ASHRAE Standard 140-2011 - Autodesk
ASHRAE Standard 140-2011Test Results ComparisonforSection 5.2 - Building Thermal Envelope and Fabric Load TestsResults for Autodesk Green Building Studio 2/13/2014vs.Informative Annex B8, Section B8.1 Example ResultsPrepared ByAutodeskResults Developed13-Feb-2014
ASHRAE Standard 140-2011Computer Programs, Program Authors, and Producers of Example Results forSection 5.2 - Building Thermal Envelope and Fabric Load TestsThe programs used to generate the example results are described in Table B11-1. Under thecomputer program column, the first entry in each cell is the proper program name and versionnumber. The entries in parentheses are the abbreviations for the programs generally used in thetables and charts which follow.The second column ("Authoring Organization") indicates the national research facility, university,or industry organization with expertise in building science that wrote the simulation software.The third column ("Implemented By") indicates the national research facility, university, or industryorganization with expertise in building science that performed the simulations. The majority oforganizations that performed simulations either ran software written by their organization orotherwise ran other building energy simulation software in addition to that written by their organization.See Standard 140, Annex B11 for further details.TABLE B11-1Computer Programs, Program Authors, and Producers of Example ResultsComputer Program (Abbrev.)BLAST-3.0 level 193 v.1(BLAST-US/IT)DOE-2.1D 14(DOE21D)ESP-RV8(ESP-DMU)SERIRES/SUNCODE 5.7(SRES/SUN)SERIRES 1.2(SRES-BRE)S3PASTASETRNSYS 13.1(TSYS-BEL/BRE)aAuthoring OrganizationaCERL, United States (U.S.)LANL/LBNL,c U.S.Example Results Produced byNREL,b U.S.Politecnico Torino, ItalyNREL, U.S.Strathclyde University, UnitedKingdom (U.K.)NREL/Ecotope, U.S.De Montfort University, U.K.NREL/BRE,d U.S./U.K.BRE, U.K.University of Sevilla, SpainTampere University, FinlandUniversity of Wisconsin, U.S.University of Sevilla, SpainTampere University, FinlandBRE, U.K.Vrije Universiteit (VUB) Brussels,BelgiumNREL, U.S.CERL-U.S. Army Construction Engineering Research LaboratoriesNREL-National Renewable Energy LaboratorycLANL/LBNL-Los Alamos National Laboratory/Lawrence Berkeley National LaboratorydBRE-Building Research Establishmentb
ASHRAE Standard 140-2010 Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014List of TablesTableDescriptionB8-1Annual Heating 12B8-13Annual Sensible Cooling LoadsAnnual Hourly Integrated Peak Heating LoadsAnnual Hourly Integrated Peak Sensible Cooling LoadsFree-Float Temperature OutputLow Mass Basic Sensitivity TestsHigh Mass Basic Sensitivity TestsLow Mass In-Depth (Cases 195 thru 320) Sensitivity TestsLow Mass In-Depth (Cases 395 thru 440) Sensitivity TestsHigh Mass Basic and In-depth Sensitivity TestsAnnual Transmissivity Coefficient of WindowsAnnual Shading Coefficient of Window Shading Devices: Overhangs & FinsB8-14B8-15Sheet TabCase 600 Annual Incident Solar Radiation (kWh/m2)Tables 1Tables 2Tables 3Tables 4Tables 5Tables 62Case 600 Annual Transmitted Solar Radiation – Unshaded (kWh/m )2Case 600 Annual Transmitted Solar Radiation –Shaded (kWh/m )Cell RBngeB7 - P47B48 - P89B7 - AH47B48 - AH88B89 - AH118B7 - P39B41 - P81B7 - P78B7 - P45B47 - P91B7 - O14B16 - O23B25 - O34B36 - O42B44 - O50
