Research Tracker | Building America Solution Center

Develop superwicking materials for indirect evaporative cooling system

UoR shall evaluate a new manufacturing process for producing lower cost superwicking materials. The wicking performance of the material produced with the new manufacturing process will be tested and compared to a wicking material produced using a laser surfacing technique.

Development and Testing of the Next Generation Residential Space Conditioning System for California

This project will develop a next-generation residential space-conditioning system optimized for California climates. The advanced efficiency solutions integrated into the HVAC system will include: variable-capacity compressor and variable-speed fans using state-of-the-art inverter technology; integrated ventilation to harness fresh air for "free cooling;" intelligent dual-fuel technology to decrease energy cost and empower consumers to choose between electricity and natural gas; zonal control to prevent conditioning of unoccupied rooms; demand-response interactivity to grid flexibility and reliability; advanced fault detection and diagnostics to ensure proper installation, operation, and maintenance; and alternative refrigerants for improved operation and significant reductions in the potential for global warming. How the Project Lead

Development of a high performance wood boiler

The project will seek to develop a residential and commercial logwood-fired boiler with the ability to modulate firing rates down to <10% of rated output while maintaining clean and efficient operation. The boiler will include high levels of insulation in both combustion chambers and preheating of combustion air to promote clean operation at low loads. Forced, multi-port injection and swirl mixing of secondary air similar to natural gas fired burners will be used. Certifications such as UL, CSA, and ASME will be sought.

Development of Laboratory Test Methods for Low-Cost Indoor Air Quality Sensors

The goal of this project is to develop laboratory test methods for performance verification of low-cost IAQ sensors and provide technical support to industry stakeholders during the development of an ASTM standard based on these test methods.

Development of supersonic nozzle to improve effectiveness of steam heating and reduce pumping requirements.

Hudson Fisonic will develop, design, manufacture, and install FDs for space heating and domestic hot water at the Woolworth building (57 stories, 900k ft2). The performance of the FD will be monitored for 12 months to determine the steam and potable water savings from use of this technology. Hudson Fisonic will start the commercialization of the FD technology by engaging the manufacturer - Division LLC Corporation, located in Long Island City, New York, in fabricating and preparing the necessary facilities and equipment for commercial manufacturing of FDs

Development of the Industry's First Smart Range Hood

Newport Partners, in partnership with Broan-NuTone, will develop and validate a smart range hood that senses pollutants and automatically operates to remove the contaminants efficiently. The proposed smart range hood will be quiet (<1 sone), five times more energy efficient than todays ENERGY STAR models, and will capture nearly 100% of pollutants.

DHP Multi-Family Billing Analyses for Side by Side Comparison of Energy Use for Electric Resistance Heat and DHPs

Multifamily (MF) is hugely underserved in Residential energy efficiency (EE) Programs and part of our MF ductless heat pump (DHP) strategy is to look at different MF use cases and identify which MF use cases provide a higher EE potential. So far DHP results in MF are mixed and this project will assess the energy use and savings of ductless heat pumps in mid-rise MF buildings. This study offers a unique opportunity for a side by side comparison of heat pumps and electric resistance heat within a single apartment building with 278 apartments. The project would collect billing data on all the individual units, conduct an analysis to disaggregate heating, cooling, and baseload energy use, and compare the two types of heating systems.

DHPNew Installation and Design Practices

Seven alternative ductless heat pump (DHP) solutions were identified during the 2014 Washington State University (WSU) Assessment Study, including multiple internal heads, ducting between rooms, etc. Two solutions were recommended for further research. Technology and research plans need to be developed for these alternatives. Research plans will need to be developed for this project.

Ductless Heat Pumps in Manufactured Homes, Multifamily, Single Family, Forced Air Furnace homes, and Small Commercial

The project is designed to test the ductless heat pump (DHP) in different applications. Fifty-one sites were installed to test different applications including single family, multifamily, manufactured homes , and small commercial across different climate zones. As part of the study, one year of data was collected through sub metering; and pre- and post-billing data were completed and analyzed for each site. Preliminary results have been promising for manufactured homes and single family homes with forced air furnace applications. The study was completed during the spring of 2013. Based on the findings of the study, Single Family and Manufactured Home applications provided sufficient energy savings to warrant presentation to the Regional Technical Forum as new measures in 2015. Both were given a provisional UES (deemed) measure status. DHPs in Manufactured Homes with zonal heat were given a Small Saver measure status.

