Entropic Analysis of Processes in Control Valves

I. Diaconescu
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Abstract

The thermodynamic analysis of irreversible processes has an important influence in energy efficiency growing of any thermodynamic processes or systems. All of thermodynamic processes are entropy generators but there are processes with such a high level of irreversibility so that couldn’t be ignored. That is why is so important to identify what causes entropy generation and also to identify those system components that contribute the most to the overall irreversibility of the thermodynamic system. One of the processes with the highest level of entropy generation is flow with friction in various ducts and flow networks such as control valves. In order to see the direct connection between frictional pressure drop and thermodynamic irreversibility the paper will firstly analyze the steady and adiabatic flow of pure substance through a short segment of pipe with variable section (control valve). Because the entropy generation value during the throttling process is proportional to control valve pressure drop, the paper will do a flow thermodynamic analysis inside the control valve and the conclusions about drop pressure in different working conditions will be taken. Pressure drops along a valve are not constant, but rather vary in relation to the port left open by the plug. They normally increase as the valve narrowest section is reduced, although the upstream drop does increase at a slower rate than the downstream one. Actual increases and decreases in pressure drop and their effects are related to valve type and flow direction. It can be deduced that, for all types, pressure drops increase at flow tending to close, mainly as a result of the increased drop generated downstream. Also, the paper will take into account the drop pressure variation during the substance flow and will be analyzed its influence on the process irreversibility. In the same time, the paper will analyze the change of state influence during the liquid throttling process on the entropy generation, in situations of low titer bipolar phase fluid or high titer bi-phase fluid and will identify this phenomenon effects and remedies.
控制阀过程的熵分析
不可逆过程的热力学分析对任何热力学过程或系统的能效提高都有重要的影响。所有的热力学过程都是熵的产生者,但是有些过程的不可逆性非常高,所以不能忽略。这就是为什么确定导致熵产生的原因以及确定那些对热力学系统整体不可逆性贡献最大的系统成分是如此重要。熵产最高的过程之一是各种管道和流量网络(如控制阀)中的摩擦流。为了了解摩擦压降与热力学不可逆性之间的直接联系,本文首先分析纯物质通过变截面短段管道(控制阀)的定常绝热流动。由于节流过程中的熵产值与控制阀压降成正比,本文将对控制阀内部进行流动热力学分析,得出不同工况下的压降结论。沿阀门的压降不是恒定的,而是随插头打开的端口而变化。它们通常随着阀门最窄段的减小而增加,尽管上游的液滴确实比下游的液滴增加的速度慢。压降的实际增减及其影响与阀门类型和流向有关。可以推断,对于所有类型,压降在流动趋于关闭时都增加,这主要是由于下游产生的压降增加。同时,本文将考虑物质流动过程中的降压变化,并分析其对过程不可逆性的影响。同时,本文将分析低滴度双相流体和高滴度双相流体在节流过程中状态的变化对熵产的影响,并找出这一现象的影响和补救措施。
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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