糙率对长距离输水管线水力特性的影响及应对措施

doi:10.11988/ckyyb.20240934

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (8): 208-216.DOI: 10.11988/ckyyb.20240934

• 重大引调水工程基础理论与关键技术研究专栏 • 上一篇下一篇

糙率对长距离输水管线水力特性的影响及应对措施

后小霞¹^,²(), 徐晓东³, 石韬⁴, 赵峰⁵, 姜治兵¹^,², 韩松林¹^,²()

¹ raybet体育在线水力学研究所,武汉 430010
² raybet体育在线水利部长江中下游河湖治理与防洪重点实验室,武汉 430010
³ 内蒙古引绰济辽供水有限责任公司,内蒙古乌兰浩特 137400
⁴ 内蒙古自治区水利水电勘测设计院,呼和浩特 010020
⁵ 内蒙古水务投资集团有限公司,呼和浩特 010020

收稿日期:2024-09-03 修回日期:2024-12-10 出版日期:2025-08-01 发布日期:2025-08-01
通信作者:
韩松林(1986-),男,河南林州人,高级工程师,博士,研究方向为水工水力学和计算水力学。E-mail:slhan@hotmail.com
作者简介:
后小霞(1991-),女,甘肃渭源人,工程师,博士,研究方向为引调水工程过渡过程。E-mail:xxhouwh@whu.edu.cn
基金资助:
中央级公益性科研院所基本科研业务费基金资助项目(CKSF2023317+SL)

Influence of Roughness Coefficient on Hydraulic Characteristics of Long-distance Water Conveyance Pipelines and Countermeasures

HOU Xiao-xia¹^,²(), XU Xiao-dong³, SHI Tao⁴, ZHAO Feng⁵, JIANG Zhi-bing¹^,², HAN Song-lin¹^,²()

¹ Department of Hydraulics, Changjiang River Scientific Research Institute, Wuhan 430010, China
² Key Laboratory of River & Lake Management and Flood Control in the Middle and Lower Reaches of Changjiang River of Ministry of Water Resources, Changjiang River Scientific Research Institute, Wuhan 430010, China
³ Inner Mongolia Chuo’er River-Xiliao River Diversion Water Supply Co., Ltd., Ulanhot 137400, China
⁴ Inner Mongolia Water Conservancy and Hydropower Survey and Design Institute, Hohhot 010020, China
⁵ Inner Mongolia Water Industry Investment Group Co., Ltd., Hohhot 010020, China

Received:2024-09-03 Revised:2024-12-10 Published:2025-08-01 Online:2025-08-01

摘要/Abstract

摘要：

长距离输水管道在运行初期管线糙率一般较小,运行一定年限后糙率逐渐增大,糙率大小直接影响工程输水能力和运行安全,开展糙率对稳定运行工况和过渡过程中管线水力特性的影响研究,并提出应对糙率变化的措施是保证工程长久高效运行的必要条件。以引绰济辽工程有压管线段206 km长的PCCP管为例,采用一维特征线法分析糙率变化对管线输水能力和过渡过程中水力特性的影响。研究表明:在稳定运行工况下当管线糙率偏大,管线引用流量减小,管线沿程水头损失增加,阀前管道压力减小,而阀后管道压力增大;在过渡过程中随糙率增大,水锤波传播的摩阻增大,管线压力与调压室水位极值均发生一定变化,工程设计时需考虑一定压力富裕度;采用改变管线阀门开度的方式应对管线糙率变化带来的风险,既能保证工程引用流量,又能将管线压力控制在安全范围之内。研究成果可为长距离输水管线糙率变化应对措施提供参考。

关键词: 长距离输水管线, 糙率, 水锤防护, 过渡过程, 过流能力, 水力特性

Abstract:

