ASHRAE 90.1
ANSI/ASHRAE/IES Standard 90.1, titled Energy Standard for Buildings Except Low-Rise Residential Buildings, establishes minimum requirements for energy-efficient design, construction, operation, and retrofitting of commercial and high-rise multifamily buildings.[1] Developed by the American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) in collaboration with the Illuminating Engineering Society (IES), it addresses key building systems including envelopes, heating, ventilation, air conditioning (HVAC), lighting, service water heating, electrical distribution, and on-site generation to achieve cost-effective energy savings.[2] First published in 1975 amid the U.S. energy crisis to reduce building energy consumption, the standard has undergone periodic revisions, with continuous maintenance adopted in 1999 to reflect technological advancements and evolving energy markets.[3] The latest edition, ANSI/ASHRAE/IES 90.1-2022, incorporates updates such as enhanced thermal bridging requirements, expanded air leakage testing criteria, revised lighting power allowances, and new compliance paths like modeled space-by-space requirements (MSSR) for HVAC systems, aiming to improve overall building performance while serving as a model for state and federal energy codes.[1][4] Widely referenced in U.S. building regulations, it supports empirical reductions in energy use intensity, with Department of Energy analyses demonstrating progressive efficiency gains across editions through whole-building simulation modeling.[5]Purpose and Scope
Objectives and Energy Efficiency Goals
ASHRAE Standard 90.1, developed by the American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) in collaboration with the Illuminating Engineering Society (IES), establishes minimum requirements for energy-efficient design applicable to most commercial buildings and sites, excluding low-rise residential structures. Its core objective is to prescribe baseline performance levels that minimize energy consumption across key systems, including envelopes, heating, ventilation, air conditioning (HVAC), lighting, and service water heating, thereby reducing operational costs and environmental impacts from fossil fuel use and electricity demand.[6][1] The standard's energy efficiency goals emphasize incremental advancements through periodic revisions, typically every three years, incorporating empirical data from simulations, field studies, and technological innovations to achieve measurable reductions in building energy use. For instance, the 2022 edition targets enhanced efficiency via updated criteria for thermal bridging, refrigeration systems, and energy credits, resulting in projected 9.8% site energy savings and 9.4% source energy savings compared to the 2019 baseline, as determined by U.S. Department of Energy analyses using prototypical building models.[5] These goals prioritize causal reductions in energy demand—such as through improved insulation U-factors, equipment efficiencies, and controls—over unsubstantiated claims of broader sustainability benefits, with compliance verified via prescriptive tables or whole-building performance modeling.[4] By setting enforceable minimums adopted into many state and local building codes, ASHRAE 90.1 seeks to standardize energy performance across diverse climates and building types, fostering long-term reductions in national energy intensity for nonresidential sectors, which historically account for about 19% of U.S. site energy use.[5] The standard's development process relies on public review and technical committee expertise to ensure revisions reflect verifiable improvements, avoiding overreliance on optimistic projections from biased advocacy sources.[6]Applicability to Buildings and Sites
ASHRAE Standard 90.1 establishes minimum energy efficiency requirements applicable to the design, construction, operation, and maintenance of buildings other than low-rise residential structures, which are defined as detached one- and two-family dwellings and townhouses of three stories or fewer in height.[6][1] The standard covers a broad range of nonresidential building types, including commercial, institutional, and high-rise multifamily residential buildings greater than three stories.[6] It applies to new construction of buildings and their systems, as well as new portions of existing buildings, ensuring that energy performance criteria are met from the outset of design.[1] For existing buildings, the standard mandates compliance for additions, alterations, and replacements of systems or equipment, such as HVAC modifications or envelope upgrades, where such changes affect energy use.[1][7] Alterations are specifically defined as replacements or additions to a building or its systems, requiring adherence to relevant sections like those for insulation, air leakage, and fenestration in the envelope.[8] This ensures that renovations do not degrade overall energy efficiency and may necessitate modeling or prescriptive upgrades to baseline requirements.[7] The 2022 edition expanded the scope beyond buildings to include "sites," defined as areas outside the physical building footprint that serve the building's operations, such as parking lots, walkways, and outdoor areas.[9][10] This revision regulates site-related energy consumption, including outdoor lighting, electric vehicle charging infrastructure, and other site loads, particularly for new buildings, major additions, and associated properties.[1][11] Compliance for sites integrates with building-wide paths, such as energy cost budgets or performance ratings, to account for total site energy use.[10] Prior editions focused solely on buildings, making the 2022 update a significant broadening to address ancillary energy demands.[9]Compliance Paths
Prescriptive Compliance Path
The prescriptive compliance path in ASHRAE Standard 90.1 mandates that buildings satisfy specific, component-level minimum efficiency criteria for the envelope, mechanical systems, lighting, service water heating, and other elements, independent of whole-building performance simulation.[12] This method applies to all buildings except low-rise residential structures and requires adherence to mandatory provisions—such as minimum equipment efficiencies, commissioning, and air leakage testing—applicable across compliance options, alongside prescriptive thresholds tailored to climate zones, building types, and system configurations.[13] Compliance documentation typically involves checklists or forms verifying each element against tabulated values, like maximum fenestration U-factors or lighting power densities, facilitating straightforward design review without energy modeling software.[14] For buildings under 25,000 ft² (2323 m²) or three stories with limited scope, a simplified prescriptive method offers reduced requirements, such as consolidated lighting power allowances and basic envelope assemblies, while still enforcing core mandatory rules.[15] Key prescriptive elements include:- Building Envelope: Maximum thermal transmittance (U-factors) for opaque assemblies (e.g., 0.038–0.070 Btu/h·ft²·°F depending on climate zone and type), solar heat gain coefficients (SHGC) ≤0.25–0.40 for fenestration, and vertical fenestration area limits (e.g., ≤30–40% of gross wall area), with mandatory whole-building air barrier continuity and testing showing leakage ≤0.4 cfm/ft² at 0.3 in. w.c.[5]
- HVAC Systems: Minimum equipment efficiencies (e.g., air-cooled chillers at 0.75 kW/ton full load for units ≥75 tons in 2022 edition), economizer requirements for systems >33,000 Btu/h cooling capacity in most climates, and controls like demand-controlled ventilation for spaces >500 ft² with occupancy ≥25 people.[9]
