上海交通大学学报 ›› 2024, Vol. 58 ›› Issue (8): 1156-1166.doi: 10.16183/j.cnki.jsjtu.2023.126

• 机械与动力工程 • 上一篇    下一篇

烟气再循环联合循环中燃气轮机温度控制方案

李柯颖1,2, 陈鲲1, 江泽鹏1, 李超1, 郭孝国1, 张士杰1,2()   

  1. 1.中国科学院 工程热物理研究所,北京 100190
    2.中国科学院大学 工程科学学院,北京 100049
  • 收稿日期:2023-04-11 修回日期:2023-06-09 接受日期:2023-06-12 出版日期:2024-08-28 发布日期:2024-08-27
  • 通讯作者: 张士杰,研究员,博士生导师;E-mail:zhangsj@mail.etp.ac.cn.
  • 作者简介:李柯颖(1993-),博士生,从事先进燃气轮机循环研究.
  • 基金资助:
    国家科技重大专项(2017-I-0002-0002)

Temperature Control Scheme for Gas Turbine of Combined Cycles with Exhaust Gas Recirculation

LI Keying1,2, CHEN Kun1, JIANG Zepeng1, LI Chao1, GUO Xiaoguo1, ZHANG Shijie1,2()   

  1. 1. Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China
    2. School of Engineering Science,University of Chinese Academy of Sciences, Beijing 100049, China
  • Received:2023-04-11 Revised:2023-06-09 Accepted:2023-06-12 Online:2024-08-28 Published:2024-08-27

摘要:

在部分负荷工况下,采用余热锅炉排气再循环与压气机进口导叶调节联合应用(EGR-IGVC)策略,可有效改善燃气轮机联合循环性能.但此策略若配合联合循环电站部分负荷工况中燃气轮机常采用的等T3(透平入口温度)-T4m(透平排气温度最大允许值)温控方案,在较低负荷下会造成较大的底循环㶲损失,底循环做功能力下降明显.提出了一种更适用于EGR-IGVC策略的等T3-T4m-T4d(透平排气温度设计值)温控方案,以PG9351FA型燃气轮机联合循环为研究对象,采用能量与㶲分析方法,对比研究了EGR-IGVC策略配合两种温控方案时的联合循环部分负荷性能.研究结果表明,当环境温度为15 ℃,部分负荷率在80%负荷以上时,EGR-IGVC策略配合等T3-T4m方案效果仍为最佳;在30%~80%负荷时,与配合等T3-T4m方案相比,EGR-IGVC策略配合等T3-T4m-T4d方案可使燃气轮机效率提高0.15~0.47个百分点,余热锅炉㶲损失减少0.51%(2.15 MW)以上.研究亦表明,当环境温度在0~40 ℃间变化时,采用等T3-T4m-T4d方案总能获得更高的联合循环效率,且随环境温度上升,部分负荷效率增幅更为明显.

关键词: 燃气轮机联合循环, 烟气再循环, 压气机进口导叶, 能量与㶲分析, 部分负荷

Abstract:

Under partial-load conditions, the combined application of exhaust gas recirculation of heat recovery steam generator and compressor inlet guide vane adjustment (EGR-IGVC) can effectively improve the performance of gas turbine combined cycle. However, if this strategy is combined with the temperature control scheme of constant T3(turbine inlet temperature)-T4m(maximum allowable turbine exhaust temperature), which is often adopted in gas turbine combined cycles under part-load conditions, it would cause a large bottoming cycle exergy destruction and a significant decrease in bottoming cycle power output at relatively lower loads. In this paper, a constant T3-T4m-T4d (the design value of turbine exhaust temperature) scheme suitable for the EGR-IGVC strategy is proposed, the PG9351FA gas turbine combined cycle unit is taken as the research object, and the partial-load performance of combined cycle under the two temperature control schemes is compared and investigated based on energy and exergy analysis. The results show that the combination of the EGR-IGVC strategy with the constant T3-T4m scheme is still the best at the ambient temperature of 15 ℃ and the partial-load rate of above 80%. At a load of 30%—80%, compared with the constant T3-T4m scheme, the EGR-IGVC strategy combined with the constant T3-T4m-T4d scheme can increase the gas turbine efficiency by 0.15%—0.47%, and decrease the exergy destruction of the heat recovery steam generator by more than 0.51%(2.15 MW). The results also show that adopting the constant T3-T4m-T4d scheme can always obtain higher combined cycle efficiency when the ambient temperature varies between 0 and 40 ℃. In addition, the increase in partial-load efficiency becomes more evident with the rise of ambient temperature.

Key words: gas turbine combined cycle, exhaust gas recirculation (EGR), compressor inlet guide vane (IGV), energy and exergy analysis, partial load

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