Hydraulic Characteristics of Inlet Vortex of Discharge Structures Based on Dispatch Regulation

doi:10.11988/ckyyb.20230512

Abstract

Abstract:

Suction vortices at the inlet of discharge structures often affect the discharge safety of water conservancy projects. Existing research primarily focuses on theoretical analyses and simulation methods for inlet vortices, while studies on the hydraulic response characteristics of vortices under operational disturbances are limited, especially with respect to scheduling control. We performed comparative experimental research through prototype observation, numerical simulations, and physical model experiments to elucidate the mechanisms and key factors influencing vortex formation. We also aim to clarify the hydraulic response of discharge structures under various regulation and operational conditions and to establish the relationship between water flow patterns and flood discharge scheduling methods. Our findings reveal that vortex formation and intensity are significantly affected by factors such as water flow velocity, circulation patterns, flow field boundary conditions, and the relative submergence depth at the gate. These vortices result from the combined effects of river regime, design and layout of flood discharge structures, and flood discharge scheduling practices. By optimizing discharge scheduling and regulation, we can effectively reduce the intensity of harmful vortices and mitigate operational risks associated with discharge structures.

Key words: discharge structure, inlet vortex, hydraulic characteristics, regulation technology, numerical simulation, physical model, prototype observation

CLC Number:

TV13水力学

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NIE Yan-hua, WANG Bo, HOU Dong-mei, HU Han. Hydraulic Characteristics of Inlet Vortex of Discharge Structures Based on Dispatch Regulation[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(11): 118-124.

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URL: http://ckyyb.crsri.cn/EN/10.11988/ckyyb.20230512

http://ckyyb.crsri.cn/EN/Y2024/V41/I11/118

Figures/Tables 8

Fig.1 Mathematical model

Fig.2 Physical model (1∶59 scale) and surface gate layout

Table 1 Typical flow velocity and direction in front of the gate

运行工况			水流流线与泄洪轴线夹角/(°)				流速/(m·s^-1)				闸首漩涡情况
下泄流量/ (m³·s^-1)	表孔开启	中孔开启	2^#	6^#	7^#	12^#	2^#	6^#	7^#	12^#	2^#	6^#	7^#	12^#
9 500	左	—	5	-45	—	—	0.08	0.10	—	—	—	Ⅱ型	—	—
	右	—	—	—	35	-30	—	—	0.07	0.05	—	—	Ⅱ型	—
	全	—	30	20	10	-10	0.05	0.06	0.07	0.08	—	—	—	—
11 000	左		15	-20	—	—	0.12	0.15	—	—	Ⅱ型	Ⅲ型	—	—
	右	左中	—	—	50	-30	—	—	0.20	0.15	—	—	Ⅲ型	Ⅲ型
	全		20	20	20	-10	0.20	0.10	0.10	0.05	—	—	—	—
	左		20	-20	—	—	0.15	0.20	—	—	无	Ⅲ型	—	—
	右	右中	—	—	50	-30	—	—	0.30	0.20	—	—	Ⅲ型	Ⅲ型
	全		20	20	10	-20	0.25	0.20	0.18	0.20	Ⅱ型	—	—	Ⅱ型
15 000	左		20	-20	—	—	0.30	0.55	—	—	—	Ⅴ型	—	—
	右	全中	—	—	65	-40	—	—	0.45	0.30	—	—	Ⅵ型	Ⅵ型
	全		15	10	0	-20	0.25	0.20	0.15	0.20	—	—	—	Ⅵ型
20 000	全	全中	45	10	10	-30	0.50	0.40	0.35	0.30	Ⅴ型	Ⅴ型	Ⅴ型	Ⅵ型