[Objective] In the early stage operation of long-distance water conveyance pipelines, the actual roughness coefficient is generally lower than the design value. After years of operation, factors such as erosion, sedimentation, and the growth of aquatic organisms cause the roughness coefficient to gradually increase, which directly affects the water conveyance capacity and operational safety of the project. This study systematically investigates the influence of roughness coefficient variations on the hydraulic characteristics of complex water conveyance pipelines under both stable operation and transient process. [Methods] The 206 km-long pressurized PCCP pipeline section of Chuo’er River to Xiliao River Diversion Project was taken as a case study (with surge protection measures of impedance-type surge tanks and flow and pressure regulating valves). The one-dimensional method of characteristics was used to analyze the influence of roughness coefficient variations on hydraulic characteristics during stable operation and transient process. Operational risks were evaluated, and strategies to address roughness uncertainty were proposed from the perspective of operational scheduling. [Results] Under stable operating conditions, when pipeline roughness coefficient was relatively high, the reference flow rate decreased, posing a risk of failing to meet the design flow rate. Additionally, the head loss along the pipeline increased, while the flow rate decreased. When the opening degree of the flow and pressure regulating valve at the mid-section of the main pipeline remained unchanged, the head drop at the valve location diminished accordingly. This resulted in decreased pressure on the main pipeline upstream of the flow and pressure regulating valve and increased pressure downstream, necessitating special attention to the influence of pipeline pressure variations. During the transient process, the water hammer waves generated by pipeline pressure fluctuations superimposed with the mass waves caused by water level fluctuations in the surge tank. After the valve was closed, the fluctuations propagated independently in the upstream and downstream sections of pipelines and gradually attenuated. With increasing roughness coefficients, the frictional damping of the water hammer waves increased, leading to reduced amplitude of head fluctuations before and after the valve, decreased magnitude of surge tank water level fluctuations, and lower stabilized water levels. Therefore, an adequate pressure margin should be considered in engineering design. It was possible to address the uncertainty caused by roughness coefficient variations by adjusting the opening degree of the flow and pressure regulating valve on the mid-section of main pipeline and terminal valves on branch pipelines, thereby ensuring the design flow rate. However, after the valve operation mode was adjusted, the pipeline pressure became dependent on the roughness coefficients and valve opening degree, making it necessary to verify in advance whether the pressure along the entire pipeline met the water hammer protection requirements. [Conclusions] In the design of long-distance water conveyance pipelines, the influence of pipeline roughness coefficient on both flow rate and hydraulic characteristics must be considered, and the upper and lower limits of roughness coefficient variations should be reasonably predicted. The upper limit is used to ensure the water conveyance capacity during long-term operation, while the lower limit is used to cope with the relatively large residual head in the early stage of operation. The findings of this study serve as a references for addressing roughness coefficient uncertainty in the design of long-distance water conveyance pipelines.

Key words: long-distance water conveyance pipelines, roughness coefficient, water hammer protection, transient process, flow capacity, hydraulic characteristics

中图分类号:

TV68

后小霞, 徐晓东, 石韬, 赵峰, 姜治兵, 韩松林. 糙率对长距离输水管线水力特性的影响及应对措施[J]. raybet体育在线院报, 2025, 42(8): 208-216.

HOU Xiao-xia, XU Xiao-dong, SHI Tao, ZHAO Feng, JIANG Zhi-bing, HAN Song-lin. Influence of Roughness Coefficient on Hydraulic Characteristics of Long-distance Water Conveyance Pipelines and Countermeasures[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(8): 208-216.

图/表 17

图1 特征线法求解管线示意图

Fig.1 Schematic diagram of calculating pipeline’s transient process by using the method of characteristics

图2 上游水库计算示意图

Fig.2 Schematic diagram of calculating the upstream reservoir boundaries

图3 分支管节点计算示意图

Fig.3 Schematic diagram of calculating branch pipe nodes

图4 引绰济辽工程有压管段布置

Fig.4 Layout of pressurized pipeline section in Chuo’er-Xiliao River Diversion Project

表1 引绰济辽工程支线特性

Table 1 Characteristics of branch pipelines in Chuo’er-Xiliao River Diversion Project

