Orthogonal optimization of flow uniformityat exit section of elbow-inlet passages
YAN Hao1, CHEN Liang2*, CHAI Liping1, ZHANG Yu1, LI Qiang1, SHI Haixia1
1. School of Mechanical Engineering, Hefei University of Technology, Hefei, Anhui 230009, China; 2. Anhui Provincial Science and Technology Department, Hefei, Anhui 230091, China
Orthogonal optimization of flow uniformity at exit section of elbow-inlet passages
YAN Hao1, CHEN Liang2*, CHAI Liping1, ZHANG Yu1, LI Qiang1, SHI Haixia1
1. School of Mechanical Engineering, Hefei University of Technology, Hefei, Anhui 230009, China; 2. Anhui Provincial Science and Technology Department, Hefei, Anhui 230091, China
摘要 Elbow-inlet passage is widely used in large drainage pumping stations. Flow uniformity at the exit section directly determines its hydraulic performance. Flow uniformity must be optimized to improve the operational efficiency of the large axial-flow pumping station. This study used modeling and numerical simulation to investigate the elbow-inlet passage, and the accuracy of the calculation results was verified. The key geometric parameters affecting the uniformity of the flow were optimized by the orthogonal experiment design. The optimal schemes were obtained and compared with the original scheme. Results showed that flow uniformity Vu after optimization was 95.41%, which was increased by 1.04%. The pumping station efficiency was increased by 1.89%, thereby confirming the applicability and accuracy of the proposed scheme, especially for the optimization of flow uniformity of the exit section of the elbow-inlet passage.
Abstract:Elbow-inlet passage is widely used in large drainage pumping stations. Flow uniformity at the exit section directly determines its hydraulic performance. Flow uniformity must be optimized to improve the operational efficiency of the large axial-flow pumping station. This study used modeling and numerical simulation to investigate the elbow-inlet passage, and the accuracy of the calculation results was verified. The key geometric parameters affecting the uniformity of the flow were optimized by the orthogonal experiment design. The optimal schemes were obtained and compared with the original scheme. Results showed that flow uniformity Vu after optimization was 95.41%, which was increased by 1.04%. The pumping station efficiency was increased by 1.89%, thereby confirming the applicability and accuracy of the proposed scheme, especially for the optimization of flow uniformity of the exit section of the elbow-inlet passage.
YAN Hao, CHEN Liang*, CHAI Liping, ZHANG Yu, LI Qiang, SHI Haixia. Orthogonal optimization of flow uniformityat exit section of elbow-inlet passages[J]. 排灌机械工程学报, 2019, 37(11): 947-952.
YAN Hao, CHEN Liang*, CHAI Liping, ZHANG Yu, LI Qiang, SHI Haixia. Orthogonal optimization of flow uniformity at exit section of elbow-inlet passages. Journal of Drainage and Irrigation Machinery Engin, 2019, 37(11): 947-952.
[1]CONSTANTINESCU G S, PATEL V C. Numerical model for simulation of pump-intake flow and vortices[J]. Journal of hydraulic engineering, 1998, 124(2): 123-134.
[2]LU Weigang, DONG Lei, WANG Zhaofei, et al. Cross influence of discharge and circulation on head loss of conduit of pump system with low head[J]. Applied mathematics and mechanics, 2012, 33(12):1533-1544.
[3]CHEN Xiaoqiang, ZHENG Yuan, CAO Ting, et al. Influence of length of outlet section and radius of elbow section on hydraulic characteristics of elbow-inlet passage[J]. Water resources and power, 2013, 31(12): 217-220.
[4]ZHAN Jiemin, WANG Bencheng, YU Linghui. Nume-rical investigation of flow patterns in different pump intake systems[J]. Journal of hydrodynamics, Ser. B, 2012, 24(6):873-882.
[5]YAN Hao, LIU Meiqing, LIANG Xing, et al. Influence of uniformity of incoming water on cavitation characteristics of large axial-flow pump unit [J]. Journal of Huazhong University of Science and Technology(natural edition), 2014, 42(10):108-113.
[6]YAN Bipeng, ZHU Honggeng, YUAN Shouqi. Predi-ction of hydraulic characteristics of new type elbow inlet conduits[J]. Transactions of the CSAM, 2006, 37(2):37-40.
[7]ZHU Honggeng, YUAN Shouqi, LIU Houlin. Numerical simulation of the influence of elbow inlet passage on hydraulic characteristics of vertical axial-flow pump[J]. Transactions of the CSAE, 2006, 22(2):6-9.
[8]SHI Wei, LI Yanjun, DENG Dongsheng, et al. Opti-mum design and numerical computation of elbow inlet passage[J]. Fluid machinery, 2009,37(12):19-23.
[9]KUROKAWA J. J-Groove technique for suppressing various anomalous flow phenomena in turbomachines[J]. International journal of fluid machinery & systems, 2011, 4(1):1-13.
[10]SI Qiaorui, LIN Gang, YUAN Shouqi, et al. Multi-objective optimization on hydraulic design of non-overload centrifugal pumps with high efficiency and low noise[J]. Transactions of the CSAE, 2016, 32(4):69-77.
[11]GAO Xiongfa, SHI Weidong, ZHANG Desheng, et al. Optimization design and test of vortex pump based on cfd orthogonal test[J]. Transactions of the CSAM, 2014, 45(5):101-106.
[12]SHI Weidong, ZHANG Desheng, GUAN Xingfan, et al. Numerical and experimental investigation of high-efficiency axial-flow pump[J]. Chinese journal of mechanical engineering, 2010, 23(1):38-44.
[13]ZHANG Desheng, WU Suqing, SHI Weidong, et al. Application and verification of different turbulence mo-dels for simulating tip leakage vortex in axial flow pump[J]. Transactions of the CSAE, 2013, 29(13):46-53.
[14]YAN Hao, LIU Meiqing, ZHAO Wensheng, et al. Influence on hydraulic performance of large axial-flow pumps station by velocity circulation[J]. Journal of Central South University(science and technology), 2016, 47(6):2125-2132.
