Search

Your search keyword '"Zero-energy building"' showing total 186 results
Start Over Descriptor "Zero-energy building" Publisher office of scientific and technical information (osti)
186 results on '"Zero-energy building"'

1. Open Building Control

Author

Jianjun Hu, Michael Wetter, Philip Haves, Paul Ehrlich, Milica Grahovac, Kun Zhang, and Antoine Gautier

Subjects
Flexibility (engineering), Zero-energy building, Computer science, Process (engineering), business.industry, Control (management), ASHRAE 90.1, Control logic, Software engineering, business, Formal verification, Building energy simulation
Abstract

Author(s): Wetter, Michael; Ehrlich, Paul; Gautier, Antoine; Grahovac, Milica; Haves, Philip; Hu, Jianjun; Zhang, Kun | Abstract: Best practice control sequences are often not implemented correctly, or are not implemented at all, in large commercial buildings. This typically leads to 10-30 percent energy waste, along with reduced occupant productivity and unnecessary equipment wear. The current process of designing and implementing such control sequences is a manual process that starts with designers who often don’t have adequate training, then requires controls programmers to interpret and program a verbose written sequence. This process has been shown to fail to deliver high performance control sequences at scale. The Open Building Control project digitizes the current control delivery process. The project is developing tools for system designers to select control sequences, assess their energy performance and load flexibility potential using whole building simulation, specify the sequence for implementation using machine-to-machine translation by a control provider and formally testing the as-installed sequences by a commissioning agent. The project developed tools for each stage of this delivery process. The key innovation of the project is the development of the Control Description Language, a language that allows such a digitized control delivery process with end-to-end verification. Libraries of control sequences have been implemented using the Control Description Language, and their performance has been demonstrated using whole building energy simulation. An automated translation of such sequences to a commercial control product line has been conducted using a prototype translator. Tools for formal verification of as-installed control sequences relative to their specification have been developed and demonstrated. The American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) started the process of forming a committee to make this language an ASHRAE/ANSI Standard. This new standard will complement existing and emerging ASHRAE standards for building communication and semantic modeling by providing a standard for expressing the control logic - the actual brain of the building. We expect this language and the process it enables to be an important contribution to the deployment of high performance building control sequences at scale because it allows taming the complexity of the control delivery process, which is continually increasing due to the need for higher performance and increased load flexibility to meet goals for net zero energy and increased renewable integration.

Published
2021

4. Efficient and Zero Net Energy-Ready Plug Loads

Author

Richard E. Brown, Richard Liou, Alan Meier, Seth R. Sanders, Margarita Kloss, Hidemitsu Koyanagi, Leo Rainer, Daniel L. Gerber, and Aditya Khandekar

Subjects
Zero-energy building, Computer science, business.industry, Range (aeronautics), The Internet, Standby power, business, Energy (signal processing), ADITYA, Efficient energy use, Power (physics), Reliability engineering
Abstract

Author(s): Meier, Alan; Brown, Richard E; Gerber, Daniel; Khandekar, Aditya; Kloss, Margarita; Koyanagi, Hidemitsu; Liou, Richard; Rainer, Leo; SANDERS, Seth | Abstract: Plug loads are the devices plugged into common electrical outlets. Modern buildings contain hundreds of these devices which, together, are responsible for at least 25 percent of the energy use in California buildings. Energy consumed by plug loads is increasing because the “Internet of Things” is, to a great extent, the “Internet of Plug Loads.” This project developed technologies that will reduce the energy use of plug loads. Two crosscutting strategies were investigated in detail: (1) technologies to reduce standby power use to near zero, and (2) methods to increase the use of direct current (DC) as a power source. Two new approaches to reduce standby to near zero were developed and have potential applicability to a wide range of devices. Prototype DC appliances were developed to demonstrate energy savings by bypassing power supplies and avoiding other losses. Networks of DC-powered devices can save even more energy and provide other benefits, such as resiliency during power outages. A unique category of energy-using devices was identified that provide life safety, health, and security to building occupants. Their installation or use is dictated by building codes, health providers, insurance companies, and other entities—none of whom would ordinarily prioritize energy efficiency. In the case of ground fault circuit interrupts (GFCIs), savings of 80 percent appear possible, simply by adopting the most efficient designs. Home medical equipment, particularly oxygen concentrators, are a rising category of energy use where significant savings are possible. This report also reviews the codes, standards, and other policies that affect energy use of plug loads.

Published
2019

6. Federal New Buildings Handbook for Net Zero Energy, Water, and Waste

Author

Robin S. Sullivan, Katherine L. McMordie Stoughton, Donna J. Hostick, Amy E. Solana, Deniz I. Demirkanli, and Kimberly M. Fowler

Subjects
Consumption (economics), Energy conservation, Zero-energy building, Environmental engineering, Environmental science
Published
2017

8. Christmas Valley Renewable Energy Assessment

Author

Robert Del Mar

Subjects
Energy conservation, Outreach, Engineering, Energy development, Zero-energy building, Waste management, business.industry, Environmental protection, business, Solar energy, Geothermal gradient, Renewable energy
Published
2017

12. Technical Feasibility Study for Zero Energy K-12 Schools

Author

Daniel Studer, Eric Bonnema, Shanti Pless, David Goldwasser, and Paul Torcellini

Subjects
Energy conservation, Architectural engineering, Engineering, Technical feasibility, Zero-energy building, business.industry, Energy intensity, Environmental resource management, business, Energy engineering, Energy accounting, Efficient energy use, Renewable energy
Abstract

A simulation-based technical feasibility study was completed to show the types of technologies required to achieve ZEB status with this building type. These technologies are prioritized across the building's subsystem such that design teams can readily integrate the ideas. Energy use intensity (EUI) targets were established for U.S. climate zones such that K-12 schools can be zero-ready or can procure solar panels or other renewable energy production sources to meet the zero energy building definition. Results showed that it is possible for K-12 schools to achieve zero energy when the EUI is between 20 and 26 kBtu/ft2/yr. Temperate climates required a smaller percentage of solar panel coverage than very hot or very cold climates. The paper provides a foundation for technically achieving zero energy schools with a vision of transforming the school construction market to mainstream zero energy buildings within typical construction budgets.

