LIFE CYCLE COST ANALYSIS INPUT SHEET NOTES 1 Input field are indicated with RED text 2 Contact Cornell for confirmation on current utility rates. 3 Input either the Energy in Mmbtu OR Energy per Unit. The Model Suumary 4 Typical Cornell operating schedules by space type are included for your Building Information Project Name XYZ Building, Cornell University Designers of Record Architect: Firm A Structural: Firm B MEP: Firm C Enclosure: Firm D Contact Person Jane Doe, P.E. Address 201 Humphreys Service Building Cornell University Ithaca, NY 14853 Energy Modeler of Record Project Design and Construction Contact Person Jane Doe, P.E. Address 201 Humphreys Service Building Cornell University Ithaca, NY 14853 Energy Code Used ASHRAE 90.1-2007 Appendix G Weather Data: Syracuse, NY TMY2 Climate Zone: 6A Date: 6/24/2022 Building Area (sf): 108806 New Construction Area (sf) 90000 New Construction Area % of total 83% Existing Renovation Area (sf) 18806 Existing Renovation Area % of total 17% Quantity of Floors: 5 Simulation Program: eQuest v. 3.6 Target Finder Score XXX Space Summary Space Classification Conditioned Unconditioned Area Area (sf) (sf) Office (Open Plan) 39767 0 Office (Executive / Private) 0 0 Wet Laboratory 44155 0 Dry Laboratory 0 0 Classroom / Lecture 0 0 Corridor 0 0 Lobby 0 0 Restrooms 0 0 Conference Rooms 0 0 Mechanical / Electrical / Utility Rooms 24884 0 Copy Rooms 0 0 Other (specify) 0 0
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LIFE CYCLE COST ANALYSISINPUT SHEET
NOTES1 Input field are indicated with RED text2 Contact Cornell for confirmation on current utility rates.3 Input either the Energy in Mmbtu OR Energy per Unit. The Model Suumary Results will automatically calculate using either value.4 Typical Cornell operating schedules by space type are included for your use. Adjustments are allowed to suit specific job conditions.
Building InformationProject Name XYZ Building, Cornell UniversityDesigners of Record Architect: Firm A
Structural: Firm BMEP: Firm CEnclosure: Firm D
Contact Person Jane Doe, P.E.Address 201 Humphreys Service Building
Cornell UniversityIthaca, NY 14853
Energy Modeler of Record Project Design and ConstructionContact Person Jane Doe, P.E.Address 201 Humphreys Service Building
Cornell UniversityIthaca, NY 14853
Energy Code Used ASHRAE 90.1-2007 Appendix GWeather Data: Syracuse, NY TMY2Climate Zone: 6ADate: 5/8/2023Building Area (sf): 108806New Construction Area (sf) 90000New Construction Area % of total 83%Existing Renovation Area (sf) 18806Existing Renovation Area % of total 17%Quantity of Floors: 5Simulation Program: eQuest v. 3.6Target Finder Score XXX
Space SummarySpace Classification Conditioned Unconditioned
Mbtu heat required 0 MbtukWh electricity required 0 kWhBuilding kWh/MMbtu Ratio #DIV/0!therms/Mbtu required #DIV/0!Therms NG input #DIV/0! thermsBaseline NYSEG Purchase (15%) 0 kWhDistrict Production #DIV/0! kWh/Mbtu
#DIV/0! kWhTotal cost avoided #DIV/0! $
Input either the Energy in Mmbtu OR Energy per Unit. The Model Suumary Results will automatically calculate using either value.Typical Cornell operating schedules by space type are included for your use. Adjustments are allowed to suit specific job conditions.
Total AreaArea(sf)
397670
44155000000
2488400
0108806
$ per kWh$ per ton-hr$ per Mmbtu$ per therm
kg CO2/MMBtukg CO2/MMBtukg CO2/MMBtukg CO2/MMBtukg CO2/MMBtu
Step 1 ton-hrs = (Step 2 Mmbtu x 1000) / (3.412 x kW/ton)Step 2 kWh = (Step 1 Mmbtu x 1000 x kW/ton) / 12Chilled water cooling input energy in Mmbtu = kWh x 3.412 x COP / 1000
Step 1 Model, Standalone, By End UseEnd Use Process Energy Type Units
BASELINE PROPOSED SAVINGS0 90 180 270 Energy Use MMbtu % total kbtu/sf $/unit $ Carbon (kg) Energy Use MMbtu % total kbtu/sf $/unit $ Carbon (kg) $ Energy Carbon
LEED EAc1, Step 2 Model with Central Plant EfficienciesEnd Use Process Energy Type Units
BASELINE PROPOSED SAVINGS0 90 180 270 Energy Use MMbtu % total kbtu/sf $/unit $ Carbon (kg) Energy Use MMbtu % total kbtu/sf $/unit $ Carbon (kg) $ Energy Carbon
Total including exceptional calculations Energy Use Cost Carbon (kg) Energy Use Cost Carbon (kg) Energy Cost Carbon District Pr 187 kWh/Mbtu12,460 MMbtu #REF! #VALUE! #VALUE! MMbtu #VALUE! #VALUE! #VALUE! #REF! #VALUE! #VALUE! kWh
Total cost #VALUE! $
Step 1 Energy Model InputsComparison of Baseline Design versus Proposed Design Purchased Utilities
Project Name: #REF!Date: #REF!
