 0.06 klf Hw = W*(H^4 / H^4 + L^4) Assumption check Pu/Ag46.667 psiUnfactored Laterally Applied Loads 0.06*f`c300 psi58.99 psf Unfactored Pressure on Wall uWw O.K. Check ACI 14.8.2.6 Lateral Pressure on Section Unfactored Axially Applied Loads0.02 klf Lw = W*(L^4 / L^4 + H^4) Unfactored Pressure on Roof uWr330.0825 psf0.04 klf Hw = W*(H^4 / H^4 + L^4) Axial Pressure on Section PB1.45 kip ShearDeflection ACI 14.8.4 Factored Loading per ACIACI eq. 9-3Service Loads Vu = wuB*(Bw-2db) / 20.09Axial1.45 kip Phi*Vc/21.33Lateral0.02 klf Check Shear ACI 11.5.5.1O.K.Allowed service deflection0.69 in Msa2.951 kip-in M2.969 kip-in Ds0.012 in Check deflectionO.K. Allowable CapacityFlexure Ig = (b*h^3)/1264 in^4Assumption check Ag = (b*h)48 in^2SpanHwLw Yt = h/22net Tensile Strain0.0110.011 fr (rupture modulus)530.330 psiCheck ACI 14.8.2.3 TensionTension Mcr16.971 kip-inMua0.653 kip-ft Beta_10.8 Trial Ast req'd0.073 in^2ACI eq. (14-6) BMu0.800 kip-ft0.360 kip-ft 7.403686795 kd 0.583 in I.crACI 9.3.2 3.35 in^4 efb 0.90.9 0.003 c e1.960 kip-ft1.960 kip-ft fMn trial = AsFy(dt - a/2) 0.005 s a0.000 kip-ft0.000 kip-ft 0.32469 psiDM =Mpos - M cAs Add'l req'd0.00 in^20.00 in^2 0.406 in AseAdditional reinf req`d0.00 in^20.00 in^2 0.27 in^2 IcrdeflectionAdd'l bar size:33 4.21 in^4 Ieqty req`d00 64.00 in^4 deltaor spacing of:00 150 r(maximum tensile reinforcement)0.02250.000 kip-ft0.000 kip-ft t As add'l = r(min. temperature reinforcement)0.0017 temp r(minimum tensile reinforcement)0.0033Ast = As + As add'l0.24 in^20.24 in^2 min r(trial reinforcement ratio bottom)0.00331.961 kip-ft1.961 kip-ft fMn = AsFy(db - a/2) trial 0.0110O.K.O.K. (reinforcement ratio provided) provided CheckMn > Mu % allowed40.80%18.36% CXT, Inc. (Precast Div.) 16 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Entire Wall REINFORCEMENT AT OPENINGS LoadingMaterial Properties Pu (factorized load from roof)0.56 klfdb (effective depth bottom)1.84 in Ww (weight of panel per sq ft)0.05 ksfa (block of strain)0.32469 psi a=As * fy / (0.85 * f`c *b) Factorized Moment H height above (-) Weight of Pw total factorized wu total Mu OpeningHorizontal LocationVertical LocationL length of opening openingOpening (LBS)panel loadfactorized load(wu*L^2)/12 Flexure Check Mn = OpeningAs req'dBar sizeqty req'd: b Mn > Mu AsFy(db - a/2) CONNECTIONS Full Resistance Value Overturning Base AnchorsBase AnchorsWall-Wall ConnectionLateral QuantityMaximumMaximumShearMoment +Moment -Moment +Moment - in ShearR - DistanceL - Distancekipkip - ftkip - ftkip - ftkip - ft 411311328.37252.3352.3362.5862.58 Base Anchors Total Tension DistTension (kip)ShearL - DistMoment +Moment - 12.622 5 in 3.886.05 113 in0.072 kip*ft36.574 kip*ft Base Anchor 1 29 in 2.438.14 89 in1.505 kip*ft14.177 kip*ft Base Anchor 2 89 in 2.438.14 29 in14.177 kip*ft1.505 kip*ft Base Anchor 3 113 in 3.886.05 5 in36.574 kip*ft0.072 kip*ft Base Anchor 4 Wall Connections CapacityCountering Dead % of Overturning Moment QuantityDistAllowable Adjoining L - Dist of eachLoad from wall to Resistance(kip-ft) of Anchors Wall(inches)Force Up LeftLow Right use AnchorAdjoining Wall 31.4769.85349.17%W2 0118.0004.4270.00043.534 Wall Connection 1 32.4223.87450.00%W6 5959.0003.87419.04519.045 Wall Connection 2 31.4769.85349.17%W4 1180.0004.42743.5340.000 Wall Connection 3 Wall Shear Checks Shear Connections at BaseWall Shear Capacity Required Shear Capacity (lb) per DesignCapacityReserveDesignResistanceReserve Base Connector Force(lb)(lb)Capacity(PLF)(PLF)checkCapacity 104362837217936 