Published
2016

13. Accounting Methodology for Source Energy of Non-Combustible Renewable Electricity Generation

Author

Paul Donohoo-Vallett

Subjects
Engineering, Zero-energy building, Renewable energy credit, Energy development, Waste management, business.industry, Intermittent energy source, Environmental economics, business, Feed-in tariff, Energy engineering, Energy accounting, Renewable energy
Abstract

As non-combustible sources of renewable power (wind, solar, hydro, and geothermal) do not consume fuel, the “source” (or “primary”) energy from these sources cannot be accounted for in the same manner as it is for fossil fuel sources. The methodology chosen for these technologies is important as it affects the perception of the relative size of renewable source energy to fossil energy, affects estimates of source-based building energy use, and overall source energy based metrics such as energy productivity. This memo reviews the methodological choices, outlines implications of each choice, summarizes responses to a request for information on this topic, and presents guiding principles for the U.S. Department of Energy, (DOE) Office of Energy Efficiency and Renewable Energy (EERE) to use to determine where modifying the current renewable source energy accounting method used in EERE products and analyses would be appropriate to address the issues raised above.

Published
2016

14. Energy Innovations for Healthy Buildings

Author

Edward A. Bogucz

Subjects
Energy conservation, Engineering, Zero-energy building, business.industry, Environmental economics, business, Environmental planning, Energy engineering, Energy (signal processing), Efficient energy use
Published
2016

16. Role of Solar Water Heating in Multifamily Zero Energy Homes

Author

James Williamson and Robb Aldrich

Subjects
Consumption (economics), Engineering, Zero-energy building, Incentive, Apartment, business.industry, Fossil fuel, Environmental engineering, Cost approach, Solar water heating, Environmental economics, business, Market penetration
Abstract

Solar domestic hot water (SDHW) systems have been installed on buildings for decades, but because of relatively high costs they have not achieved significant market penetration in most of the country. As more buildings move towards zero net energy consumption, however, many designers and developers are looking more closely at SDHW. In multifamily buildings especially, SDHW may be more practical for several reasons: 1) When designing for zero net energy consumption, solar water heating may be part of the lowest cost approach to meet water heating loads; 2) Because of better scale, SDHW systems in multifamily buildings cost significantly less per dwelling than in single-family homes; 3) Many low-load buildings are moving away from fossil fuels entirely. SDHW savings are substantially greater when displacing electric resistance water heating; and 4) In addition to federal tax incentives, some states have substantial financial incentives that dramatically reduce the costs (or increase the benefits) of SDHW systems in multifamily buildings. With support from the U.S. DOE Building America program, the Consortium for Advanced Residential Buildings (CARB) worked with a developer in western Massachusetts to evaluate a SDHW system on a 12-unit apartment building. Olive Street Development completed construction in spring of 2014, andmore » CARB has been monitoring performance of the water heating systems since May 2014.« less

Published
2016

17. University of Louisville Research and Energy Independence Program

Author

Mahendra K. Sunkara

Subjects
Engineering, Architectural engineering, Energy development, Zero-energy building, Primary energy, business.industry, Energy independence, Solar energy conversion, Biomass fuels, business, Renewable energy storage, Management
Published
2016

19. SEE Action Guide for States: Energy Efficiency as a Least-Cost Strategy to Reduce Greenhouse Gases and Air Pollution and Meet Energy Needs in the Power Sector

Author

Emily Martin Fadrhonc, Lisa Schwartz, Greg Leventis, Molly Roy, Johanna Zetterberg, Christopher A. James, Ken Colburn, John shenot, and Steven R. Schiller

Subjects
Energy conservation, Weatherization, Zero-energy building, Greenhouse gas, Environmental engineering, Economics, Environmental economics, Energy engineering, Energy accounting, Energy policy, Efficient energy use
Published
2016

20. BEopt-CA (Ex) -- A Tool for Optimal Integration of EE/DR/ES+PV in Existing California Homes. Cooperative Research and Development Final Report, CRADA Number CRD-11-429

Author

Craig Christensen

Subjects
Demand response, Engineering, Zero-energy building, business.industry, Photovoltaics, Systems engineering, business, Grid, Civil engineering, Solar power, Energy storage, Renewable energy, Efficient energy use
Abstract

Opportunities for combining energy efficiency, demand response, and energy storage with PV are often missed, because the required knowledge and expertise for these different technologies exist in separate organizations or individuals. Furthermore, there is a lack of quantitative tools to optimize energy efficiency, demand response and energy storage with PV, especially for existing buildings. Our goal is to develop a modeling tool, BEopt-CA (Ex), with capabilities to facilitate identification and implementation of a balanced integration of energy efficiency (EE), demand response (DR), and energy storage (ES) with photovoltaics (PV) within the residential retrofit market. To achieve this goal, we will adapt and extend an existing tool -- BEopt -- that is designed to identify optimal combinations of efficiency and PV in new home designs. In addition, we will develop multifamily residential modeling capabilities for use in California, to facilitate integration of distributed solar power into the grid in order to maximize its value to California ratepayers. The project is follow-on research that leverages previous California Solar Initiative RD&D investment in the BEopt software. BEopt facilitates finding the least cost combination of energy efficiency and renewables to support integrated DSM (iDSM) and Zero Net Energy (ZNE) in California residential buildings. However,more » BEopt is currently focused on modeling single-family houses and does not include satisfactory capabilities for modeling multifamily homes. The project brings BEopt's existing modeling and optimization capabilities to multifamily buildings, including duplexes, triplexes, townhouses, flats, and low-rise apartment buildings.« less

