Hydraulic Characteristics and Application of Cylindrical Surge Tower for Blocking Water Hammer Propagation

doi:10.11988/ckyyb.20231434

Abstract

Abstract:

Safe and controllable water hammer pressure is a necessary condition to ensure the stable operation of long pressurized piping system. However, in ultra-long pressurized pipeline system, extreme accidents such as local pipe bursts may paralyze the entire system or lead to secondary disasters due to the widespread propagation of water hammer pressure throughout the entire pipeline.To address this issue, we introduce a cylindrical overflow surge tower designed to block water hammer propagation. The surge tower features a vertical inlet pipe, which effectively segments the pipelines and prevents water hammer from spreading. We analyzed the hydraulic characteristics of this surge tower using both model tests and numerical simulations. Our findings indicate that the flow patterns within the tower are uniform, and the overflow water dissipates sufficient energy before entering the downstream pipeline. Finally, we describe the application of this surge tower to the Chaoer River to Liaohe River Diversion Project. Results demonstrate that the surge tower effectively blocks the propagation of water hammer in case of local pipe bursts, thereby mitigating the negative impact of water hammer on the entire pipeline system. The findings offer valuable insights into protection strategies against water hammer for ultra-long pressurized piping systems.

Key words: ultra-long pressurized piping system, transient process, water hammer protection, blocking-up surge tower, hydraulic characteristics

CLC Number:

TV68

HOU Xiao-xia, XU Xiao-dong, SHI Tao, REN Kun-jie, XIN Fu-xuan, YANG Qing-yuan, HAN Song-lin. Hydraulic Characteristics and Application of Cylindrical Surge Tower for Blocking Water Hammer Propagation[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(10): 86-93.

Figures/Tables 17

Fig.1 Schematic diagram of the Chaoer River to Liaohe River Diversion Project

Fig.2 Original design of protection against water hammer

Table 1 Branch pipeline parameters of the Chaoer River to Liaohe River Diversion Project

支线	长度/km	管径/mm	引用流量/(m³·s^-1)
突泉支线1	2.76	800	0.37
突泉支线2	1.00	1 200	1.00
科右中旗支线	19.51	1 400	1.29
扎鲁特旗支线	29.96	2 000	3.62
科左中旗支线	90.17	1 100	0.65
开鲁支线	2.50	900	0.65
经济技术开发区支线	33.22	1 800	2.55
科尔沁南区支线	41.25	2 400	4.49

Fig.3 Pressure envelopes under normal emergencies and extreme emergencies for the original design scheme

Fig.4 Schematic diagram of blocking-up surge tower

Table 2 Position and dimensions of blocking-up surge tower

调压塔编号	桩号	底部高程/ m	下溢高程/ m	外溢高程/ m	塔顶高程/ m	内塔内径/ m	外塔内径/ m
1^#	T141+903.57	259.80	273.5		285.1	5.2	11.0
2^#	T274+694	203.57	236.5	239.5	242.0	5.2	11.0
3^#	T318+400	207.46	215.0	218.0	221.0	5.2	11.0

Fig.5 Layout of protection facilities against water hammer for blocking-up surge tower scheme

Fig.6 Photo of physical model test

Fig.7 Three-dimensional model of blocking-up surge tower

Table 3 Calculation working modes of transient process

工况分类	计算工况	工况说明
常规过渡过程工况	主线控制阀关闭	支线阀门始终关闭,主线阀门2 400 s内关闭
常规过渡过程工况	所有支线阀门同时开启	各支线阀门同时开启到设计流量开度
爆管极端事故过渡工况	1^#—2^#调压塔之间管线低处爆管	爆管面积从600 s内发展到管道断面大小
爆管极端事故过渡工况	2^#—3^#调压塔之间管线低处爆管	爆管面积从60 s内发展到管道断面大小

Fig.8 Head envelopes in conventional transient processes

Fig.9 Head envelopes in pipe-burst extreme conditions

Fig.10 Nephogram of fow pattern distribution under free flow conditions of the inner-tower

Fig.11 Flow distribution of blocking-up surge tower of model test

Fig.12 Bubble aggregation and emission in downstream pipelines

Fig.13 Nephogram of flow pattern distribution under submerged discharge in inner-tower while free flow in outer-tower

Fig.14 Pressure distribution at the bottom of the blocking-up surge tower

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