Table 1 Typical flow velocity and direction in front of the gate

运行工况			水流流线与泄洪轴线夹角/(°)				流速/(m·s^-1)				闸首漩涡情况
下泄流量/ (m³·s^-1)	表孔开启	中孔开启	2^#	6^#	7^#	12^#	2^#	6^#	7^#	12^#	2^#	6^#	7^#	12^#
9 500	左	—	5	-45	—	—	0.08	0.10	—	—	—	Ⅱ型	—	—
	右	—	—	—	35	-30	—	—	0.07	0.05	—	—	Ⅱ型	—
	全	—	30	20	10	-10	0.05	0.06	0.07	0.08	—	—	—	—
11 000	左		15	-20	—	—	0.12	0.15	—	—	Ⅱ型	Ⅲ型	—	—
	右	左中	—	—	50	-30	—	—	0.20	0.15	—	—	Ⅲ型	Ⅲ型
	全		20	20	20	-10	0.20	0.10	0.10	0.05	—	—	—	—
	左		20	-20	—	—	0.15	0.20	—	—	无	Ⅲ型	—	—
	右	右中	—	—	50	-30	—	—	0.30	0.20	—	—	Ⅲ型	Ⅲ型
	全		20	20	10	-20	0.25	0.20	0.18	0.20	Ⅱ型	—	—	Ⅱ型
15 000	左		20	-20	—	—	0.30	0.55	—	—	—	Ⅴ型	—	—
	右	全中	—	—	65	-40	—	—	0.45	0.30	—	—	Ⅵ型	Ⅵ型
	全		15	10	0	-20	0.25	0.20	0.15	0.20	—	—	—	Ⅵ型
20 000	全	全中	45	10	10	-30	0.50	0.40	0.35	0.30	Ⅴ型	Ⅴ型	Ⅴ型	Ⅵ型

Fig.3 Characteristic surface inlet vortices under different scheduling modes at flow rate 15 000 m3/s

Table 2 Mathematical simulation conditions

计算组次	上游水位/m	整体流量/ (m³·s^-1)	表孔闸门开度/m		中闸闸门开度/m
计算组次	上游水位/m	整体流量/ (m³·s^-1)	1^#—6^#	7^#—12^#	1^#—5^#	6^#—10^#
1	378	11 073	0.0	4.5	0.0	3.0
2	375	15 000	0.0	7.5	3.0	3.0
3	375	15 000	4.0	4.0	3.0	3.0

Table 2 Mathematical simulation conditions

计算组次	上游水位/m	整体流量/ (m³·s^-1)	表孔闸门开度/m		中闸闸门开度/m
计算组次	上游水位/m	整体流量/ (m³·s^-1)	1^#—6^#	7^#—12^#	1^#—5^#	6^#—10^#
1	378	11 073	0.0	4.5	0.0	3.0
2	375	15 000	0.0	7.5	3.0	3.0
3	375	15 000	4.0	4.0	3.0	3.0

Fig.4 Comparative analysis of numerical simulation results

Table 3 Characteristics of inlet vortices under different scheduling methods

运行工况			漩涡分布及类型	最大漩涡出现位置及直径
下泄流量/ (m³·s^-1)	表孔开启	中闸开启	漩涡分布及类型	最大漩涡出现位置及直径
11 000	左区6个表孔均匀开启4.5 m	左区5个中闸均匀开启3 m	6^#闸Ⅲ型纯水漩涡,2^#、3^#闸Ⅱ型表面凹陷涡,1^#、4^#、5^#闸无漩涡	6^#闸,1~2 m
	右区6个表孔均匀开启4.5 m		7^#、12^#闸Ⅲ型纯水漩涡,8^#—11^#闸Ⅱ型表面凹陷涡	7^#、12^#闸,2 m
	全部12个表孔均匀开启2.5 m		Ⅱ型表面凹陷涡(2^#、12^#闸),其他闸无漩涡	12^#闸,1 m
	左区6个表孔均匀开启4.5 m	右区5个中闸均匀开启3 m	6^#闸Ⅱ型表面凹陷涡,1^#—5^#闸无漩涡	6^#闸,1 m
	右区6个表孔均匀开启4.5 m		7^#闸Ⅵ型携物漩涡,12^#闸Ⅲ型纯水漩涡,8^#—11^#闸Ⅱ型表面凹陷涡	7^#闸,2~3 m
	全部12个表孔均匀开启2.5 m		2^#、12^#闸Ⅱ型表面凹陷涡,其他闸无漩涡	2^#、12^#闸,1 m
15 000	左区6个表孔均匀开启8 m	全部10个中闸均匀开启3 m	6^#闸Ⅴ型间歇吸气漩涡,2^#—5^#闸Ⅲ型纯水漩涡,1^#闸水流往复波动	6^#闸,3~4 m
	右区6个表孔均匀开启8 m		7^#、11^#、12^#闸Ⅵ型连续吸气漩涡,Ⅴ型间歇8^#、9^#闸吸气漩涡,10^#闸水流往复波动	12^#闸,4 m
	全部12个表孔均匀开启 4.0 m		12^#闸Ⅵ型携物漩涡,11^#闸Ⅲ型纯水漩涡,2^#、6^#、10^#闸Ⅱ型表面凹陷涡,其他闸无漩涡	12^#闸,2 m
17 000	全部12个表孔均匀开启5.5 m	全部10个中闸均匀开启3.5 m	10^#—12^#闸Ⅴ型间歇吸气漩涡,2^#—4^#闸Ⅵ型携物漩涡,5^#—9^#闸Ⅲ型纯水漩涡,1^#闸水流往复波动	12^#闸,4 m

