The ESM process focuses on energy reliability for critical missions and immediately-deployable technologies, and cybersecurity for the control systems. This decentralized approach allows DERs to be managed intelligently, efficiently, and reliably. It does this by integrating distributed energy resources (DERs) such as backup generators, local PV systems, small wind turbines, and electrical energy storage into a local electrical distribution service area (microgrid).
DE-FOA-0000997) awarded more than $8 million in September 2014 to develop and test microgrid system designs with advanced controllers for technical feasibility and economic performance in meeting the Energy Department’s program targets and the resiliency objectives of the communities. A funding opportunity announcement (FOA No. Industry partnerships for commercial viability and to meet community-defined resiliency objectives.The MDT and its underlying technologies have been used for many projects and agencies, including the Smart Power Infrastructure Demonstration and Energy Reliability and Security project, the City of Hoboken, the New Jersey backup power system, the US Marine Corps Expeditionary Energy Office, and many resilience analyses for communities around the U.S. Using the MDT, a designer can effectively search through large design spaces for efficient alternatives investigate the simultaneous impacts of several design decisions derive defensible, quantitative evidence for decisions gain a quantitative understanding of the tradeoff relationships between design objectives and gain a quantitative understanding of the trade-offs associated with alternate technology choices. The tool applies powerful search algorithms to identify and characterize alternative microgrid design decisions in terms of user-defined objectives such as cost, performance, and reliability.
#MICRO GRIDS MAP SOFTWARE#
The Microgrid Design Toolkit (MDT), which was developed by Sandia National Laboratories, is a decision support software tool for microgrid designers intended for use in early stages of the design process.For more information, visit the LBNL Microgrids News and Events website. The goal is to broaden its use for the development of resilient microgrids that reduce energy costs and CO 2 emissions during normal operations, as well as maintaining power delivery during extended outages over a range of potential grid events with durations as brief as a few minutes or as long as several days or weeks. Its strength derives from the flexibility to optimize over a wide range of parameters, from net-zero energy requirements to financial incentives and subsidies for specific technologies to local utility tariffs. DER-CAM can also be used for dispatching DER, on day-ahead to week-ahead schedules, based on load and weather forecasting. Using state-of-the-art optimization techniques, DER-CAM assesses distributed energy resources and loads in microgrids, finding the optimal combination of generation and storage equipment to minimize energy costs and/or CO 2 emissions at a given site, while also considering strategies such as load-shifting and demand-response.
The model’s objective is to minimize the cost of operating on-site generation and combined heat and power systems. The Distributed Energy Resources Customer Adoption Model (DER-CAM) is an economic and environmental model that has been in development at Lawrence Berkeley National Laboratory (LBNL) since 2000.Operations and control, addressing steady-state control and coordination, transient-state control and protection, and operational optimization.Planning and design, addressing system architecture, monitoring and analysis, and system design and.Key R&D activities undertaken by the Department’s National Laboratories are in two focus areas:.OE’s microgrid program goals are to develop commercial scale microgrid systems (capacity of less than 10 MW) capable of reducing outage time of required loads by more than 98% at a cost comparable to non-integrated baseline solutions while reducing emissions by more than 20% and improving system energy efficiencies by more than 20% by 2020. Microgrid research and development (R&D) goals to advance foundational science and technology were defined jointly with stakeholder groups during two workshops held in 20. The Office of Electricity (OE) has a comprehensive portfolio of activities that focuses on the development and implementation of microgrids to further improve reliability and resiliency of the grid, help communities better prepare for future weather events, and keep the nation moving toward a cleaner energy future.
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