基于计算流体动力学(CFD)的闸阀水力分析

E. Žic, Patrik Banko, L. Lešnik
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引用次数: 4

摘要

作为大多数供水系统的一个非常重要的部件,阀门暴露在强烈的水动力作用下。当暴露在大量物理量下时,阀门和管道可能会损坏,从而危及供水系统的性能。这就是为什么有必要预测和确定在一定条件下系统中可能出现的速度、压力和其他物理量的最大值的主要原因。预测极端条件使我们能够根据阀门可能暴露的预期条件正确调整阀门的尺寸,这也是本文的主要目标。预测和确定阀门极值的方法之一是利用计算流体力学(CFD)进行仿真。这正是本文准备中所使用的方法,目的是深入了解在阀门关闭的特征程度下位于管道内的闸阀模型的物理量级。采用Ansys CFX 19.1和Ansys Fluent 19.1软件进行水动力仿真分析,得到了所需的结果。对四种开度闸阀进行了水动力分析
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Hydraulic analysis of gate valve using computational fluid dynamics (CFD)
As a very important element of most water supply systems, valves are exposed to the effects of strong hydrodynamic forces. When exposed to large physical quantities, the valve and piping can be damaged, which could endanger the performance of a water supply system. This is the main reason why it is necessary to foresee and determine the maximum values of velocity, pressure and other physical quantities that can occur in the system under certain conditions. Predicting extreme conditions allows us to correctly size the valve for the expected conditions to which the valve might be exposed, which is also the main objective of this paper. One of the methods for predicting and determining extreme values on a valve is to perform a simulation with computational fluid dynamics (CFD). This is exactly the method used in the preparation of this paper with the aim of gaining insight into the physical magnitudes for models of gate valves positioned inside a pipe under characteristic degrees of valve closure. The Ansys CFX 19.1 and Ansys Fluent 19.1 software was used to simulate the hydrodynamic analysis and obtain the required results. The hydrodynamic analysis was performed for four opening degrees of gate valve
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来源期刊
Scientific Review Engineering and Environmental Sciences
Scientific Review Engineering and Environmental Sciences Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
1.50
自引率
0.00%
发文量
24
审稿时长
26 weeks
期刊介绍: Scientific Review Engineering and Environmental Sciences [Przegląd Naukowy Inżynieria i Kształtowanie Środowiska] covers broad area of knowledge and practice on fields such as: sustainable development, landscaping of non-urbanized lands, environmental engineering, construction projects engineering land management, protection and land reclamation, environmental impact of investments, ecology, hydrology and water management, ground-water monitoring and restoration, geotechnical engineering, meteorology and connecting subjects. Authors are welcome to submit theoretical and practice-oriented papers containing detailed case studies within above mentioned disciplines. However, theoretical papers should contain part with practical application of the theory presented. Papers (in Polish or English languages) are accepted for publication after obtaining positive opinions of two reviewers. Papers published elsewhere are not accepted.
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