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Modeling of Pem Fuel Cell Systems Including Controls and Reforming Effects for Hybrid Automotive Applications.

机译：包括控制和混合汽车应用重整效应的pem燃料电池系统建模。

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Due to the nature of fuel cell reactions, fuel cells have the potential of being more fuel efficient while generating fewer harmful emissions than conventional automotive power systems. Additionally, by hybridizing a fuel cell system with a battery, opportunities may exist for significantly improving overall performance. This study develops models for a stand-alone Proton Exchange Membrane (PEM) fuel cell stack, a direct-hydrogen fuel cell system including auxiliaries, and a methanol reforming fuel cell system for integration into a vehicle performance simulator. Exergetic efficiencies associated with the three models are examined and sources of inefficiency are identified. Fuel cell stack efficiency is highest when operating at low current density. Air compressor power consumption and losses associated with reformer operation significantly lower the overall system efficiency and highlight the importance of low-level control of components within the system. By incorporating the models developed in this study into the vehicle performance simulator, alternative fuel cell vehicle configurations can be explored using various driving cycles, component sizing, and control strategies to determine effects on overall vehicle performance and fuel economy. For a typical sport utility vehicle operating over the Federal Urban Driving Schedule and Federal Highway Driving Schedule driving cycles, the simulator is used to examine fuel economy in four cases: direct-hydrogen fuel cell vehicle, methanol reforming fuel cell vehicle, direct-hydrogen hybrid (fuel cell system/battery) vehicle, and methanol reforming hybrid vehicle. Results indicate the direct-hydrogen hybrid vehicle shows the strongest potential for high fuel economy. Additionally, for the direct-hydrogen hybrid vehicle, simple supervisory control strategies for the fuel cell system and battery are used to examine component sizing and operational limits.

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作者
Boettner, D. D.;
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年度 2001
页码 1-262
总页数 262
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Emission; Fuel cells; Simulators; Fuel systems; United states government; Strategy; Cost effectiveness; Performance(Engineering); Efficiency; Current density; Protons; Cycles; Scheduling; Limitations; Configurations; Self contained; Methanols; Low level; Fuel consumption; Power supplies; Storage batteries; Hybrid systems; Membranes; Consumption; Low density; Air power; Exchange; Air compressors; Stacking; Recreation; Automotive components; Urban areas; Supervision; Automotive engineering; Utility vehicles;

机译：排放;燃料电池;模拟器;燃料系统;美国政府;战略;成本效益;性能（工程）;效率;电流密度;质子;周期;调度;限制;配置;自给;甲醇;低水平;燃料消耗;电源;蓄电池;混合动力系统;薄膜;消耗;低密度;空气动力;交换;空气压缩机;堆垛;娱乐;汽车部件;市区;监督;汽车工程;多用途车辆;

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专利

1. Modeling and control of distributed generation systems including PEM fuel cell and gas turbine [J] . Rekha T. Jagaduri, Ghadir Radman Electric power systems research . 2007,第1期

机译：分布式发电系统（包括PEM燃料电池和燃气轮机）的建模和控制
2. Dynamic modeling and control analysis of a methanol autothermal reforming and PEM fuel cell power system [J] . Ipsakis Dimitris, Ouzounidou Martha, Papadopoulou Simira, Applied Energy . 2017,第deca15期

机译：甲醇自热重整和PEM燃料电池动力系统的动力学建模与控制分析
3. Fuel effects on start-up energy and efficiency for automotive PEM fuel cell systems [J] . Troy A. Semelsberger, Rodney L. Borup International journal of hydrogen energy . 2005,第4期

机译：燃料对汽车PEM燃料电池系统启动能量和效率的影响
4. MODELING AND PERFORMANCE SIMULATION OF A REFORMER AND FUEL CELL SYSTEM FOR ELECTRICITY GENERATION FROM DIGESTER GAS USING PEM FUEL CELLS [C] . Sebastian Roa Prada, ASME Member, Oscar Eduardo Rueda Sanchez ASME international mechanical engineering congress and exposition . 2018

机译：基于PEM燃料电池的沼气发电转化器和燃料电池系统的建模和性能模拟
5. Modeling of PEM fuel cell systems including controls and reforming effects for hybrid automotive applications. [D] . Boettner, Daisie Dawson. 2001

机译：PEM燃料电池系统的建模，包括混合动力汽车应用的控制和重整效果。
6. Adaptive control paradigm for photovoltaic and solid oxide fuel cell in a grid-integrated hybrid renewable energy system [O] . Sidra Mumtaz, Laiq Khan 2012

机译：网格集成混合可再生能源系统中光伏和固体氧化物燃料电池的自适应控制范例
7. Dynamic modeling of a NG-fueled SOFC-PEMFC hybrid system coupled with TSA process for fuel cell vehicle [O] . Zhen Wu, Meng Ni, Pengfei Zhu, 2019

机译：NG燃料SOFC-PEMFC混合系统的动态建模，燃料电池车辆TSA工艺

Modeling of Pem Fuel Cell Systems Including Controls and Reforming Effects for Hybrid Automotive Applications.

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