whole-building energy analysis and energy modeling · inputs needed for whole -building simulation...
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NREL is a national laboratory of the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, operated by the Alliance for Sustainable Energy, LLC.
Whole-Building Energy Analysis and Energy Modeling
ASHRAE Arkansas Chapter Presentation
Nicholas Long
December 1-2, 2010
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Outline
• U.S. Building Energy Use• Energy Modeling in the Design Process
• Building Model Progressions
• Energy Modeling Results in Real Projects• ASHRAE Standards and Advanced Energy Design
Guide Modeling• Performance Based Design Build Procurement• Modeling for Retrofits• Other Barriers• ASHRAE Energy Modeling Conference
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73% of U.S. Electricity
Building’s are the Largest Energy Consumer in U.S.
Combined residential and commercial buildings sector account for:
34% of direct U.S. Natural Gas
40% of U.S. Primary Energy Consumption
Source: Buildings Energy Data Book 2008, http://buildingsdatabook.eere.energy.gov/Default.aspx. Tables 1.1.3, 1.1.9, 1.1.10.
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What does the commercial building stock look like?
4.8 Million Buildings
72 Billion Square Feet
Average Commercial Building is 15,000 Square Foot
Credit: DOE EIA CBECS, 2003, Google Earth
53% are Small Buildings (1,000 to 5,000 ft2)consume 11% of energy
0.2% are Large Buildings (> 500,000ft2)consume 14% of energy
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“Every building is a forecast.Every forecast is wrong.”
Stewart Brand
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Simulation vs. Operating Energy
In DOE’s low-energy building research, simulation has been critical for designing and operating buildings to support decision-making.
Focus on Energy Efficiency, then Renewable Energy
BUT, compared to simulations, real buildings:• Use more energy • Produce less power• Have worse controls • Have more varied schedules• Have more occupant complaints• GIGO
Credit: NREL PIX6
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Why Use Energy Simulation?
• Inform energy decisions from the earliest phases• Help the design team and owner focus energy-use
reduction• Assess predicted performance with project goals• Size renewable energy systems and • determine contribution• Evaluate alternatives
throughout programming, design, construction, operation—as well as retrofit
• Simulation is cheaper than constructing the wrong building!
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Typical Use of Energy Modeling
Energy efficiency is often not a primary consideration during the building design process, and evidence of modeling and energy simulation is often used only to get a LEED certification if it is used at all.
Modeling for LEED certification, Standards
Compliance, HVAC Capacity
Selection
(Limited impact)
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Typical Use of Energy Modeling
Energy modeling needs to be about more than getting a checkbox on a certification.
Holistic Energy-Based Design
(High impact)
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What Can Energy Simulation Do for My Buildings?
Typically used for studies of individual buildings. Simulation can help determine:
– Building overheating– Heating, cooling equipment design– Predict the dynamic response and performance of buildings– Compare different design or retrofit options—load calculations, energy
performance, peak demand, and cost-benefit implications– Simulate complex and ‘green’ technologies:
• Naturally ventilated, passive buildings• Thermal energy storage• Daylighting• Overheating in unconditioned spaces• Advanced controls operation
– Regulatory compliance– Integrated views of performance– Points for green building ratings
Other multiple building set uses include:– Policy—set standards levels, support decision-making– Technology R&D—market penetration, technology applicability
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Visual History of Whole Building Energy Analysis Tools
1980 1990 2000 2010
SimulationEngines
GUIInterfaces
Proprietary(Web, GUI)
TextInterfaces
WebInterfaces
Free
or P
ublic
Dom
ain
BLAST C&E
Restricted Source
Open Source
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Visual History of Whole Building Energy Analysis Tools
1980 1990 2000 2010
SimulationEngines
GUIInterfaces
Proprietary(Web, GUI)
TextInterfaces
WebInterfaces
Free
or P
ublic
Dom
ain
BLAST C&E
Restricted Source
Open Source
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Inputs Needed for Whole-Building Simulation
• Weather Data• Ground Temperatures• Building Geometry• Window Areas• Constructions• Ground Coupling• Building Program / Thermal Zoning• Plug Loads (Electric / Gas)• Miscellaneous Electrical Loads• People Activity• Lighting Type• Infiltration• Daylighting Configuration• Schedules
• HVAC Systems• Fans• Coils• Boilers• Chillers• ERV• PTHP/VAV/etc
• Ventilation Requirements• Exhaust Requirements• HVAC Performance Data• Control Sequences• Temperature Setpoints• SWH / DHW• Water Use• Utility Rates
… and more
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Building Model Progression
• Energy models have a natural progression that are similar to the design process
• Earlier phases of the design process require heavily defaulted data, but can be used to get order of magnitude results
• As one enters more detail, they “jumps fidelity levels”.• Higher fidelity models will have changes in:
• temporality: deals with better accuracy in time.Example: 10-minute data versus 1-hour data, or moving to a more complex level in order to catch control cycles of certain equipment
• spatiality: deals with more detailed geometry/program. Example: zone refinement in the model. More accurate daylighting analyses.