Please be sure to review reference paragraphs for exceptions and minimum requirements
Building Element
1.0 GeneralSpace Use Classification:Climate Zone: #REF!Modeling Software Used: #REF!Building Area (sf): #REF!2.0 Building Envelope2.1 New Buildings or Additions2.1.1 Roof
Total Supply AirflowOutside Air AirflowSupply-air-to-room-air temperature differenceBaseline Air Temperature Reset StrategyProposed Supply Air Temperature Reset Strategy, Heating SeasonProposed Supply Air Temperature Reset Strategy, Cooling SeasonSystem Fan Power SummarySystem Fan Power SummarySystem Fan Power SummarySupply Fan
3.4 Hydronic Systems3.4.1 Hot Water Heating Systems
Total Heating System CapacityTotal System Flow SummaryAverage Hot Water System Differential TemperatureTotal Motor Power SummaryTotal Motor Power SummaryTotal Pump Power SummaryPump EfficiencyMotor EfficiencyPump Head PressureBaseline Hot Water Heating System
Unit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyMotor Power
Proposed Glycol Pre-Heat SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Hot Water Re-Heat SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Hot Water Perimeter SystemUnit Designation
TypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Floor Radiant Heating SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Ceiling Radiant Heating SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
3.4.2 Chilled Water Cooling SystemsTotal Cooling System CapacityTotal System Flow SummaryAverage Chilled Water System Differential TemperatureTotal Motor Power SummaryTotal Motor Power SummaryTotal Pump Power SummaryPump Efficiency
Motor EfficiencyPump Head PressureBaseline Chilled Water Cooling System
Unit DesignationTypeCapacity Control
System CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyMotor Power
Proposed Chilled Water Cooling SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Chilled Beam Cooling SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Radiant Ceiling Cooling SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return Temperature
Chilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
3.5 Zone Level3.5.1 Offices3.5.2 Laboratories3.5.3 Conference/Meeting/Auditorium/Classrooms3.5.4 Computer Rooms3.5.5 Zone Temperature Setpoints
Occupied Thermostatic ControlsWinter temperature setpoint and allowable swingSummer temperature setpoint and allowable swingWinter relative humidity setpoint and allowable swingSummer relative humidity setpoint and allowable swing
Unoccupied Setback ControlsWinter temperature setpoint and allowable swingSummer temperature setpoint and allowable swingWinter relative humidity setpoint and allowable swingSummer relative humidity setpoint and allowable swing
Automatic shutdownSupply Air Temperature Reset (Systems 5 and 7), Heating SeasonSupply Air Temperature Reset (Systems 5 and 7), Cooling SeasonVAV Minimum Flow Setpoint (Systems 5 and 7)VAV Minimum Flow Setpoint (Systems 5 and 7), Cooling Season
4.0 Service Water Heating4.1 Unit Designation
TypeEfficiencyCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperaturePump PowerPump Efficiency
Head PressureMotor PowerMotor HorsepowerMotor EfficiencyCondenser Heat Recovery System
5.0 Electrical Systems, Lighting, Power and Process Loads5.1 Lighting Power Density (Space Function or Building Area)
5.3 Receptacle & Process Load Power Density5.4 Daylighting Controls5.5 Elevators or Escalators
5.6 Refrigeration Equipment5.7 Other Process Loads
Notes:1 Cornell Recommends a plug load power density of 3 Watts per square foot for laboratories, and 1 Watt per square foot for office/classrooms.2 The baseline heating and cooling capacities are derived by averaging the loads of 4 orientations (as designed, +90, +180, +270) per Table G3.1-5a3 Cornell Standards recommend using NEMA Premium Efficiency motors for all motors 1/2 hp and above.4 Baseline vertical fenestration area shall be equal to proposed design, OR 40% of gross above grade wall area, whichever is SMALLER, and shall be distributed uniformly in horizontal bands across the four orientations.5 Baseline skylight area shall be equal to proposed design, OR 5% of gross roof area, whichever is SMALLER.6 Baseline minimum flow setpoints is 0.4 cfm/sf of floor area served.7 Economizer High Limit: Standard CU sequence disables economizer when OA temp exceeds RA temperature, typical RA temperature is 75 degrees.8 Economizer Low Limit: Standard CU sequence disables economizer when Mixed Air temperature falls below AHU discharge air temperature setpoint, typical setpoint temperature is 55 is degrees.
Cornell Recommends a plug load power density of 3 Watts per square foot for laboratories, and 1 Watt per square foot for office/classrooms.The baseline heating and cooling capacities are derived by averaging the loads of 4 orientations (as designed, +90, +180, +270) per Table G3.1-5aCornell Standards recommend using NEMA Premium Efficiency motors for all motors 1/2 hp and above.Baseline vertical fenestration area shall be equal to proposed design, OR 40% of gross above grade wall area, whichever is SMALLER, and shall be distributed uniformly in horizontal bands across the four orientations.Baseline skylight area shall be equal to proposed design, OR 5% of gross roof area, whichever is SMALLER.
Economizer High Limit: Standard CU sequence disables economizer when OA temp exceeds RA temperature, typical RA temperature is 75 degrees.Economizer Low Limit: Standard CU sequence disables economizer when Mixed Air temperature falls below AHU discharge air temperature setpoint, typical setpoint temperature is 55 is degrees.
Baseline vertical fenestration area shall be equal to proposed design, OR 40% of gross above grade wall area, whichever is SMALLER, and shall be distributed uniformly in horizontal bands across the four orientations.
Economizer Low Limit: Standard CU sequence disables economizer when Mixed Air temperature falls below AHU discharge air temperature setpoint, typical setpoint temperature is 55 is degrees.
Credit can be taken for programmable timing control, occupancy sensors and daylighting
Two elevators operated intermittently (5 kW per elevator with 490 equivalent full load hours of operation per elevator)
Telecom Rooms, one per floor, 2.3 kW peak with 3,680 equivalent full load hours of operation
Step 2 Energy Model InputsComparison of Baseline Design versus Proposed Design Upstream Central Systems
Project Name: #REF!Date: #REF!