Published
2016

21. Heat pump concepts for nZEB Technology developments, design tools and testing of heat pump systems for nZEB in the USA: Country report IEA HPT Annex 40 Task 2, Task 3 and Task 4 of the USA

Author

Dustin G. Poppendieck, William M. Healy, William V. Payne, Lisa C. Ng, Joshua D. Kneifel, Arthur H. Fanney, Tania Ullah, Brian P. Dougherty, Farhad Omar, and Steven T. Bushby

Subjects
Engineering, Zero-energy building, business.industry, Mechanical engineering, Thermal comfort, Oak Ridge National Laboratory, law.invention, Task (project management), Energy conservation, law, HVAC, Systems engineering, NIST, business, Heat pump
Abstract

The IEA HPT Annex 40 "Heat pump concepts for Nearly Zero Energy Buildings" deals with the application of heat pumps as a core component of the HVAC system for Nearly or Net Zero energy buildings (nZEB). This report covers Task 2 on the system comparison and optimisation and Task 3 dedicated to the development of adapted technologies for nZEB and field monitoring results of heat pump systems in nZEB. In the US team three institutions are involved and have worked on the following projects: The Oak Ridge National Laboratory (ORNL) will summarize development activities through the field demonstration stage for several integrated heat pump (IHP) systems electric ground-source (GS-IHP) and air-source (AS-IHP) versions and an engine driven AS-IHP version. The first commercial GS-IHP product was just introduced to the market in December 2012. This work is a contribution to Task 3 of the Annex. The University of Maryland will contribute a software development project to Task 2 of the Annex. The software ThermCom evaluates occupied space thermal comfort conditions accounting for all radiative and convective heat transfer effects as well as local air properties. The National Institute of Standards and Technology (NIST) is working on a field study effort onmore » the NIST Net Zero Energy Residential Test Facility (NZERTF). This residential building was constructed on the NIST campus and officially opened in summer 2013. During the first year, between July 2013 and June 2014, baseline performance of the NZERTF was monitored under a simulated occupancy protocol. The house was equipped with an air-to-air heat pump which included a dedicated dehumidification operating mode. Outdoor conditions, internal loads and modes of heat pump operation were monitored. Field study results with respect to heat pump operation will be reported and recommendations on heat pump optimization for a net zero energy building will be provided. This work is a contribution to Task 3 of the Annex.« less

Published
2015

22. Photovoltaic at Hollywood and Desert Breeze Recreational Centers

Author

Shane Ammerman

Subjects
Engineering, Zero-energy building, business.industry, Photovoltaic system, Operations management, Environmental economics, business, Feed-in tariff, Solar energy, Electricity retailing, Solar power, Grid parity, Renewable energy
Abstract

Executive Summary Renewable Energy Initiatives for Clark County Parks and Recreation Solar Project DOE grant # DE-EE0003180 In accordance with the goals of the Department of Energy (DOE) Office of Energy Efficiency and Renewable Energy for promoting solar energy as clean, carbon-free and cost-effective, the County believed that a recreational center was an ideal place to promote solar energy technologies to the public. This project included the construction of solar electricity generation facilities (40kW) at two Clark County facility sites, Desert Breeze Recreational Center and Hollywood Recreational Center, with educational kiosks and Green Boxes for classroom instruction. The major objectives and goals of this Solar Project include demonstration of state of the art technologies for the generation of electricity from solar technology and the creation of an informative and educational tool in regards to the benefits and process of generating alternative energy. Clark County partnered with Anne Johnson (design architect/consultant), Affiliated Engineers Inc. (AEI), Desert Research Institute (DRI), and Morse Electric. The latest photovoltaic technologies were used in the project to help create the greatest expected energy savings for60443 each recreational center. This coupled with the data created from the monitoring system will help Clark County and NREL further understandmore » the real time outputs from the system. The educational portion created with AEI and DRI incorporates material for all ages with a focus on K - 12. The AEI component is an animated story telling the fundamentals of how sunlight is turned into electricity and DRI‘s creation of Solar Green Boxes brings environmental education into the classroom. In addition to the educational component for the public, the energy that is created through the photovoltaic system also translates into saved money and health benefits for the general public. This project has helped Clark County to further add to its own energy reduction goals created by the energy management agenda (Resolution to Encourage Sustainability) and the County’s Eco-initiative. Each site has installed photovoltaic panels on the existing roof structures that exhibit suitable solar exposure. The generation systems utilize solar energy creating electricity used for the facility’s lighting system and other electrical requirements. Unused electricity is sent to the electric utility grid, often at peak demand times. Educational signage, kiosks and information have been included to inform and expand the public’s understanding of solar energy technology. The Solar Green Boxes were created for further hands on classroom education of solar power. In addition, data is sent by a Long Term PV performance monitoring system, complete with data transmission to NREL (National Renewable Energy Laboratory), located in Golden, CO. This system correlates local solar irradiance and weather with power production. The expected outcomes of this Solar Project are as follows: (1) Successful photovoltaic electricity generation technologies to capture solar energy in a useful form of electrical energy. (2) Reduction of greenhouse gas emissions and environmental degradation resulting from reduced energy demand from traditional electricity sources such as fossil fuel fired and nuclear power plants. (3) Advance the research and development of solar electricity generation. (4) The education of the general public in regards to the benefits of environmentally friendly electricity generation and Clark County’s efforts to encourage sustainable living practices. (5) To provide momentum for the nexus for future solar generation facilities in Clark County facilities and buildings and further the County’s energy reduction goals. (6) To ultimately contribute to the reduction of dependence on foreign oil and other unsustainable sources of energy. This Solar Project addresses several objectives and goals of the U.S. Department of Energy’s Solar Energy Technology Program. The project improves the integration and performance of solar electricity directly through implementation of cutting edge technology. The project further addresses this goal by laying important ground work and infrastructure for integration into the utility grid in future related projects. There will also be added security, reliability, and diversity to the energy system by providing and using reliable, secure, distributed electricity in Clark County facilities as well as sending such electricity back into the utility electric grid. A final major objective met by the Solar Project will be the displacement of energy derived by fossil fuels with clean renewable energy created by photovoltaic panels.« less

