Tackling of hydraulic cavitation in pressurized pipe flow using high- or low-density polyethylene penstock and short-section

IF 2.1 4区 环境科学与生态学 Q2 ENGINEERING, CIVIL AQUA-Water Infrastructure Ecosystems and Society Pub Date : 2023-10-31 DOI:10.2166/aqua.2023.189
Dalila Kraiem, Ali Triki
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Abstract

Abstract Recent studies have proved that the utilization of polyethylene (PE) short-section or penstock is a promising water hammer control tool. However, the interplay between the magnitude attenuation and the phase offset of pressure-wave oscillations remains challenging. This study aimed at inspecting the capacity of a dual PE penstock/short-section-based control technique, with regard to the aforementioned interplay. In this technique, a PE penstock was lumped to the transient initiating zone of the main pipe and a short-section of the counter extremity of the pipe was replaced with PE. The transient pressure-wave behavior in a gravitational viscoelastic pipe involving cavitation was described by the extended 1D water hammer equations embedding the Vitkovsky and Kelvin–Voigt add-ons. The numerical solution was performed by the fixed grid method of characteristics. The high- (HDPE) and low-density (LDPE) were demonstrated in this study. Analysis revealed that upgrading techniques based on LDPE enabled a desirable tradeoff between the magnitude attenuation and the phase offset of pressure-wave oscillations. Particularly, the dual penstock/short-section specific upgrading technique allowed a more important attenuation magnitude of pressure peak (or crest), and led to a similar expansion of the wave oscillation period. Furthermore, results evidenced that the proposed technique outperformed the renewal of the original piping system.
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利用高密度或低密度聚乙烯压力管和短截面处理高压管道中的水力空化现象
摘要近年来的研究证明,利用聚乙烯(PE)短截面或压力管是一种很有前途的水锤控制工具。然而,压力波振荡的幅度衰减与相位偏移之间的相互作用仍然具有挑战性。本研究旨在考察双PE压力管/基于短截面的控制技术在上述相互作用方面的能力。在该技术中,将PE压力管集中在主管道的瞬态起爆区,并将管道反端的短段替换为PE。采用嵌入Vitkovsky和Kelvin-Voigt附加分量的一维水锤扩展方程描述了重力粘弹性管中含空化的瞬态压力波行为。采用特征固定网格法进行数值求解。高密度(HDPE)和低密度(LDPE)在本研究中得到证实。分析表明,基于LDPE的升级技术可以在压力波振荡的幅度衰减和相位偏移之间实现理想的权衡。特别是,双压力管/短截面特定升级技术允许更重要的压力峰值(或峰值)衰减幅度,并导致波浪振荡周期的类似扩展。此外,结果表明,所提出的技术优于原有管道系统的更新。
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来源期刊
CiteScore
4.10
自引率
21.10%
发文量
0
审稿时长
20 weeks
期刊最新文献
Biogas production from water lilies, food waste, and sludge: substrate characterization and process performance How suitable is the gold-labelling method for the quantification of nanoplastics in natural water? Corrigendum: AQUA – Water Infrastructure, Ecosystems and Society 72 (7), 1115–1129: Application of system dynamics model for reservoir performance under future climatic scenarios in Gelevard Dam, Iran, Ali Babolhakami, Mohammad Ali Gholami Sefidkouhi and Alireza Emadi, https://dx.doi.org/10.2166/aqua.2023.193 Exploring the rise of AI-based smart water management systems Unraveling air–water two-phase flow patterns in water pipelines based on multiple signals and convolutional neural networks
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