Sensitivity Analysis of Optimal Flow Allocation Scheme for a Water Diversion Pump Station

doi:10.11988/ckyyb.20240514

Abstract

Abstract:

To address the insufficient reliability and practicality in the optimal flow allocation scheme, which arises from flow monitoring errors during water pumping at diversion pump stations, we developed an optimal flow allocation model based on the particle swarm optimization algorithm. This model reveals how the number of pumping units and overall efficiency respond to flow monitoring errors, and identifies a sensitive range for the optimal number of power-on pumping units to guide real-time control strategies. With the Liyuzhou Pumping Station from the Pearl River Delta Water Resources Allocation Project as a case study, our results indicate that the sensitive range for the optimal number of pumping units primarily concentrates in the transition zone during number adjustments. When the flow monitoring error remains constant, this sensitive range expands as flow increases, with the proportion of the sensitive range positively correlated to the absolute value of the monitoring error. Additionally, flow monitoring error leads to changes (fluctuating within 2%) in the efficiency of pumping station. Consequently, when making start-up plans for the pumping station, it is crucial to pay special attention to flow monitoring errors in the transition interval of operating conditions, as these conditions significantly impact the necessity for unit regulation adjustments.

Key words: water diversion pump station, optimal flow allocation, sensitivity analysis, flow monitoring error, particle swarm optimization algorithm

CLC Number:

TV675

Cite this article

XU Si-yu, ZHANG Zhao, LEI Xiao-hui, DU Meng-ying, JING Xiang, FAN Hai-long. Sensitivity Analysis of Optimal Flow Allocation Scheme for a Water Diversion Pump Station[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(10): 23-29.

share this article

0
/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: http://ckyyb.crsri.cn/EN/10.11988/ckyyb.20240514

http://ckyyb.crsri.cn/EN/Y2024/V41/I10/23

Figures/Tables 10

Table 1 Basic information of the pump station[17-18]

泵站名称	台数	泵站流量/(m³·s^-1)		泵站扬程/m
泵站名称	台数	最小值	最大值	最小值		最大值
鲤鱼洲	8	20	80	12.3		48.0

Table 1 Basic information of the pump station[17-18]

泵站名称	台数	泵站流量/(m³·s^-1)		泵站扬程/m
泵站名称	台数	最小值	最大值	最小值		最大值
鲤鱼洲	8	20	80	12.3		48.0

Fig.1 Curves of motor efficiency

Fig.2 Constraint area of safe and stable operation of water pump

Fig.3 Flowchart of solution to the optimal flow allocation model for pumping station

Table 2 Optimal flow allocation scheme under partial working conditions

扬程/m	不同泵站流量下各机组分配的流量/(m³·s^-1)				机组编号
扬程/m	20 m³/s	40 m³/s	60 m³/s	80 m³/s	机组编号
12.3	10	10	10.01	—	1
	10	10	10.01	—	2
	0	10	10.01	—	3
	0	10	10.01	—	4
	0	0	9.99	—	5
	0	0	9.99	—	6
	0	0	0	—	7
	0	0	0	—	8
30.3	10	13.33	11.92	12.89	1
	0	0	0	0	2
	10	13.33	11.92	12.85	3
	0	0	0	0	4
	0	13.33	12.07	13.53	5
	0	0	0	13.53	6
	0	0	12.04	13.59	7
	0	0	12.04	13.59	8

Table 2 Optimal flow allocation scheme under partial working conditions

扬程/m	不同泵站流量下各机组分配的流量/(m³·s^-1)				机组编号
扬程/m	20 m³/s	40 m³/s	60 m³/s	80 m³/s	机组编号
12.3	10	10	10.01	—	1
	10	10	10.01	—	2
	0	10	10.01	—	3
	0	10	10.01	—	4
	0	0	9.99	—	5
	0	0	9.99	—	6
	0	0	0	—	7
	0	0	0	—	8
30.3	10	13.33	11.92	12.89	1
	0	0	0	0	2
	10	13.33	11.92	12.85	3
	0	0	0	0	4
	0	13.33	12.07	13.53	5
	0	0	0	13.53	6
	0	0	12.04	13.59	7
	0	0	12.04	13.59	8

Fig.4 Distribution of the optimal number of power-on pumping units

Fig.5 Pumping station efficiency

Fig.6 Sensitive ranges under different flow monitoring errors

Table 3 Proportion of sensitive areas under the influence of different flow monitoring errors

监测误差/%	占比/%	监测误差/%	占比/%
+1	3.52	-1	3.41
+3	8.37	-3	8.85
+5	13.79	-5	15.18

Table 3 Proportion of sensitive areas under the influence of different flow monitoring errors

监测误差/%	占比/%	监测误差/%	占比/%
+1	3.52	-1	3.41
+3	8.37	-3	8.85
+5	13.79	-5	15.18

Table 4 Proportions of pumping station efficiency variation under different flow monitoring errors

类别	误差/ %	占比/%			类别	误差/ %	占比/%
类别	误差/ %	变幅 0~2%	变幅 2%~ 4%	变幅 4%~ 6%	类别	误差/ %	变幅 0~2%	变幅 2%~ 4%	变幅 4%~ 6%
敏感区域	+1	85.63	14.37	0.00	不敏感区域	+1	98.45	1.55	0.00
	-1	87.31	12.69	0.00		-1	97.57	2.43	0.00
	+3	86.64	13.11	0.25		+3	97.49	2.51	0.00
	-3	92.73	7.27	0.00		-3	96.32	3.68	0.00
	+5	91.97	7.65	0.38		+5	96.83	3.11	0.06
	-5	91.31	8.34	0.35		-5	96.71	3.16	0.13