• dimensionality: deals with physical models of equipment and systems.
Example: adding more dimensions to a model’s parameters (i.e. 50 inputs to define PV performance)
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Building Model ProgressionPr
ojec
tInf
orm
atio
n Re
quire
d
Design Timeline or Fidelity Required
Leve
l 100
Leve
l 200
Leve
l 300
Leve
l 400 Le
vel 5
00
Additional savings possible
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Building Model ProgressionPr
ojec
tInf
orm
atio
n Re
quire
d
Design Timeline or Fidelity Required
Leve
l 100
• Predesign / Basic (Level 100)– Form
• Orientation• Aspect Ratio• Number of Floors• Envelope Construction
– Fabric• Lighting Power Density• Daylighting• Fenestration
– Program• Daylight Fenestration• HVAC Equipment• Efficiencies
– Equipment• HVAC
– Renewables
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Building Model ProgressionPr
ojec
tInf
orm
atio
n Re
quire
d
Design Timeline or Fidelity Required
Leve
l 200
• Conceptual / Detailed (Level 200)– Fixed
• Orientation• Aspect Ration• Number of Floors
– Optimize on• Envelope• Lighting Power Density• Daylighting• Fenestration• Daylight Fenestration• SWH• HVAC Equipment• Efficiencies
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Building Model ProgressionPr
ojec
tInf
orm
atio
n Re
quire
d
Design Timeline or Fidelity Required
Leve
l 300
• Design Development / Analytical (Level 300)
– Fixed• Orientation• Aspect Ration• Number of Floors• Envelope• Lighting Power Density• Fenestration• Daylight Fenestration• SWH• HVAC Equipment
– Optimize on• Daylighting • Efficiencies• Schedules / Usage Patterns
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Building Model ProgressionPr
ojec
tInf
orm
atio
n Re
quire
d
Design Timeline or Fidelity Required
Leve
l 400
• Representational / Analytical Model (Level 400)– Fixed
• Orientation• Aspect Ration• Number of Floors• Envelope• Lighting Power Density
• Fenestration• Daylight Fenestration• SWH• HVAC Equipment
– Optimize on• Daylighting • Efficiencies• Schedules / Usage• Controls• Sequencing
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Building Model ProgressionPr
ojec
tInf
orm
atio
n Re
quire
d
Design Timeline or Fidelity Required Le
vel 5
00
• Granular / As-Built Model(Level 500)
– Optimize on• HVAC• Lighting • Controls• Insulation• Window Types
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Thick Wall vs Thin Wall
• Level 500 exposes the “Thick Wall” model• Most Energy Modeling occurs on “Thin Wall” models.