- Lighting: Building area method power densities (e.g., 0.62 W/ft² for offices, 0.66 W/ft² for retail in 2022), automatic shutoff controls, and daylight-responsive dimming in sidelit/perimeter zones ≥15% of floor area.[9]
- Service Water Heating: Insulation on pipes ≥1 in. diameter, circulation loop controls, and efficiency minima for equipment (e.g., storage water heaters ≥0.82 EF for ≥20 gallons).[5]
Performance Compliance Path
The Performance Compliance Path in ASHRAE Standard 90.1, primarily governed by Appendix G, permits demonstration of compliance via whole-building energy simulation, comparing the proposed design's modeled performance against a standardized baseline building to verify equivalent or superior energy efficiency. This method accommodates system trade-offs, such as enhanced HVAC efficiency compensating for deviations in envelope insulation, while requiring adherence to all mandatory provisions across envelope, lighting, mechanical, and service water heating systems.[18][12] The baseline building model incorporates prescriptive elements from the standard but employs fixed parameters that do not evolve with edition updates, ensuring a consistent reference for relative performance evaluation; for example, baseline HVAC system types are determined by building size, use classification, and climate zone per Appendix G tables, with equipment efficiencies set to minimum allowable levels outlined therein.[19] Simulations must account for site-specific factors like orientation, internal loads, schedules, and weather data from approved sources, typically using DOE-approved software such as EnergyPlus, with outputs reported in terms of energy cost index (ECI) or building performance rating (PR).[20] Compliance requires the proposed design's ECI to not exceed the baseline's or the PR to be less than or equal to zero, indicating no increase in modeled energy use relative to the baseline.[21] In the 2022 edition, Appendix G refinements include clarified baseline system selection rules, updated modeling for variable refrigerant flow systems, and expanded credits for onsite renewable energy and demand response, alongside a new optional Mechanical System Performance Rating Method that isolates HVAC evaluation from full-building simulation, permitting trade-offs within mechanical disciplines while holding envelope and lighting to prescriptive minima.[19][22] This HVAC-focused path mandates mechanical efficiency scores meeting or exceeding reference system benchmarks derived from Appendix G, applicable only when all systems serve conditioned spaces and integrate with compliant non-HVAC elements. Documentation entails detailed simulation inputs, outputs, and third-party verification where required by jurisdictions, emphasizing accurate representation of as-built conditions to mitigate modeling uncertainties.[23][12]Additional Modeling and Verification Methods
Section 11 of ASHRAE Standard 90.1 specifies verification requirements for the Energy Cost Budget (ECB) method, mandating the use of simulation programs capable of modeling building geometry, orientation, envelope characteristics, internal loads, HVAC systems, service water heating, and schedules to calculate annual energy costs under specified weather data.[24] These programs must demonstrate accuracy through validation against ASHRAE-provided benchmark models or approval by the authority having jurisdiction, ensuring outputs align with physical principles and empirical data.[12] Documentation for ECB compliance includes detailed input parameters, simulation outputs, deviation justifications exceeding 5% from prescriptive requirements, and evidence of budget compliance within tolerances like ±5% for energy costs.[25] For the Performance Rating Method (PRM) in Appendix G, verification involves submittal reviews confirming that baseline and proposed models accurately reflect design documents, with checks on zoning, system types, efficiency assumptions, and schedules.[25] Modeling must adhere to specific rules, such as baseline HVAC systems selected from Tables G3.1.3.1 through G3.1.3.7 based on proposed design characteristics, and lighting power derived from prescriptive allowances rather than actual design to isolate efficiency impacts.[9] Software outputs require validation of energy use intensity (EUI) or cost index against independent calculations, with tolerances for discrepancies under 10% in key parameters like envelope U-factors and HVAC fan power.[12] Informative Appendix H offers guidance on verification, testing, and commissioning beyond basic modeling, emphasizing functional performance testing (FPT) for systems including HVAC controls, demand response, and economizers.[26] It outlines protocols such as pre-functional checklists, integrated system testing, and post-occupancy verification, with Table H-3 listing specific items like air barrier continuity inspections and sensor calibration traceable to standards like ANSI/ASHRAE Standard 55.[27] These practices aim to confirm as-built performance matches modeled assumptions, reducing discrepancies observed in field studies where unverified controls contribute to 20-30% overconsumption.[28] Normative Appendix L in the 2022 edition introduces the Mechanical System Performance Rating Method as an optional HVAC-focused modeling approach, calculating the total system performance ratio (TSPR) as the ratio of annual heating and cooling loads to energy consumption, requiring TSPR_p ≥ TSPR_baseline for compliance.[22] Applicable only when all building HVAC systems use this method and meet preconditions like variable-speed equipment, it employs detailed simulations of duct losses, pump efficiencies, and part-load performance, verified against manufacturer data and field measurements.[29] This method enables targeted HVAC trade-offs while maintaining envelope and lighting prescriptive compliance, with documentation including load calculations per ANSI/ASHRAE Standard 183 and sensitivity analyses for key variables.[22]Key Technical Requirements
Building Envelope Standards
The building envelope requirements in ASHRAE Standard 90.1, outlined in Section 5, aim to reduce thermal transmission and air infiltration through mandatory and prescriptive criteria tailored to climate zones 0 through 8. Mandatory provisions include proper insulation installation per Section 5.2, which requires continuous insulation or framing cavity insulation meeting labeled R-values without compression, and fenestration products certified by an approved agency for U-factor, solar heat gain coefficient (SHGC), and visible transmittance (VT). Air leakage must be controlled under Section 5.4.3, with whole-building testing required for buildings over 1,000 ft² demonstrating a maximum infiltration rate of 0.40 cfm/ft² at 0.3 in. w.c. pressure; partial testing is permitted for larger buildings exceeding 50,000 ft² if zones meet the limit when normalized.[30][31] Prescriptive requirements in Section 5.5 specify maximum assembly U-factors or minimum R-values for opaque elements such as roofs, walls, floors, and slabs, varying by climate zone, space-conditioning category (nonresidential, residential, semiheated), and assembly type (e.g., mass vs. wood-framed walls). For instance, in Climate Zone 5 for nonresidential buildings, steel-framed walls require a maximum U-factor of 0.038 Btu/h·ft²·°F or R-13.3 cavity plus R-5 continuous insulation. Fenestration assemblies, per Table 5.5-4, must meet maximum U_c factors (e.g., 0.38 for fixed windows in Zone 5) and SHGC limits (e.g., 0.40 north-oriented, 0.25 others), with vertical fenestration area capped at 30%–40% of gross wall area unless adjusted for daylighting. Skylights and doors have analogous criteria, including dynamic glazing options for SHGC modulation.