Research Tracker

This project will develop and pilot-test a complete, low cost, and standards based Retail Automated Transactive Energy System (RATES), and behind the meter energy management solution, that minimizes the cost and complexity of customer participation in energy efficiency programs, while maximizing the potential of large numbers of small loads to improve system load factor, shave peaks, integrate renewable generation and otherwise provide low opportunity-cost resources to the grid.

NextEnergywill reduce market barriers to adoption of lighting controls solution to spur market adoption. This will be achieved through demonstrations, consumer education, and utility incentive adjustment. NextEnergy and partners will train over 100 contractors in advanced lighting controls and simplified installation methods and develop a model for streamlined incentives for lighting controls.

The purpose of this agreement is to fund the full-scale deployment demonstration of the Vortex Process Technology in cooling towers of commercial buildings. This technology has been used successfully in Europe and will be testing in California to address state specific goals for water and energy savings

Three different attic designs will be refined, tested, evaluated, and demonstrated in new home construction. The team will recommend the best of these approaches to home builders addressing cost-effectiveness and energy-efficiency. The baseline for comparison will be current energy efficiency code practices for attic construction involving ventilated, uninsulated attics containing code compliant ducts. The team will evaluate the new design approaches analytically at the start of the project. Researchers will assess approaches that include methods to produce sealed, insulated attics, as well as, standard vented attics, both of which have been demonstrated and are in limited use in the market today but currently add considerable cost to builders. The team will employ new and novel installation methods and materials that have the potential for energy savings on par with ducts in the conditioned space, but at a cost similar to current practice.

This project will assess factors affecting the scale of solar water heating (SWH) installations, such as system cost, performance, and reliability and scale. Such factors impact whether a project is undertaken at the individual or community level. The project team will consider different SWH technologies, installation types and financing mechanisms and develop a model to address questions on investing in solar water heating and how investments can be focused to maximize uptake of SWH. The team aims to quantify state-level energy and emissions impacts of the reduction in natural gas usage from solar water heating installations.

BlocPower will develop a crowd-sourcing website to help market, finance, and install energy efficiency retrofits for 1,500 small buildings in low-income communities across the country. These efforts could help these communities achieve notable energy savings and reduce their carbon emissions.

This project will develop and demonstrate an approach to scale residential retrofits for disadvantaged communities that will focus on customer-centric solutions. This project will develop and demonstrate an innovative approach, focusing on energy efficient retrofit packages that are non-intrusive to occupants and have the potential of reducing energy use by 30 to 40 percent.

This project will demonstrate how a large number of small electric loads, each impacted by and tuned to individual customer preferences can provide load management for both utilities and the California Independent System Operator (California ISO). The recipient will work with an extensive spectrum of leading product providers covering all major distributed energy resources (DERs), such as Nest (thermostats), ThinkEco (plug loads), Honda, BMW (auto), EGuana (smart Inverter) and Ice Energy (Thermal Storage). A variety of price signals will be tested for Time-of-Use customers such as Critical Peak Pricing and Demand Rate. The project will use deep analytics to evaluate individual customer preferences for demand management using microdata from devices and aggregate the responses to meet grid needs at different distribution and transmission levels.

The purpose of this project is to improve small and large commercial customer participation in demand response programs by providing a cost-effective energy management system that allows a wide range of hardware and service offerings as well as effective and automated price-based management.

The purpose of this project is to improve small and large commercial customer participation in demand response programs by providing a cost-effective energy management system that allows a wide range of hardware and service offerings as well as effective and automated price-based management.

The project goal is to demonstrate the substantial demand response (DR) and energy savings are achievable in supermarket refrigeration systems and that the integrity and safety of refrigerated products will be maintained to minimize risks to supermarket owners and customers. The project plans to analyze supermarket refrigeration energy loads in the Pacific Northwest for both demand response and energy efficiency. The purpose is to identify the most promising control strategies and technologies that can yield energy savings and demand response as part of an integrated management approach.

This project is a controlled field study and lab test that assessed the demand response (DR) potential of split system and unitary heat pump water heaters (HPWHs) that use carbon dioxide (CO2) refrigerant. The researchers included Washington State University (WSU), Pacific Northwest National Laboratory (PNNL), Efficiency Solutions, and Ecotope working with Cascade Engineering Services.

This project seeks to conduct the technical analyses, demonstration, market evaluation, and regulatory engagement necessary to realize cost-effective high-accuracy measurement and verification (M&V) for northwest efficiency programs. The focus of the effort is whole-building M&V for commercial buildings.

Optimize heat pump water heater (HPWH) next generation project for both EE and DR. The major objectives of the project are: 1. Demonstrate and quantify the energy performance of the prototype GE Brillion GeoSpring Hybrid Water Heater with and without exhaust air ducting over heating and cooling conditions in the lab homes 2. Evaluate or quantify the potential for the GE smart grid-enabled HPWH to provide demand response (to both increase/absorb [INC] and decrease/shed/shift [DEC] load) under various price signals sent to the unit. In addition, the proposed project will provide GE information to determine and design the optimal ducting configurations for their unit should they decide to offer this feature as an option for this new-to-the-market unit.