Table 4 Proportions of pumping station efficiency variation under different flow monitoring errors

类别	误差/ %	占比/%			类别	误差/ %	占比/%
类别	误差/ %	变幅 0~2%	变幅 2%~ 4%	变幅 4%~ 6%	类别	误差/ %	变幅 0~2%	变幅 2%~ 4%	变幅 4%~ 6%
敏感区域	+1	85.63	14.37	0.00	不敏感区域	+1	98.45	1.55	0.00
	-1	87.31	12.69	0.00		-1	97.57	2.43	0.00
	+3	86.64	13.11	0.25		+3	97.49	2.51	0.00
	-3	92.73	7.27	0.00		-3	96.32	3.68	0.00
	+5	91.97	7.65	0.38		+5	96.83	3.11	0.06
	-5	91.31	8.34	0.35		-5	96.71	3.16	0.13

Related Articles 15

[1]	NIU Yun-gang, MA Feng-hai, WANG Qiong-yi. Deformation of Foundation Pit Retaining Piles in Footwall Zone Influenced by Normal Fault [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(9): 130-137.
[2]	GAO Lin-jing, DAI Jun-de, XU Ze-yong, ZHANG Jie, LIANG Bin. Impact of Deep Foundation Pit Excavation for Luoyang Longmen Comprehensive Transportation Hub on Adjacent Pipelines [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(4): 157-165.
[3]	DING Ze-lin, WEI Xin-ke, WANG Jing, ZHU Xuan-yi, GAO Yu-peng. Modelling of Hydraulic Structure Materials and Application to Cementitious Sand Gravel Dam [J]. Journal of Yangtze River Scientific Research Institute, 2023, 40(12): 181-187.
[4]	WU He-gao, YU Jin-hong, SHI Chang-zheng, SHI Ya-zhu. Sensitivity Analysis for Parameters of Buried Steel Pipes Based on Orthogonal Test Method [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(8): 97-103.
[5]	BI Biao, QIAN Yun-kai, AI Xian-feng, ZHAO Ting-ning. Sensitivity Analysis of VG Model Parameters under Rainfall Infiltration Using HYDRUS-1D Simulation [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(7): 36-41.
[6]	LAI Han, WANG Rui-jun, LI Yang, XIONG Xiao-bin, ZHANG Xu, YU Ning-ning, LEI Yan. Sensitivity Analysis of VC Value of Cemented Sand, Gravel and Rock Dam Building Materials [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(3): 142-148.
[7]	WU Guang-dong, XU Ji-jun, Hoshin Gupta, ZHANG Xiao. The “abcd” Water Balance Model: Application to Xin’an River Basin and Sensitivity Analysis [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2019, 36(7): 23-27.
[8]	CHANG Jun-bin, KE Xian-min, WANG Wei, SUN Qi-ming, TIAN Guo-lin. Field Test and Numerical Simulation on Seepage Well of Mazhen County [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2019, 36(7): 83-88.
[9]	LIU Chong, SHEN Zhen-zhong, GAN Lei, DANZENG Chi-lie, YAN Zhong-qi. A Time Series Prediction Model of High Slope Displacement Based on Support Vector Machine and Elman Neural Network [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2019, 36(5): 62-68.
[10]	NIE Bing-qi,TANG Ming-gao,SHAO Shan,MA Xin-jian,LI Yun-jie,YANG He. Sensibility Analysis of Influencing Factors of Reservoir Slope Stability Based on Grey Correlation [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2019, 36(1): 123-126.
[11]	WANG Wen-po, HAN Ai-guo, REN Guang-ming, YANG Lei, HUANG Wen-fang. Sensitivity Analysis of Hazard-brewing Environmental Factors ofLandslides in Puge County of Sichuan Province [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2018, 35(9): 63-67.
[12]	FU Hao-long,LUO Yu-feng,LI Ya-long. Evaluation and Analysis of Forecasting Short-term Daily ReferenceCrop Evapotranspiration by Hargreaves-Samani Equation Based onTemperature Forecast [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2018, 35(2): 51-56.
[13]	Excavation Based on Orthogonal Experiment MethodRAN Tao,MAO Jiang-nan, MEI Song-hua,WANG Wei-wei,TAN Li-hua. Sensitivity Analysis of Rock-Soil Parameters of a Gravity Anchor [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2018, 35(1): 101-106.
[14]	WANG Wei, XU Kai, FANG Xu-shun, ZHONG Qi-ming. Weighted Statistical Model of Dam Monitoring Based on Improved Particle Swarm Optimization Algorithm [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2017, 34(8): 41-46.
[15]	WANG Sen, MA Zhi-peng, LI Shan-zong, XIONG Jing. Coarse-grained Parallel Adaptive Hybrid Particle Swarm Optimization Algorithm and Its Application to Optimal Operation of Cascaded Reservoirs [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2017, 34(7): 149-154.

Metrics

Viewed

Full text

Abstract

Comments

Abstract
Figures/Tables
Related Articles
Recommended Articles
Metrics
Comments

TOP