基于NSGA-Ⅱ的滑油泵叶轮结构优化设计

doi:10.3969/j.issn.1004-132X.2024.03.018

摘要/Abstract

摘要： 滑油泵常需要在高空、低压工况下稳定运转，常会出现供油不足、效率降低等问题。为了得到满足设计要求且具有最佳性能的滑油泵，以某直升机用滑油泵叶轮为研究对象，对其结构进行优化设计。选择高空两个典型工况的效率与扬程作为优化目标，利用NSGA-Ⅱ算法对滑油泵叶轮几何参数进行寻优，对优化前后的滑油泵效率、扬程进行对比分析。采用CFD流体仿真及实验方法对优化结果进行对比验证。结果表明：所选优化参数对滑油泵性能有较大影响，优化后的滑油泵叶片位置附近流动更加平稳，高低压区域过渡平缓，能量损失更小，且降低了汽蚀发生的可能性；优化后的滑油泵设计点扬程提高2.6 m，效率提高2.86%。

关键词: 滑油泵叶轮, 优化设计, 非支配排序遗传算法NSGA-Ⅱ, 扬程, 效率

Abstract: Slip oil pumps often needed to operate stably at high altitude and under low pressure conditions, which often led to cause problems such as insufficient oil supply and reduced efficiency. In order to get the best performance of the pump to meet the design requirements, this paper taken the impeller of a helicopter oil pump as the research object and to optimise the structure. The efficiency and lift of two typical working conditions at high altitude were selected as the optimisation targets, and the NSGA-Ⅱ was used to optimise the geometric parameters of the oil pump impellers, and the efficiency and lift of the oil pump before and after the optimisation were compared and analysed. CFD fluid simulation and experimental methods were used to verify the optimisation results. The results show that: the selected optimization parameters have a greater impact on the performance of the slip oil pumps, near the optimized slip oil pump vane positions the flow is more smooth, the high and low pressure areas of the excessively smooth, the energy loss is smaller, and the possibility of cavitation is reduced. The optimized slip oil pump design point lift increases 2.6 m, the efficiency increases 2.86%.

Key words: oil pump impeller, optimal design, non-dominated sorting genetic algorithm(NSGA-Ⅱ), lift, efficiency

中图分类号:

TH325

孙永国, 金欣, 薛冬, 单建平, 石晓春. 基于NSGA-Ⅱ的滑油泵叶轮结构优化设计[J]. 中国机械工程, 2024, 35(03): 559-569.

SUN Yongguo, JIN Xin, XUE Dong, SHAN Jianping, SHI Xiaochun. Optimal Design of Slip Oil Pump Impeller Structures Based on NSGA-Ⅱ[J]. China Mechanical Engineering, 2024, 35(03): 559-569.