[5] The 2022 edition introduced explicit thermal bridging provisions in Section 5.5.5, recognizing linear (e.g., steel studs) and point (e.g., fasteners) thermal bridges that can degrade effective R-values by 20%–50% in some assemblies. Compliance requires either modeling effective U-factors (U_eff) using approved software accounting for bridges or applying prescriptive adjustments like increased continuous insulation thickness; default linear transmittance values (ψ-factors) are provided for common details, such as 0.6 Btu/h·ft·°F for steel clips in insulated panels. These updates, informed by empirical data from field studies, enhance envelope performance without mandating full redesigns, yielding 4%–5% overall energy savings in prescriptive paths.[23][32][33] An alternative component performance path in Section 5.6 allows trade-offs among envelope elements if the combined annual heating and cooling load meets or exceeds a baseline calculated from prescriptive tables, verified via simulation tools like EnergyPlus. All assemblies must still satisfy mandatory criteria, and labeling of insulation products is required under Section 5.8 to ensure installed performance matches design values.[12][31]HVAC and Mechanical Systems
Chapter 6 of ASHRAE Standard 90.1 establishes mandatory and prescriptive requirements for HVAC and mechanical systems to achieve minimum energy efficiency in commercial buildings, excluding low-rise residential structures.[6] Mandatory provisions include accurate load calculations, equipment sizing not exceeding 115% of design load, zoning to prevent simultaneous heating and cooling in the same space, off-hour controls with automatic setbacks or shutdowns, demand-controlled ventilation for spaces over 500 ft², and duct sealing with insulation minimums of R-6 for supply/return ducts in unconditioned spaces.[10] Piping insulation requirements specify minimum R-values based on fluid temperature and pipe size, such as R-4.5 for hot water pipes up to 1.25 inches in diameter operating above 140°F.[6] Prescriptive requirements mandate minimum equipment efficiencies detailed in tables such as Table 6.8.1 for unitary air conditioners and heat pumps, where air-cooled units below 65,000 Btu/h must meet updated SEER2 and HSPF2 ratings, and larger systems achieve higher Integrated Energy Efficiency Ratios (IEER), with significant increases for commercial rooftop units to emphasize part-load performance.[9] Chillers require path A or B efficiencies, such as full-load EER of 9.6 for air-cooled positive displacement units under 75 tons, while boilers and furnaces have thermal efficiencies like 80% for gas-fired hot water boilers.[5] Fan systems face power limitations per Table 6.5.3.1-1, generally 0.60 W/cfm for supply fans in constant-volume systems, with variable frequency drives required for motors over 5 hp in variable air volume setups and efficiency grades (e.g., Grade A for fans over 5 hp) to reduce energy use.[34] Air economizers are required for cooling systems over specified capacities (e.g., 54,000 Btu/h in many climates) unless high-efficiency alternatives like DOAS with energy recovery achieve at least 10% better performance, with control high limits varying by climate zone such as fixed dry-bulb at 75°F for zones 0A-3B.[9] Hydronic systems limit pump power to 0.12 hp/1000 gpm baseline, with variable flow controls, and energy recovery ventilation mandates exhaust air recovery effectiveness of at least 50% for systems serving areas over 26,000 ft² of conditioned space in colder climates.[10] The 2022 edition introduces the optional Mechanical System Performance Path (Section 6.6 and Appendix L), enabling trade-offs across HVAC components by comparing the proposed Total System Performance Ratio (TSPR_p) against a reference (TSPR_r) adjusted by a Mechanical Performance Factor (MPF) for building type and climate, allowing omission of elements like economizers if overall system efficiency exceeds prescriptive baselines by specified margins.[4] This path supports integrated design for decarbonization, complementing mandatory maintenance information requirements for system optimization.[6] Compliance documentation must verify adherence to these provisions, with modeling in performance paths simulating baseline efficiencies from the same tables.[5]Lighting Power and Controls
The prescriptive compliance path in ASHRAE 90.1 limits interior lighting power through two methods: the Building Area Method, which applies uniform power densities by building type per Table 9.6.1, and the Space-by-Space Method, which uses detailed allowances per Tables 9.5.2.1-1 and 9.5.2.1-2 for specific space functions.[35] In the 2022 edition, space-by-space lighting power densities (LPDs) reflect an overall 4% reduction from 2019 values, such as 0.88 W/ft² for conference rooms (down from 0.97 W/ft²) and 0.72 W/ft² for classrooms (stable from 0.71 W/ft²).[36] Additional interior allowances include 0.70 W/ft² for decorative lighting (reduced from 0.75 W/ft²) and 0.50 W/ft² for videoconferencing setups.[36] Exterior lighting power follows a base site allowance plus zoned densities per applicable tables, with 2022 values reduced approximately 30% from 2016 levels, for example, 0.037 W/ft² for parking areas in Zone 3 (down from 0.06 W/ft²).[36] Mandatory controls under Section 9.4 ensure automatic reduction or shutoff of lighting power to minimize waste. All interior lighting requires automatic shutoff via time-of-day scheduling, occupancy sensors, or signal from another control system, with full off controls limited to zones of 5,000 ft² or less (or 25,000 ft² per floor for scheduling).[35] Local control mandates manual-on operation with partial automatic-on capped at 50% of general lighting power, multi-level controls capable of continuous dimming to 10% or less, and power reductions of at least 50% (or 80% in open offices over 300 ft²) within 20 minutes of vacancy detection.[36] [35] Occupancy sensors apply to spaces like offices under 150 ft², restrooms, and corridors, with zone limits of 2,500 ft² generally (up to 3,600 ft² for parking garages). Daylighting controls are required for sidelit zones exceeding 75 W (primary) or 150 W (secondary) and toplit areas, with continuous dimming to 20% or less power.[35] Specific provisions target high-use areas: hotel guest rooms require shutoff after 20 minutes of vacancy, while dwelling units mandate dimmers or auto-off on 50% of luminaires and exterior controls turning off during daylight or after 15 minutes of inactivity.[36] Efficacy minima in 2022 raise thresholds for dwelling unit luminaires to 50 lumens per watt and lamps to 75 lumens per watt for at least 75% of fixtures; track lighting power is capped at 10 W per linear foot for line-voltage systems (down from 30 W/ft).[36] Exceptions exclude germicidal luminaires from power calculations and apply tailored controls for horticultural lighting, such as minimum photosynthetic photon efficacy of 1.7 μmol/J for greenhouses. For alterations, interior replacements exceeding 2,000 W or exterior changes involving over 10 luminaires must comply fully with Section 9.[36] These requirements integrate with performance paths via modeling but emphasize prescriptive limits to achieve verifiable efficiency gains.[5]Service Water Heating and Other Loads