支线	主线里程/ (km+m)	长度/ km	管径/ mm	引用流量/ (m³·s^-1)	管道类型
突泉支线1	113+034	2.76	800	0.37
突泉支线2	121+800	1.00	1 200	1.00
科右中旗支线	157+669	19.51	1 400	1.29	球墨铸铁管
扎鲁特旗支线	212+823	29.96	2 000	3.62
科左中旗支线	287+099	90.17	1 100	0.65
开鲁支线	302+520	2.50	900	0.65
经济技术开发区	310+820	33.22	1 800	2.55	PCCP管道
科尔沁南区支线	318+416	41.25	2 400	4.49

图5 糙率对管线过流量影响

Fig.5 Influence of roughness coefficient on pipeline flow rate

图6 不同管线糙率下主线水力坡降线与压力分布

Fig.6 Hydraulic gradient lines and pressure distribution of main pipeline under different roughness coefficients

表2 过渡过程计算工况

Table 2 Calculation conditions for transient process

计算工况	管线糙率	初始状态	过渡过程	结束状态
主线调流调压阀关闭过程	0.010 0	主线正常过流,各支线阀门关闭,中部调流调压阀全开,流量全部进入莫力庙水库	中部调流调压阀逐渐关闭(1 200 s内分段关闭)	中部调流调压阀关闭,管线不过流,流量全部从稳流连接池溢出
	0.010 5
	0.011 0
	0.011 5
	0.012 0
	0.012 5
主线调流调压阀开启过程	0.010 0	主线与各支线阀门关闭,管线不过流,流量全部从稳流连接池溢出	中部调流调压阀逐渐开启(1 200 s内线性开启)	主线中部调流调压阀全开,各支线末端阀门关闭,流量全部进入莫力庙水库
	0.010 5
	0.011 0
	0.011 5
	0.012 0
	0.012 5

图7 主线中部调流调压阀启闭过程

Fig.7 Opening and closing processes of flow and pressure regulating valve at mid-section of main pipeline

图8 中部调流调压阀关闭工况主线水头包络线

Fig.8 Water head envelopes of main pipeline when mid-section flow and pressure regulating valve is closed

图9 中部调流调压阀关闭工况特征建筑物水力特性变化过程

Fig.9 Variations in hydraulic characteristics of key structures when mid-section flow and pressure regulating valve is closed

图10 中部调流调压阀开启工况主线水头包络线

Fig.10 Water head envelopes of main pipeline when mid-section flow and pressure regulating valve is open

图11 中部调流开启过程中特征建筑物水力特性变化过程

Fig.11 Variations in hydraulic characteristics of key structures during the opening of mid-section flow regulating valve

表3 不同管线糙率工况下引用设计流量时各阀门流量系数Kv

Table 3 Values of Kv of valves with different roughness coefficients (reference design flow rate) m3/h

工况	糙率 n	中部阀门	支线阀门
			突泉支线1	突泉支线2	科右中旗		扎鲁特	科左中旗		开鲁	经济开发区	科尔沁南区
			突泉支线1	突泉支线2	泵站	西日道卜	扎鲁特	花吐骨拉	宝龙山	开鲁	经济开发区	科尔沁南区
稳定运行工况	0.010 0	7 750	1 150	1 745	1 785	935	7 082	715	625	2 832	6 160	11 235
	0.011 0	8 659	1 188	1 763	1 936	1 016	8 408	740	780	2 876	7 055	12 649
	0.012 5	11 535	1 191	1 779	2 120	1 116	10 280	740	870	2 868	7 290	13 010

图12 不同糙率下引用设计流量时管线水力坡降线

Fig.12 Hydraulic gradient lines at design flow rate under different roughness coefficients

图13 中部调流调压阀关闭过程中主线水头包络线

Fig.13 Water head envelopes of main pipeline during the closing of mid-section flow and pressure regulating valve

图14 中部调流调压阀关闭过程中特征建筑物水力特性演变过程

Fig.14 Variations in hydraulic characteristics of key structures during the closing of mid-section flow and pressure regulating valve

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糙率对长距离输水管线水力特性的影响及应对措施

Influence of Roughness Coefficient on Hydraulic Characteristics of Long-distance Water Conveyance Pipelines and Countermeasures

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