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首页» 过刊浏览» 2020» Vol.5» Issue(2) 269-276     DOI : 10.3969/j.issn.2096-1693.2020.02.023
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熵产理论在液力透平内流场分析中的应用
黄宁,李振林
中国石油大学(北京)机械与储运工程学院,北京 102249
Application of entropy production theory in flow field analysis of hydraulic turbines
HUANG Ning, LI Zhenlin
College of Mechanical and Transportation Engineering, China University of Petroleum-Beijing, Beijing 102249, China

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摘要  液力透平通常用于取代石油化工工艺流程的焦耳—汤姆逊节流阀起到降压作用,可以提高整体效率,也 能回收高压液体能量,提高能量利用率。液力透平的整体性能关乎其回收能量的效率,为了对液力透平流场中 的能量损失做出定量、定向的评价,更准确地计算流场水力损失的大小和位置,本文引入基于热力学第二定律 的熵产分析理论进行分析。选用RNG κ-ε湍流模型对透平全流道进行数值模拟,并与实验结果进行对比,发现 计算结果与实验结果吻合性较好。对数值模拟结果进行熵产理论分析,得到了不同工况下导叶和转轮流域的熵 产,计算结果表明,在设计工况点,转轮流域流场的流线分布最佳,熵产最小,导叶和转轮流域熵产分别占总 熵产的 56%和 44%,转轮内高熵产率主要分布在入口区域,由冲击损失造成。在偏工况点转轮内流场出现旋 涡,熵产增大。转轮的熵产与内流场速度场分布相关,在非设计工况点,转轮流域内存在不良流动,引起的湍 流脉动导致水力损失增大,同时伴随着熵产的增加。结果表明,熵产理论在水力损失评估上具有明显的优势, 可以准确定位能量损失来源。
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关键词 : 液力透平转轮;数值模拟;熵产理论
Abstract
Hydraulic turbines are usually used to replace Joule-Thomson valves in petrochemical processes to reduce pressure, which can not only improve the overall efficiency, but also recover high-pressure liquid energy and improve energy efficiency. The overall performance of a hydraulic turbine is related to its efficiency of energy recovery. In order to make a quantitative and direct evaluation of the energy loss in the flow field of the hydraulic turbine, and to more accurately calculate the size and position of the hydraulic loss in the flow field, entropy production analysis theory based on the second law of thermodynamics is introduced for the analysis. The RNG κ-ε turbulence model is used to simulate the whole flow passage of the turbine, and compared with the experimental results. It is found that the calculated results are in good agreement with the experimental results. The entropy generation theory of the numerical simulation results is analyzed, and the entropy production of the guide vane and runner basin under different working conditions is obtained. The calculation results show that at the design operating point, the streamline distribution of the flow field of the runner basin is the best and the entropy production is the smallest. The entropy production of the guide vane and runner basin accounts for 56% and 44% of the total entropy production respectively, and the high entropy production in the runner is mainly distributed in the entrance area, which is caused by impact loss. There is a vortex in the flow field in the runner at the partial operating point, and the entropy production increases. The entropy production of the runner is related to the distribution of the velocity field of the internal flow field. At the off-design operating point, There are bad-behaved flow fields in the runner basin, which leads to an increase in hydraulic loss caused by turbulent pulsation, accompanied by an increase of entropy production. The results show that the entropy production theory has obvious advantages in hydraulic loss assessment and can accurately locate the source of hydraulic loss.

 

Key words: hydrodynamic turbine runner; numerical simulation; entropy production theory
收稿日期: 2020-06-30     
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通讯作者: zhenlinli@263.net
引用本文:   
HUANG Ning, LI Zhenlin. Application of entropy production theory in flow field analysis of hydraulic turbines. Petroleum Science Bulletin, 2020, 02: 269-276.
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