Service water heating systems in ASHRAE Standard 90.1 encompass equipment and controls designed to minimize energy use for non-space-conditioning hot water needs, such as domestic sanitation and laundry. Mandatory provisions under Section 7.4 require water heating equipment to achieve specified thermal efficiencies or uniform energy factors (UEF), as detailed in Table 7.4.1; for instance, gas-fired storage water heaters with inputs ≤75,000 Btu/h must have an energy factor (EF) ≥0.82, while electric storage models ≥20 gallons and <12 kW input require EF ≥0.93.[37] Piping insulation is mandated with minimum R-values based on pipe size and temperature, such as R-3 for pipes <1 inch serving hot water above 140°F, updated in the 2022 edition to reflect typical operating conditions for improved accuracy.[9] Storage tanks must incorporate heat traps or equivalent devices to reduce standby losses, and circulation systems require controls like timers or demand-based pumps to limit flow during off-hours.[38] Prescriptive compliance paths in Section 7.5 specify system configurations, such as limiting heated water temperature to 110°F except for commercial dishwashers or laundries requiring higher settings with isolation valves.[39] Heat recovery from condenser waste heat is required for preheating service water in facilities with ≥600,000 Btu/h annual usage if the system serves ≥50% of the load, provided design conditions allow recovery without excessive pumping energy.[40] For larger systems, options include centralized storage with efficiency ≥0.70 or distributed instantaneous heaters meeting input-based ratings, ensuring overall system performance aligns with baseline energy targets.[5] Other equipment loads addressed in Section 10 cover non-HVAC, non-lighting, and non-service water heating systems, including elevators, escalators, commercial refrigeration, and kitchen appliances, with mandatory efficiency standards to curb parasitic energy consumption. Elevators must incorporate regenerative drives for traction systems over 100 hp and standby power reduction modes limiting draw to ≤5 W per elevator when idle.[10] Escalators and moving walks require variable-frequency drives (VFDs) and automatic speed controls reducing speed to ≤15% during low use, detected via sensors or timers. Commercial refrigeration equipment, such as reach-in cases, must meet case-specific energy use limits in Table 10.4.3-1, factoring in volume and type (e.g., ≤0.8 W/ft² for solid-door refrigerators), with door gaskets and anti-sweat heater controls to minimize infiltration losses. Additional requirements target laundry and kitchen equipment, mandating heat recovery or efficient dryers in high-volume facilities, such as coin-operated laundries with ≥25 washers requiring exhaust air recovery ≥60% of dryer heat.[42] Compliance documentation under Section 7.7 and 10.7 verifies installations against rated performance, with exceptions for equipment serving <1% of total load or historic buildings, emphasizing measurable reductions in non-core energy demands.[43]History and Development
Early Development (1975–1989)
The development of what would become ASHRAE Standard 90.1 originated in the wake of the 1973 oil embargo and subsequent energy shortages, which exposed dependencies on imported oil and spurred federal and state initiatives for building energy conservation. ASHRAE, leveraging technical input from the Illuminating Engineering Society (IES), expedited the creation of the inaugural edition, published in August 1975 as ASHRAE Standard 90-75, "Energy Conservation in New Building Design." This marked the first national voluntary standard addressing energy use across new residential and non-residential buildings, specifying minimum insulation values, HVAC equipment efficiencies, lighting power allowances, and service water heating controls to curb consumption without mandating specific fuels. Drawing on foundational research like National Bureau of Standards report NBSIR 74-452, the standard prioritized economically justified measures, with projected savings of 20-30% in building energy relative to pre-crisis practices, though implementation relied on voluntary adoption by designers and codes.[44][45][46][47] The 1980 update, designated ANSI/ASHRAE/IES 90A-1980 and approved as an American National Standard, revised core sections of the 1975 edition to incorporate field experience, refining prescriptive criteria for envelopes, mechanical distribution, and electrical systems while formalizing IES co-sponsorship via a June 25, 1980, agreement. Key enhancements included clarified compliance procedures and sustained emphasis on minimum efficiencies for pumps, fans, and boilers—requirements dating to 1975 that targeted operational losses. These changes responded to early critiques of vagueness in the original, such as ambiguous fenestration limits, and aligned with ASHRAE's policy of quinquennial reviews to ensure relevance amid stabilizing energy markets.[45][48][49] By 1983–1984, escalating complexity in applying unified rules across building types prompted the ASHRAE 90 committee to bifurcate the project: Standard 90.1 for commercial and high-rise residential structures, emphasizing larger-scale systems and occupancy patterns, and 90.2 for low-rise residential. This restructuring facilitated targeted advancements, such as sector-specific envelope U-factors and ventilation mandates. The effort culminated in ASHRAE/IES Standard 90.1-1989, approved June 24, 1989, under ANSI consensus processes with public input; titled "Energy Efficient Design of New Buildings Except New Low-Rise Residential Buildings," it integrated dynamic heat flow modeling for fenestration and walls, alongside updated lighting controls and economizer provisions, to enhance accuracy over static assumptions in prior editions.[45][50]1990s to Early 2000s Editions
The 1993 edition served as an update to the 1989 version, incorporating addenda and codifying provisions without major structural overhauls.[51] It maintained the core prescriptive requirements for building envelopes, HVAC systems, and lighting from 1989, with refinements such as updated references to service water heating criteria and motor efficiencies.[52] The 1999 edition marked a comprehensive rewrite of the standard, expanding its scope to encompass renovations and modifications to existing buildings beyond new construction alone.[53] Key revisions included adjusted economizer requirements, mandating them in fewer climate zones than the 1989 edition to balance energy recovery with system complexity.[54] Lighting provisions yielded modest efficiency gains through refined power density limits, while HVAC updates emphasized staged equipment like smaller boilers for improved part-load performance over single large units.[55][56] These changes, informed by economic analyses, aimed to enhance enforceability with mandatory language and prescriptive paths, though simulated building energy models indicated variable savings depending on building type and location.[57] The 2001 edition applied 34 addenda to the 1999 baseline, resulting in minor revisions such as clarifications to fan power limitations and compliance documentation.[58] It also formalized the standard's nomenclature as ANSI/ASHRAE/IESNA Standard 90.1.[59] U.S. Department of Energy evaluations concluded that these updates did not yield significant overall energy efficiency improvements relative to 1999 provisions.[60] The 2004 edition introduced further updates and reorganization for clarity, including more restrictive interior lighting power allowances that reduced permitted densities across building types.[61] It added mandatory controls for exterior building grounds and parking lot lighting powered by the building service, alongside new climate zone definitions while retaining envelope U-factors and solar heat gain coefficients from prior editions in equivalent zones.[62] HVAC enhancements focused on fan and pump efficiencies, supporting a positive federal determination of improved energy performance over the 1999 edition.[58]Mid-2000s to 2010 Editions
