论文信息 - GLOBAL STRATEGIES FOR OPTIMIZING THE RELIABILITY AND PERFORMANCE OF U.S. ARMY MOBILE POWER TRANSFER SYSTEMS

GLOBAL STRATEGIES FOR OPTIMIZING THE RELIABILITY AND PERFORMANCE OF U.S. ARMY MOBILE POWER TRANSFER SYSTEMS

Abstract : As the U.S. Army develops its 30-year science and technology strategy for ground systems, these systems are seen more as mobile power generation systems than just semi-autonomous mobile protection systems. As ground systems continue to have greater levels of electrification, they are perceived as key to providing power not only to the propulsion and mobility systems, but to protection systems, communications, information systems and a complex, ever-increasing suite of auxiliary power systems which are not limited to the vehicle platform itself, but to external systems and platforms. All power systems can be connected wirelessly, or through a microgrid. Therefore, optimizing the overall ground system along with an external suite of loads and sources through a power grid, as a system of systems, becomes crucial in vehicle design. This optimization problem for performance and reliability is complex when considering the outside grid and a mix of other sources and loads with uncertain power quality and availability. This paper proposes how this optimization problem can be formulated and solved, and attempts to change the perspective of the importance of the overall ground system as a power generation system on the battlefield, and for base operations, restoration and contingency operations. Because a microgrid is designed for a period of time, our optimization problem considers factors such as cost to operate, maintenance, reliability, repair time and logistics. This paper also focuses on optimizing the vehicle-microgrid system using these factors with emphasis on the vehicle to grid management where a vehicle is a mobile power generation system and a key part of the grid.

[1] Matthew P. Castanier,et al. RELIABILITY AND FUNCTIONALITY OF REPAIRABLE SYSTEMS USING A MINIMAL SET OF METRICS: DESIGN AND MAINTENANCE OF A SMART CHARGING MICROGRID , 2013, DAC 2013.

[2] Willett Kempton,et al. Using fleets of electric-drive vehicles for grid support , 2007 .

[3] Willett Kempton,et al. Vehicle-to-Grid Power: Battery, Hybrid, and Fuel Cell Vehicles as Resources for Distributed Electric Power in California , 2001 .

[4] Kalyanmoy Deb,et al. A Fast Elitist Non-dominated Sorting Genetic Algorithm for Multi-objective Optimisation: NSGA-II , 2000, PPSN.

[5] Willett Kempton,et al. Vehicle-to-grid power fundamentals: Calculating capacity and net revenue , 2005 .

[6] Zissimos P. Mourelatos,et al. New Metrics to Assess Reliability and Functionality of Repairable Systems , 2013 .

[7] Willett Kempton,et al. Electric-drive vehicles for peak power in Japan , 2000 .

[8] Kenneth S Kurani,et al. Estimating the early household market for light-duty hydrogen-fuel-cell vehicles and other “Mobile Energy” innovations in California: A constraints analysis ☆ , 2006 .

[9] Willett Kempton,et al. Vehicle-to-grid power implementation: From stabilizing the grid to supporting large-scale renewable energy , 2005 .

[10] Brett David Williams,et al. Commercializing light-duty plug-in/plug-out hydrogen-fuel-cell vehicles: , 2007 .