ASHRAE Standard 140-2010 Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014List of FiguresFigure TitleB8-1 BESTEST BASIC Annual Incident Solar 1B8-32B8-33BESTEST BASIC Annual Transmitted Solar Radiation UnshadedBESTEST BASIC Annual Transmitted Solar Radiation ShadedBESTEST BASIC Annual Transmissivity Coefficient of Windows(Unshaded Transmitted)/(Incident Solar Radiation)BESTEST BASIC Annual Overhang and Fin Shading Coefficients(1-(Shaded)/(Unshaded)) Transmitted Solar RadiationBESTEST BASIC Low Mass Annual HeatingBESTEST BASIC Low Mass Annual Sensible CoolingBESTEST BASIC Low Mass Peak HeatingBESTEST BASIC Low Mass Peak Sensible CoolingBESTEST BASIC High Mass Annual HeatingBESTEST BASIC High Mass Annual Sensible CoolingBESTEST BASIC High Mass Peak HeatingBESTEST BASIC High Mass Peak Sensible CoolingBESTEST BASIC Maximum Hourly Annual Temperature Free-Float CasesBESTEST BASIC Minimum Hourly Annual Temperature Free-Float CasesBESTEST BASIC Average Hourly Annual Temperature Free-Float CasesBESTEST BASIC South Window Shading (Delta)Annual Heating and Sensible CoolingBESTEST BASIC South Window Shading (Delta)Peak Heating and Sensible CoolingBESTEST BASIC East & West Window (Delta)Annual Heating and Sensible CoolingBESTEST BASIC East & West Window (Delta)Peak Heating and Sensible CoolingBESTEST BASIC East & West Shaded Window (Delta)Annual Heating and Sensible CoolingBESTEST BASIC East & West Shaded Window (Delta)Peak Heating and Sensible CoolingBESTEST BASIC Thermostat Setback (Delta) Annual HeatingBESTEST BASIC Thermostat Setback (Delta) Peak HeatingBESTEST BASIC Vent Cooling (Delta) Annual Sensible CoolingBESTEST BASIC Vent Cooling (Delta) Peak Sensible CoolingBESTEST BASIC Sunspace (Delta) Annual Heating and Sensible CoolingBESTEST BASIC Sunspace (Delta) Peak Heating and Sensible CoolingBESTEST BASIC AND IN-DEPTH Mass Effect (Delta)Annual Heating and Sensible CoolingBESTEST BASIC AND IN-DEPTH Mass Effect (Delta)Peak Heating and Sensible CoolingBESTEST IN-DEPTH South Window (Delta)Annual Heating and Sensible CoolingBESTEST IN-DEPTH South Window (Delta)Peak Heating and Sensible CoolingBESTEST IN-DEPTH Low Mass Annual Heating Cases 195 to 250Sheet TabFig B8-1 Ann Incident SolarFig B8-2 Ann SolRad UnshadedFig B8-3 Ann SolRad ShadedFig B8-4 Trans CoeffFig B8-5 OH&Fin Shade CoeffFig B8-6 Lomass Ann HeatFig B8-7 Lomass Ann CoolFig B8-8 Lomass Peak HeatFig B8-9 Lomass Peak CoolFig B8-10 Himass Ann HeatFig B8-11 Himass Ann CoolFig B8-12 Himass Peak HeatFig B8-13 Himass Peak CoolFig B8-14 FF Maximum TempFig B8-15 FF Minimum TempFig B8-16 FF Average TempFig B8-17 Delta-S Shade-LoadFig B8-18 Delta-S Shade-PeakFig B8-19 Delta-E&W-LoadFig B8-20 Delta-E&W-PeakFig B8-21 Delta-E&WShade-LoadFig B8-22 Delta-E&WShade-PeakFig B8-23 Delta-TSetback-HeatFig B8-24 Delta-TSetback-PeakFig B8-25 Delta-VentCool-LoadFig B8-26 Delta-VentCool-PeakFig B8-27 Delta-Sunspace-LoadFig B8-28 Delta-Sunspace-PeakFig B8-29 Delta-Mass Effect-AnnFig B8-30 Delta-Mass Effect-PkFig B8-31 Delta-S Win-AnnFig B8-32 Delta-S Win-PeakFig B8-33 Indepth 1