Embedded Data Center - Airflow Management

The 7th Power Plan has targeted 261aMWs of savings for embedded data centers and BPA would like to develop a series of new measures to acquire these savings. Embedded Data Centers are defined as server rooms located on-site in commercial buildings which are larger than server closets but smaller than enterprise data centers. This project will inform and streamline custom projects for future Data Center Air Flow Management retrofits which may include multiple data center HVAC retrofits, including blanking panels, raising space temperatures, containment and air flow management. Up to two grants will be awarded to participate in this field study to test Data Center Air Flow Management retrofits and other HVAC solutions for Embedded Data Centers. This field study will also demonstrate and verify a Data Center Air Flow Management (AFM) energy savings calculator developed by Seattle City Light in the Data Center Track and Tune Project.

Energy Efficient HVAC Packages for Existing Residential Buildings

This project will develop and demonstrate innovative pre-commercial, cost-effective retrofit packages for cooling and ventilating single family homes. Energy savings, occupant behavior and indoor air quality (IAQ) will be measured for two specific retrofit packages that each includes three innovative technologies: (1) building envelope sealing, (2) two variants of smart mechanical ventilation that include pre-cooling strategies, and (3) compressor-free evaporative air-conditioning. Furthermore, barriers and opportunities towards adoption of such retrofits will be identified through stakeholder interviews.

Energy Efficient HVAC Packages for Existing Residential Buildings

This project will develop and demonstrate innovative pre-commercial, cost-effective retrofit packages for cooling and ventilating single family homes. Energy savings, occupant behavior and indoor air quality (IAQ) will be measured for two specific retrofit packages that each includes three innovative technologies: (1) building envelope sealing, (2) two variants of smart mechanical ventilation that include pre-cooling strategies, and (3) compressor-free evaporative air-conditioning. Furthermore, barriers and opportunities towards adoption of such retrofits will be identified through stakeholder interviews.

EPRI Supplemental: Coordinated Early Deployments of Efficient End Use Technologies PID# 072982

This project will apply the framework created in the prior research to develop early deployment plans for three additional technologies and to guide early deployments with multiple utilities for five technologies, two of which were planned in prior research. The three technologies being deployed are heat pump water heaters, led menu boards, and engine generator block heaters.

Evaluation of cold-climate air-source heat pumps (ccASHPs)

SWA will evaluate the opportunities, savings potential, and limitations of ccASHPs in New York State homes. Improved energy modeling techniques will be developed for various tools. Guidelines will be developed describing ccASHP opportunities in NYS homes, including operating costs, installed costs, climate-dependent factors, low-temperature limitations, integration issues and possible limitations. Guidelines will also be developed for energy modelers to help accurately predict ccASHP performance with common modeling tools.

Fault Detection and Diagnosis (FDD) Tools for Retro-Commissioning and Continuous Commissioning of HVAC and Refrigeration Systems

This project will study selected software and hardware platforms that apply algorithms to identify, diagnose, and sometimes fix broken electric cooling, ventilation and refrigeration systems in buildings. If widely used, the fault detection and diagnosis tools validated in this project could have savings of 927 Tbtu per year.

Field Test for HVAC Premium Pumping for Commercial Applications (Commercial High Efficiency Pumping Systems - CHEPS)

Commercial HVAC Efficient Pumping Technology has been identified by BPA as having significant electrical energy savings potential. Grants will be awarded to BPA customer utilities to test CHEP installation for Commercial, Agricultural and Industrial applications. Pump retrofits include integrated, variable-speed HVAC system pumps ranging in size between 1/3 and 10 horse power with controls. To date, three utilities have requested financial assistance for installations. The units will be installed in 2017 and utilities will provide reports within one year to report on system performance and present information on potential market barriers.

