
Improved Energy Resilience
ESTCP, Installation Energy and Water Program Area
Updated January 7, 2021
Closed March 4, 2021
FY 2021-2022
The Department of Defense Installation Energy Test Bed sought demonstration projects of innovative technologies and processes to improve the performance and reduce the cost of providing energy resilience on military installations. As defined in 10 U.S.C. § 101(e), energy resilience means the ability to avoid, prepare for, minimize, adapt to, and recover from anticipated and unanticipated energy disruptions in order to ensure energy availability and reliability sufficient to provide for mission assurance and readiness.
Installations have a wide variety of energy systems that deliver electrical and thermal energy to power critical missions, fuel industrial processes, and power and condition facilities. Most installations rely on the commercial electrical grid for primary power, natural gas for thermal energy, and building-level diesel generators and uninterruptable power supplies for back- up power to serve critical loads. Microgrids also can provide improved resiliency and are beginning to be deployed across the DoD. More frequent and stronger natural disasters and threats to the commercial electric grid require new solutions to improve energy resilience and meet the energy requirements for mission assurance. During long duration outages, the potential for disruption in other supplies also greatly increases. ESTCP sought demonstrations that contributed to energy resilience that would have broad application across military installations worldwide. Of particular interest were pilots and demonstrations that addressed the following issues:
- Innovative thermal energy that is inherently resilient and cost effective. Technologies that provide thermal energy that are independent of off-base supplies that can be disrupted are of particular interest.
- Innovative on-base electric power generation that provides increased resiliency through higher efficiency or is independent of external supplies. Power generation technologies should be cost competitive or show a viable path to cost competitiveness with current alternatives.
- Advanced load management approaches to support mission functions during a grid outage (i.e., when islanded) and provide additional revenue when grid tied. Load shedding decisions must be based on the priority of mission requirements as well as their anticipated impacts.
- Innovative agreements and tariffs that exploit a microgrid’s capability while grid tied to provide revenue or cost savings that help offset a microgrid’s O&M costs. Projects conducted in partnership with local utilities are of particular interest.
- Low-cost solutions (such as how to plan, retrofit, and test generator quick connects to existing buildings) to increase the flexibility of on-site or portable generation assets to adapt to changing energy demands during unplanned outages.
Other innovative technologies that would enhance energy security on their own or through integration with a microgrid were also of interest. Proposals for building microgrid systems and testing common renewable energy generation assets were not of interest. Proposals that addressed only unique site-specific needs or sought to demonstrate mature technologies were not considered responsive to the intent of this solicitation.
The following projects were funded in 2022. Project overviews will appear below as they posted to the website.
- Demonstration of Hybrid Rooftop Unit with Thermal Storage to Improve Resilience in DoD Facilities
- Principal Investigator: Xiaohui Zhou, Slipstream
- High Temperature Subsurface Borehole Thermal Energy Storage
- Principal Investigator: Ronald Falta, Clemson University
- Water Collection From Cooling Towers
- Principal Investigator: Karim Khalil, Infinite Cooling Inc.
- Packaged Hybrid Combined Heat and Power (CHP) and Hot Water Boiler Solution for Barrack, Dormitory, or Food Service Energy Resiliency
- Principal Investigator: Michael Parker Johnson, Controls Government Systems
- High-Resolution Metering & State Estimation for Low-Cost Real-Time Awareness and Improved Microgrid Design
- Principal Investigator: Tim Hansen, 350Solutions, Inc.
- Cybersecurity for Energy Resilience
- Principal Investigator: Chuck Weissenborn, Dragos, Inc
- Physics-Informed Intelligent and Proactive Building Load Management for Energy Resilience
- Principal Investigator: Fei Ding, National Renewable Energy Laboratory
- Demonstration of a Novel Technology to Manage Electricity Demand in Grid-independent Military Microgrids
- Principal Investigator: William Livingood, National Renewable Energy Laboratory
- Advancing Energy Resilience through Demonstrating, Characterizing, and Modeling Anaerobic Co-digestion of Organic Wastes for Widespread Implementation on DoD Installations
- Principal Investigator: Andrew Pfluger, United States Military Academy
- Resilient Power Router for Energy Resiliency and Power Management
- Principal Investigator: Hunter Spence, Naval Facilities Engineering and Expeditionary Warfare Center
- Geothermal District Heating and Cooling in Cold Regions
- Principal Investigator: Viktoria Gisladottir, U.S. Army Engineer Research and Development Center, Cold Regions Research Laboratory