ASHRAE Standard 140-2010 Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014List of FiguresFigure TitleB8-34 BESTEST IN-DEPTH Low Mass Annual Sensible Cooling Cases 195 to 250B8-35 BESTEST IN-DEPTH Low Mass Peak Heating Cases 195 to 250Sheet TabFig B8-34 Indepth 2Fig B8-35 Indepth 3
ASHRAE Standard 140-2010 Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014List of -53B8-54B8-55B8-56B8-57B8-58B8-59TitleBESTEST IN-DEPTH Low Mass Peak Sensible Cooling Cases 195 to 250BESTEST IN-DEPTH Low Mass Annual Heating Cases 270 to 320BESTEST IN-DEPTH Low Mass Annual Sensible Cooling Cases 270 to 320BESTEST IN-DEPTH Low Mass Peak Heating Cases 270 to 320BESTEST IN-DEPTH Low Mass Peak Sensible Cooling Cases 270 to 320BESTEST IN-DEPTH Cases 195 to 220 (Delta)Annual Heating and Sensible CoolingBESTEST IN-DEPTH Cases 195 to 220 (Delta)Peak Heating and Sensible CoolingBESTEST IN-DEPTH Cases 220 to 270 (Delta)Annual Heating and Sensible CoolingBESTEST IN-DEPTH Cases 220 to 270 (Delta)Peak Heating and Sensible CoolingBESTEST IN-DEPTH Cases 270 to 320 (Delta)Annual Heating and Sensible CoolingBESTEST IN-DEPTH Cases 270 to 320 (Delta)Peak Sensible CoolingBESTEST IN-DEPTH Annual Heating Cases 395 to 440, 800, 810BESTEST IN-DEPTH Annual Sensible Cooling Cases 395 to 440, 800, 810BESTEST IN-DEPTH Peak Heating Cases 395 to 440, 800, 810BESTEST IN-DEPTH Peak Sensible Cooling Cases 395 to 440, 800, 810BESTEST IN-DEPTH Cases 395 to 600 (Delta)Annual Heating and Sensible CoolingBESTEST IN-DEPTH Cases 395 to 600 (Delta)Peak Heating and Sensible CoolingBESTEST Case 900FF Annual Hourly Temperature FrequencyBESTEST Case 600 Cloudy & Clear Day Hourly Incident SolarSouth Facing SurfaceBESTEST Case 600 Cloudy & Clear Day Hourly Incident SolarWest Facing SurfaceBESTEST HOURLY FREE FLOAT TEMPERATURESClear Cold Day - Cases 600FF and 900FFBESTEST HOURLY FREE FLOAT TEMPERATURESClear Hot Day - Cases 650FF and 950FFBESTEST HOURLY LOADS Clear Cold Day, Case 600Heating ( ), Sensible Cooling (-)BESTEST HOURLY LOADS Clear Cold Day, Case 900Heating ( ), Sensible Cooling (-)Sheet TabFig B8-36 Indepth 4Fig B8-37 Indepth 5Fig B8-38 Indepth 6Fig B8-39 Indepth 7Fig B8-40 Indepth 8Fig B8-41 Indepth Delta 1Fig B8-42 Indepth Delta 2Fig B8-43 Indepth Delta 3Fig B8-44 Indepth Delta 4Fig B8-45 Indepth Delta 5Fig B8-46 Indepth Delta 6Fig B8-47 Indepth 9Fig B8-48 Indepth 10Fig B8-49 Indepth 11Fig B8-50 Indepth 12Fig B8-51 Indepth Delta 7Fig B8-52 Indepth Delta 8Fig B8-53 Hrly-Temp FreqFig B8-54 Hrly-IncidentSol-SFig B8-55 Hrly-IncidentSol-WFig B8-56 Hrly-FF Temp-ColdDayFig B8-57 Hrly-FF Temp-HotDayFig B8-58 Hrly-Loads-Case600Fig B8-59 Hrly-Loads-Case900
ASHRAE Standard 140-2011 Test Results Comparison for Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014Note: The statistics in the tables below are based on the Standard 140 informative example results.These statistics do not have any substantial importance and are not to be interpreted as acceptance criteria.Table B8-1. Annual Heating Loads (MWh)Simulation Model:Organization or Country:ESPDMUBLASTUS-ITDOE21D SRES-SUNNRELNRELSRES*BRES3PASSPAINTSYSTASEBEL-BRE FINLANDStatistics for Example ResultsMinMaxMean (Max-Min)/ GBS 2/13/2014CaseMean** (%)Autodesk600 