用刚性水柱全局梯度算法扩展EPANET液压求解器容量

IF 2.4 3区 环境科学与生态学 Q2 ENGINEERING, CIVIL
Mehmet Melih Koşucu , Enes Albay , Mehmet Cüneyd Demirel
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引用次数: 2

摘要

EPANET是基于稳态和长周期模拟方法的水利配水网络(wdn)建模中最常用的开源程序之一。这些方法有效地估计了网络的流量和平均压力;然而,EPANET还不能完全有效地模拟wdn中的不可压缩非定常流场。本文采用刚性水柱全局梯度算法(RWC-GGA)对EPANET 3的水力求解能力进行了扩展,以模拟wdn中不可压缩非定常流力学。此外,我们在默认的EPANET代码中动态加入了比现有的更精确的阀门表达式,并在求解器代码中引入了一种新的全局收敛算法——收敛跟踪控制方法(CTCM)。RWC-GGA、CTCM和阀门表达式在三种不同的wdn中进行了测试和验证,这些wdn从简单到复杂都有。结果表明,不可压缩非定常流动可以用RWC-CGA和动态阀表示来建模。最后,利用实现的全局收敛算法CTCM解决了气门运动和压力相关算法(PDA)的收敛问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Extending EPANET hydraulic solver capacity with rigid water column global gradient algorithm

EPANET is one of the most commonly used open-source programs in hydraulic modelling water distribution networks (WDNs), based on steady-state and extended period simulation approaches. These approaches effectively estimate flow capacity and average pressures in networks; however, EPANET is not yet fully effective in modelling incompressible unsteady flows in WDNs. In this study, the hydraulic solver capacity of EPANET 3 is extended with the Rigid Water Column Global Gradient Algorithm (RWC-GGA) to model incompressible unsteady flow hydraulics in WDNs. Moreover, we incorporated dynamically more accurate valve expressions than the existing ones in the default EPANET code and introduced a new global convergence algorithm, Convergence Tracking Control Method (CTCM), in the solver code. The RWC-GGA, CTCM, and valve expressions are tested and validated in three different WDNs varying from simple to sophisticated set-ups. The results show that incompressible unsteady flows can be modelled with RWC-CGA and dynamic valve representations. Finally, the convergence problem due to the valve motion and the pressure-dependent algorithm (PDA) is solved by the implemented global convergence algorithm, i.e. CTCM.

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来源期刊
Journal of Hydro-environment Research
Journal of Hydro-environment Research ENGINEERING, CIVIL-ENVIRONMENTAL SCIENCES
CiteScore
5.80
自引率
0.00%
发文量
34
审稿时长
98 days
期刊介绍: The journal aims to provide an international platform for the dissemination of research and engineering applications related to water and hydraulic problems in the Asia-Pacific region. The journal provides a wide distribution at affordable subscription rate, as well as a rapid reviewing and publication time. The journal particularly encourages papers from young researchers. Papers that require extensive language editing, qualify for editorial assistance with American Journal Experts, a Language Editing Company that Elsevier recommends. Authors submitting to this journal are entitled to a 10% discount.
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