64820365OK2609(17936)OK RIGIDITY CALCULATED VALUES100%Final 6.060034501 PierLengthHeightFixed Top?Useable?Stiffness (k)Deflection Label(inches)(inches)(Y/N)(Y/N)(1000 kip / IN)(in / 1000 kip) Entire Wall118103.37YY6.0600.165 Combine Logic First SegmentSecond SegmentRe-NameCombine/SubtractMethodCombined Entire Wall0Final6.060 CXT, Inc. (Precast Div.) 17 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID:ACI's Alternate Design of Slender Walls ACI 14.8 DESIGN OF WALL MARKED W6 Assumptions from this methodology: Wall panel shall be simply supported, axially loaded, and subject to out-of-plane uniform lateral loading where maximum ACI 14.8.2.1 moments and deflections occur at mid-height of the wall. NotesThe cross section is constant over the height of the wall panel. ACI 14.8.2.2 The wall cross sections shall be tension controlled. ACI 14.8.2.3 Phi*Mn >= Mcr ACI 14.8.2.4 Concentrated gravity loads are distributed over the wall length ACI 14.8.2.5 The vertical stress Pu/Ag at mid-height shall not exceed 0.06*f'c ACI 14.8.2.6 Material Properties f`c5000 psiGeometric Properties Steel ReinforcementPlain WWF >= W1.2-A185 X Corridinate71.5 Fy wire mesh65000 psi Y Corridinate10 Fy rebar60000 pcf Direction of WallY Lightweight?No Center of gravity X71.500 Concrete density150 pcf O.K.Center of gravity Y26.000 E (Steel)29000000 psiWall Weight 1228.000 lbs. E (Concrete)4290000 psiCentral wall?Yes ACI 8.5.1 n (modular ratio)6.76Yes Wall that supports 2 roof panels? 0 ft lop (length of opening on wall) Shear ParametersH (height of wall)110.74 in Phi.v0.85Lh (length of wall)2.667 ft ACI 9.3.2.3 Vc3.123 kipOne-way slab Analyisis will be performed as : ACI 11.3.1.1 & 11.2.1.2 Phi*Vc2.654 kipb (section width)12 in ACI 11.1.1 h (section thickness)4 in Minimum Wall Reinforcement Requirementsct (cover top)2 in roe.min.vert0.0012cb (cover bottom)2 in ACI 14.3.2 roe.min.hor0.0020.319 in rd (assumed reinf. diameter) ACI 14.3.3 Max Vertical spacing18 indt (effective depth top)1.84 in ACI 14.3.5 Max Horizontal spacing18 in1.84 in db (effective depth bottom) ACI 14.3.5 0.278 Cs (% of DL used for Seismic) LoadingEccentricity - Axial Load1 in Axial Design Loads (pressure from roof)Lateral Design Loads (pressure on wall)Is wall SplitNo D (Dead load) + Ww ( Wall weight)110.94 psfDead Load (DL.lat)0 psf S (Snow Load)250 psfSnow Load (SL.lat)0 psf L (Live Load)0 psfLive Load (LL.lat)0 psfWire Mesh Lr (Live Roof Load)30 psfLive Roof Load (LLr.lat)0 psfWire SizeW8 W (Wind Load)108.86 psfWind Load (WL.lat)58.99 psfspacing4 in E (Earthquake Load)16.95 psfEarthquake Load (EL.lat)13.91 psfMesh Area0.24 in^2 = As Factored Axially Applied LoadsFactored Laterally Applied Loads Factored Loading per ACIACI eq. 9-3Factored Loading per ACI ACI eq. 9-4 Factored Pressure on Roof Wr560.21394.38 psf Factored Pressure on Wall Ww Axial Pressure on SectionLateral Pressure on Section PuB2.26 kip0.09 klf Lw = W*(L^4 / L^4 + H^4) 0 klf Hw = W*(H^4 / H^4 + L^4) Assumption check Pu/Ag47.083 psiUnfactored Laterally Applied Loads 0.06*f`c300 psi58.99 psf Unfactored Pressure on Wall uWw O.K. Check ACI 14.8.2.6 Lateral Pressure on Section Unfactored Axially Applied Loads0.06 klf Lw = W*(L^4 / L^4 + H^4) Unfactored Pressure on Roof uWr330.0825 psf0 klf Hw = W*(H^4 / H^4 + L^4) Axial Pressure on Section PB1.47 kip ShearDeflection ACI 14.8.4 Factored Loading per ACIACI eq. 9-3Service Loads Vu = wuB*(Bw-2db) / 2-0.05Axial1.47 kip Phi*Vc/21.33Lateral0.06 klf Check Shear ACI 11.5.5.1O.K.Allowed service deflection0.74 in Msa8.400 