Please be sure to review reference paragraphs for exceptions and minimum requirements
Building Element
1.0 GeneralSpace Use Classification:Climate Zone: #REF!Modeling Software Used: #REF!Building Area (sf): #REF!2.0 Building Envelope2.1 New Buildings or Additions2.1.1 Roof
3.0 Heating, Ventilating, and Air Conditioning3.1 Air Handling Systems3.1.1 Unit Designation
Type
Total Supply AirflowOutside Air AirflowSupply-air-to-room-air temperature differenceBaseline Air Temperature Reset StrategyProposed Supply Air Temperature Reset Strategy, Heating SeasonProposed Supply Air Temperature Reset Strategy, Cooling SeasonSystem Fan Power SummarySystem Fan Power SummarySystem Fan Power SummarySupply Fan
3.4 Hydronic Systems3.4.1 Hot Water Heating Systems
Total Heating System CapacityTotal System Flow SummaryAverage Hot Water System Differential TemperatureTotal Motor Power SummaryTotal Motor Power SummaryTotal Pump Power SummaryPump EfficiencyMotor Efficiency
Pump Head PressureBaseline Hot Water Heating System
Unit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyMotor Power
Proposed Glycol Pre-Heat SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Hot Water Re-Heat SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Hot Water Perimeter SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump Power
Water Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Floor Radiant Heating SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Ceiling Radiant Heating SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperatureHot Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
3.4.2 Chilled Water Cooling SystemsTotal Cooling System CapacityTotal System Flow SummaryAverage Chilled Water System Differential TemperatureTotal Motor Power SummaryTotal Motor Power SummaryTotal Pump Power SummaryPump EfficiencyMotor EfficiencyPump Head PressureBaseline Chilled Water Cooling System
Unit DesignationType
Capacity ControlSystem Capacity
System FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyMotor Power
Proposed Chilled Water Cooling SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Chilled Beam Cooling SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
Proposed Radiant Ceiling Cooling SystemUnit DesignationTypeCapacity ControlSystem CapacitySystem FlowChilled Water Supply TemperatureChilled Water Return TemperatureChilled Water System Differential TemperatureChilled Water Pump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor Efficiency
Unit DesignationTypeCapacity ControlSystem CapacitySystem FlowWater System Differential TemperaturePump PowerWater Temperature Reset StrategyPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyMinimum Operating Speed
3.5 Zone Level3.5.1 Offices3.5.2 Laboratories3.5.3 Conference/Meeting/Auditorium/Classrooms3.5.4 Computer Rooms3.5.5 Zone Temperature Setpoints
Occupied Thermostatic ControlsWinter temperature setpoint and allowable swingSummer temperature setpoint and allowable swingWinter relative humidity setpoint and allowable swingSummer relative humidity setpoint and allowable swing
Unoccupied Setback ControlsWinter temperature setpoint and allowable swingSummer temperature setpoint and allowable swingWinter relative humidity setpoint and allowable swingSummer relative humidity setpoint and allowable swing
Automatic shutdownSupply Air Temperature Reset (Systems 5 and 7), Heating SeasonSupply Air Temperature Reset (Systems 5 and 7), Cooling SeasonVAV Minimum Flow Setpoint (Systems 5 and 7)VAV Minimum Flow Setpoint (Systems 5 and 7), Cooling Season
4.0 Service Water Heating4.1 Unit Designation
TypeEfficiencyCapacity ControlSystem CapacitySystem FlowHot Water Supply TemperatureHot Water Return TemperatureHot Water System Differential TemperaturePump PowerPump EfficiencyHead PressureMotor PowerMotor HorsepowerMotor EfficiencyCondenser Heat Recovery System
5.0 Electrical Systems, Lighting, Power and Process Loads5.1 Lighting Power Density (Space Function or Building Area)
5.2 Automatic Lighting Control5.3 Receptacle & Process Load Power Density5.4 Daylighting Controls5.5 Elevators or Escalators5.6 Refrigeration Equipment5.7 Other Process Loads6.0 Central Heating and Cooling Systems6.1 Heating Plant
Unit DesignationType
Capacity, outputCapacity, inputEntering Hot Water TemperatureLeaving Hot Water TemperatureHot Water Flow RateTurndownCapacity ControlMinimum Operating SpeedEfficiency
6.2 Cooling PlantUnit DesignationType
CapacityCapacity ControlInput PowerLeaving Chilled Water TemperatureEntering Chilled Water TemperatureCooler Flow RateCooler Pressure DropEntering Condenser Water Temperature
Leaving Condenser Water TemperatureCondenser Flow RateCondenser Pressure DropMinimum Operating SpeedEfficiencyEfficiency
6.3 Heat Rejection EquipmentUnit Designation
Type
AirflowCapacity ControlSystem CapacitySystem FlowDesign Wet-Bulb TemperatureLeaving Water Temperature
Entering Water TemperatureSystem Differential TemperatureWater Temperature Reset StrategyRequired Minimum PerformanceActual PerformanceFan PowerMotor Horsepower, nameplate ratingMotor EfficiencyMinimum Operating Speed
6.4 Condenser Water Loop PumpsUnit DesignationType
Notes:1 Cornell Recommends a plug load power density of 3 Watts per square foot for laboratories, and 1 Watt per square foot for office/classrooms.2 The baseline heating and cooling capacities are derived by averaging the loads of 4 orientations (as designed, +90, +180, +270) per Table G3.1-5a3 Cornell Standards recommend using NEMA Premium Efficiency motors for all motors 1/2 hp and above.4 Baseline vertical fenestration area shall be equal to proposed design, OR 40% of gross above grade wall area, whichever is SMALLER, and shall be distributed uniformly in horizontal bands across the four orientations.5 Baseline skylight area shall be equal to proposed design, OR 5% of gross roof area, whichever is SMALLER.6 Baseline minimum flow setpoints is 0.4 cfm/sf of floor area served.7 Economizer High Limit: Standard CU sequence disables economizer when OA temp exceeds RA temperature, typical RA temperature is 75 degrees.8 Economizer Low Limit: Standard CU sequence disables economizer when Mixed Air temperature falls below AHU discharge air temperature setpoint, typical setpoint temperature is 55 is degrees.
Cornell Recommends a plug load power density of 3 Watts per square foot for laboratories, and 1 Watt per square foot for office/classrooms.The baseline heating and cooling capacities are derived by averaging the loads of 4 orientations (as designed, +90, +180, +270) per Table G3.1-5aCornell Standards recommend using NEMA Premium Efficiency motors for all motors 1/2 hp and above.Baseline vertical fenestration area shall be equal to proposed design, OR 40% of gross above grade wall area, whichever is SMALLER, and shall be distributed uniformly in horizontal bands across the four orientations.Baseline skylight area shall be equal to proposed design, OR 5% of gross roof area, whichever is SMALLER.