Published
2015

23. Implementing a Zero Energy Ready Home Multifamily Project

Author

Alea German and David Springer

Subjects
Engineering, Architectural engineering, Incentive, Zero-energy building, Leverage (negotiation), business.industry, Process (engineering), Perfect competition, Certification, Business case, business, Environmental planning, Efficient energy use
Abstract

Building cost-effective, high-performance homes that provide superior comfort, health, and durability is the goal of the U.S. Department of Energy’s (DOE’s) Zero Energy Ready Home (ZERH) program. Building America research and other innovative programs throughout the country have addressed many of the technical challenges of building to the ZERH standard. The cost-effectiveness of measure packages that result in 30% source energy savings compared to a code-compliant home have been demonstrated. However, additional challenges remain, particularly with respect to convincing production builders of the strong business case for ZERH. The Alliance for Residential Building Innovation (ARBI) team believes that the keys to successfully engaging builders and developers in the California market are to help them leverage development agreement requirements, code compliance requirements, incentives, and competitive market advantages of ZERH certification, and navigate through this process. A primary objective of this project was to gain a highly visible foothold for residential buildings that are built to the DOE ZERH specification that can be used to encourage participation by other California builders. This report briefly describes two single-family homes that were ZERH certified and focuses on the experience of working with developer Mutual Housing on a 62-unit multifamily community at the Spring Lakemore » subdivision in Woodland, California. The Spring Lake project is expected to be the first ZERH-certified multifamily project in the country. This report discusses the challenges encountered, lessons learned, and how obstacles were overcome.« less

Published
2015

24. High-Performance Ducts in Hot-Dry Climates

Author

Rick Chitwood, Alea German, Elizabeth Weitzel, and Marc Hoeschele

Subjects
Engineering, Zero-energy building, Residential energy, business.industry, HVAC, Home program, Duct (flow), Attic, business, Civil engineering, Automotive engineering, Test data, Cost database
Abstract

Duct thermal losses and air leakage have long been recognized as prime culprits in the degradation of heating, ventilating, and air-conditioning (HVAC) system efficiency. Both the U.S. Department of Energy’s Zero Energy Ready Home program and California’s proposed 2016 Title 24 Residential Energy Efficiency Standards require that ducts be installed within conditioned space or that other measures be taken to provide similar improvements in delivery effectiveness (DE). Pacific Gas & Electric Company commissioned a study to evaluate ducts in conditioned space and high-performance attics (HPAs) in support of the proposed codes and standards enhancements included in California’s 2016 Title 24 Residential Energy Efficiency Standards. The goal was to work with a select group of builders to design and install high-performance duct (HPD) systems, such as ducts in conditioned space (DCS), in one or more of their homes and to obtain test data to verify the improvement in DE compared to standard practice. Davis Energy Group (DEG) helped select the builders and led a team that provided information about HPD strategies to them. DEG also observed the construction process, completed testing, and collected cost data.

Published
2015

25. Achieving a Net Zero Energy Retrofit – in a humid, temperate climate – lessons from the University of Hawai’i at M&#257noa

Author

Cindy Regnier, Ari Harding, and Alastair Robinson

Subjects
Energy conservation, Engineering, Zero-energy building, business.industry, Clean energy, Temperate climate, Square (unit), Energy consumption, National laboratory, business, Design collaboration, Civil engineering
Abstract

The University of Hawai’i at M&#257noa (UHM) partnered with the US Department of Energy (DOE) and the Hawai`i Clean Energy Initiative to develop and implement solutions to retrofit exiting buildings to reduce energy consumption by at least 30% as part of DOE’s Commercial Building Partnerships (CBP) Program1. Kuykendall Hall, located on the UHM campus in Honolulu, was the focus of a CBP analysis and design collaboration among the University of Hawai’i, their consultants, and Lawrence Berkeley National Laboratory (LBNL). Kuykendall Hall consists of two 1960s-era wings – a four-story wing containing classrooms, and a seven-story tower containing offices – with a total floor area of approximately 76,000 square feet (ft²).

Published
2015

26. Solar Power. Policy Overview and Good Practices

Author

Terri Walters, Sarah Booth, Sadie Cox, and Sean Esterly

Subjects
Nameplate capacity, Energy development, Zero-energy building, Commerce, business.industry, Photovoltaics, Economics, Environmental economics, business, Feed-in tariff, Solar power, Grid parity, Renewable energy
Abstract

As global electricity demand increases, governments are designing and implementing policies to scale up and catalyze renewable energy, which now meets 22% of global electricity demand (REN21 2014). Solar technologies are a critical component of this expanded deployment, and they have experienced unprecedented growth in recent years. As presented in Figure 1, solar prices have decreased significantly over the last decade (REN21 2014) and in 2013, new capacity installation of solar electricity from photovoltaics (PV) 1 surpassed all other renewable energy technologies worldwide—excluding hydropower—with 39 gigawatts installed that year. Concentrating solar thermal power,2 although it still represents a fairly nascent market, also continues to expand as installed capacity increased by 36% in 2013 compared to 2012. In addition to meeting energy demand in an increasingly cost-effective manner, solar deployment can also support critical economic, social, and environmental development goals (Flavin and Hull Aeck, n.d.).

