王晓放

个人信息Personal Information

教授

博士生导师

硕士生导师

任职 : 现任中国工程热物理学会流体机械专委员会委员、中国航空学会学轻型燃气轮机分会委员、教育部重型燃气轮机教学资源库专家委员会委员、辽宁省能动类专业教指委副主任、大连市核事故应急指挥部专家组成员等职。

性别:女

毕业院校:大连理工大学

学位:硕士

所在单位:能源与动力学院

电子邮箱:dlwxf@dlut.edu.cn

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超临界水煤气化工艺发电气轮机排气压力分析

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发表时间:2022-10-07

发表刊物:Harbin Gongcheng Daxue Xuebao/Journal of Harbin Engineering University

所属单位:能源与动力学院

卷号:42

期号:1

页面范围:119-125

ISSN号:1006-7043

摘要:To determine the exhaust pressure of a turbine with mixed working fluid (H2O+CO2) in a thermal power generation system based on coal supercritical water gasification technology, we first calculate the internal flow resistance of steam and mixed working fluid in a condenser. We then study the condensing process of the mixed working fluid. Finally, we discuss quantitatively the parameters influencing the optimum exhaust pressure, providing a reference for the determination of the exhaust pressure of a turbine with mixed working fluid. The results show that the flow resistance of mixed working fluid in the condenser is very small and that the condensing process requires constant pressure and cooling. The vacuum created in the condenser is not only related to the ambient temperature and terminal difference of the condenser, but also dependent on the steam condensation ratio. When the ambient temperature, terminal difference of the condenser, and condensation ratio are determined, the lowest working pressure in the condenser can be found. In the range of working conditions studied, when other parameters are constant, the steam condensation ratio increases by 3%, the optimum exhaust pressure increases by 180%, the net power of the system decreases by 56%, and the system efficiency decreases by 3.3 percentage points. When the ambient temperature increases by 10 ℃, the optimum exhaust pressure increases by 79.6%, net power increment decreases by 23%, and efficiency decreases by 2.8 percentage points. Copyright ©2021 Journal of Harbin Engineering University.

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