Research Tracker | Building America Solution Center

Low-Cost Identification and Monitoring of Diverse MELs in Residential and Commercial Buildings with PowerBlade

This project will help address the challenge of identifying loads within the long tail of consumption by integrating the previously developed PowerBlade wireless AC plug-through meters to measure real, reactive, and apparent power with load monitoring based on extracting high-fidelity electrical waveform features to capture power profiles and automatically identify and categorize MELs in a scalable manner.

Low-Cost, Highly Transparent Flexible Low-e Coating Film to Enable Electrochromic Windows with Increased Energy Savings

ITN Energy Systems will develop a low-cost coating film for use on existing "smart" windows. This film will further advance the energy savings potential and appearance of these windows and could result in approximately 2 quads of energy savings annually.

Low-GWP HVAC System with Ultra-Small Centrifugal Compression

Mechanical Solutions, Inc. will develop a residential HVAC system featuring a highly efficient small centrifugal compressor. This project could provide a cheaper, more efficient, more environmentally friendly HVAC option for residential and commercial buildings.

Luminaires for Advanced Lighting in Education

RTI International will develop and demonstrate novel luminaire designs that utilize advanced classroom lighting system technology, demonstrate the benefits of dynamic lighting, and collect feedback from education stakeholders. These efforts could increase the use of next-generation lighting in schools.

Manufacturing Process for OLED Integrated Substrate

PPG Industries, Inc. will develop and demonstrate manufacturing processes that will enable commercialization of a large area and low-cost "integrated substrate" for rigid OLED SSL lighting. Enabling large volume manufacturing with these new processes will grow the OLED market, leading to a potential 1.51 quads of energy savings by 2030.

Market evaluation and detailed energy analysis of the NextAire variable refrigerant volume natural gas-fired heat pump

Gas Technology Institute will develop and conduct advanced modeling of the GHP system in order to provide a detailed assessment of the technology using regional weather data and detailed utility information for several New York locations and building types. The project will include a market assessment of the competitiveness of the variable refrigerant volume (VRV) GHP, including energy and economic benefits, the value of resiliency, and the value of self-powered heating and cooling systems for customers in New York. The Proposer will take into account the energy savings, operating costs, lifecycle costs, and greenhouse gas emissions in order to determine any energy, economic, or environmental merits of GHPs over standard HVAC equipment

Market Focused Commercial and Multi-Family Water Heating and Power

The Contractor seeks to baseline test, install, and evaluate the performance of a 21kW micro-CHP system, that provides hot water and power as a packaged unit, at (2) Host Sites in NY. The proposed System shall feature a synchronous generator and black-start capability. The goal of the project is to provide manufacturers, building owners, and installers information regarding the deployment of micro-CHP systems, in order to promote a sustainable market for micro-CHP systems in NY. Once the Host Sites are selected, the System shall be independently tested and configured and the Host Sites shall be prepared for the proper integration of the Systems on-site. The Systems shall be installed and monitored for 12 months before developing a report to disseminate to the stakeholders.

Materials and Designs for High-Efficacy LED Light Engines

Cree, Inc. will develop high-efficacy, cost-effective LED light engines for next-generation luminaires. The advancements made in this project could lead to more efficient LED lighting options.

Measure Development Study for Extended Motor Products Labeling Initiative (EMPLI) for Circulatory Pumps in Commercial, Industrial and Agricultural Applications

The goal of this project is similar to the Unit Energy Savings (Deemed) Measure Development study with a focus on Circulatory Pumps across sectors. The study will fund the development of the Regional Technical Forum (RTF) workbook to present data to achieve RTF UES Planning Measures for Circulatory Pumps. This project will include data collection and analyses and does not involve field or primary research.

Measurement and Control of Ventilation Rates in Commercial Buildings in California

This project uses modeling to analyze peak energy demand, and indoor air quality advantages of controlled minimum ventilation rates (VR); evaluates multiple technologies applicable to real-time measurement and control of ventilation rates; and uses the results to develop occupancy specific guidelines for using carbon dioxide (CO2) in demand controlled ventilation systems and for measurement of ventilation rates.