Base Case, South 965.7095.09027.8%4.530610 S. Windows 3555.7865.14627.8%4.607620 East & West 135.9445.40724.6%5.514630 E&W Windows Overhang & .78324.5%5.357640 Case 600 with Htg Temp. 513.8033.20732.8%2.660650 Case 600 with Night 00.0000.0000.000---900 South 702.0411.74549.9%1.660910 S. Windows 5752.2822.06634.2%1.543920 East & West 134.3003.97324.8%3.902930 E&W Windows Overhang & .74525.1%4.332940 Case 900 with Htg Temp. 931.4111.16053.3%1.130950 Case 900 with Night 00.0000.0000.000---960 3113.3732.84637.3%2.487195 Solid Conduction4.1674.1674.1674.1670.0%4.649200 Surface Convection (Int & Ext IR "off")5.2525.2525.2525.2520.0%210 Infrared Radiation (Int IR "off", Ext IR "on")6.4566.5596.5546.9676.4566.9676.6347.7%215 Infrared Radiation (Int IR "on", Ext IR "off")5.5475.5475.5475.5470.0%7.290220 In-Depth Base .7877.66624.0%8.362230 .84010.964 10.376 12.243 11.18516.7%11240 Internal 7.4486.39628.1%7250 Exterior Shortwave 84.7517.0246.03137.7%6270 South Solar 0627.1%5280 Cavity 126.8%5290 South 5426.0%5.658300 East/West 322.3%5.835310 East/West 8%5.795320 4.50428.5%4.230395 Low Mass Solid 4.7995.8355.08520.4%5.772400 Low Mass Opaque 008.7707.55824.7%8.329410 Low Mass 0858.596 10.5069.30920.5%9420 Low Mass Internal 9.1518.01623.1%8430 Low Mass Ext. Shortwave 05.4297.8276.72335.7%6.412440 Low Mass Cavity 325.8%4.815800 High Mass Opaque 687.2286.15338.4%6.351810 High Mass Cavity 844.7%2.152* SRES-BRE (SERIRES 1.2) simulations for cases with interior solar absorptance 0.9 have an input error that likely affects annual heating and cooling loads by 0.2 MWh/y (2-3%); see Section B7.2.** ABS[ (Max-Min) / (Mean of Example Simulation Results) ]GBS 3349.2687.923638.5%480.1%632.5%213.0%
ASHRAE Standard 140-2011 Test Results Comparison for Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014Note: The statistics in the tables below are based on the Standard 140 informative example results.These statistics do not have any substantial importance and are not to be interpreted as acceptance criteria.Table B8-2. Annual Sensible Cooling Loads (MWh)Simulation Model:Organization or Country:ESPDMUBLASTUS-ITDOE21D SRES-SUNNRELNRELSRES*BRES3PASSPAINTSYSTASEBEL-BRE FINLANDStatistics for Example ResultsMinMaxMean (Max-Min)/ GBS 2/13/2014CaseMean** (%)Autodesk7.669600 Base Case, South 377.9646.83226.7%5.623610 S. Windows 9155.7784.96437.5%4.894620 East & West 175.0044.21837.6%2.924630 E&W Windows Overhang & .83255.5%7.259640 Case 600 with Htg Temp. 527.8116.59228.2%5.911650 Case 600 with Night 64.8166.5455.48231.5%3.219900 South 323.4152.67847.9%1.748910 S. Windows 8211.8721.44772.6%3.081920 East & West 403.0922.55249.1%1.770930 E&W Windows Overhang & .64473.0%3.087940 Case 900 with Htg. Temp. 793.2412.57845.1%0.768950 Case 900 with Night 10.3870.9210.60588.2%0.768960 4110.8030.61863.4%0.617195 Solid Conduction0.4140.4140.4140.4140.0%200 Surface Convection (Int & Ext IR "off")0.5700.5700.5700.5700.0%210 Infrared Radiation (Int IR "off", Ext IR 215 Infrared Radiation (Int IR "on", Ext IR "off")0.6390.6390.6390.6390.0%0.386220 In-Depth Base .8350.638101.8%0.621230 850.4541.1390.93073.7%0.643240 Internal 1.2460.98784.2%3.327250 Exterior Shortwave 02.1773.3802.79343.1%9.293270 