The 2004 edition of ASHRAE Standard 90.1 introduced a reorganization for improved usability and adopted new climate zones in place of prior climate bins, mapping envelope and economizer requirements to enhance stringency across regions.[58] Key positive changes included added insulation requirements for buried ductwork, ventilation fan controls, occupancy sensors, and reduced lighting power densities, though some provisions relaxed slab insulation and damper leakage standards.[58] The U.S. Department of Energy (DOE) determined that this edition achieved approximately 11.9% site energy savings nationally compared to the 2001 version, prompting states to update building codes accordingly by December 2010.[58] The 2007 edition incorporated 44 addenda from continuous maintenance proposals, with 11 yielding energy savings through updates like reduced U-factors for residential roofs (e.g., attic insulation from 0.027 to 0.021 in Zone 5), walls, slabs-on-grade, and doors, alongside HVAC enhancements such as demand-controlled ventilation and lower fan power limits.[63][63] Lighting updates included tighter controls for retail displays, while only two changes increased energy use, such as exceptions for visually impaired lighting.[63] DOE's qualitative review confirmed overall efficiency gains, particularly in envelope and mechanical systems.[63] The 2010 edition processed 109 addenda, targeting 30% energy cost savings relative to the 2004 baseline through measures like mandatory daylighting controls, cool roof requirements, expanded heat recovery, chiller efficiency updates, and economizers for computer rooms.[64][65] HVAC revisions mandated supply-air temperature reset for multiple-zone systems and receptacle load controls, while lighting power densities were lowered with added occupancy sensors.[65] Of the changes, 56 were positive for energy use, six negative (e.g., higher ventilation allowances), and the rest neutral or editorial, resulting in net efficiency improvements as verified by DOE analysis.[65]2013–2019 Editions
The 2013 edition of ANSI/ASHRAE/IES Standard 90.1 introduced over 100 addenda from the prior 2010 version, focusing on enhancements to building envelope requirements, HVAC system efficiencies, lighting power densities, and service water heating. Key modifications included updated chiller efficiency metrics shifting from integrated part-load value (IPLV) to integrated energy efficiency ratio (IEER) for certain applications, revised economizer controls to optimize outside air usage, and tightened lighting power allowances through the building area method and space-by-space approach.[66][67] Appendix G, the performance rating method, was expanded to serve as a compliance path alongside prescriptive options, enabling modeling of baseline versus proposed designs for energy cost index comparisons.[18] U.S. Department of Energy (DOE) analysis using prototype commercial building models across 16 climate zones estimated 7.4% site energy savings relative to the 2010 edition, with variations by building type such as 8-10% for offices and retail but lower for warehouses.[66] These modeled improvements were deemed cost-effective nationally, supporting DOE's adoption of 90.1-2013 as the federal baseline for new commercial buildings effective October 2014.[68][67] The 2016 edition built on 2013 provisions with approximately 120 changes, emphasizing HVAC fan power limits, improved demand-controlled ventilation, and refined envelope U-factors and solar heat gain coefficients for climate zones. Notable updates encompassed higher efficiency requirements for data center cooling, expanded controls for variable refrigerant flow systems, and adjustments to lighting controls mandating multilevel switching in larger spaces.[69] DOE prototype modeling indicated 7.6% site energy and 8.5% source energy savings over the 2013 edition, derived from simulations of 16 building types in 16 U.S. climates, with fan and pump systems contributing significantly to gains.[70][71] Cost-effectiveness evaluations confirmed positive net present value for most prototypes, though savings were marginal in milder climates or for refrigerated warehouses.[72] These revisions aligned with ongoing ASHRAE Standing Standard Project Committee (SSPC) 90.1 efforts to incorporate emerging technologies while maintaining prescriptive feasibility. The 2019 edition incorporated more than 100 addenda from 2016, introducing a fan energy index (FEI) metric to replace fan energy index (FBI) for assessing total fan system efficiency, updated pump efficiency tables, and mandatory commissioning for HVAC systems over 480,000 Btu/h. Additional changes targeted heat recovery minimums, daylight-responsive controls with stricter automatic reduction requirements, and revised building envelope assemblies for nonresidential conditioned spaces.[73][74] DOE analysis reported 4.7% site energy savings versus 2016, based on prototype simulations emphasizing end-use breakdowns like lighting (20-25% of savings) and mechanical systems.[75][76] Among the 88 addenda, 29 directly advanced energy savings, with enhancements to renewable energy credits and carbon emission considerations in Appendix G modeling.[74] Overall, the 2013-2019 progression achieved modeled cumulative efficiencies exceeding 18% site energy reduction from 2010 baselines, driven by iterative SSPC reviews of empirical data and technology advancements, though real-world performance depends on enforcement and modeling accuracy.[70][76]2022 Edition and Ongoing Updates
The ANSI/ASHRAE/IES Standard 90.1-2022, titled Energy Standard for Sites and Buildings Except Low-Rise Residential Buildings, was published in January 2023, incorporating over 80 addenda approved since the 2019 edition.[77][6] This edition expands the standard's scope beyond buildings to include site-level elements such as exterior lighting, parking lot lighting, and onsite renewable energy systems, marking the first inclusion of minimum prescriptive requirements for onsite renewables at 0.5 W/ft² of gross site area.[78][5] Key enhancements include a new optional mechanical system performance path using the Total System Performance Ratio (TSPR) metric, updated efficiency requirements for equipment such as increased Integrated Energy Efficiency Ratios (IEER) for commercial rooftop units and adoption of SEER2/HSPF2 ratings for air-cooled heat pumps under 65,000 Btu/h, and provisions addressing thermal bridging in building envelopes.[6][78] A significant addition is Section 11 on "Additional Efficiency Requirements," introducing an energy credits system with 33 credits available to achieve approximately 4% to 5% energy cost savings beyond baseline compliance, allowing flexibility for customized efficiency measures while maintaining modeled performance targets.[9] The standard also incorporates references to ASHRAE Guideline 36 for sequences of operation in HVAC controls and provides optional guidance for alternative compliance metrics like carbon emissions, site energy, and source energy, supporting broader environmental goals.