Mechanical Dehumidification Using High-Frequency Ultrasonic Vibration

Oak Ridge National Laboratory (ORNL) will investigate a novel dehumidification process to avoid the excessive energy utilized by conventional approaches, through high-frequency mechanical vibration of ultrasonic transducers to eject adsorbed water in a liquid form.

Megawatt Scale Battery Energy Storage System and Renewables Integration

The goal of this proposed effort is to conduct a multi-year testing and demonstration of all types of grid- and renewables-supporting services by a utility-scale battery energy storage system (BESS) at NRELs National Wind Technology Center (NWTC). This work will be conducted as a collaborative effort involving NREL and Powin Energy, the goal of which is to demonstrate via long-term testing the capabilities of BESS technologies to address operational and reliability challenges of integrating large amounts of variable renewable generation into the power system that are caused by resource variability, temporal mismatch between generation and demand, and forecast uncertainty.

Membrane Based Air Conditioning

Dais Analytic Corporation will develop membrane HVAC technology that offers improved energy efficiency and eliminates harmful refrigerants. This technology has the potential to lead to notable energy usage reductions and environmental benefits.

Miniaturized Air to Refrigerant Heat Exchangers

This project will attempt to develop and demonstrate a novel fabrication process that eliminates the use of shadow masks during the OLED deposition process. The proposed system will allow blanket deposition of all organic and cathode layers everywhere on the substrate, eliminating the need for masks.

Miniaturized Air to Refrigerant Heat Exchangers

The University of Maryland will develop a heat exchanger that is 20% better than current designs in terms of size, weight, and performance. This next-generation heat exchanger will be designed for use in heat pumps and air conditioners and will drive energy savings in those applications.

Mobile Efficiency for Plug Load Devices

The goal of the project is to reduce the energy consumption of residential and commercial plug load devices, such as set-top boxes, TVs, computers and game consoles. The project will leverage mobile design practices, hardware components and energy management software kernels, and prove their effectiveness on virtual prototypes and reference designs of targeted plug load devices. Based on these findings, the recipient will develop, tune and deploy the design methodology guidelines for energy efficient plug load designs to the manufacturers of plug load devices and their hardware, software and tools suppliers. The recipient will also define and introduce a widely accepted industry standard through the Institute of Electrical and Electronics Engineers (IEEE) to support the newly developed unified design methodology and secure its long-term adoption and further evolution.

MOISTHERM: Integrated Heat/Moisture Transfer Envelope Modeling Tool

Lawrence Berkeley National Laboratory will integrate heat and moisture transfer analysis of building envelop performance into one modeling system by adding moisture transfer to Lawrence Berkeley National Laboratory'es THERM engine.

Moisture Performance of High-R Wall Systems

Home Innovation Research Labs, Inc. will develop wall system design guidance for builders and improve the durability of envelope assembly systems. Findings from this project could play a critical role in improving the efficiency of home heating and cooling and could reduce HVAC energy use by at least 10%.

Monitoring of Unvented Roofs with Diffusion Vents and Interior Vapor Control in a Cold Climate

Building Science Corporation and partners will evaluate the use of a vapor control membrane, or diffusion vent, which could substantially reduce the risk of moisture issues in roof assemblies with fibrous insulation. This project will field test this solution in a cold climate new construction test house over three years, and will also test the approach in a high impact existing home weatherization application to be determined through stakeholder engagement.

Multifamily Measure Development for Feasibility Design for Central Heat Pump Mechanical System - CO2HPWH?

BPA's Emerging Technology group is actively working on improving multifamily domestic hot water and space heating energy efficiency research. The goal is to identify and work out the technical challenges associated with integrating these technologies into multifamily buildings. This project is providing assistance for a feasibility design to determine if this concept is feasible and in turn, the potential mechanical system costs in aiding in the determination of potential utility incentives. The design study will determine if this central heat pump mechanical system is feasible and to determine project costs. The results of the study will be given to BPA and EWEB to determine if the project will move forward.

Narrow Emitting Red Phosphors for Improving pcLED Efficacy

Lumenari, Inc. will develop a narrow-bandwidth red phosphor to improve phosphor-converted LED efficacy up to 28%. This will be accomplished through a combination of experimental and computational techniques to develop a novel host material for the selected emitter ion.