Economizer High Limit: Standard CU sequence disables economizer when OA temp exceeds RA temperature, typical RA temperature is 75 degrees.Economizer Low Limit: Standard CU sequence disables economizer when Mixed Air temperature falls below AHU discharge air temperature setpoint, typical setpoint temperature is 55 is degrees.
#REF!Baseline System 3: PSZ-AC, Single Zone Constant Volume
Rooftop Air Conditioner, Direct Expansion Cooling, Fossil Fuel Furnace
#REF!#REF! 6.4.3.9#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF! 6.5.3.2#REF!#REF!#REF!#REF!#REF! CU Standard#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF! CU Standard#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF! CU Standard#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF! CU Standard#REF!#REF! 6.5.6.1#REF!#REF!#REF!
Direct Expansion Cooling Coil
Compressor Cycle#REF!#REF!#REF!
10.1#REF!
Natural Gas Duct Furnace#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF! 6.5.1#REF! CU Standard#REF! CU Standard#REF!#REF!#REF! 6.4.3.9
#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF!#REF! CU Standard#REF!#REF! 6.5.6.1#REF!#REF!
#REF!No direction given regarding capacity control
0.79#REF!#REF!#REF!
95#REF!
4.455.2
Cooling TowerCT-1
Baseline Systems 1, 5, 7: Single boiler for plants serving buildings less than 15,000 sf; two equally sized boilers for plants serving
buildings greater than 15,000 sf staged as required to met load.
Baseline Systems 7 & 8: Single screw chiller plant serving buildings less than or equal to 120,000 sf; two screw chillers sized
equally for plants serving uildings 120,000-240,000 sf; two centrifugal chillers minimum with chillers added so that no chiller is
larger than 800 tons all sized equally for plants serving buildings greater than or equal to 240,000 sf.
85 or 10 °F approach to design wet-bulb temperature, whichever is lower.
Two speed#REF!#REF!
73
9510
OAT: 95 => SWT: 85; OAT: 80 => SWT: 7038.2
#REF!3730.5
0.5850.5
CWP-1
No direction given regarding capacity control#REF!
190.8
#REF!#REF!#REF!0.585
0.30
Cornell Recommends a plug load power density of 3 Watts per square foot for laboratories, and 1 Watt per square foot for office/classrooms.The baseline heating and cooling capacities are derived by averaging the loads of 4 orientations (as designed, +90, +180, +270) per Table G3.1-5a
Baseline vertical fenestration area shall be equal to proposed design, OR 40% of gross above grade wall area, whichever is SMALLER, and shall be distributed uniformly in horizontal bands across the four orientations.
Economizer High Limit: Standard CU sequence disables economizer when OA temp exceeds RA temperature, typical RA temperature is 75 degrees.Economizer Low Limit: Standard CU sequence disables economizer when Mixed Air temperature falls below AHU discharge air temperature setpoint, typical setpoint temperature is 55 is degrees.
Baseline Systems 7 & 8: Axial Fan Cooling Tower with two-speed fans
85 or 10 °F approach to design wet-bulb temperature, whichever is lower.
Each chiller to have separate condenser water and chilled water pumps interlocked to operate with the associated chiller.
Proposed Model Inputs NotesBuilding Modeled as Designed
Cornell University District Combined Heat and Power PlantCHP
#REF!
N/AN/AN/AN/A
Cornell University District Cooling Plant, Lake Source CoolingLSC
#REF!
0.1
Cayuga Lake
For every Mmbtu of building heat required, 187 kW-hr of electricity is provided free, and 25.6 therms of natural gas are required for production. 0.11 therms of natural gas per Kw-hr is required to
produce additional electricity, if required to meet the building load. 15% of the building electric load is assumed to be provided directly
from NYSEG.
For every ton of chilled water "load", an energy input of 0.10 kW-ton-hr is required for production. 100% of this power is assumed to
come directly from NYSEG.
Modeling Inputs for Cornell District Energy System
Ratio of Building Electrical Therms Natural Gas kW-hr / Mmbtu Demand to Heating Demand Required per 1 generated at
lbs CO2 kg CO2 mmbtu lbs CO2/mmbtu lbs CO2/kWh kg CO2/Mmbtu2000 0.45359
388000 175992.92 1671.494 232.13 0.79 105.29
lbs CO2 kg CO2 mmbtu lbs CO2/mmbtu lbs CO2/ton-hr kg CO2/Mmbtu5400 2449.386 584.868 9.23 0.11 4.19
lbs CO2 kg CO2 mmbtu lbs CO2/mmbtu lbs CO2/klb kg CO2/Mmbtu1512000 685828.08 5040.97 299.94 329.91 136.05
