Research Tracker

This project demonstrates three innovative bundles of pre-commercial technologies. The technology bundles were strategically developed through a systems-level approach to address the most energy-intensive areas in commercial buildings. These include: (1) Chilled Water Plants: Optimized all-variable-speed chilled-water (CHW) plants utilizing alternative refrigerant chillers. (2) Office and Exterior Space LED fixtures with integrated advanced controls, advanced building management system (BMS), and plug load controls controllable for demand response (DR), and off-grid, exterior, LED lighting in the parking lot, and lastly (3) Advanced laboratory ventilation, fume hood exhaust, and direct current (DC) lighting systems.

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.

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.

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.

This project will research and develop new technologies and strategies to eliminate or significantly reduce energy use in standby mode by redesigning the power supply for plug load devices. This research project will also develop and demonstrate strategies to remove plug load devices from grid AC power by redesigning these devices to use DC power from photovoltaic power sources.

This project will research and develop new technologies and strategies to eliminate or significantly reduce energy use in standby mode by redesigning the power supply for plug load devices. This research project will also develop and demonstrate strategies to remove plug load devices from grid AC power by redesigning these devices to use DC power from photovoltaic power sources.

This project will assess the energy reduction potential of electric commercial plug load foodservice equipment at five different commercial kitchens and demonstrate reduced energy consumption through the use of pre-commercial appliance designs and control technologies.

This project will develop integrated plug load control strategies appropriate for different spaces within multiple types of commercial buildings. The project will implement a flexible energy management system (FEMS) to demonstrate the integrated control strategies for plug loads at pilot sites, including installation of smart power outlets and integration of various plug load control strategies with building energy management and/or lighting control systems. The project is designed to demonstrate and measure the degree of effectiveness of the flexible control strategies developed for integrally managing operation of plug loads to achieve energy efficiency and demand reductions.

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.

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.

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.

This project will develop an interoperable protocol that can be implemented in all plug-load devices, unhampered by proprietary restrictions which will implement energy reporting to enable plug-load devices to transmit operating information - such as identity, power consumption, and functional state - through a communications network to a central entity. After a communication infrastructure is established for plug-load devices, the data flow can be reversed to send control signals to individual devices. The central management system that this project will demonstrate is well positioned to provide comprehensive control over diverse plug-load devices.

This project will develop an interoperable protocol that can be implemented in all plug-load devices, unhampered by proprietary restrictions which will implement energy reporting to enable plug-load devices to transmit operating information - such as identity, power consumption, and functional state - through a communications network to a central entity. After a communication infrastructure is established for plug-load devices, the data flow can be reversed to send control signals to individual devices. The central management system that this project will demonstrate is well positioned to provide comprehensive control over diverse plug-load devices.