Natural Gas Fired Air Conditioner and Heat Pump

ThermoLift, Inc. will develop a natural-gas-driven heat pump/air conditioner that provides space heating, space cooling, and water heating for residential and commercial buildings. This device would offer 30% - 50% improved efficiency over standard heat pumps.

Natural Gas Fired Heat Pump for HVAC and DHW based on the Vuilleumier Thermodynamic Cycle

This project will develop a TL-N heat pump that will incorporate several substantial innovations to improve efficiency, reduce complexity and manufacturing cost and place TL-N at an attractive price point compared to traditional building HAC-HW systems. The goal of this project is to complete the research and development necessary to redesign the purely mechanical system previously developed into an advanced mechanical/electronic or mechatronic system, and will produce two working prototypes. The design, build, and testing of these prototypes will be accomplished in this effort. The TL-N mechatronic-driven system will incorporate several innovations to improve performance and reduce costs. These include an ultra-low-emission combustion burner, electronically-controlled actuators for cycle efficiency improvement, and innovative heat exchangers. Adaptation of these low cost mature technologies into the heat pump design will significantly increase operational efficiencies of the thermodynamic process while reducing cost.

Natural Refrigerant High Performance Heat Pump for Commercial Applications

S-RAM Dynamics, LLC will develop a regenerative air source heat pump for commercial and industrial HVAC applications. Initial units of this heat pump could offer a 50% improvement over existing state-of-the-art technology, leading to substantial energy-use reductions.

Next-Generation "Giant" Quantum Dots: Performance-Engineered for Lighting

Los Alamos National Laboratory will develop quantum-dot down-converters to be used in LED lighting. Advancements made in this project could drive further efficiency improvements in LED lighting.

Next-Generation LED Package Architectures Enabled by Thermally Conductive Transparent Encapsulants

Momentive will develop next-generation LED package architectures enabled by thermally conductive composite encapsulant materials. These LED package architectures could provide more-efficient lighting options for use in U.S. buildings.

Novel Energy-Efficient Ventless Thermoelectric Clothes Dryer

Oak Ridge National Laboratory will develop and demonstrate a cost-effective, energy-efficient clothes dryer that is based on thermoelectric technology. This transformative dryer technology has the potential to save 356 TBtu/year.

Novel Ground-Level Integrated Diverse Energy Storage (GLIDES) Coupled with Building Air Conditioning

Oak Ridge National Laboratory, in partnership with Georgia Tech and IntelliChoice Energy, will integrate its Ground-Level Integrated Diverse Energy Storage (GLIDES) system with HVAC systems to provide efficient building-integrated electrical and thermal energy storage. This system enables smarter building-grid integration, as well as the use of low-grade heat, which would otherwise be lost in traditional HVAC systems.

Novel Infiltration Diagnostics based on Laser-line Scanning and Infrared Temperature Field Imaging

Iowa State University will develop an infiltration diagnostics system that uses a laser to locally heat a portion of the building envelope, and then uses an infrared camera to pinpoint air leaks. This system is able to measure and locate leaks within a building envelope, producing an energy saving potential of about 566 TBtu by 2030.

Novel Lighting Strategies for Circadian and Sleep Health in Shift Work Applications

This project will develop and test the efficacy of novel light-based circadian interventions for enhancing sleep, health, alertness, performance, and quality of life in nightshift workers.

Novel Solid State Magnetocaloric Air Conditioner

Oak Ridge National Laboratory will develop a novel magnetocaloric air conditioner with the potential for efficiency improvements of up to 25% over conventional vapor compression systems. This new technology could save the U.S. 1 quad annually.

Novel Thermal-Break with Simplified Manufacturing for R7 Commercial Windows

Alcoa will develop advanced aluminum window frame technology as well as a manufacturing process for energy-saving commercial window systems that use the technology. Use of these windows in new and existing commercial buildings would drive progress toward national energy savings goals.

Novel Transparent Phosphor Conversion Matrix with High Thermal Conductivity for Next-Generation Phosphor-Converted LED-based Solid State Lighting

Carnegie Mellon University will develop an improved phosphor matrix to include materials that increase the thermal conductivity more than 5 times over standard matrix materials. This technology could reduce the price of light by as much as 50% - 60%.

