基于模型的 9EA-GT 工业单阀芯燃气轮机性能研究--改变进气导叶角度并修改压缩机图

IF 2 Q2 ENGINEERING, MECHANICAL Frontiers in Mechanical Engineering Pub Date : 2024-04-19 DOI:10.3389/fmech.2024.1369876
Adel Alblawi
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引用次数: 0

摘要

本文讨论了带单阀芯的工业燃气涡轮发动机(单阀芯 9EA-GT),并介绍了用于计算稳态性能的热力学模型。此外,通过从 GasTurb 12 工具下载并缩放至压气机和涡轮机的设计点,针对不同的压气机和涡轮机开发了一种用于研究燃气涡轮发动机(GTE)的新型组件图制作方法。介绍了一种通过改变进气导叶(IGV)来控制发动机流动电容的系统。调整可控 IGV 叶片可通过持续修正压气机特征图优化所有发动机单元。通过压缩机的气流,进而控制整个系统的气流,都由 IGV 进行管理。稳态性能的计算涉及两个模型:发动机启动时的稳态行为(从 65% 到 100% 速度,无负载)和加载时的稳态行为(持续速度为 100% )。在这一模型中,由于缺乏对各阶段性能的了解,我们采用适当的缩放方法,根据先前研究得出的通用映射建立人工机器映射,并通过实际发电厂的实验观测进行验证,从而解决了因缺乏对各阶段性能的了解而带来的挑战。使用 MATLAB 对这些映射进行了发动机性能模拟。评估结果与实际性能数据十分吻合。在稳定启动期间,本研究中使用的控制系统使 GTE 的燃油消耗量、废气质量流量和压缩机驱动功率分别降低了 9.5%、19.3% 和 37.5%,而在发动机加载时,这些变量分别降低了 1%、12.2% 和 19.7%。
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Model-based performance study of an industrial single spool gas turbine 9EA-GT by changing the inlet guide vane angle and modifying the compressor map
In this article, an industrial gas turbine engine with a single spool (single spool 9EA-GT) is discussed, and a thermodynamic model for computing steady-state performance is presented. In addition, a novel component map production method for investigating a gas turbine engine (GTE) is developed for a different compressor and turbine by downloading from the GasTurb 12 tool and scaling to the compressor and turbine’s design points. A system of controlling engine flow capacitance by changing inlet guide vanes (IGVs) is presented. Adjusting the controllable IGV blades can optimize all the engine units by continuously correcting the compressor features map. The airflow via the compressor, which in turn controls the airflow throughout the entire system, is managed by IGVs. The computations for steady-state performance involve two models: steady-state behavior at engine startup (from 65% to 100% speed, without load) and steady-state behavior while loading (continuous speed of 100%). In this model, the challenges brought by the lack of understanding of stage-by-stage performance are resolved by building artificial machine maps using suitable scaling methods to generalized maps derived from the previous research and validating them with experimental observations from real power plants. The engine performance simulation utilizing the maps is carried out using MATLAB. Assessment results are found to be in good agreement with the actual performance data. During a steady start, the control system used in this study decreased the fuel consumption, exhaust gas mass flow rate, and compressor-driven power for the GTE by 9.5%, 19.3%, and 37.5%, respectively, and those variables decreased by 1%, 12.2%, and 19.7%, respectively, when loading the engine.
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来源期刊
Frontiers in Mechanical Engineering
Frontiers in Mechanical Engineering Engineering-Industrial and Manufacturing Engineering
CiteScore
4.40
自引率
0.00%
发文量
115
审稿时长
14 weeks
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