FLYWHEEL ENERGY STORAGE SYSTEM FOR NAVAL APPLICATIONS

机译：海军应用的飞轮储能系统

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A recent trend in designing naval ships is to improve performance through using more electric equipment. The reliability and quality of the onboard electric power, therefore, becomes critical as the ship functionality would entirely depend on its availability. This paper investigates the possibility of using Flywheel Energy Storage Systems (FESS), similar to those earlier developed for commercial applications, to address issues related to onboard power supplies. A design of a FESS for onboard power backup and railroad electrical stations is presented. The FESSs power output parameters are 500kWx30sec in high-duty mode and up to 2MW in pulse mode. High power output is one of the main advantages of FESS over commercially available electrochemical batteries. The other advantages include essentially an unlimited number of charge/discharge cycles, observable state of charge and environmental friendliness. Designs of the main FESS components are discussed: low-loss magnetic bearings, an energy-storage hub, a high-efficiency motor/generator and power electronics.

机译：设计海军舰船的最新趋势是通过使用更多的电气设备来提高性能。因此，船上电力的可靠性和质量变得至关重要，因为船的功能将完全取决于其可用性。本文研究了使用飞轮储能系统（FESS）来解决与车载电源有关的问题的可能性，该系统类似于早期为商业应用而开发的储能系统。提出了一种用于车载备用电源和铁路车站的FESS设计。 FESS的功率输出参数在高负载模式下为500kWx30sec，在脉冲模式下高达2MW。相对于市售电化学电池，高功率输出是FESS的主要优势之一。其他优点基本上包括无限数量的充电/放电循环，可观察的充电状态和环境友好性。讨论了主要FESS组件的设计：低损耗磁性轴承，储能轮毂，高效电动机/发电机和电力电子设备。

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《ASME(American Society of Mechanical Engineers) Turbo Expo vol.5 pt.A; 20050606-09; Reno-Tahoe,NV(US)》|2005年|P.25-33|共9页
会议地点 Reno-TahoeNV(US)
作者
Co Huynh; Patrick McMullen; Alexei Filatov; Shamim Imani; Hamid A. Toliyat; Salman Talebi;
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Calnetix Inc., 12880 Moore Street, Cerritos, CA 90703, USA;

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原文格式 PDF
正文语种 eng
中图分类气体透平（涡轮机）;
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专利

1. A preliminary dynamic behaviors analysis of a hybrid energy storage system based on adiabatic compressed air energy storage and flywheel energy storage system for wind power application [J] . Zhao Pan, Wang Mingkun, Wang Jiangfeng, Energy . 2015,第maya1期

机译：基于绝热压缩空气储能和飞轮储能系统的风能混合动力储能系统的初步动力学行为分析
2. Design and thermodynamic analysis of a hybrid energy storage system based on A-CAES (adiabatic compressed air energy storage) and FESS (flywheel energy storage system) for wind power application [J] . Pan Zhao, Yiping Dai, Jiangfeng Wang Energy . 2014,第juna1期

机译：基于A-CAES（绝热压缩空气储能）和FESS（飞轮储能系统）的混合储能系统的设计和热力学分析，用于风力发电
3. Review of Flywheel Energy Storage Systems structures and applications in power systems and microgrids [J] . Arani A. A. Khodadoost, Karami H., Gharehpetian G. B., Renewable & Sustainable Energy Reviews . 2017,第MARa期

机译：飞轮储能系统的结构及其在电力系统和微电网中的应用综述
4. FLYWHEEL ENERGY STORAGE SYSTEM FOR NAVAL APPLICATIONS [C] . Co Huynh, Patrick McMullen, Alexei Filatov, ASME TURBO exposition . 2006

机译：用于海军应用的飞轮储能系统
5. Control Algorithm Design, Testing, and Use Cases for the INSTAR [INertial STorage And Recovery] System: A Flywheel-Based Dedicated High-Power Energy Storage System for Improved Hybrid Vehicle Fuel Efficiency and Performance with Special Application in Urban Commercial Vehicles [D] . Madura, John Michael 2018

机译：INSTAR [惯性存储和恢复]系统的控制算法设计，测试和用例：一种基于飞轮的专用大功率储能系统，可提高混合动力汽车的燃油效率和性能，并特别应用于城市商用车
6. Clean energy storage technology in the making: An innovation systems perspective on flywheel energy storage [O] . Samuel Wicki, Erik G. Hansen -1

机译：清洁能源存储技术的发展：飞轮能量存储的创新系统观点
7. RETRACTED: Energy recovery data characteristics extraction of flywheel energy storage control system for vehicular applications [O] . Hongliang Li, Jiangwei Chu, Jialu Li, 2017

机译：缩回：车辆应用飞轮储能控制系统的能量恢复数据特性提取
8. Summary of the State of the Art of Superconducting Magnetic Energy Storage Systems, Flywheel Energy Storage Systems, and Compressed Air Energy Storage Systems [R] . Butler, P., DiPietro, P., Johnson, L., 1999

机译：超导磁储能系统，飞轮储能系统和压缩空气储能系统的现状综述

FLYWHEEL ENERGY STORAGE SYSTEM FOR NAVAL APPLICATIONS

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