Published
2015

27. Community Power Works Final Report and Conclusions

Author

Christie Baumel

Subjects
Weatherization, Consumption (economics), Architectural engineering, Engineering, Zero-energy building, business.industry, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Energy engineering, Civil engineering, Power (social and political), Energy conservation, Technical report, business, Efficient energy use
Abstract

This is the final technical report for the City of Seattle's Community Power Works program, funded through the US DOE Better Buildings grant program.

Published
2015

28. EcoVillage: A Net Zero Energy Ready Community

Author

L. Arena and O. Faakye

Subjects
Engineering, Architectural engineering, Zero-energy building, Apartment, business.industry, Ecovillage, Design standard, Passive house, Green building, Passive solar building design, Environmental design, business
Abstract

CARB is working with the EcoVillage co-housing community in Ithaca, New York, on their third neighborhood called the Third Residential EcoVillage Experience (TREE). This community scale project consists of 40 housing units --15 apartments and 25 single family residences. The community is pursuing certifications for DOE Zero Energy Ready Home, U.S. Green Building Council Leadership in Energy and Environmental Design Gold, and ENERGY STAR for the entire project. Additionally, seven of the 25 homes, along with the four-story apartment building and community center, are being constructed to the Passive House (PH) design standard.

Published
2015

29. Roadmap for the Future of Commercial Energy Codes

Author

Philip R. Hart, Rahul A. Athalye, Jian Zhang, and Michael I. Rosenberg

Subjects
Flexibility (engineering), Engineering, Engineering drawing, Zero-energy building, Risk analysis (engineering), Occupancy, business.industry, Component (UML), Certificate of occupancy, Code (cryptography), business, Baseline (configuration management), Bridge (nautical)
Abstract

Building energy codes have significantly increased building efficiency over the last 38 years, since the first national energy code was published in 1975. The most commonly used path in energy codes, the prescriptive path, appears to be reaching a point of diminishing returns. The current focus on prescriptive codes has limitations including significant variation in actual energy performance depending on which prescriptive options are chosen, a lack of flexibility for designers and developers, the inability to handle optimization that is specific to building type and use, the inability to account for project-specific energy costs, and the lack of follow-through or accountability after a certificate of occupancy is granted. It is likely that an approach that considers the building as an integrated system will be necessary to achieve the next real gains in building efficiency. This report provides a high-level review of different formats for commercial building energy codes, including prescriptive, prescriptive packages, capacity constrained, outcome based, and predictive performance approaches. This report also explores a next generation commercial energy code approach that places a greater emphasis on performance-based criteria. For commercial building energy codes to continue to progress as they have over the last 40 years, the next generation of more » building codes will need to provide a path that is led by energy performance, ensuring a measurable trajectory toward net zero energy buildings. This report outlines a vision to serve as a roadmap for future commercial code development. That vision is based on code development being led by a specific approach to predictive energy performance combined with building-specific prescriptive packages that are designed both to be cost-effective and to achieve a desired level of performance. Compliance with this new approach can be achieved by either meeting the performance target, as demonstrated by whole building energy modeling, or by choosing one of the prescriptive packages. This review of the possible code formats (further described in Section 2.1) arrives at the following conclusions: • Predictive performance with energy use index (EUI) targets falls short as a code mechanism, since it is difficult to match individual building use to broad EUI targets. • Outcome-based codes–while an essential approach that should be applied to all buildings–are not a substitute for design and construction energy codes that focus on compliance at occupancy. • For a design and construction code, a differential predictive performance method with a stable and independent baseline provides the best accuracy and potential for a highly automated approach that could eventually be applied to most buildings. • Current performance codes that have a dependent and time-variable baseline should be replaced by a differential predictive performance method with a stable and independent baseline. • At some point in the future, tools that demonstrate predictive performance compliance may become so simple that there will no longer be a need for any prescriptive path. • As a bridge, prescriptive packages can provide a transition from the current component prescriptive approach to a performance only code, while providing flexibility and improved energy equivalency. « less

Published
2015

30. Aspinall Courthouse: GSA's Historic Preservation and Net-Zero Renovation Case Study

Author

S. Hayter, R. Chang, Shanti Pless, C. Smith-Larney, J. Sielcken, and Eliza Hotchkiss

Subjects
Engineering, Government, Zero-energy building, business.industry, business, Civil engineering, Zero (linguistics), Renewable energy
Abstract

The federal government is mandated with improving efficiency of buildings, incorporating renewable energy, and achieving net-zero energy operations where possible. These challenges led GSA to consider aligning historic preservation renovations with net-zero energy goals. The Wayne N. Aspinall Federal Building and U.S. Courthouse (Aspinall Courthouse), in Grand Junction, Colorado, is an example of a renovation project that aimed to accomplish both historic preservation and net-zero energy goals.

Published
2014

31. NASA Net Zero Energy Buildings Roadmap

Author

Jennifer Scheib, B. Hendron, Paul Torcellini, Shanti Pless, and M. Slovensky

Subjects
Energy conservation, Engineering, Zero-energy building, business.industry, Energy intensity, Mechanical engineering, business, Energy engineering, Civil engineering, Energy accounting
Published
2014

32. Final Technical Report for the Net-Zero Energy Commercial Buildings Consortium

Author

Sandy Fazeli

Subjects
Engineering, Engineering management, Government, Zero-energy building, business.industry, Software deployment, Emerging technologies, General partnership, Technical report, Energy Independence and Security Act of 2007, Operations management, The Internet, business
Abstract

The Commercial Buildings Consortium (CBC) was established in 2009, under the chairmanship of the National Association of State Energy Officials (NASEO), as a supporting organization to the Commercial Buildings Initiative (CBI). The CBI was created by Congress through the Energy Independence and Security Act of 2007 (EISA) and launched by the Department of Energy (DOE) in 2008 with the goal to “develop and disseminate technologies, practices, and policies for establishment of zero net energy commercial buildings.”. The impact of the CBC since 2009 has been multifold, resulting in increased collaboration, increased innovation, and increased demonstration and deployment. During the project performance period of 2009-2014, the CBC provided an organizational framework for sustained public-private collaboration among more than 600 commercial building professionals, researchers and educators, utilities, and government agencies at federal, state, and local level. The CBC’s research has identified emerging technologies, market strategies, and innovative public and corporate policies to help advance CBI’s zero-net-energy. Finally, the CBC worked in close partnership with DOE’s commercial building teams and the Better Buildings Alliances to identify opportunities for proving out and deploying energy-saving technologies and practices.