Table 3 Characteristics of inlet vortices under different scheduling methods

运行工况			漩涡分布及类型	最大漩涡出现位置及直径
下泄流量/ (m³·s^-1)	表孔开启	中闸开启	漩涡分布及类型	最大漩涡出现位置及直径
11 000	左区6个表孔均匀开启4.5 m	左区5个中闸均匀开启3 m	6^#闸Ⅲ型纯水漩涡,2^#、3^#闸Ⅱ型表面凹陷涡,1^#、4^#、5^#闸无漩涡	6^#闸,1~2 m
	右区6个表孔均匀开启4.5 m		7^#、12^#闸Ⅲ型纯水漩涡,8^#—11^#闸Ⅱ型表面凹陷涡	7^#、12^#闸,2 m
	全部12个表孔均匀开启2.5 m		Ⅱ型表面凹陷涡(2^#、12^#闸),其他闸无漩涡	12^#闸,1 m
	左区6个表孔均匀开启4.5 m	右区5个中闸均匀开启3 m	6^#闸Ⅱ型表面凹陷涡,1^#—5^#闸无漩涡	6^#闸,1 m
	右区6个表孔均匀开启4.5 m		7^#闸Ⅵ型携物漩涡,12^#闸Ⅲ型纯水漩涡,8^#—11^#闸Ⅱ型表面凹陷涡	7^#闸,2~3 m
	全部12个表孔均匀开启2.5 m		2^#、12^#闸Ⅱ型表面凹陷涡,其他闸无漩涡	2^#、12^#闸,1 m
15 000	左区6个表孔均匀开启8 m	全部10个中闸均匀开启3 m	6^#闸Ⅴ型间歇吸气漩涡,2^#—5^#闸Ⅲ型纯水漩涡,1^#闸水流往复波动	6^#闸,3~4 m
	右区6个表孔均匀开启8 m		7^#、11^#、12^#闸Ⅵ型连续吸气漩涡,Ⅴ型间歇8^#、9^#闸吸气漩涡,10^#闸水流往复波动	12^#闸,4 m
	全部12个表孔均匀开启 4.0 m		12^#闸Ⅵ型携物漩涡,11^#闸Ⅲ型纯水漩涡,2^#、6^#、10^#闸Ⅱ型表面凹陷涡,其他闸无漩涡	12^#闸,2 m
17 000	全部12个表孔均匀开启5.5 m	全部10个中闸均匀开启3.5 m	10^#—12^#闸Ⅴ型间歇吸气漩涡,2^#—4^#闸Ⅵ型携物漩涡,5^#—9^#闸Ⅲ型纯水漩涡,1^#闸水流往复波动	12^#闸,4 m

Fig.5 Optimized surface inlet vortices under different scheduling modes at flow rate 15 000 m3/s

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