lbs CO2 kg CO2 mmbtu lbs CO2/mmbtu lbs CO2/cf kg CO2/Mmbtu
120 54.4308 1.027 116.85 0.12 53.06
lbs CO2 kg CO2 mmbtu lbs CO2/mmbtu lb CO2/kWh kg CO2/Mmbtu725 328.85275 3.414 212.36 0.725 96.32
79.00
3.12
88.00
kg C/Mmbtu0.272728.72
kg C/Mmbtu1.14
kg C/Mmbtu37.10
kg C/Mmbtu
14.47
kg C/Mmbtu26.27
ASHRAE 90.1 Power Calculations
FAN POWERFinal Full Load Fan Power (Watts)Allowable Fan System Power (bhp)Allowable Nameplate Motor Power (hp)PUMP POWERHot Water Pump Power (Watts)Chilled Water Pump Power (Watts)INPUTSSystem Supply Airflow (cfm)System Type (CV, VAV)Supply Filter Airflow (cfm)Supply Filter Clean Pressure Drop (in wc)Exhaust Filter Airflow (cfm)Exhaust Filter Clean Pressure Drop (in wc)Hot Water Pump Flow (gpm)Chilled Water Pump Flow (gpm)Temperature Ratio (Tspace - Tsupply)Heat Recovery Supply Airflow (cfm)Heat Recovery Exhaust Airflow (cfm)Heat Recovery Coil Supply PD (in wc)Heat Recovery Coil Exhaust PD (in wc)Evaporative Humidifier/Cooler Airflow (cfm)Evaporative Humidifier/Cooler Airflow PD (in wc)Relief Fan Airflow (cfm)Relief Fan, Motor Nameplate (hp)Fully Ducted Return/Exhaust system (Y/N)Fully Ducted Return/Exhaust Airflow (cfm)Return/exhaust airflow control devices (Y/N)Return/exhaust airflow control device Airflow (cfm)Exhaust filter scrubber or other exhaust treatment PD (in wc)Exhaust filter scrubber or other exhaust treatment Airflow (cfm)Supply Side MERV 9-12 Filters (Y/N)Supply Side MERV 9-12 Filter Airflow (cfm)Supply Side MERV 13-15 FiltersSupply Side MERV 13-15 Filters Airflow (cfm)Supply Side MERV 16 and above, electronically enhanced filter CLEAN PD (in wc)Supply Side MERV 16 and above, electronically enhanced filter Airflow (cfm)Exhaust Side MERV 9-12 Filters (Y/N)Exhaust Side MERV 9-12 Filters Airflow (cfm)Exhaust Side MERV 13-15 Filters (Y/N)Exhaust Side MERV 13-15 Filters Airflow (cfm)Exhaust Side MERV 16 and above, electronically enhanced filter CLEAN PD (in wc)Exhaust Side MERV 16 and above, electronically enhanced filter Airflow (cfm)Supply Side Carbon & other gas-phase air cleaner CLEAN pressure drop (in wc)Supply Side Carbon & other gas-phase air cleaner Airflow (cfm)Exhaust Side Carbon & other gas-phase air cleaner CLEAN pressure drop (in wc)Exhaust Side Carbon & other gas-phase air cleaner Airflow (cfm)Supply Side Sound Attenuation Section (Y/N)Supply Side Sound Attenuation Section Airflow (cfm)Exhaust Side Sound Attenuation Section (Y/N)
Exhaust Side Sound Attenuation Section Airflow (cfm)Is Fume Hood Exhaust Exception being taken (6.5.3.1.1 exception c) (Y/N)Fume Hood Exhaust Airflow (cfm)
CALCULATIONS< 20,000 cfm, Constant VolumeBaseline Fan Motor Brake Horsepowerln(bhp)-0.2437899 x ln(bhp) - 1.685541e^(-0.2437899 x ln(bhp) - 1.685541)Baseline Fan Power (Watts)Opt 1: Allowable Nameplate Motor hpOpt 1: Allowable Nameplate Motor hp maxOpt 2: Allowable Fan System bhpOpt 2: Allowable Fan System bhp max
< 20,000 cfm, Variable VolumeBaseline Fan Motor Brake Horsepowerln(bhp)-0.2437899 x ln(bhp) - 1.685541e^(-0.2437899 x ln(bhp) - 1.685541)Baseline Fan Power (Watts)Opt 1: Allowable Nameplate Motor hpOpt 1: Allowable Nameplate Motor hp maxOpt 2: Allowable Fan System bhpOpt 2: Allowable Fan System bhp max
≥ 20,000 cfm, Constant VolumeBaseline Fan Motor Brake Horsepowerln(bhp)-0.2437899 x ln(bhp) - 1.685541e^(-0.2437899 x ln(bhp) - 1.685541)Baseline Fan Power (Watts)Opt 1: Allowable Nameplate Motor hpOpt 1: Allowable Nameplate Motor hp maxOpt 2: Allowable Fan System bhpOpt 2: Allowable Fan System bhp max
≥ 20,000 cfm, Variable VolumeBaseline Fan Motor Brake Horsepowerln(bhp)-0.2437899 x ln(bhp) - 1.685541e^(-0.2437899 x ln(bhp) - 1.685541)Baseline Fan Power (Watts)Opt 1: Allowable Nameplate Motor hpOpt 1: Allowable Nameplate Motor hp maxOpt 2: Allowable Fan System bhpOpt 2: Allowable Fan System bhp max
DEVICE PRESSURE CREDITSFully ducted return and/or exhaust air system (0.5 in wc)Fully ducted return and/or exhaust air system (bhp)
Return/exhaust airflow control devices (0.5 in wc)Return/exhaust airflow control devices (bhp)
Exhaust filter scrubber or other exhaust treatment PD (in wc)Exhaust filter scrubber or other exhaust treatment (bhp)
Supply Side MERV 9-12 Filters (0.5 in wc)Supply Side MERV 9-12 Filters (bhp)
Supply Side MERV 13-15 Filters (0.9 in wc)Supply Side MERV 13-15 Filters (bhp)