kip-in M8.457 kip-in Ds0.039 in Check deflectionO.K. Allowable CapacityFlexure Ig = (b*h^3)/1264 in^4Assumption check Ag = (b*h)48 in^2SpanHwLw Yt = h/22net Tensile Strain0.0110.011 fr (rupture modulus)530.330 psiCheck ACI 14.8.2.3 TensionTension Mcr16.971 kip-inMua0.094 kip-ft Beta_10.8 Trial Ast req'd0.073 in^2ACI eq. (14-6) BMu0.120 kip-ft0.080 kip-ft 7.403686795 kd 0.583 in I.crACI 9.3.2 3.35 in^4 efb 0.90.9 0.003 c e1.960 kip-ft1.960 kip-ft fMn trial = AsFy(dt - a/2) 0.005 s a0.000 kip-ft0.000 kip-ft 0.32469 psiDM =Mpos - M cAs Add'l req'd0.00 in^20.00 in^2 0.406 in AseAdditional reinf req`d0.00 in^20.00 in^2 0.27 in^2 IcrdeflectionAdd'l bar size:33 4.21 in^4 Ieqty req`d00 64.00 in^4 deltaor spacing of:00 150 r(maximum tensile reinforcement)0.02250.000 kip-ft0.000 kip-ft t As add'l = r(min. temperature reinforcement)0.0017 temp r(minimum tensile reinforcement)0.0033Ast = As + As add'l0.24 in^20.24 in^2 min r(trial reinforcement ratio bottom)0.00331.961 kip-ft1.961 kip-ft fMn = AsFy(db - a/2) trial 0.0110O.K.O.K. (reinforcement ratio provided) provided CheckMn > Mu % allowed6.12%4.08% CXT, Inc. (Precast Div.) 18 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Entire Wall REINFORCEMENT AT OPENINGS LoadingMaterial Properties Pu (factorized load from roof)0.56 klfdb (effective depth bottom)1.84 in Ww (weight of panel per sq ft)0.05 ksfa (block of strain)0.32469 psi a=As * fy / (0.85 * f`c *b) Factorized Moment H height above (-) Weight of Pw total factorized wu total Mu OpeningHorizontal LocationVertical LocationL length of opening openingOpening (LBS)panel loadfactorized load(wu*L^2)/12 Flexure Check Mn = OpeningAs req'dBar sizeqty req'd: b Mn > Mu AsFy(db - a/2) CONNECTIONS Full Resistance Value Overturning Base AnchorsBase AnchorsWall-Wall ConnectionLateral QuantityMaximumMaximumShearMoment +Moment -Moment +Moment - in ShearR - DistanceL - Distancekipkip - ftkip - ftkip - ftkip - ft 2242413.8877.247.2419.3711.81 Base Anchors Total Tension DistTension (kip)ShearL - DistMoment +Moment - 6.519 8 in 3.266.94 24 in0.724 kip*ft6.519 kip*ft Base Anchor 1 24 in 3.266.94 8 in6.519 kip*ft0.724 kip*ft Base Anchor 2 Wall Connections CapacityCountering Dead % of Overturning Moment QuantityDistAllowable Adjoining L - Dist of eachLoad from wall to Resistance(kip-ft) of Anchors Wall(inches)Force Up LeftLow Right use AnchorAdjoining Wall 31.4766.07050.00%W3 032.0004.4270.00011.806 Wall Connection 1 32.4228.42950.00%W5 320.0007.26619.3750.000 Wall Connection 2 Wall Shear Checks Shear Connections at BaseWall Shear Capacity Required Shear Capacity (lb) per DesignCapacityReserveDesignResistanceReserve Base Connector Force(lb)(lb)Capacity(PLF)(PLF)checkCapacity 4561388713432 5020365OK228(13432)OK RIGIDITY CALCULATED VALUES100%Final 0.385906228 PierLengthHeightFixed Top?Useable?Stiffness (k)Deflection Label(inches)(inches)(Y/N)(Y/N)(1000 kip / IN)(in / 1000 kip) Entire Wall32110.74YY0.3862.591 Combine Logic First SegmentSecond SegmentRe-NameCombine/SubtractMethodCombined Entire Wall0Final0.386 CXT, Inc. (Precast Div.) 19 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 0.40 2.86 f t 0.40 ki Bs p -WAY SLA 0.21 ki B wB p 3.50 Ls 0.21 ki ON E p h Bs d SECTION PROPERTIES TWO-WAY SLA steel botto t B steel to m wB p Ls wb wL rd db ct cb 0.70 ki 0.46 ki p p 2.86 f2.86 f tt 0.70 ki 0.46 ki p p 0.39 ki0.25 ki pp 3.500 f 3.500 f t t providedprovidedprovidedprovided 0.39 ki0.25 ki pp temptrialtrial min t d CXT, Inc. (Precast Div.) 20 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Bs -WAY SLA B wB Ls ON E h Bs d SECTION PROPERTIES TWO-WAY SLA steel botto t B steel to m wB p Ls wb wL rd db ct cb comp providedprovidedprovidedprovided d CXT, Inc. (Precast Div.) 21 Page of Schweitzer SW-552 (WA) 21 Date: 04/16/15 Schweitzer SW-552 ID: Geometric propertiesLoading Wv (weight of vault)** Bs (width of roof panel)11.92 ft0 lb Wtr(roof panel weight) Ls (Length of roof panel)21.00 ft15510 lb Ww (total walls panel weight) Ar Area of Roof250.25 ft^226135 lb Fw (floor panel weight) H (height of building)9.75 ft11190 lb We (estimated weight of building) Lb (length of building)20 ft52835 lb Wev (estimated weight of building w/ vault) Wb (width of building)10.5 ft52835 lb PSFr (roof snow load) Ab(Area of building)210 ft^2210 psf PSFf (Floor Live Load) Nv (quantity of vaults)0400 psf Pmax(Maximum allowable pressure) Avl (Area of Vault Lips)0.00 ft^21500 psf Fupmw(MWFRS Uplift Force) Av (Area of Vault)0.00 ft^239.53 psf WLlat(MWFRS lateral wind pressure) Vh (Vault height)0 ft51.74 psf w(specific weight of water) Cab (Closed Area of building)199.94 ft^262.4 pcf Hw(depth of floodwater)**Weight of vault is not considered in sliding resistance1 ft FS (factor of safety required) (sliding factor)0.401.00 CHECK SLIDING RESISTANCE .7*Vseismic (from seismic analysis with snow) 12334.4 lb Shear.7*Vseismic (from seismic analysis without snow) 10287.9 lb Vwind = WLlat * max(Wb,Lb)*H 10089.8 lb * Load adjustment per IBC 1605.3 load combinations. Sliding Resistance with SnowPslide = u*(.6*We+.75*PSFr*Ar)28446.15 lbPslide = Fsreqd FSwind = Pslide / VwindFSwind =2.81.0O.K. Factor of Safety FSseismic = Pslide / VseismicFseismic =2.31.0O.K. Sliding Resistance with No SnowPslide = u*.6*We12680.4 lbPslide = Fsreqd FSwind = Pslide / VwindFswind =1.31.0O.K. Factor of Safety FSseismic = Pslide / VseismicFseismic =1.21.0O.K. CHECK OVERTURNING RESISTANCE .7*Otseismic (from seismic analysis with snow)110.501 kip-ft Shear .7*Otseismic (from seismic analysis without snow)80.798 kip-ft Otwind = (WLlat*Lb*H^2 / 2) + (Fupmw*Lb*Wb^2 / 2)92.773 kip-ft * Load adjustment per IBC 1605.3 load combinations. Overturning Resistance with Otrsnow = (.6*We+.75*PSFr*Ar)*(Wb/2)174.492 kip-ftOtrsnow = Snow Fsreqd FSwind = Otrsnow / OtwindFSwind =1.881.0O.K. Factor of Safety FSseismic = Otrsnow / VseismicFseismic =1.581.0O.K. Overturning Resistance with No Otr = .6*We*Wb/2166.430 kip-ftOtr Snow Fsreqd FSwind = Otr / VwindFswind =1.791.0O.K. Factor of Safety FSseismic = Otr / VseismicFseismic =2.061.0O.K. CHECK BEARING PRESSURE CONDITION Net PressurePnet = (Wev + PSFr*Ar + PSFf*Af) / Ab901.85 psf AllowablePmax > PnetO.K.1500 psf 901.85 psf By observation, if the building is placed on a properly prepared well drained granular sub-base, the design is sufficient for lateral and vertical loads. CHECK BUOYANCY FORCE CONDITION Buoyant ForceFb = w*Av*Hw+w*Cab*(Hw-Vh)Fb =12476.53 lb Factor of SafetyFSb = We / FbFSb =4.231.00O.K. The weight of the building exceeds the buoyant force due to hydrostatic pressure acting on the horizontal surface of the vault, therefore, the design is sufficient against buoyancy. Floor Design Information: 1) The referenced building is made of flood damage resistant 5000 psi reinforced concrete. 2) The vault system, if existing, is designed to minimize infiltration into system and can be considered water tight to a height of 17" 3) Flood Ventilation is available at threshold level and flood ventilation exceeding 1" per sq. ft. of floor area is provided no more than 12" A.F.F.