VS
Credit: David Goldwasser / NREL
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Combining design measures for more savings
Credit: Nicholas Long / NREL
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Energy Modeling Results
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Skylight Analysis: Daylighting for Large Retail Building
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Start with 133,275 ft2 energy model– Refined with comparisons to sub-metered data
Add skylights and lighting controls to the sales and grocery areas (103,750 ft2 total)
– Skylights: modeled 1% to 5% skylight to floor area (SFA) ratio in 1% increments
– Skylight properties: U-Value = 0.82, SHGC = 0.49, VLT = 0.65– Lighting control: one sensor per zone, 50 footcandle setpoint,
continuous dimming to offInvestigate annual energy performance of the different models using weather data from 7 different climate zones across the United StatesReported results for 3% SFA ratio
– Diminishing returns for higher SFA ratios
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Skylight Analysis: 3% SFA Energy Model Rendering
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Credit: Eric Bonnema / NREL
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Skylight Analysis: Determining SFA Ratio to Report
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40
45
50
55
60
65
70
0.00 SFA 0.01 SFA 0.02 SFA 0.03 SFA 0.04 SFA 0.05 SFA
Ener
gy In
tens
ity (k
Btu/
ft2)
Miami Phoenix Atlanta San Francisco Chicago Boulder Duluth
Curves flatten out after 3% SFA for climate zones
simulated
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Skylight Analysis: Energy Savings: AtlantaClimate Zone 3A: Hot and Humid
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Cooling11.9%
Heating5.1%
Lighting28.4%
Equipment26.3%
Fans9.0%
Refrigeration19.2%
Baseline Model
Cooling10.8%
Heating7.0%
Lighting16.0%
Equipment26.3%
Fans8.4%
Refrigeration19.2%
Savings12.3%
3% SFA Daylit Model
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Skylight Analysis: Cost Savings
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8.7%
7.1%
10.1%
10.9%
10.1%
8.0%
2.6%
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Util
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ost (
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Codes & Standards Development• Whole Building Energy Modeling is major part of
ASHRAE Codes and Standards Development• ASHRAE 90.1 and the Reference Buildings
(http://www1.eere.energy.gov/buildings/commercial_initiative/reference_buildings.html)• High level evaluation of
ASHRAE Standard 189.1• AEDG / TSD • Appendix G• Energy Cost Budget Method
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Large Hotel
Floor area (ft²) Number of Floors Aspect Ratio WWR
122,132 6(plus basement)
Ground & basement floor: 3.8
All other floors: 5.127%
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History of ASHRAE Standard 90.1
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Std 189.1: Wide Variation in Sizing/ZoningAmong Reference Models
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Std 189.1: Items Included in Simulations
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Form– Skylights
Fabric– Roofs/Walls/Floors/Slabs– Vertical Glazing/Skylights– Continuous Air Barrier– High-albedo Roofs
Lighting– Daylighting controls– LPD– Exterior Lighting Controls– Exterior LPD
Plug and Process– Energy Efficient Equipment
HVAC– Cooling/Heating Efficiencies– Economizers– Energy Recovery– Fan Power Limitations– Supply Fans– Ventilation– Dampers
SWH– Efficiencies– Lower flow rates
Other– On-site renewables
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Std 189.1: Weighted Percent Savings
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Building Type Name 90.1-2007 v. 90.1-2004 189.1P v. 90.1-2007
Small Hotel 1.5% 37.8%
Large Hotel 0.7% 27.2%
Small Office 4.5% 35.0%
Medium Office 3.5% 36.0%
Large Office 3.1% 37.5%
Hospital 1.8% 21.0%
Mid-rise Apartment * *
Outpatient Care 4.8% 15.4%
Primary School 4.3% 24.3%
Secondary School 4.1% 32.2%
Quick Service Restaurant 0.6% 29.3%
Full Service Restaurant 0.5% 33.5%
Supermarket 1.6% 20.4%
Stand-alone Retail 4.2% 22.6%
Strip Mall 3.9% 24.5%
Warehouse 1.2% 54.6%
Average 3.3% 30.2%* No weighting factors were defined for the Mid-rise Apartment
http://www.nrel.gov/docs/fy10osti/47906.pdf
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Large Hospital TSD: Modeling Process
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Large Hospital TSD: Prototype Model
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Form– 527,000 ft2
– 40% window-to-wall ratioSpace Types
– Floor 1: offices, laboratories, dining, mechanical, support spaces, clinic
– Floor 2: emergency department, surgery suite, imaging,
– Floor 3: birthing center– Floor 4-7: patient tower– 5-story attached medical office building
Envelope– Slab-on-grade– Steel framed exterior walls– Insulation above deck roof– Double pane fixed windows
Internal Loads– Plug load density: 2.6 W/ft2
– Occupant density: 136 ft2/personVentilation/Airflow Standards
– Healthcare spaces• 2006 AIA Guidelines• Standard 170-2008
– Administrative spaces• Standard 62.1-2004
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Large Hospital TSD: Annual Energy Savings
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NREL RSF: Performance Based Design Build Procurement
NREL Research Support Facility• Building type = office with data center• Size = 222,000 ft2, 3 stories• Occupancy = approx. 600 people• Energy use before PV = 25 kBtu/ft2
• 50% savings over ANSI/ASHRAE/IESNA Standard 90.1-2004• Targeted LEEDTM Platinum rating
37Credit: NREL PIX
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NREL RSF: Performance Based Design BuildRFP - Priority List RankMISSION CRITICAL
Attain Safe Work Performance/Safe Design practices LEED™ Platinum ENERGY STAR First ―Plus‖, unless other system outperforms
HIGHLY DESIRABLE Up to 800 staff capacity 25 kBTU/sf/yearArchitectural integrityHonor future staff needsMeasurable ASHRAE 90.1 - 50% plusSupport culture and amenities Expandable buildingErgonomics Flexible workspace Support future technologies Documentation to produce a ―How to‖ manual on DBAllow secure collaboration with outsidersBuilding information modelingSubstantial Completion by May 2010
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NREL RSF: Energy Goal Risk Analysis
25 kBTU/sf/Year a. The Owner‘s requirements demand innovation and creativity. Unfortunately, the assumption by the industry is that the construction of an efficient facility increases the cost to the project. b. The Owner will be required to control the energy consumption at the plug loads which will require the tight interface with the NREL staff and management. c. It should be noted that the Data Centers will be included in the facility energy consumption goals.
