Turbomachine Operation with Magnetic Bearings in Supercritical Carbon Dioxide Environment

IF 1.3 Q2 ENGINEERING, AEROSPACE
A. Hacks, D. Brillert
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Abstract

In the sCO2-HeRo project, the Chair of Turbomachinery at the University of Duisburg-Essen developed, built and tested a turbomachine with an integral design in which the compressor, generator and turbine are housed in a single hermetic casing. However, ball bearings limited operation because their lubricants were incompatible with supercritical CO2 (sCO2) and they had to operate in gaseous CO2 instead. To overcome this problem, the turbomachine was redesigned built and tested in the sCO2-4-NPP project. Instead of ball bearings, magnetic bearings are now used to operate the turbomachine with the entire rotor in sCO2. This paper presents the revised design, focusing on the usage of magnetic bearings. It also investigates whether the sCO2 limits the operating range. Test runs show that increasing the density and rotational speed results in greater deflection of the rotor and greater forces on the bearings. Measurements are also analyzed with respect to influence of the density increase on the destabilizing forces in the rotor–stator cavities. The conclusion is that for the operation of the turbomachine, the control parameters of the magnetic bearings must be adjusted not only to the rotor speed, but also to the fluid density. This enabled successful operation of the turbomachine, which reached a speed of about 40,000 rpm during initial tests in CO2.
超临界二氧化碳环境下磁力轴承的涡轮机运行
在sCO2 HeRo项目中,杜伊斯堡-埃森大学涡轮机械系主任开发、建造并测试了一种整体设计的涡轮机,其中压缩机、发电机和涡轮机安装在一个密封外壳中。然而,滚珠轴承的运行受到限制,因为它们的润滑剂与超临界CO2(sCO2)不兼容,并且它们必须在气态CO2中运行。为了克服这个问题,涡轮机在sCO2-4-NPP项目中进行了重新设计、建造和测试。磁性轴承取代了滚珠轴承,现在用于操作涡轮机,整个转子都在sCO2中。本文介绍了修改后的设计,重点介绍了磁性轴承的使用。它还调查了sCO2是否限制了工作范围。测试运行表明,密度和转速的增加会导致转子的偏转更大,轴承上的力也更大。还分析了密度增加对转子-定子腔中失稳力的影响。结论是,对于涡轮机的运行,磁性轴承的控制参数不仅必须根据转子速度进行调整,还必须根据流体密度进行调整。这使得涡轮机能够成功运行,在二氧化碳的初始测试中,涡轮机的速度达到了约40000转/分。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
2.30
自引率
21.40%
发文量
29
审稿时长
11 weeks
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