参考文献

［1］李国权. 航空发动机滑油系统的现状及未来发展［J］. 航空发动机, 2011, 37(6):49-52.
LI Guoquan. Present and Future of Aeroengin Oil System［J］. Aeroengine, 2011, 37(6):49-52.
［2］孙杨慧, 杨坤, 侯乃先, 等. 航空发动机滑油系统动态故障分析［J］. 科技导报, 2015, 33(5):72-77.
SUN Yanghui, YANG Kun, HOU Naixian, et al. Dynamic Fault Analysis of Engine Lubrication System［J］. Science & Technology Review, 2015, 33(5):72-77.
［3］倪圆, 古成中, 罗日荣, 等. 基于EDM包络谱和模态测试的汽轮滑油泵振动分析［C］∥第十七届船舶水下噪声学术讨论会.衢州, 2019:306-311.
NI Yuan, GU Chengzhong, LUO Rirong, et al. Vibration Analysis of Turbine Slip Oil Pump Based on EDM Envelope Spectrum and Modal Test［C］∥17th Symposium on Underwater Noise of Ships. Quzhou, 2019:306-311.
［4］杨国朝, 孔青松, 李海英, 等. 某型号滑油泵设计［J］. 液压气动与密封, 2017, 37(3):5-7.
YANG Guochao, KONG Qingsong, LI Haiying, et al. The Design of an Lubricating Oil Pump［J］. Hydraulics Pneumatics & Seals, 2017, 37(3):5-7.
［5］张显鹏, 徐绯, 吴京泽, 等. 基于光滑粒子流体动力学的滑油泵数值仿真［J］. 计算力学学报, 2022, 39(1):113-119.
ZHANG Xianpeng, XU Fei, WU Jingze, et al. Numerical Simulations of Oil Pump by Smoothed Particle Hydrodynamics(SPH)Method［J］. Chinese Journal of Computational Mechanics, 2022, 39(1):113-119.
［6］王会敏, 李征乾, 刘建芳. 某型航空发动机滑油泵供油级汽蚀的数值研究［J］. 中国设备工程, 2021(15):117-118.
WANG Huimin, LI Zhengqian, LIU Jianfang. Numerical Study on Cavitation in the Oil Supply Stage of an Aero-engine Lubricating Oil Pump［J］. China Plant Engineering, 2021(15):117-118.
［7］TANG Lingdi, YUAN Shouqi, TANG Yue, et al. Optimization of Impulse Water Turbine Based on GA-BP Neural Network Arithmetic［J］. Journal of Mechanical Science and Technology, 2019, 33(1):241-253.
［8］THAKKAR S, VALA H, PATEL V K, et al. Performance Improvement of the Sanitary Centrifugal Pump through an Integrated Approach Based on Response Surface Methodology, Multi-objective Optimization and CFD［J］. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2021, 43(1):24.
［9］LU Yeming, WANG Xiaofang, LIU Haoran, et al. Investigation of the Effects of the Impeller Blades and Vane Blades on the CAP1400 Nuclear Coolant Pump’s Performances with a United Optimal Design Technology［J］. Progress in Nuclear Energy, 2020, 126:103426.
［10］ZHU Baoshan, WANG Xuhe, TAN Lei, et al. Optimization Design of a Reversible Pump-turbine Runner with High Efficiency and Stability［J］. Renewable Energy, 2015, 81:366-376.
［11］PEI Ji, WANG Wenjie, OSMAN M K, et al. Multiparameter Optimization for the Nonlinear Performance Improvement of Centrifugal Pumps Using a Multilayer Neural Network［J］. Journal of Mechanical Science and Technology, 2019, 33(6):2681-2691.
［12］PEI Ji, WANG Wenjie, YUAN Shouqi. Multi-point Optimization on Meridional Shape of a Centrifugal Pump Impeller for Performance Improvement［J］. Journal of Mechanical Science and Technology, 2016, 30(11):4949-4960.
［13］DUCCIO B, MEHRDAD Z. On the Coupling of Inverse Design and Optimization Techniques for the Multiobjective, Multipoint Design of Turbomachinery Blades［J］. Journal of Turbomachinery, 2009, 131(2):021014.
［14］PISKIN A, AKTAS H, TOPAL A, et al. Rotor Balancing with Turbine Blade Assembly Using Ant Colony Optimization for Aero-engine Applications［J］. International Journal of Turbo and Jet Engines, 2017, 38(2):125-134.
［15］YU D O, LEE H M, KWON O J. Aerodynamic Shape Optimization of Wind Turbine Rotor Blades Considering Aeroelastic Deformation Effect［J］. Journal of Mechanical Science and Technology, 2016, 30(2):705-718.
［16］LI H, CHANDRASHEKHARA K. Particle Swarm-based Structural Optimization of Laminated Composite Hydrokinetic Turbine Blades［J］. Engineering Optimization, 2015, 47(9):1191-1207.
［17］张海佳, 张宸宇, 蒋荔荔, 等. 涡轮增压器压气机叶轮与压壳相对偏心对性能的影响［J］. 内燃机与配件, 2021(24):7-9.
ZHANG Haijia, ZHANG Chenyu, JIANG Lili, et al. Relative Location between Impeller and Scroll on Turbocharger Compressor Performance［J］. Internal Combustion Engine & Parts, 2021(24):7-9.
［18］MORITA Y, FUJISAWA N, GOTO T, et al. Effects of Diffuser Vane Geometries on Compressor Performance and Noise Characteristics in a Centrifugal Compressor［C］∥Proceedings of ASME 2013 Fluids Engineering Division Summer Meeting. Incline Village, Nevada, 2013:V01BT10A011.
［19］OHTA Y, OKUTSU Y, GOTO T, et al. Aerodynamic Performance and Noise Characteristics of a Centrifugal Compressor with Modified Vaned Diffusers［J］. Journal of Thermal Science, 2006, 15(4):289-295.
［20］吴军腾, 李娜, 甘斌林. 适用于高空的机械增压器压气机叶轮设计及流动分析研究［C］∥中国航天第三专业信息网第四十届技术交流会暨第四届空天动力联合会议.昆明, 2019:18-22.
WU Junteng, LI Na, GAN Binlin. Study on the Design and Flow Analysis of Mechanical Supercharger Compressor Impeller Applicable to High Altitude［C］∥ China Aerospace Third Professional Information Network 40th Technical Exchange Conference and 4th Joint Conference on Air and Space Power.Kunming, 2019:18-22.
［21］李文广, 张玉良. 泵叶轮正反问题［M］. 镇江:江苏大学出版社, 2020:25-26.
LI Wenguang, ZHANG Yuliang. Pump Impeller Direct and Inverse Problems［M］. Zhenjiang:Jiangsu University Press, 2020:25-26.