Supply Side MERV 16 and above, electronically enhanced filter CLEAN PD (in wc)Supply Side MERV 16 and above, electronically enhanced filter (bhp)
Exhaust Side MERV 9-12 Filters (0.5 in wc)Exhaust Side MERV 9-12 Filters (bhp)
Exhaust Side MERV 13-15 Filters (0.9 in wc)Exhaust Side MERV 13-15 Filters (bhp)
Exhaust Side MERV 16 and above, electronically enhanced filter CLEAN PD (in wc)Exhaust Side MERV 16 and above, electronically enhanced filter (bhp)
Supply Side Carbon & other gas-phase air cleaner CLEAN pressure drop (in wc)Supply Side Carbon & other gas-phase air cleaner CLEAN pressure drop (bhp)
Exhaust Side Carbon & other gas-phase air cleaner CLEAN pressure drop (in wc)Exhaust Side Carbon & other gas-phase air cleaner CLEAN pressure drop (bhp)
Supply Side Heat Recovery Device (in wc)Supply Side Heat Recovery Device (bhp)
Exhaust Side Heat Recovery Device (in wc)Exhaust Side Heat Recovery Device (bhp)
Evaporative humidifier/cooler in series w/ another cooling coil (in wc)Evaporative humidifier/cooler in series w/ another cooling coil (bhp)
Supply Side Sound Attenuation Section (0.15 in wc)Supply Side Sound Attenuation Section (bhp)
Exhaust Side Sound Attenuation Section (0.15 in wc)Exhaust Side Sound Attenuation Section (bhp)
Total Device CreditsA (bhp) = sum of (PD x CFM/4131)
Final Full Load Fan Power (Watts)Allowable Fan System Power (bhp)Allowable Nameplate Motor Power (hp)
Part Load Fan PerformancePart Load Ratio (PLR)0.000.100.200.300.400.500.600.700.800.901.00
Hot Water Pump PowerHot Water Pump Power (Watts)
Chilled Water Pump PowerChilled Water Pump Power (Watts)
CODE REFERENCEApp G Baseline, 2004
2357532n/a
19002200
22000VAV
220001.25
220001.2510010020
17.25 + (cfm - 20000) x 0.0008625193
-2.40.09
0
24 + (cfm - 20000) x 0.0012263
-2.50.08
0
17.25 + (cfm - 20000) x 0.000825193
-2.40.09
0
24 + (cfm - 20000) x 0.001125263
-2.50.08
21368
CFMfilter x (SPfilter - 1)/4.9841104
11042207
2357532
0.0013 + 0.1470 x PLR + 0.9506 x (PLR)² - 0.0998 x (PLR)³Fraction of Full Load Power
0.000.030.070.130.210.300.410.540.680.831.00
19 Watts / gpm1900
22 Watts / gpm2200
CODE REFERENCE90.1 Prescriptive Limits, 2004
n/an/a42
no power limits indicatedno power limits indicated
22000VAV
220001.25
220001.2510010015
2200022000
0.60.6
220000.5
50005
1.2 hp / 1000 cfm0
1.7 hp / 1000 cfm0
1.1 hp / 1000 cfm0
1.5 hp / 1000 cfm33
CFMfilter x (SPfilter - 1) / 3718113
CFMhr x SPhr / 3718447
CFMevap x SPevap / 37183
RFhp x (1 - CFMrf / CFMfilter)4
n/a42
CODE REFERENCEApp G Baseline, 2007
n/a58n/a
19002200
22000VAV
220001.25
220001.2510010015
2200022000
0.60.6
220000.5
50005Y
20000Y
200001.25
20000Y
20000Y
200001.5
20000Y
20000Y
200001.5
200000.75
200000.75
20000Y
20000Y
20000Y
10000
hp ≤ CFM x .00110
bhp ≤ CFM x .00094 + A0
hp ≤ CFM x .00150
bhp ≤ CFM x .0013 + A0
hp ≤ CFM x .00110
bhp ≤ CFM x .00094 + A0
hp ≤ CFM x .001533
bhp ≤ CFM x .00094 + A58
0.52
0.52
1.256
0.52
0.94
315
0.52
0.94
315
0.754
0.754
0.63
0.63
0.53
0.151
0.151
-1-2
4.529
5833
19 Watts / gpm1900
22 Watts / gpm2200
CODE REFERENCE90.1 Prescriptive Limits, 2004
Addendum ac
n/a5833
no power limits indicatedno power limits indicated
22000VAV
220001.25
220001.2510010015
2200022000
0.60.6
220000.5
50005Y
20000Y
200001.25
20000Y
20000Y
200001.5
20000Y
20000Y
200001.5
200000.75
200000.75
20000Y
20000Y
20000Y
10000
hp ≤ CFM x .00110
bhp ≤ CFM x .00094 + A0
hp ≤ CFM x .00150
bhp ≤ CFM x .0013 + A0
hp ≤ CFM x .00110
bhp ≤ CFM x .00094 + A0
hp ≤ CFM x .001533
bhp ≤ CFM x .00094 + A58
0.52
0.52
1.256
0.52
0.94
315
0.52
0.94
315
0.754
0.754
0.63
0.63
0.53
0.151
0.151
-1-2
4.529
5833
ENVELOPE 90.1 Prescriptive, 2004
NonresidentialAssembly Insulation Min.
OPAQUE ELEMENTS Maximum R-Value
RoofsInsulation Entirely Above Deck U - 0.063 R - 15.0 ciMetal Building U - 0.065 R - 19.0Attic and Other U - 0.027 R - 38.0
Walls, Above-GradeMass U - 0.104 R - 9.5 ciMetal Building U - 0.113 R - 13.0Steel-Framed U - 0.084 R - 13.0 + R - 3.8 ciWood-Framed and Other U - 0.089 R - 13.0
Walls, Below-GradeBelow-Grade Wall C - 1.140 NR
FloorsMass U - 0.087 R - 8.3 ciSteel-Joist U - 0.038 R - 30.0Wood-Framed and Other U - 0.033 R - 30.0
Slab-on-Grade FloorsUnheated F - 0.730 NRHeated F - 0.840 R - 10 for 36 in.
Opaque DoorsSwinging U - 0.700Non-Swinging U - 0.500
Area shall be equal that in the proposed design or 5% of gross roof wall area, whichever is smaller.
Performance shall match the appropriate criteria described above.