Novel Ultra-Low Energy Consumption Ultrasonic Clothes Dryer

Oak Ridge National Laboratory will develop a clothes dryer that is extremely energy efficient and has a load drying time of approximately 20 minutes. This technology has the potential to revolutionize the clothes dryer industry, as well as to achieve 0.4 quads of energy savings.

OLED Luminaire with Panel Integrated Drivers and Advanced Controls

Acuity Brands Lighting will develop an OLED luminaire that features DC current drivers integrated with each panel and advanced user controls. This advancement in OLED technology could lead to more-efficient OLED lighting systems and reduced energy use for building lighting.

OpenBuildingControl: Simulation, Specification and Verification of Control Sequences

Lawrence Berkeley National Laboratory, along with its partners, will develop a platform for design and specification of HVAC control sequences that inter-operates with both whole-building energy simulation and automated control implementation workflows. OpenBuildingControl will unify control design, evaluation, and optimization via whole-building energy simulation with control implementation, eliminating the manual translation steps currently associated with HVAC control implementation, reducing both error as well as effort and cost.

OpenEfficiency Initiative

The OEI will capitalize on existing DOE investments to create an integrated open source technology platformthe OpenEfficiency Platform (OEP)capable of supporting a range of energy efficiency program types. Working closely with a group of utility program administrators, the OEI will support the design, planning, and use of the OEP in a series of commercial pilot programs for whole building energy efficiency, local government benchmarking, and auditing.

Optimizing Radiant Systems for Energy Efficiency and Comfort

This project will develop new practical design and operation tools for radiant cooling and heating systems in order to provide a standardized guidance for radiant systems. The approach will include a combination of fundamental full-scale laboratory experiments, whole-building simulations, development of simplified models for radiant system controls, validation of these new methods in field studies, occupant satisfaction surveys, and an update to Title-24 for radiant systems. The project outcomes will include 1) a simplified tool for calculating the cooling load and cooling capacity of a radiant slab system, including calculation methods with significant direct solar radiation, 2) a simplified online operational tool for radiant slab systems, and 3) updates to the Title 24 Alternative Calculation Method Reference Manual to enable improved modeling capabilities of radiant systems.

Optimizing Radiant Systems for Energy Efficiency and Comfort

This project will develop new practical design and operation tools for radiant cooling and heating systems in order to provide a standardized guidance for radiant systems. The approach will include a combination of fundamental full-scale laboratory experiments, whole-building simulations, development of simplified models for radiant system controls, validation of these new methods in field studies, occupant satisfaction surveys, and an update to Title-24 for radiant systems. The project outcomes will include 1) a simplified tool for calculating the cooling load and cooling capacity of a radiant slab system, including calculation methods with significant direct solar radiation, 2) a simplified online operational tool for radiant slab systems, and 3) updates to the Title 24 Alternative Calculation Method Reference Manual to enable improved modeling capabilities of radiant systems.

Passively-Powered Adaptively-Located Flexible Hybrid Sensors

PARC, A Xerox Company, in partnership with Energy ETC Inc., will develop a wireless system of peel-and-stick sensor nodes that are powered by radio frequency hubs, relaying data to building management systems that can significantly reduce energy use. The wireless sensors and radio frequency hubs provide an opportunity to increase building energy efficiency by gathering and compiling data needed for building management.

Performance of Thermal Storage Retrofit

The Wild Center will refine the analysis to determine the optimum thermal storage volume with respect to energy savings, cost, and available area. The preliminary analysis shows that 1,700 gallons would yield improved performance, however they do not have the space to install a single tank with this volume. Instead, they will install two tanks each with half the identified volume. Clarkson University will build upon their previous studies of the boiler and extensively monitor the performance benefits associated with the thermal storage. They will capture data of the course of two years which will provide a comprehensive data set. They will also conduct an evaluation according to the ASHRAE 155P test method. The Wild Center will incorporate the data into their exhibits, allowing visitors to better understand biomass combustion.