[1]	鲁开讲, 师俊平, 张锋涛. 平面三自由度并联机构动力学优化设计 [J]. J4, 201016, 21(16): 1926-1931.
[2]	刘杰, 翦林杰, 窦泽城, 文桂林, 王锐坤, 李方义. 超细微穿孔板构筑轻质结构的吸声特性研究[J]. 中国机械工程, 2023, 34(20): 2395-2402.
[3]	蒲志新, 郭建伟, 潘玉奇, 白杨溪. 2PPaPaR并联机构性能分析及优化设计[J]. 中国机械工程, 2023, 34(19): 2304-2312.
[4]	王倩玥, 曹华军, 林江海, 赖科旭, 李本杰, 葛威威. 考虑冷却能耗的干切机床效率分析及评价模型[J]. 中国机械工程, 2023, 34(19): 2333-2342.
[5]	魏冰阳, 古德万, 王永强, 杨建军, . 高减比准双曲面齿轮摩擦功耗分析与效率试验[J]. 中国机械工程, 2023, 34(13): 1525-1532.
[6]	田宗睿, 智鹏鹏, 云国丽, 郭新凯, 官毅. 基于自适应增量Kriging模型的多目标稳健优化设计方法[J]. 中国机械工程, 2023, 34(08): 931-940.
[7]	沈凡, 赵刚, 陈燕才, 熊雯. 高温雾化降尘效率关键影响参数研究及优化[J]. 中国机械工程, 2023, 34(07): 789-795，802.
[8]	吴紫俊, 肖人彬. 基于子结构的宏微结构协同优化方法[J]. 中国机械工程, 2022, 33(23): 2851-2858.
[9]	王一熙, 沈惠平, 陈谱, 吴广磊. 基于运动学、刚度和动力学性能的并联机构有序递进三级优化设计及其应用[J]. 中国机械工程, 2022, 33(13): 1560-1575,1621.
[10]	曾祥, 周怡君, 袁伟钦, 罗晨. 基于Twin-Bennett机构固面可展开天线的优化设计[J]. 中国机械工程, 2021, 32(11): 1361-1369，1376.
[11]	王成志, 王云超. 含运动副间隙的空间转向机构运动精度分析及优化设计#br#[J]. 中国机械工程, 2021, 32(09): 1027-1034,1042.
[12]	宿月文;郭彩霞. 摆线传动接触载荷与效率的关联模式及试验验证[J]. 中国机械工程, 2021, 32(05): 556-564.
[13]	张琦1;李增亮1;董祥伟1;刘延鑫1;王雨婷2. 大功率潜水电机冷却系统分析方法与试验研究[J]. 中国机械工程, 2021, 32(03): 368-377.
[14]	刘世豪, 林茂. [综述]高速数控转台优化设计方法研究现状与展望[J]. 中国机械工程, 2020, 31(13): 1629-1637.
[15]	高富东;王德心;王海东;曹建平. 基于射流冲击作用的舰机适配性数值分析与优化[J]. 中国机械工程, 2020, 31(12): 1425-1436.