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NREL RSF: Plug Load Reduction
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24” LCD energy-efficient monitors: 18 Watts24” CRT: 70 Watts
Sensor-controlled LED task lights: 6 WattsFluorescent task lights: 35 Watts
VOIP phones: 2 WattsConventional phones: 15 Watts
Removing personal space heaters saves 1500 Watts
Removing desktop printers saves 460 Watts/printer
Thin client laptop computer: 30 WattsDesktop computer (Energy Star): 100-200 Watts
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NREL RSF: Design Features
PV System
Natural Ventilation
Thermal Mass
UFAD
Outdoor Air Pre-cool
Transpired Collectors
Radiant CoolingRadiant Heating
Workplace
Daylighting
Enhanced Envelope
Thermal Bridging
Electrical lighting
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NREL RSF: Achieving the Goal
How did the RSF team turn the goal of a net zero building into a reality?
– Early, strong commitment to energy savings– Integrated design-build process– Focus on efficiency to reduce PV needed– Energy Modeling and Analysis
Credit: Rob Guglielmetti / NREL
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Energy Modeling and Retrofits
Large amount of existing data and advanced photometricsexist. Leverage audit information with existing geometry
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Credit: David Goldwasser / NREL
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Retrofit Modeling
Credit: Nicholas Long / NREL
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Retrofit Modeling
Credit: Nicholas Long / NREL
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Retrofit Modeling
Electricity [GJ]Natural Gas
[GJ]Other Fuel
[GJ]District
Cooling [GJ]District
Heating [GJ] Water [m3]
Heating 0.00 0.00 0.00 0.00 76.97 0.00Cooling 0.00 0.00 0.00 29.53 0.00 0.00Interior Lighting 22.71 0.00 0.00 0.00 0.00 0.00
Exterior Lighting 0.00 0.00 0.00 0.00 0.00 0.00
Interior Equipment 35.14 0.00 0.00 0.00 0.00 0.00
Exterior Equipment 0.00 0.00 0.00 0.00 0.00 0.00
Fans 0.00 0.00 0.00 0.00 0.00 0.00Pumps 0.00 0.00 0.00 0.00 0.00 0.00
Heat Rejection 0.00 0.00 0.00 0.00 0.00 0.00
Humidification 0.00 0.00 0.00 0.00 0.00 0.00
Heat Recovery 0.00 0.00 0.00 0.00 0.00 0.00
Water Systems 0.00 0.00 0.00 0.00 0.00 0.00
Refrigeration 0.00 0.00 0.00 0.00 0.00 0.00Generators 0.00 0.00 0.00 0.00 0.00 0.00
Total End Uses 57.86 0.00 0.00 29.53 76.97 0.00
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Typical Barriers to Using Simulation
Some real, some perceived• Complexity• Time Investment• Experience required• Lack of Data• Belief of Inaccurate Results
How to overcome?• Training courses• User listservs (i.e. bldg-sim)• Software documentation• Conference proceedings (IBPSA)• Sessions like this• Design Guides
• ASHRAE/AIA/DOE/IES/USGBC Advanced Energy Design Guide series• Other
• Example files as starting point / Wizards• Included with some software• DOE’s commercial reference buildings• Others 47
Credit: Nicholas Long / NREL
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Conclusions
Energy modeling can accurately represent real building energy use as long as
• Input data is reasonable• Weather data is accurate• Schedules are calibrated• Occupants are predicable• Performance curves are correct
Energy modeling is useful for performance based metrics, for codes & standards compliance, and for validating design strategies
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Save the Date
ASHRAE’s Energy Modeling ConferenceApril 4-5, 2011Location: ASHRAE Headquarters
Atlanta, GA
Presentations and Panels on:• HVAC Modeling, Envelope, Daylighting, Various Modeling Tools,
Codes & Standards, Controls, etc.
Thank You – [email protected]
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