Lighting
90.1, 2004 90.1, 2007
EXTERIOR TRADABLE SURFACESUncovered Parking Areas
Parking Lots and drives 0.15 0.15Building Grounds
Walkways less than 10 ft wide W/linear foot 1.0 1.0Walkways 10 feet wide or greater 0.2 0.2Plaza Areas 0.2 0.2Special Feature Areas 0.2 0.2Stairways not defined 1.0
Building Entrances and ExitsMain entries W/linear foot of door width 30 30Other doors W/linear foot of door width 20 20
CALENDAR (2009-2010 School Year):Fall Semester, Aug 27 thru Dec 18Spring Semester, Jan 25 - May 30Summer Semester (SS), Jun 1 - Aug 26Winter Semester (WS), Jan 2 - Jan 24Holidays (Hol), Jan 1, Mar 14-22, May 31, Oct 11 - 14, Nov 21 - 26, Dec 19 - 31
SCHEDULED OCCUPIED PERIOD: Mon-Fri, 8:00 am - 9:00 pm
Step 1: Determine OccupancyConcept Design: Assume 15 sf/person (based on a typical 150,000 sf Cornell Classroom/Office Building with 7% classroom area); adjust in consultation with OwnerSchematic Design: Determine using the following campus average data per space, adjust in consulation with Owner
AREA/SEAT (STATION)20 sf/seat for Small Seminar/Classroom/Conference Areas, 5-19 people, with moveable tables & chairs17 sf/seat for Small Seminar/Classroom/Conference Areas, 20-39 people, with moveable tables & chairs15 sf/seat for Seminar/Classroom, 40-59 people, with moveable tablet arm chairs13 sf/seat for Seminar/Classroom, 60-149 people, with fixed auditorium seating11 sf/seat for Seminar/Classroom, 150-500 people, with fixed auditorium seating
ROOM UTILIZATION RATE (RUR)30-32 Hours/week based on a 45 hour week, Small Seminar/Classroom/Conference Areas, 5-19 people
30 Hours/week based on a 45 hour week, Small Seminar/Classroom, 20-39 people28-30 Hours/week based on a 45 hour week, Seminar/Classroom, 40-59 people22-26 Hours/week based on a 45 hour week, Seminar/Classroom, 60-149 people
20 Hours/week based on a 45 hour week, Seminar/Classroom, 150-500 peopleSEAT OCCUPANCY RATIO (SOR): 60-75%
Design Development: Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Step 2: Determine lighting and plug loadsConcept Design: Utilize the following values, adjusted in consultation with Owner for special conditions:
1.4 W/sf max lighting power density for classrooms1.0 W/sf max equipment power density for classrooms, tied to occupancy (principally, laptop computers)
Design Development: Obtain design lighting power density
Step 3: Determine annual energy use through modelingApply the diversity factors listed below, or as determined by consultant calculations for special conditions
NOTES WS: Winter semester is based on 10% of fall/spring semester occupancy (per central scheduling)SS: Summer Semester occupancy is same as fall/spring occupancy (per central scheduling)CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hours
These schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
Schedule A: Applicable Diversity Factors for People Loads
Assume 15 sf/person (based on a typical 150,000 sf Cornell Classroom/Office Building with 7% classroom area); adjust in consultation with OwnerDetermine using the following campus average data per space, adjust in consulation with Owner
sf/seat for Small Seminar/Classroom/Conference Areas, 5-19 people, with moveable tables & chairssf/seat for Small Seminar/Classroom/Conference Areas, 20-39 people, with moveable tables & chairssf/seat for Seminar/Classroom, 40-59 people, with moveable tablet arm chairssf/seat for Seminar/Classroom, 60-149 people, with fixed auditorium seatingsf/seat for Seminar/Classroom, 150-500 people, with fixed auditorium seating
Hours/week based on a 45 hour week, Small Seminar/Classroom/Conference Areas, 5-19 peopleHours/week based on a 45 hour week, Small Seminar/Classroom, 20-39 peopleHours/week based on a 45 hour week, Seminar/Classroom, 40-59 peopleHours/week based on a 45 hour week, Seminar/Classroom, 60-149 peopleHours/week based on a 45 hour week, Seminar/Classroom, 150-500 people
Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Utilize the following values, adjusted in consultation with Owner for special conditions:
W/sf max equipment power density for classrooms, tied to occupancy (principally, laptop computers)
Apply the diversity factors listed below, or as determined by consultant calculations for special conditions
WS: Winter semester is based on 10% of fall/spring semester occupancy (per central scheduling)
CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hours
These schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
CALENDAR (2009-2010 School Year):Holidays (Hol): New Years Day (Jan 1), Memorial Day (May 31), Independence Day (Jul 4), Labor Day (Sep 7), Thanksgiving (Nov 21-22), Winter Holiday (Dec 25 - 31)
SCHEDULED OCCUPIED PERIOD: Mon-Fri, 6:00 am - 6:00 pm
Step 1: Determine OccupancyConcept Design: Assume 145 sf/person (based on a typical 150,000 sf Cornell Classroom/Office Building with 28% classroom area); adjust in consultation with OwnerSchematic Design: Determine using the following campus average data per space, adjust in consulation with Owner
AREA/SEAT (STATION)400 sf/person for President/Provost Office spaces, included in the area is space for 6-8 visitors240 sf/person for Vice President/Dean Office spaces, included in the area is space for 5-6 visitors160 sf/person for Faculty Office spaces, included in the area is space for 1-2 visitors120 sf/person for Program Directors, included in the area is space for 1-2 visitors80 sf/person for Emeritus and Visiting Faculty, Lecturers, Research Associates 80 sf/person for Administrative Staff spaces50 sf/person for Student Workers, Research Assistants, Teaching Assistants, and Graduate Students
ROOM UTILIZATION RATE (RUR)40 Hours per week, based on a 45 hour week
SEAT OCCUPANCY RATIO (SOR): 2-90% Based on Time of DayDesign Development: Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Step 2: Determine lighting and plug loadsConcept Design: Utilize the following values, adjusted in consultation with Owner for special conditions:
1.1 W/sf max lighting power density for offices0.75 W/sf max equipment power density for offices
Design Development: Obtain design lighting power density
Step 3: Determine annual energy use through modelingApply the diversity factors listed below, or as determined by consultant calculations for special conditions
NOTES CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hoursThese schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
Schedule A: Applicable Diversity Factors for People Loads
Holidays (Hol): New Years Day (Jan 1), Memorial Day (May 31), Independence Day (Jul 4), Labor Day (Sep 7), Thanksgiving (Nov 21-22), Winter Holiday (Dec 25 - 31)
Assume 145 sf/person (based on a typical 150,000 sf Cornell Classroom/Office Building with 28% classroom area); adjust in consultation with OwnerDetermine using the following campus average data per space, adjust in consulation with Owner
sf/person for President/Provost Office spaces, included in the area is space for 6-8 visitorssf/person for Vice President/Dean Office spaces, included in the area is space for 5-6 visitorssf/person for Faculty Office spaces, included in the area is space for 1-2 visitorssf/person for Program Directors, included in the area is space for 1-2 visitorssf/person for Emeritus and Visiting Faculty, Lecturers, Research Associates