South Solar Windows7.5288.6709.82810.3508.7648.7147.528 10.3508.97631.4%6.136280 Cavity 936.9%6.775290 South 5140.9%6.032300 East/West 147.4%3.647310 East/West 0%5.988320 6.10336.8%395 Low Mass Solid 0.0000.0160.009177.1%0.001400 Low Mass Opaque 000.0610.036167.3%0.004410 Low Mass 650.0000.0840.054155.5%0.034420 Low Mass Internal 0.1890.130136.9%0.922430 Low Mass Ext. Shortwave 50.4220.8750.62872.1%4.698440 Low Mass Cavity 627.8%0.090800 High Mass Opaque 550.3250.202133.9%1.640810 High Mass Cavity 945.5%* SRES-BRE (SERIRES 1.2) simulations for cases with interior solar absorptance 0.9 have an input error that likely affects annual heating and cooling loads by 0.2 MWh/y (2-3%); see Section B7.2.Affected results for Cases 270 and 290 through 320 are indicated by italics** ABS[ (Max-Min) / (Mean of Example Simulation Results) ]GBS 040.0340.9434.7290.0911.656
ASHRAE Standard 140-2011 Test Results Comparison for Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014Note: The statistics in the tables below are based on the Standard 140 informative example results.These statistics do not have any substantial importance and are not to be interpreted as acceptance criteria.Table B8-3. Annual Hourly Integrated Peak Heating LoadsSimulation Model:Organization or Country:Case600 Base Case, South Windows610 S. Windows Overhang620 East & West Windows630 E&W Windows Overhang & Fins640 Case 600 with Htg. Temp. Setback650 Case 600 with Night Ventilation900 South Windows910 S. Windows Overhang920 East & West Windows930 E&W Windows Overhang & Fins940 Case 900 with Htg. Temp. Setback950 Case 900 with Night Ventilation960 Sunspace195 Solid Conduction200 Surface Convection (Int & Ext IR "off")210 Infrared Radiation (Int IR "off", Ext IR "on")215 Infrared Radiation (Int IR "on", Ext IR "off")220 In-Depth Base Case230 Infiltration240 Internal Gains250 Exterior Shortwave Absorptance270 South Windows280 Cavity Albedo290 South Shading300 East/West Window310 East/West Shading320 Thermostat395 Low Mass Solid Conduction400 Low Mass Opaque Windows410 Low Mass Infiltration420 Low Mass Internal Gains430 Low Mass Ext. Shortwave Absorptance440 Low Mass Cavity Albedo800 High Mass Opaque Windows810 High Mass Cavity 7804-Jan 8Hr04-Jan 22204-Jan 82.973 04-Jan n04-Jan04-Jan04-Jan04-Jan04-Jan04-Jan04-Jan04-Jan* SRES-BRE (SERIRES 1.2) simulations did not produce output for this variable.** ABS[ (Max-Min) / (Mean of Example Simulation Results) ]5255555555855555773.909 04-Jan 7TSYSBEL-BREDate HrHr3.902 04-Jan 8kWTASEFINLANDDate Hr04-Jan04-Jan04-Jan04-Jan04-Jan666684.354 04-Jan 24.354 04-Jan 24.379 04-Jan 204-Jan04-Jan04-Jan04-Jan03-Jan7777904-Jan 704-Jan 704-Jan 76.9540.0003.7973.8014.06104-Jan 804-Jan 86.428 04-Jan 80.0002.779 04-Jan 82.981 04-Jan 53.325 04-Jan Jan666666666686666677Example Result StatisticsGBS 2/13/2014MinMaxMean (Max-Min)/AutodeskkWkWkW Mean** 2.3603.3553.8513.6703.9483.9163.4873.575GBS 59