Published
2014

34. Energy Savings from GSA's National Deep Retrofit Program

Author

John A Shonder

Subjects
Consumption (economics), Engineering, Zero-energy building, business.industry, Square foot, Sample (statistics), Operations management, Environmental economics, Project management office, business, Deep energy retrofit, Energy (signal processing), Renewable energy
Abstract

Under its National Deep Energy Retrofit (NDER) program, the U.S. General Services Administration (GSA) awarded 10 ESPC projects with the objectives of using innovative technologies and renewable energy technologies, and moving buildings toward net zero energy consumption. This report analyzes data on energy savings from the 10 NDER projects, and compares them with the savings of a sample of other recently awarded Federal ESPC projects. It is shown that by emphasizing the need for deeper energy savings, and by the establishment of a central Project Management Office (PMO) to provide authoritative contracting, technical and pricing assistance, the NDER projects achieved an average level of savings more than twice that of the other Federal ESPC projects. The level of savings achieved in each project seems to be dependent more on the availability of ECMs at the site than on energy price, energy cost per square foot, pre-retrofit EUI or the length of the contract term. This suggests that GSA can achieve similar results in a wide variety of building

Published
2014

35. Final Report for Clean, Reliable, Affordable Energy that Reflects the Values of the Pinoleville Pomo Nation

Author

Zachary N Sampsel and Lenora Steele

Subjects
Energy conservation, Engineering, Zero-energy building, Wind power, Energy development, business.industry, Intermittent energy source, Alternative energy, Environmental economics, business, Civil engineering, Efficient energy use, Renewable energy
Abstract

This report aims to present and analyze information on the potential of renewable energy power systems and electric vehicle charging near the Pinoleville Pomo Nation in Ukiah, California to provide an environmentally-friendly, cost-effective energy and transportation options for development. For each renewable energy option we examine, solar, wind, microhydro, and biogas in this case, we compiled technology and cost information for construction, estimates of energy capacity, and data on electricity exports rates.

Published
2014

36. West Village Student Housing Phase I: Apartment Monitoring and Evaluation

Author

C. Bell, M. Hoeschele, A. German, and B. Dakin

Subjects
Engineering, Architectural engineering, Zero-energy building, Apartment, business.industry, Energy modeling, Monitoring and evaluation, Attic, law.invention, law, HVAC, business, Efficient energy use, Heat pump
Abstract

Building America team Alliance for Residential Building Innovation (ARBI) worked with the University of California, Davis (UC Davis) and the developer partner West Village Community Partnership (WVCP) to evaluate performance on 192 student apartments completed in September, 2011 as part of Phase I of the multi-purpose West Village project. West Village, the largest planned zero net energy community in the United States. The campus neighborhood is designed to enable faculty, staff and students to affordably live near campus, take advantage of environmentally friendly transportation options, and participate fully in campus life. The aggressive energy efficiency measures that are incorporated in the design contribute to source energy reductions of 37% over the B10 Benchmark. The energy efficiency measures that are incorporated into these apartments include increased wall & attic insulation, high performance windows, high efficiency heat pumps for heating and cooling, central heat pump water heaters (HPWHs), 100% high efficacy lighting, and ENERGY STAR major appliances. Results discuss how measured energy use compares to modeling estimates over a 10 month monitoring period and includes a cost effective evaluation.

Published
2014

37. Somerset County Renewable Energy Initiative

Author

Denise Katula

Subjects
Zero-energy building, Geography, Environmental protection, business.industry, Natural resource economics, Feed-in tariff, Solar energy, business, Renewable energy
Published
2014

38. ReEDS Modeling of the President’s 2020 U.S. Renewable Electricity Generation Goal (Presentation)

Author

Trieu Mai, Owen Zinaman, Gian Porro, Rachel Gelman, and Eric Lantz

Subjects
Engineering, Energy development, Renewable energy credit, Energy subsidies, Zero-energy building, Economy, business.industry, Environmental economics, business, Electricity retailing, Feed-in tariff, Energy policy, Renewable energy
Abstract

President Obama announced in 2012 an Administration Goal for the United States to double aggregate renewable electricity generation from wind, solar, and geothermal sources by 2020. This analysis, using the Regional Energy Deployment System (ReEDS) model, explores a full range of future renewable deployment scenarios out to 2020 to assess progress and outlook toward this goal. Under all modeled conditions, consisting of 21 scenarios, the Administration Goal is met before 2020, and as early as 2015.