sf/person for Student Workers, Research Assistants, Teaching Assistants, and Graduate Students
2-90% Based on Time of DayObtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Utilize the following values, adjusted in consultation with Owner for special conditions:
Apply the diversity factors listed below, or as determined by consultant calculations for special conditions
CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hoursThese schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
CALENDAR (2009-2010 School Year):Holidays (Hol): New Years Day (Jan 1), Memorial Day (May 31), Independence Day (Jul 4), Labor Day (Sep 7), Thanksgiving (Nov 21-22), Winter Holiday (Dec 25 - 31)
SCHEDULED OCCUPIED PERIOD: Mon-Fri, 9:00 am - 5:00 pm
Step 1: Determine OccupancyConcept Design: Assume 140 sf/person (based on a typical 170,000 sf Cornell Lab/Office Building with 28% research lab area); adjust in consultation with Owner
A typcial cornell lab is 990 sf, with one Principal Investigator and 6 researcher stationsSchematic Design: Determine using the following campus average data per space, adjust in consulation with Owner
AREA/SEAT (STATION)160 Total sf per module (40 sf/seat) Computer WorKstation Lab Module, 4 seats per module225 Total sf per module (113 sf/seat) Dry Lab Module, includes 2 seats per module330 Total sf per module (113 sf/seat) Wet Lab Module, includes 2 seats per module, and 105 sf of service space200 sf/seat per Design Lab Module (to accommodate for drafting table, easel, etc) 1 seat per module
ROOM UTILIZATION RATE (RUR)7 Hours per day, based on a 24 hour day (30% of available hours)
SEAT OCCUPANCY RATIO (SOR): 80% Based on Time of DayDesign Development: Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Step 2: Determine lighting and plug loadsConcept Design: Utilize the following values, adjusted in consultation with Owner for special conditions:
1.4 W/sf max lighting power density for offices6.0 W/sf max equipment power density for laboratories, based on LABS 21 recommendations
Design Development: Obtain design lighting power density
Step 3: Determine annual energy use through modelingApply the diversity factors listed below, or as determined by consultant calculations for special conditions
NOTES CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hoursThese schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
Schedule A: Applicable Diversity Factors for People Loads
Holidays (Hol): New Years Day (Jan 1), Memorial Day (May 31), Independence Day (Jul 4), Labor Day (Sep 7), Thanksgiving (Nov 21-22), Winter Holiday (Dec 25 - 31)
Assume 140 sf/person (based on a typical 170,000 sf Cornell Lab/Office Building with 28% research lab area); adjust in consultation with OwnerA typcial cornell lab is 990 sf, with one Principal Investigator and 6 researcher stationsDetermine using the following campus average data per space, adjust in consulation with Owner
Total sf per module (40 sf/seat) Computer WorKstation Lab Module, 4 seats per moduleTotal sf per module (113 sf/seat) Dry Lab Module, includes 2 seats per moduleTotal sf per module (113 sf/seat) Wet Lab Module, includes 2 seats per module, and 105 sf of service spacesf/seat per Design Lab Module (to accommodate for drafting table, easel, etc) 1 seat per module
Hours per day, based on a 24 hour day (30% of available hours)80% Based on Time of Day
Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Utilize the following values, adjusted in consultation with Owner for special conditions:
W/sf max equipment power density for laboratories, based on LABS 21 recommendations
Apply the diversity factors listed below, or as determined by consultant calculations for special conditions
CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hoursThese schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
CALENDAR (2009-2010 School Year):Fall Semester, Aug 27 thru Dec 18Spring Semester, Jan 25 - May 30Summer Semester (SS), Jun 1 - Aug 26Winter Semester (WS), Jan 2 - Jan 24Holidays (Hol), Jan 1, Mar 14-22, May 31, Oct 11 - 14, Nov 21 - 26, Dec 19 - 31
SCHEDULED OCCUPIED PERIOD: Mon-Fri, 9:00 am - 5:00 pm
Step 1: Determine OccupancyConcept Design: Assume 50 sf/person (based on a typical 170,000 sf Cornell Lab/Office Building with 5% teaching lab area); adjust in consultation with OwnerSchematic Design: Determine using the following campus average data per space, adjust in consulation with Owner
AREA/SEAT (STATION)40 sf/seat per Computer Worstation Teaching Lab Module50 sf/seat per Dry Teaching Lab Module60 sf/seat per Wet Teaching Lab Module75 sf/seat per Design Teaching Lab Module, to accommodate for drafting table, easel, etc
ROOM UTILIZATION RATE (RUR)20 Hours/week based on a 45 hour week
SEAT OCCUPANCY RATIO (SOR): 80%Design Development: Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Step 2: Determine lighting and plug loadsConcept Design: Utilize the following values, adjusted in consultation with Owner for special conditions:
1.4 W/sf max lighting power density for teaching/laboratory spaces1.0 W/sf max equipment power density for classrooms, tied to occupancy (principally, laptop computers)
Design Development: Obtain design lighting power density
Step 3: Determine annual energy use through modelingApply the diversity factors listed below, or as determined by consultant calculations for special conditions
NOTES WS: Winter semester is based on 10% of fall/spring semester occupancy (per central scheduling)SS: Summer Semester occupancy is same as fall/spring occupancy (per central scheduling)CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hoursThese schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.
Schedule A: Applicable Diversity Factors for People Loads
Assume 50 sf/person (based on a typical 170,000 sf Cornell Lab/Office Building with 5% teaching lab area); adjust in consultation with OwnerDetermine using the following campus average data per space, adjust in consulation with Owner
sf/seat per Computer Worstation Teaching Lab Module
sf/seat per Design Teaching Lab Module, to accommodate for drafting table, easel, etc
Obtain anticipated occupancy based on final programming using actual (not egress) occupancy; consult with Owner to ensure consistency with campus norms
Utilize the following values, adjusted in consultation with Owner for special conditions:W/sf max lighting power density for teaching/laboratory spacesW/sf max equipment power density for classrooms, tied to occupancy (principally, laptop computers)
Apply the diversity factors listed below, or as determined by consultant calculations for special conditions
WS: Winter semester is based on 10% of fall/spring semester occupancy (per central scheduling)
CDD: Design condition for design day simulation to obtain peak cooling load, Space fully occupied for 24 hoursHDD: Design condition for design day simulation to obtain peak heating load, Space unoccupied for 24 hoursThese schedules reflect general patterns experienced by Cornell. The consultant is encouraged to consult with owner to develop schedules on a project-by-project basis.