ASHRAE Standard 140-2011 Test Results Comparison for Section 5.2 - Building Thermal Envelope and Fabric Load TestsAutodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example ResultsBy Autodesk , 13-Feb-2014Note: The statistics in the tables below are based on the Standard 140 informative example results.These statistics do not have any substantial importance and are not to be interpreted as acceptance criteria.Table B8-4. Annual Hourly Integrated Peak Sensible Cooling LoadsSimulation Model:Organization or Country:Case600 Base Case, South Windows610 S. Windows Overhang620 East & West Windows630 E&W Windows Overhang & Fins640 Case 600 with Htg. Temp. Setback650 Case 600 with Night Ventilation900 South Windows910 S. Windows Overhang920 East & West Windows930 E&W Windows Overhang & Fins940 Case 900 with Htg. Temp. Setback950 Case 900 with Night Ventilation960 Sunspace195 Solid Conduction200 Surface Convection (Int & Ext IR "off")210 Infrared Radiation (Int IR "off", Ext IR "on")215 Infrared Radiation (Int IR "on", Ext IR "off")220 In-Depth Base Case230 Infiltration240 Internal Gains250 Exterior Shortwave Absorptance270 South Windows280 Cavity Albedo290 South Shading300 East/West Window310 East/West Shading320 Thermostat395 Low Mass Solid Conduction400 Low Mass Opaque Windows410 Low Mass Infiltration420 Low Mass Internal Gains430 Low Mass Ext. Shortwave Absorptance440 Low Mass Cavity Albedo800 High Mass Opaque Windows810 High Mass Cavity 726-Jul * SRES-BRE (SERIRES 1.2) simulations did not produce output for this variable.** ABS[ (Max-Min) / (Mean of Example Simulation Results) Sep1426-Jul160.937 27-Jul1.455 27-Jul1.119 27-Jul2.605 05-Sep141414110.0000.265 27-Jul0.413 27-Jul0.631 27-Jul1.427 27-Jul02-Sep0.74328-Jul 14151517171515161.215 26-Jul1.700 26-Jul1.398 26-Jul2.258 l26-Jul26-Jul26-Jul18171615151.02827-Jul .4863.3342.6771.179TSYSBEL-BREkWDate6.486 16-Oct5.675 25-Nov4.275 26-Jul3.608 26-Jul6.442 16-Oct6.378 17-Oct3.567 17-Oct2.792 17-Oct3.050 26-Jul2.498 26-Jul3.567 17-Oct2.686 02-Sep1.378 e6.812 17-Oct6.146 17-Oct5.096 7-Oct26-Jul3.457 17-Oct2.867 02-Sep1.403 26-Jul1.06826-Jul 16 16131414141717141817171613141414Example Result StatisticsGBS 2/13/2014MinMaxMean (Max-Min)/AutodeskHrkWkWkW Mean** (%)kWDate14 5.965 6.827 6.46113.3%6.61517-Oct14 5.669 6.371 5.98811.7%6.00913-Jan16 3.634 5.096 4.34333.7%4.51526-Jul3.072 4.116 3.62628.8%3.60826-Jul14 5.892 6.776 6.41013.8%6.53117-Oct14 5.831 6.679 6.32113.4%6.41217-Oct15 2.888 3.871 3.39029.0%3.65017-Oct15 1.896 3.277 2.67651.6%2.91117-Oct17 2.385 3.505 3.07736.4%3.36026-Jul1.873 3.080 2.47948.7%2.55226-Jul15 2.888 3.871 3.39029.0%3.65717-Oct14 2.033 3.170 2.67442.5%3.02602-Sep16 0.953 1.403 1.21237.1%1.32026-Jul0.651 0.651 0.6510.0%0.91126-Jul0.863 0.863 0.8630.0%26-Jul15 0.476 1.142 0.92671.9%26-Jul1.007 1.007 1.0070.0%1.12226-Jul15 0.560 1.340 1.08771.7%0.89026-Jul15 1.059 1.875 1.59951.0%1.65216-Aug15 0.739 1.540 1.27263.0%1.06726-Jul12 2.258 4.912 3.14184.5%2.51426-Aug14 6.356 7.234 6.77213.0%6.63517-Oct14 4.444 5.236 4.86316.3%4.74416-Oct14 6.203 6.976 6.52511.9%6.39213-Jan17 3.404 4.929 4.27235.7%4.30426-Jul2.848 4.164 3.58736.7%3.36926-Jul14 5.701 6.553 6.10414.0%5.76217-Oct18 0.000 0.394 0.260151.6%17 0.000 0.666 0.473140.9%0.19826-Jul17 0.035 0.814 0.591131.8%0.32327-Jul15 0.258 1.047 0.80897.7%0.62216-Aug12 1.427 2.578 1.77264.9%2.04215-Aug14 4.424 5.278 4.79717.8%4.80917-Oct12 0.585 1.358 1.00277.1%0.74428-Jul14 1.852 2.991 91817181718181615151418191519181815151616GBS v3.4AutodeskkWDate6.620 17-Oct6.018 13-Jan4.51826-Jul3.61026-Jul6.571 17-Oct6.413 17-Oct3.650 17-Oct2.911 17-Oct3.35926-Jul2.55026-Jul3.657 6-Jul27-Jul#########