Published
2014

40. Renewable Energy: science, politics, and economics

Author

Albert Migliori

Subjects
Energy subsidies, Zero-energy building, Energy development, Economy, business.industry, Natural resource economics, Intermittent energy source, Economics, Environmental impact of the energy industry, Feed-in tariff, business, Energy policy, Renewable energy
Published
2014

41. Monitoring and Characterization of Miscellaneous Electrical Loads in a Large Retail Environment

Author

J. Smith, E. Rader, C. Lobato, S. Frank, M. Sheppy, Nicholas Long, and L. Gentile-Polese

Subjects
Energy conservation, Engineering, Zero-energy building, Primary energy, Waste management, business.industry, Greenhouse gas, Production (economics), Electricity, Nuclear power, business, Efficient energy use
Abstract

Buildings account for 40% of primary energy consumption in the United States (residential 22%; commercial 18%). Most (70% residential and 79% commercial) is used as electricity. Thus, almost 30% of U.S. primary energy is used to provide electricity to buildings. Plug loads play an increasingly critical role in reducing energy use in new buildings (because of their increased efficiency requirements), and in existing buildings (as a significant energy savings opportunity). If all installed commercial building miscellaneous electrical loads (CMELs) were replaced with energy-efficient equipment, a potential annual energy saving of 175 TWh, or 35% of the 504 TWh annual energy use devoted to MELs, could be achieved. This energy saving is equivalent to the annual energy production of 14 average-sized nuclear power plants. To meet DOE's long-term goals of reducing commercial building energy use and carbon emissions, the energy efficiency community must better understand the components and drivers of CMEL energy use, and develop effective reduction strategies. These goals can be facilitated through improved data collection and monitoring methodologies, and evaluation of CMELs energy-saving techniques.

Published
2014

42. Colorado Better Buildings Project. Final Report

Author

Lea Yancey and Susie Strife

Subjects
Energy conservation, Finance, Economic growth, Zero-energy building, business.industry, Energy independence, Local government, Economics, Market transformation, Workforce development, business, Block grant, Efficient energy use
Abstract

The Colorado Better Buildings project intended to bring new and existing energy efficiency model programs to market with regional collaboration and funding partnerships. The goals for Boulder County and its program partners were to advance energy efficiency investments, stimulate economic growth in Colorado and advance the state’s energy independence. Collectively, three counties set out to complete 9,025 energy efficiency upgrades in 2.5 years and they succeeded in doing so. Energy efficiency upgrades have been completed in more than 11,000 homes and businesses in these communities. Boulder County and its partners received a $25 million BetterBuildings grant from the U.S. Department of Energy under the American Recovery and Reinvestment Act in the summer of 2010. This was also known as the Energy Efficiency and Conservation Block Grants program. With this funding, Boulder County, the City and County of Denver, and Garfield County set out to design programs for the residential and commercial sectors to overcome key barriers in the energy upgrade process. Since January 2011, these communities have paired homeowners and business owners with an Energy Advisor – an expert to help move from assessment to upgrade with minimal hassle. Pairing this step-by-step assistance with financing incentives has effectively addressed many key barriers, resulting in energy efficiency improvements and happy customers. An expert energy advisor guides the building owner through every step of the process, coordinating the energy assessment, interpreting results for a customized action plan, providing a list of contractors, and finding and applying for all available rebates and low-interest loans. In addition to the expert advising and financial incentives, the programs also included elements of social marketing, technical assistance, workforce development and contractor trainings, project monitoring and verification, and a cloud-based customer data system to coordinate among field advisors and across local governments and local service vendors. A portion of the BetterBuildings grant went to the Metro Mayors Caucus (MMC) who worked in partnership with the Denver Regional Council of Governments (DRCOG) to conduct a series of 10 energy efficiency workshops for local government officials and other interested parties. The workshops helped showcase lessons learned on energy efficiency and helped guide other local governments in the establishment of similar programs. The workshops covered a wide range of energy efficiency and renewable energy topics such as clean energy finance, social mobilization and communications, specific case studies of Colorado towns, energy efficiency codes, net zero buildings and solar power. Since the programs launched in January 2011, these communities have collectively spurred economic investments in energy efficiency, achieved greater than 5:1 leveraging of grant funds, saved energy and reduced greenhouse gas emissions, provided trainings for a robust local energy contractor network, and proved out viable and replicable program models that local utilities and other communities are adopting, with long lasting market transformation.

Published
2013

43. Overview of Opportunities for Co-Location of Solar Energy Technologies and Vegetation

Author

Jordan Macknick, G. Hill, and Brenda Beatty

Subjects
Engineering, Zero-energy building, Electricity generation, Land use, Photovoltaics, business.industry, Environmental resource management, Vegetation, business, Solar energy, Civil engineering, Grid parity, Renewable energy
Abstract

Large-scale solar facilities have the potential to contribute significantly to national electricity production. Many solar installations are large-scale or utility-scale, with a capacity over 1 MW and connected directly to the electric grid. Large-scale solar facilities offer an opportunity to achieve economies of scale in solar deployment, yet there have been concerns about the amount of land required for solar projects and the impact of solar projects on local habitat. During the site preparation phase for utility-scale solar facilities, developers often grade land and remove all vegetation to minimize installation and operational costs, prevent plants from shading panels, and minimize potential fire or wildlife risks. However, the common site preparation practice of removing vegetation can be avoided in certain circumstances, and there have been successful examples where solar facilities have been co-located with agricultural operations or have native vegetation growing beneath the panels. In this study we outline some of the impacts that large-scale solar facilities can have on the local environment, provide examples of installations where impacts have been minimized through co-location with vegetation, characterize the types of co-location, and give an overview of the potential benefits from co-location of solar energy projects and vegetation. The varieties of co-locationmore » can be replicated or modified for site-specific use at other solar energy installations around the world. We conclude with opportunities to improve upon our understanding of ways to reduce the environmental impacts of large-scale solar installations.« less

Published
2013

44. Integrating Solar PV in Utility System Operations

Author

Andrew Mills, Z. Zhou, B-M. Hodge, J. Wu, Audun Botterud, and M. Heaney

Subjects
Energy conservation, Architectural engineering, Engineering, Zero-energy building, Energy subsidies, Operations research, business.industry, Photovoltaic system, business, Feed-in tariff, Solar energy, Renewable energy, Efficient energy use
Abstract