[10] U.S. Department of Energy analysis confirms the 2022 edition improves energy efficiency over the 2019 version, with projected national site energy savings of 4.1% in new commercial buildings, though actual savings depend on adoption and enforcement.[5] Ongoing maintenance occurs through ASHRAE's continuous addenda process, where proposed changes are publicly reviewed and approved individually before potential bundling into future editions; addenda post-2022 include updates to climate data annexes (e.g., May 2024 extraction from ANSI/ASHRAE Standard 169-2013) and refinements to renewable capacity requirements (e.g., Addendum aq increasing onsite rated capacity to 0.75 W/ft²).[79][80][81] The 2022 edition initiates a trajectory toward net-zero carbon emissions compliance by 2031, with an optional appendix for low-carbon pathways, though full realization requires subsequent addenda and editions to escalate stringency in areas like electrification and renewables.[82] As of October 2025, ASHRAE continues approving addenda, such as those enhancing ventilation definitions and outdoor air rates, ensuring the standard evolves with empirical data on equipment efficiencies and building performance.[83]Adoption and Regulatory Status
Role as Model Energy Code
ASHRAE Standard 90.1 establishes minimum requirements for the energy-efficient design of commercial buildings and sites, excluding low-rise residential structures, and functions as a foundational model for commercial energy codes across the United States.[6] It provides prescriptive and performance-based compliance paths that jurisdictions adopt either directly or by reference, often as a supplement to or replacement for the commercial provisions in the International Energy Conservation Code (IECC).[84] [85] Under the Energy Policy Act of 2005, the U.S. Department of Energy (DOE) evaluates each new edition of ASHRAE 90.1 to determine if it achieves greater energy efficiency than the prior version, triggering a federal mandate for states to review and potentially update their commercial energy codes to match or exceed the standard within two years of the determination.[86] For instance, DOE's March 2024 determination for the 90.1-2022 edition concluded it delivers an average national site energy savings of 14% compared to the 2019 edition, based on simulations across 16 U.S. climate zones using prototype building models.[87] [5] This process ensures periodic advancements in code stringency, with states certifying compliance to DOE; as of 2024, nearly all states reference or adopt elements of 90.1 for commercial and high-rise multifamily buildings.[88] [1] As a continuous maintenance standard, ASHRAE 90.1 undergoes ongoing revisions through public proposals reviewed by its Standing Standard Project Committee (SSPC), allowing it to incorporate technological advancements and empirical data without fixed triennial cycles, unlike some model codes.[88] This adaptability positions it as a benchmark influencing not only U.S. regulations but also voluntary green building certifications and international standards, though adoption varies by jurisdiction with some opting for IECC modifications over direct 90.1 use.[4] [89]Jurisdictional Adoption and Enforcement
ASHRAE Standard 90.1 acquires mandatory status solely upon adoption into jurisdictional building codes, transforming it from a voluntary consensus standard into a legally enforceable requirement for commercial and high-rise multifamily buildings.[90] In the United States, primary adoption authority resides with states, though local governments may enact amendments or more stringent provisions; federal facilities, such as those under the General Services Administration, also reference it directly.[91] Under the Energy Policy and Conservation Act, as amended, states must review and certify to the U.S. Department of Energy every six years that their commercial energy codes meet or exceed the updated ASHRAE 90.1 edition, with non-compliance risking loss of certain federal funds.[77] As of 2024, adoption of the 2022 edition includes states such as Alabama, Indiana, New Jersey, Oregon, West Virginia, and New York, alongside the District of Columbia; additional jurisdictions encompass Illinois, Nevada, and localities like Portland, Oregon, and Austin, Texas.[91] Earlier editions persist in some areas—for instance, certain states reference ASHRAE 90.1-2019 or 2016 as alternatives to the International Energy Conservation Code (IECC), which itself incorporates 90.1 elements for commercial provisions.[85] State-level processes vary, often involving legislative approval, executive orders, or regulatory rulemaking by building code councils, with timelines influenced by cost-effectiveness determinations from the Department of Energy.[88] Enforcement, delegated to local building departments or authorities having jurisdiction, occurs through the standard permitting workflow: pre-construction plan reviews assess compliance via prescriptive checklists or energy modeling software like those supporting Section 11's performance path; on-site inspections verify installation of envelopes, HVAC systems, lighting, and controls; and final occupancy certificates require documentation of adherence.[12][92] Performance-based options, including whole-building simulations, demand third-party validation in some cases, while prescriptive paths emphasize component efficiencies.[93] Challenges in uniform enforcement arise from resource constraints in smaller jurisdictions and varying local interpretations, though tools like DOE-approved compliance forms aid consistency.[12] Non-compliance may result in permit denials, stop-work orders, or fines, scaled to project scope.[92] Internationally, select Canadian provinces and other nations reference 90.1 provisions, but U.S. adoption dominates its regulatory footprint.[94]Integration with Federal and International Standards
ASHRAE Standard 90.1 serves as a foundational reference for federal energy efficiency requirements in the United States, particularly through its influence on the International Energy Conservation Code (IECC) commercial provisions, which many jurisdictions adopt as mandatory codes. The U.S. Department of Energy (DOE) annually reviews updates to Standard 90.1 under the Energy Conservation and Production Act (as amended by the Energy Independence and Security Act of 2007) to assess whether they represent a more stringent energy efficiency baseline than prior editions; for instance, DOE's analysis of the 2022 edition determined it achieves 9.8% site energy savings, 9.4% source energy savings, and 9.3% energy cost savings relative to the 2019 edition, qualifying it as a "model energy code."[87][5] Federal agencies must comply with these standards for new construction and major renovations, with Executive Order 14057 (2021) updating the baseline to require designs at least 30% more efficient than ASHRAE 90.1-2019—or the maximum achievable level if less—for federal buildings.[95] In practice, Standard 90.1 integrates with federal programs by providing performance paths (e.g., energy cost budget or modeling) that align with DOE's Building Energy Codes Program, which supports state adoption of IECC/90.1 equivalents to meet national energy savings targets.[89] For federally funded or owned projects, compliance often involves demonstrating equivalence to 90.1 via whole-building simulations, ensuring alignment with broader DOE goals like reducing national building sector energy use by 30% by 2030 relative to 2010 levels.