May 02, 2014 · B8-15 Case 600 Annual Transmitted Solar Radiation –Shaded (kWh/m2) B44 - O50 Tables 2 Tables 3 Tables 5 Tables 6 ASHRAE Standard 140-2010 Section 5.2 - Building Thermal Envelope and Fabric Load Tests Autodesk Green Building Studio 2/13/2014 vs. Annex B8, Section B8.1 Example Results By Autodesk , 13-Feb-2014 List of Tables Tables 1
Autodesk Inventor Routed Systems Autodesk Maya Animation Autodesk Maya Modeling Autodesk Moldflow Adviser Autodesk Moldflow Insight Autodesk Nastran In-CAD Autodesk Navisworks Manage Autodesk Navisworks Simulate Autodesk ReCap . SketchUp Basics B
What Is Autodesk Direct-Connect Autodesk DirectConnect is a family of data translators. Each of these translators imports a specific CAD file format into one or more of the following Autodesk software products: Autodesk Alias Autodesk Maya Autodesk Showcase Autodesk Opticore Studio 3ds Max /3ds Max Design VRED The translators also export some CAD file formats from some .
ADESK011 Autodesk Certified User - Autodesk Inventor Autodesk Architecture & Construction CAPE Industry Certification Autodesk Inventor 2011 or later 0.2 ADESK021 Autodesk Certified Professional - AutoCAD Autodesk Architecture & Construction CAPE Industry Certification AutoCAD 2011 or later 0.2 ADESK023 Autodesk Certified Professional - AutoCAD .
ASHRAE ADDENDA ANSI/ASHRAE/IES Addenda bi and bt to ANSI/ASHRAE/IESNA Standard 90.1-2007 Energy Standard for Buildings Except Low-Rise Residential Buildings Approved by the ASHRAE Standards Committee on June 26, 2010; by the ASHRAE Board of Directors on June 30, 2010; by the IES Board of Directors on June 23, 2010; and by the American National Standards Insti-tute on July 1, 2010. These .
Autodesk AutoCAD Mechanical 2018 Autodesk AutoCAD Raster Design 2018 Autodesk ReCap Autodesk 3ds Max Design 2018: Autodesk Navisworks Simulate 2018 Autodesk Vault Autodesk Showcase 2018 JMAG Designer 2D/3D magnetostatic JMAG Express Motor-Cad
2-4 Parametric Modeling with Autodesk Inventor The Adjuster Design Starting Autodesk Inventor 1. Select the Autodesk Inventor option on the Start menu or select the Autodesk Inventor icon on the desktop to start Autodesk Inventor. The Autodesk Inventor main window will appear on the screen. 2. Select the Projects icon with a single click of the
Autodesk Productstream Professional Pro/E Wildfire V5 Integration 2005 2x Autodesk Productstream Professional Pro/E Wildfire V5 Integration 5.0 3x Autodesk Productstream Integration 2008 1x Autodesk Productstream Professional 2009 Pro Autodesk Productstream Professional 2008 Pro 1x Autodesk Productstream Professional 2005 Pro 2x
STORAGE TANK DESIGN CALCULATION - API 650 1of14 1 .0 DESIGN CODE & SPECIFICATION DESIGN CODE : APIAPI 650 11th Edition 1 .1 TANK Item numberte u beb : 7061706T-3901390 Roof ( Open/Close ) : Close T f f(C f/D f/Fl t f/NA)Type of roof ( Cone-roof / Dome-roof / Flat-roof / NA )yp ( ) : Fl ti R fFloating Roofg 1 .2 GEOMETRIC DATA Inside diameter , Di ( corroded ) (@ 39,000 mm ) 39,006 mm Nominal .