LBNL-XXXX E RNEST O RLANDO L AWRENCE B ERKELEY N ATIONAL L ABORATORY Integrating Solar PV in Utility System Operations A. Mills 1 , A. Botterud 2 , J. Wu 2,4 , Z. Zhou 2 , B-M. Hodge 3 , M. Heany 3 Environmental Energy Technologies Division October 2013 Lawrence Berkeley National Laboratory Argonne National Laboratory National Renewable Energy Laboratory University of Chicago Lawrence Berkeley National Laboratory’s contribution to this work was funded by the U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy (Solar Energy Technologies Office) under Lawrence Berkeley National Laboratory Contract No. DE-AC02-05CH112

Published
2013

45. Simulation Models for Improved Water Heating Systems

Author

Peter W. Grant, Jim Lutz, and Margarita Kloss

Subjects
Transport engineering, Energy conservation, Engineering, Energy subsidies, Zero-energy building, Operations research, business.industry, Energy planning, business, Energy engineering, Energy policy, Renewable energy, Efficient energy use
Abstract

Simulation Models for Improved Water Heating Systems Jim Lutz, Peter Grant, and Margarita Kloss Energy Analysis and Environmental Impacts Department Environmental Energy Technologies Division Lawrence Berkeley National Laboratory Berkeley, CA 94720 December 2013 This work was sponsored by the California Energy Commission, Public Interest Energy Research (PIER) Program, under the National Lab Buildings Energy Efficiency Research Projects Contract No. 500-10-052. This work was supported by the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of Building Technology, State, and Community Programs, of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231.

Published
2013

46. Low Cost Electrochromic Film on Plastic for Net-Zero Energy Buildings

Author

N. Gomez, M. Stowell, T. Vincent, M. Guy, L. Davenport, R. Naranamurthy, J. Schoepski, J. Frey, B. Lanning, R. Schaller, A. Ammarnath, P. Swanson, D. Kershner, and B. Berland

Subjects
Zero-energy building, Materials science, Electrochromism, Engineering physics
Published
2013

47. The Role of Occupant Behavior in Achieving Net Zero Energy: A Demonstration Project at Fort Carson

Author

Kathleen S. Judd, Nicholas Fernandez, Thomas F. Sanquist, and Mary D. Zalesny

Subjects
Energy conservation, Intervention (law), Engineering, Architectural engineering, Zero-energy building, business.industry, Institutional change, Behavior change, Operations management, business
Abstract

This study, sponsored by the U.S. General Services Administration’s Office of Federal High-Performance Green Buildings, aimed to understand the potential for institutional and behavioral change to enhance the performance of buildings, through a demonstration project with the Department of Defense in five green buildings on the Fort Carson, Colorado, Army base. To approach this study, the research team identified specific occupant behaviors that had the potential to save energy in each building, defined strategies that might effectively support behavior change, and implemented a coordinated set of actions during a three-month intervention.

Published
2013

48. Transforming Markets for Energy-Efficient Buildings in China: Final Report on Activity Conducted by the Institute for Market Transformation (IMT) Under Cooperative Agreement DE-FC01-00EE10672 with the U.S. Department of Energy (DOE)

Author

Mark Chao

Subjects
Energy conservation, Climate zones, Engineering, Economic growth, Zero-energy building, business.industry, Market transformation, Accounting, business, China, Efficient energy use
Abstract

This report summarizes activity conducted by the Institute for Market Transformation and a team of American and Chinese partners in development of a new building energy-efficiency code for the transitional climate zone in the People's Republic of China.

Published
2013

49. Utility-Scale Solar 2012: An Empirical Analysis of Project Cost, Performance, and Pricing Trends in the United States

Author

Mark Bolinger and Samantha Weaver

Subjects
Energy conservation, Engineering, Zero-energy building, Energy subsidies, Public economics, business.industry, Environmental economics, Feed-in tariff, business, Solar energy, Energy engineering, Energy policy, Renewable energy
Abstract

LBNL-XXXXX E RNEST O RLANDO L AWRENCE B ERKELEY N ATIONAL L ABORATORY Utility-Scale Solar 2012 An Empirical Analysis of Project Cost, Performance, and Pricing Trends in the United States Mark Bolinger and Samantha Weaver Lawrence Berkeley National Laboratory Environmental Energy Technologies Division September 2013 Download from emp.lbl.gov The work described in this report was funded by the U.S. Department of Energy’s Solar Energy Technologies Office, within the Office of Energy Efficiency and Renewable Energy, under Contract No. DE-AC02- 05CH11231.

Published
2013

50. Transformations, Inc.. Partnering To Build Net-Zero Energy Houses in Massachusetts

Author

D. Bergey, H. Wytrykowska, and K. Ueno

Subjects
Engineering, Architectural engineering, Zero-energy building, Building science, business.industry, Cold climate, General partnership, Air source heat pumps, Sustainable housing, Townsend, business, Corporation
Abstract

Transformations, Inc. is a residential development and building company that has partnered with Building Science Corporation to build new construction net-zero energy houses in Massachusetts under the Building America program. There are three communities that will be constructed through this partnership: Devens Sustainable Housing ("Devens"), The Homes at Easthampton Meadow ("Easthampton") and Phase II of the Coppersmith Way Development ("Townsend"). This report intends to cover all of the single-family new construction homes that have been completed to date. The houses built in these developments are net zero energy homes built in a cold climate. They will contribute to finding answers to specific research questions for homes with high R double stud walls and high efficiency ductless air source heat pump systems ("mini-splits"); allow to explore topics related to the financing of photovoltaic systems and basements vs. slab-on-grade construction; and provide feedback related to the performance of ductless mini-split air source heat pumps.

Published
2013

Catalog

Books, media, physical & digital resources
See catalog results