The proposed project will demonstrate Transformative Wave Technology eIQ building management system (BMS) year-round capability for meeting BPA demand response criteria for roof top units, lighting, miscellaneous electric loads, and electric hot water heaters. The demand response that will be met will be for day-ahead response, under 10-minute response and permanent load reduction. The goal is to evaluate the cost-effectiveness, feasibility and scalability of the eIA BMS for both energy efficiency and demand response.

This project will demonstrate cost-competitive ZNE design strategies that combine occupant needs with technology solutions to create new pathways for residential ZNE communities. The project's goals are cost effectiveness for the customer, affordability, overcoming customer apprehension, establishing a track record of new technology for builders, enabling distribution grid integration, creating a planning process for ZNE communities, evaluating community solar and evaluating the impact of future changes to ZNE cost effectiveness. This project will also aim to understand the operation and energy use of the unregulated loads.

A.O. Smith Corporation will demonstrate underutilized micro-combined-heat-and-power (micro-CHP) applications, which produce electricity and heat from a single source, in buildings with significant hot water demand. These micro-CHP applications can provide 38% energy savings in these building types.

The Lighting Research Center (LRC) of Rensselaer Polytechnic Institute will work with the Lighting Design Lab at Seattle City Light (SCL), a leading manufacturer of LED outdoor lighting and a leading controls manufacturer to demonstrate a sensor-controlled, adaptable LED lighting system in the parking lots for municipal, retail, or similar parking lot.

Working with project partners from the Seattle Lighting Design Laboratory, the Lighting Research Center (LRC) will identify a suitable outdoor lighting installation in a parking lot and conduct evaluations of energy and power use, visual responses of people in and approaching the outdoor location, and subjective ratings of safety and personal security while viewing and occupying the location. The design of the lighting installation will utilize published research on the spectral sensitivity of the human visual system for scene brightness perception and on the relationships between scene brightness and perception of safety and security previously published by the LRC project team. The proposed project will consist of a full-scale outdoor lighting demonstration at a parking lot facility within BPA service territory. The demonstration will be based on a proposed specification method for maximizing perceptions of safety and security of occupants, taking advantage of the differential spectral (color) sensitivity of the human visual system for brightness perception at nighttime light levels. Sensations of brightness are in turn strongly related to perceptions of personal safety and security in outdoor locations. It is anticipated that using white light sources such as a lighting emitting diode (LED) illumination in place of conventional high pressure sodium (HPS) illumination energy savings of 40-50% will be possible while maintaining perceptions of brightness, safety, and security.

This project seeks to develop operational procedures and proper system sizing guidelines for the inclusion of thermal storage in biomass-fired steam generation. The Town of Chester will design, install, commission, and evaluate a high-efficiency, low-emission pellet-fired steam boiler integrated with a wet steam accumulator for thermal storage. The system will be installed in the Town of Chester municipal building in Chestertown, NY, a 36,000 sq. ft. brick building originally fitted with a steam heating system. The existing boiler room has two oil-fired steam boilers, one currently out-of-service, which will be replaced by the proposed biomass-fired steam boiler. The project will demonstrate, measure, and evaluate the benefits of complete system integration, including a properly sized biomass-fired boiler, adequate thermal storage, building energy management and controls, and an existing oil-fired boiler

Demonstrate Strategic Energy Management Analytics (Build Plus) in 2 buildings for 1 year. This research builds on a tool created with funding through BPAs Technology Innovation Research and Development Program. Work has continued to refine the tool and research needs to be conducted to verify savings. The tools will be installed at the facilities for up to 1 year starting in 2016 and analyses will follow in late 2017.

The University of Maryland will develop the next generation air-to-refrigerant heat exchangers using non-round tubes that are 25% smaller, 25% lighter and 30% reduced charge than state-of-the-art heat exchangers.

Advanced Climate Technologies (ACT) is a manufacturer of fully automatic, high-efficiency, low-emission biomass-fired boilers, interested in expanding their manufacturing facility in Niskayuna, NY to include an automated manufacturing system. This project involves the design, purchase, installation, and commissioning of the automated manufacturing system. The automated manufacturing system will allow ACT to process raw steel into prepared components. This will include a state-of-the art multi-tiered automated process that will allow for the cutting, drilling, and nesting of ASME steel plate used for the vessel and component parts of the boiler. By increasing their manufacturing capabilities, the ACT will bring processes in-house that have thus far been subcontracted. This project will eliminate certain inefficiencies in the manufacturing value chain and reduce total manufacturing time for product improvement, cost, and waste. The cost savings will be passed to consumers, directly benefiting the biomass heating market and customers in NY.

The Lighting Research Center at Rensselaer Polytechnic will create a prototype office desktop lighting control. The device will be a combination of a motion sensor, photosensor, manual dimmer or switch, and wireless transmitter. It will sit either directly on a desk surface or be mounted to the top of a computer monitor, and will control the lighting in private or open offices. It will be paired with a receiver that will control the luminaire(s) that are nearby.

An advanced thermal post-packaging food preservation technology for controlling pathogens called "Microwave Assisted Thermal Sterilization" (MATS) has been developed by a team led by Washington State University (WSU) (http://www.microwaveheating.wsu.edu/). MATS technology has the potential for replacing conventional thermal retort ("canning") food preservation methodologies due to its greatly reduced processing time. Typical MATS processes cut conventional canning processing time by 80%, with increased energy efficiency and superior finished product characteristics like improved nutrient retention and substantially increased food quality.