[96] Internationally, Standard 90.1 has limited direct regulatory integration but influences global practices through voluntary certifications and adaptations. In Europe, the ASHRAE 90.1 Europe Alternative Compliance Path (ACP) allows substitution of regional standards (e.g., EN 15251 for indoor environmental quality or national building codes) for certain U.S.-centric provisions in LEED projects, facilitating its use in non-U.S. contexts without full harmonization.[97] It aligns conceptually with ISO 52000 series on energy performance of buildings, sharing methodologies for envelope, lighting, and HVAC efficiency modeling, though European directives like the Energy Performance of Buildings Directive (EPBD) emphasize nearly zero-energy buildings via national implementations rather than adopting 90.1 verbatim.[98] ASHRAE's international membership contributes to cross-pollination, with 90.1 referenced in comparisons to EU fan efficiency regulations under Ecodesign Directive, but adoption remains primarily U.S.-driven due to metric/imperial differences and local code precedence.[99]Effectiveness and Empirical Impacts
Documented Energy Savings
Studies evaluating the energy savings attributable to ASHRAE 90.1 compliance primarily rely on U.S. Department of Energy (DOE) prototype building simulations, which compare energy use intensity (EUI) under successive editions of the standard assuming full compliance. For instance, the 2019 edition achieved modeled national average savings of 4.7% in site energy, 4.3% in source energy, and 4.3% in energy costs relative to the 2016 edition across 16 U.S. climate zones and six building types.[76] Similarly, the 2022 edition demonstrated 9.8% site energy savings and 8.9% energy cost savings compared to the 2019 edition in DOE analyses.[5] These incremental improvements, typically 3-10% per edition, accumulate over time; DOE estimates that buildings compliant with 90.1-2016 exhibit approximately 34% lower energy use than those modeled to the 2004 edition.[64] Empirical documentation of realized savings, derived from field data rather than simulations, indicates lower performance due to incomplete compliance. Pacific Northwest National Laboratory (PNNL) analyses of commercial building datasets, including utility billing and inspection records, reveal that average compliance rates yield only partial realization of modeled potentials, with full compliance potentially saving an additional 15% in annual energy costs in studied jurisdictions like Seattle.[100] Commercial Buildings Energy Consumption Survey (CBECS) data corroborates gradual EUI reductions in newer vintages of buildings post-2000, aligning with code adoptions based on 90.1, though overall commercial sector site EUI declined by about 20% from 1992 to 2018, influenced by multiple factors including codes, equipment efficiency, and operational changes.[101][102] Broader assessments, such as PNNL's evaluation of code impacts, estimate that model codes derived from 90.1 contributed to cumulative savings of 10-15% in commercial building energy use nationwide by 2020 compared to pre-code baselines, factoring in adoption and partial compliance rates averaging 50-70% across measures like envelope and lighting.[103] However, these figures underscore a compliance gap: DOE and PNNL studies consistently find that real-world savings fall short of modeled targets by 20-50%, attributable to enforcement variability, design errors, and post-occupancy deviations.[104][105]Measured vs. Modeled Performance
ASHRAE Standard 90.1 permits performance-based compliance paths, such as the Energy Cost Budget and Performance Rating Method in Appendix G, which rely on whole-building energy simulations to predict compliance relative to a baseline model derived from the standard's prescriptive requirements.[12] These models incorporate standardized assumptions for factors like occupancy schedules, lighting controls, and HVAC operation, often drawn from ASHRAE-recommended profiles.[22] However, real-world measured energy performance frequently deviates from these simulations due to variables such as occupant behavior, construction tolerances, commissioning deficiencies, and deviations from modeled operational conditions.[106] Empirical studies of buildings designed to ASHRAE 90.1 compliance levels highlight a consistent "performance gap," where actual energy use intensity (EUI) exceeds modeled predictions. In a 2008 analysis by the New Buildings Institute of 91 LEED-certified commercial buildings—many using ASHRAE 90.1 Appendix G for energy modeling—the aggregate ratio of predicted to actual EUI was 92% for medium-energy-use structures (e.g., offices), indicating actual consumption about 9% higher than simulated; over half deviated by more than 25%, with high-energy-use buildings (e.g., labs) showing actual EUI 2.5 times the predicted value.[107] Actual energy savings relative to ASHRAE 90.1 baselines averaged 28%, aligning closely with the modeled 25%, but the high variability underscores modeling's limitations for project-specific predictions.[107] A 2013 study by RDH Building Science of seven high-performance buildings (built 2005–2011) compliant with or exceeding ASHRAE 90.1-2004 or equivalent standards found that measured EUI exceeded the modeled proposed design in six cases and the baseline in four; only one project achieved lower-than-modeled consumption, attributing discrepancies to operational realities not fully captured in simulations.[108] Fixed assumptions in ASHRAE 90.1 models, such as idealized occupancy and equipment schedules, contribute to underestimation of actual use, as real occupant patterns introduce variability that amplifies the gap.[109] Calibration efforts, including post-occupancy monitoring and model adjustments, can reduce but not eliminate these differences, with empirical validation remaining sparse compared to reliance on simulated outcomes for code determinations.[110]Broader Environmental and Grid Effects
Compliance with ASHRAE 90.1 has been associated with measurable reductions in carbon dioxide emissions through decreased building energy consumption, with the 2022 edition projecting a 9.3% decrease in emissions relative to the 2019 baseline across prototypical commercial buildings, based on national average grid factors.[5] Similarly, adoption of the 2019 edition yields a modeled 4.2% carbon emissions reduction, reflecting efficiencies in lighting, HVAC, and envelope systems that lower site and source energy use.[76] State-level analyses, such as in New Hampshire, estimate cumulative CO2 savings of 0.8 million metric tons over 30 years from 90.1-2019 implementation, equivalent to removing emissions from approximately 166,900 passenger vehicles for one year.[111] These outcomes depend on regional electricity generation profiles; fossil fuel-dominant grids amplify emission benefits, while renewable-heavy grids shift emphasis to non-energy environmental impacts like reduced water use in thermal power plants, though empirical data on the latter remains limited. On the electric grid, ASHRAE 90.1-driven efficiencies contribute to lower overall demand, with buildings accounting for about 80% of peak load drivers, enabling deferred infrastructure investments and enhanced stability.[112] Efficiency measures in the standard, including demand-responsive controls and optimized equipment sizing, facilitate peak demand reductions; for instance, National Renewable Energy Laboratory modeling indicates that high-efficiency building envelopes and HVAC systems can cut summer net peak intensity by up to several kilowatts per square meter in U.S. regions by 2030.[113] The standard's provisions for interactive building-grid systems, such as load shifting via on-site storage or responsive appliances, support greater integration of variable renewables by absorbing excess generation during low-demand periods and curtailing usage at peaks, as outlined in ASHRAE guidance on decarbonization interactivity.[114] Empirical demonstrations, including commercial building pilots, show that 90.1-compliant designs enable curtailment strategies reducing grid peaks by 10-20% through automated controls, though widespread realization requires complementary utility programs and digital infrastructure.[115] These grid benefits are regionally variable, with higher value in constrained systems facing rapid electrification.Economic Analyses and Cost-Benefit Considerations