Performance Testing of Phase Change Material in US Army Reserve Buildings

The objective of the research is to test the energy performance and demand reduction capabilities of phase change material (PCM) in conditioned buildings at a USAR site. PCM is a substance used to increase the thermal mass of a building due to its ability to melt and solidify at certain temperatures, providing the capability to store and release large amounts of thermal energy. PCM works in conjunction with traditional insulation to decrease heat gain (or loss) by storing and releasing heat to the conditioned space at different times of the day

Performance-Based IAQ and Optimized Venilation

Southface Energy Institute and partners will develop and validate a performance-based indoor air quality assessment protocol for homes. The assessment protocol and smart ERV solution will achieve annual HVAC energy cost savings of approximately $100 compared to central fan integrated supply system, as well as a 50% reduction in ventilation-related latent loads compared to supply or exhaust ventilation strategies.

Physics-based Interval Data Models to Automate and Scale Home Energy Performance Evaluations

Fraunhofer USA Center for Sustainable Energy Systems Inc. and partners will develop models that use communicating thermostat data and interval electricity and gas data to remotely identify homes with significant energy savings opportunities. The tool will identify the top 20% of homes with the greatest potential for energy savings from insulation, air sealing, and/or heating system upgrades, reducing the number of unnecessary energy audits.

Pilot-Scale Evaluation of an Integrated Building Control Retrofit Package

This project will test an Integrated Building Control Package that maximizes energy efficiency for existing commercial buildings. The project will refine novel control algorithms that utilize shared device state and environmental data for lighting, fenestration and heating, ventilating and air conditioning (HVAC) systems. Sharing and considering data from multiple device types will further improve overall, sustained, system performance and operation. Control algorithms will prioritize lighting or heating/cooling savings based on climate and building design. HVAC system management will leverage passive ventilatio

Pilot-Scale Evaluation of an Integrated Building Control Retrofit Package

This project will test an Integrated Building Control Package that maximizes energy efficiency for existing commercial buildings. The project will refine novel control algorithms that utilize shared device state and environmental data for lighting, fenestration and heating, ventilating and air conditioning (HVAC) systems. Sharing and considering data from multiple device types will further improve overall, sustained, system performance and operation. Control algorithms will prioritize lighting or heating/cooling savings based on climate and building design. HVAC system management will leverage passive ventilatio

Plug & Play Component and Smart Control Pre-Assembly for Biomass Boilers

Hydronic Specialty Supply will develop an interface module that organizes the hydronics layout of a biomass-fired boiler and integrates smart control options for multi-boiler systems. The controls will be able to optimally manage the operation of the existing fossil fuel boiler, new biomass boiler, thermal storage tank, space heating, and even DHW. This interface module will be comprised of standardized hardware components, therefore reducing net installed cost to consumers and taking advantage of economies of scale. The project will bring the proposed solution through the prototyping phase into laboratory and field tests.

Plug Load Reduction App:RYPL

This project will research methods to reduce home idle loads by utilizing smart meter analytics, an engaging smart phone app, a new online crowd-sourced database of miscellaneous electric loads, and an online efficient product marketplace to educate California residents about the idle load of their home and ways to reduce it. The system will be piloted within all three electric investor owned utility territories and measure actual energy savings through smart meter data.

Power Management User Interface

This project seeks to reduce computers' energy consumption by improving how users employ existing power management capabilities. Although all computers have the capacity to enter low-power modes such as sleep, and can be shut down when not in use, this potential for energy savings has not been realized in the majority of desktop computers. The majority of desktop computers remain on at full power when they are not being used. The problem is one of user behavior. The project will use a software solution to change user behavior by changing the tool they are using. This approach is firmly based in behavior theory and human-computer interaction research, which have long demonstrated that the interface of a device can change users' behavior. The energy savings of applying such an interface is estimated to be as high as 50 percent per computer, between 139 and 321 kWh per year.

Power Management User Interface

This project seeks to reduce computers' energy consumption by improving how users employ existing power management capabilities. Although all computers have the capacity to enter low-power modes such as sleep, and can be shut down when not in use, this potential for energy savings has not been realized in the majority of desktop computers. The majority of desktop computers remain on at full power when they are not being used. The problem is one of user behavior. The project will use a software solution to change user behavior by changing the tool they are using. This approach is firmly based in behavior theory and human-computer interaction research, which have long demonstrated that the interface of a device can change users' behavior. The energy savings of applying such an interface is estimated to be as high as 50 percent per computer, between 139 and 321 kWh per year.