Field Test for RTU Replacements which include VCHP + HRV+ DOAS in Commercial applications

The goal of this grant is to share the cost for the design, installation, and commissioning to replace Roof Top Units (RTU) with Heat Recovery Ventilation (HRV) and Variable Capacity Heat Pump (VCHP) systems. In 2016, Northwest Energy Efficiency Alliance (NEEA) identified this potential RTU replacement strategy to help meet the regions energy efficiency targets and conducted a proof of concept study for this new replacement system. NEEAs preliminary analysis estimates that an HRV and VC HP system could be combined to save over seventy percent of the energy used by RTUs. BPA is interested in obtaining field data for additional systems in the Pacific Northwest. The expected results from this project include the following: HRV and VC HP system cost effectiveness information; System performance data; Verification that whole-building billing analysis is an adequate methodology to measure savings, and Identification of best practices for installation and commissioning based on feedback from the owner, utility, designer, contractor and occupants.

Field Test of Reverse-Cycle Chillers (Commercial HPWH) in Multifamily Residential Buildings

The project includes feasibility and design studies followed by demonstration of a large central reverse cycle chiller (RCC) or heat pump water heaters for energy efficient production of domestic hot water in multifamily residential projects. Feasibility and design studies were completed in 2010. The first installation was completed in November 2012; a second installation was completed in the Spring 2013. The next phase of the project will include measurement and verification of energy savings. The project will conclude with a final report of lessons learned and recommendations for future applications of this technology. This project will look to answer the following research question: quantify the energy savings using a large heat pump water heater (or called RCC) vs. electric resistance domestic hot water in a multifamily (MF) application to prove the concept, and understand technical challenges and whether this is a good technology for multifamily sector.

Field Tests for Ducted Minisplit in Single Family Applications

Ducted mini-splits are currently available for single family applications. Research is required to determine if these units will be more efficient than the traditional ductless heat pumps (DHPs) with back up resistance heating. If the lab test shows that Ducted mini splits provide more sufficient savings then a field test will be implemented.

Field Tests for Ductless Heat Pumps Do It Yourself Installations in Single Family Homes

BPA funded a small field test through NEEA to understand if DHPs could be installed by owners to reduce installation costs to improve cost effectiveness. NEEA received funding to track the 4 installations. There were key learnings from each installation which were documented to share with the region. Preliminary results were reported earlier this year to members of the BPA and NEEA by Ecotope who managed the installations.

Gas-Fired Absorption Heat Pump

This project is developing a gas-fired absorption heat pump that offers a significant advancement for space and water heating technologies when compared to conventional gas heating technologies (an Annual Fuel Utilization Efficiency (AFUE) of 140% versus 100%, respectively). This heat pump will provide efficient space and water heating for single and multi-family homes in most climate zones.

Geothermal HP versus VRF in Multifamily Applications

In 2013, BPA received an unsolicited proposal for a case study for a side-by-side comparison of a geothermal heat pump and variable refrigerant flow (VRF) system in nearly identical multifamily housing units in Tacoma, Washington. The project provided a unique opportunity to evaluate these two technologies while providing an application for multifamily housing. The project will determine how the seasonal performance of the two systems for space conditioning and production of hot water compares. The following information will be provided for the operation of both units: quantified savings and costs over a specific baseline; understanding of the engineering design, installation, ownership, and possible utility barriers; quantified annual energy savings, benefits, and costs; documented magnitude and longevity of the incremental electric energy savings; documented operation and energy use; and described energy savings time of occurrence and duration, load shape, and lifetime.

High Efficiency Solid-State Heat Pump Module

United Technologies Research Center will demonstrate a compressor design that will enable high-efficiency small commercial rooftop air conditioning systems. This technology could provide 30% annual energy savings and reduce energy use by 2.5 quads by 2030.

High Performance Commercial Cold Climate Heat Pump (CCCHP)

United Technologies Research Center will develop a high-performance commercial cold climate heat pump system. The system could enable annual electricity use for building space heating in cold climates to decrease by at least 25%.

High-efficiency Low Global-Warming Potential (GWP) Compressor

United Technologies Research Center will demonstrate a heat pump that is smaller, quieter, and cheaper to maintain than current models. The heat pump could result in annual energy savings of more than 1.5 quads and reduce greenhouse gas emissions by 60 million metric tons.