Upfront Costs and Payback Periods
Compliance with ASHRAE 90.1 typically incurs incremental upfront costs for enhanced building envelope insulation, efficient HVAC systems, lighting controls, and other measures relative to prior standards or baseline construction practices. For the 2022 edition compared to the 2019 edition, the U.S. Department of Energy (DOE) estimates national weighted average incremental construction costs ranging from $0.57/ft² for small offices to $1.69/ft² for large offices across climate zones, representing less than 1% of total building costs in most cases.[116] These costs arise from material and equipment upgrades, such as improved fenestration U-factors or higher-efficiency motors, though some provisions yield net cost reductions through optimized designs.[116] Simple payback periods, defined as incremental first costs divided by annual energy cost savings, average 6.1 years nationally for the 2022 edition across prototypical building types and climate zones representing 72% of new commercial floor area.[116] Paybacks vary by sector: standalone retail achieves 4.6 years due to high lighting and envelope savings, while primary schools extend to 9.3 years from lower operating hours and ventilation demands.[116]| Building Type | Incremental Cost ($/ft², national weighted) | Simple Payback (years, national weighted) |
|---|---|---|
| Small Office | 1.09 | 7.5 |
| Large Office | 1.41 | 8.5 |
| Standalone Retail | ~1.22 (avg. range) | 4.6 |
| Primary School | ~1.33 (avg. range) | 9.3 |
| Small Hotel | ~1.63 (avg. range) | 7.5 |
| Mid-rise Apartment | 3.17 | 5.0 |
Lifecycle Economic Evaluations
The U.S. Department of Energy (DOE) conducts lifecycle economic evaluations of ASHRAE Standard 90.1 updates using life-cycle cost analysis (LCCA), which quantifies the net present value (NPV) of incremental first costs (e.g., materials, labor, and installation for energy-efficient features) against future benefits including energy cost savings, maintenance adjustments, and replacement costs for components with shorter lifespans.[118] These analyses incorporate annual energy use simulated via tools like EnergyPlus across prototype buildings and U.S. climate zones, with energy prices derived from EIA data and escalated per NIST guidelines.[118] Key parameters include a 30-year study period for public and private scenarios (with real discount rates of 3.0% for public and nominal rates around 6-9.34% for private, per ASHRAE guidelines), and metrics such as NPV (positive values indicate cost-effectiveness), savings-to-investment ratio (SIR ≥1.0), and simple payback period.[118] An additional ASHRAE scalar method evaluates over 40 years, comparing cumulative discounted costs to a scalar limit (e.g., 18.2-22.24 years depending on heating/cooling dominance).[118] National evaluations of recent editions demonstrate positive lifecycle economics. For instance, the transition to ASHRAE 90.1-2022 from 90.1-2019 yields an average annual energy cost savings of $2.58 per square foot, with incremental costs of $0.59–$1.69 per square foot, resulting in a national weighted NPV of $2.56 per square foot and a simple payback of 6.1 years across prototypes and climates.[116] State-level assessments align, as seen in New Jersey's adoption of 90.1-2019 over 90.1-2016, which projects $0.048 per square foot in annual energy savings, $3.27–$3.76 per square foot in LCC net savings (public/private), and statewide NPV energy savings of $410 million over 30 years.[119] These modeled evaluations consistently conclude that ASHRAE 90.1 compliance is cost-effective, with energy savings outweighing upfront investments under standard assumptions, supporting DOE's determinations for federal building baselines and state code adoptions.[116][118] However, results depend on discount rates, energy price forecasts, and exclusion of non-modeled factors like property taxes in base cases (though added in private scenarios at 2.04% national average).[118]DOE Determinations on Cost-Effectiveness
The U.S. Department of Energy (DOE) evaluates the cost-effectiveness of updates to ASHRAE Standard 90.1 as part of its statutory responsibilities under the Energy Conservation and Production Act (ECPA) to determine whether new editions improve energy efficiency in commercial buildings, thereby qualifying as model codes for state and local adoption.[86] Separately, under the Energy Policy and Conservation Act (EPAct), DOE assesses cost-effectiveness for federal building standards, requiring adoption of ASHRAE 90.1 updates if they enhance efficiency without excessive costs.[95] These determinations rely on analyses conducted by Pacific Northwest National Laboratory (PNNL), incorporating energy simulations and economic metrics to compare updated standards against prior versions.[120] DOE's methodology for cost-effectiveness includes life-cycle cost analysis (LCCA) over a 30-year period using a 3% real discount rate, the ASHRAE SSPC 90.1 Scalar Method, and simple payback periods, applied to representative prototype buildings (e.g., small office, large office, retail) simulated via EnergyPlus software across multiple U.S. climate zones.[116] Incremental first costs for compliance are estimated from RSMeans data or industry inputs, offset against energy cost savings derived from national average utility rates (e.g., $0.1099/kWh electricity in 2023 analyses).[117] Positive net present value (NPV) savings, savings-to-investment ratios (SIR) exceeding 1, or scalar ratios below economic limits indicate cost-effectiveness, with national weighting based on construction floor area data from 2003–2018.[116] For ASHRAE 90.1-2019 relative to 90.1-2016, DOE's analysis found national weighted-average site energy savings contributing to NPV savings of $4.12/ft², with simple payback periods immediate for most prototypes and up to 8.1 years for small hotels; the scalar ratio was -203 nationally (below the 22.08-year limit), confirming cost-effectiveness across all prototypes and climate zones analyzed.[117] Similarly, for 90.1-2022 versus 90.1-2019, results showed 10.8% national weighted-average site energy savings, NPV of $2.56/ft², and a 6.1-year simple payback, with a scalar ratio of 4.72 (below the 22.24-year limit), deeming it cost-effective nationally for all prototypes in zones 2A through 5A.[116]| Edition Comparison | Site Energy Savings (%) | NPV Savings ($/ft²) | Simple Payback (years) | Scalar Ratio |
|---|---|---|---|---|
| 90.1-2019 vs. 2016 | Contributes to positive LCC | 4.12 (national weighted) | 0–8.1 | -203 |
| 90.1-2022 vs. 2019 | 10.8 (national weighted) | 2.56 (national weighted) | 6.1 | 4.72 |