基于Fluent网格变形的旋流器的形状优化

doi:10.16085/j.issn.1000-6613.2016.08.08

化工进展 ›› 2016, Vol. 35 ›› Issue (08): 2355-2361.DOI: 10.16085/j.issn.1000-6613.2016.08.08

基于Fluent网格变形的旋流器的形状优化

蒋明虎¹, 谭放¹, 金淑芹², 龙桂兰², 陈桂芹³, 徐保蕊¹

1. 东北石油大学机械科学与工程学院, 黑龙江大庆 163318;
2. 大庆采油三厂一矿, 黑龙江大庆 163113;
3. 山东华宸高压容器有限公司, 山东济南 250101

收稿日期:2016-02-18 修回日期:2016-03-11 出版日期:2016-08-05 发布日期:2016-08-05
通讯作者: 蒋明虎(1962—),男,教授,博士生导师,主要研究方向为旋流分离技术。E-mail:jmhdq@126.com。
作者简介:蒋明虎(1962—),男,教授,博士生导师,主要研究方向为旋流分离技术。E-mail:jmhdq@126.com。
基金资助:
国家高技术研究发展计划（2012AA061303）。

Sharp optimization of hydrocyclone based on Fluent mesh morphing

JIANG Minghu¹, TAN Fang¹, JIN Shuqin², LONG Guilan², CHEN Guiqin³, XU Baorui¹

1. School of Mechanical Science and Engineering, Northeast Petroleum University, Daqing 163318, Heilongjiang, China;
2. The First Oil Mine, Daqing No.3 Oil Production Company, Daqing 163113, Heilongjiang, China;
3. Shandong Huachen High Pressure Vessel Co., Ltd., Ji'nan 250101, Shandong, China

Received:2016-02-18 Revised:2016-03-11 Online:2016-08-05 Published:2016-08-05

摘要/Abstract

摘要： 目前，旋流器的流体结构优化主要局限于单参数的尺寸优化；大多采用多组网格分别模拟的方法；不仅费时，而且对于微小的尺寸变形常常难以操控。当旋流器的分离效率优化到一定峰值后，进一步提高则比较困难。为解决这一问题，提出了基于网格变形的形状优化方法。以旋流器的分离效率为目标，采用ANSYS Fluent的网格变形方法，优化了旋流器的外形结构，将旋流器的分离效率由原来的95.69%提高到了99.18%，并对比分析了优化前后的压降、速度和油相体积分布。研究结果表明：Fluent 网格变形器驱动网格节点的平滑变形，可以同时实现变形区域的结构参数的优化组合，以及优化迭代的自动化和智能化，具有良好的全局搜索能力和较强的鲁棒性；Fluent网格变形优化算法能够缩短CAD建模的时间，避免网格重构；可在单一尺寸优化的基础上，在一定范围内提高旋流器的分离效率。

关键词: 形状优化, 网格变形, 分离效率, 轴流式旋流器, 目标函数

Abstract: Currently,fluid-structure optimization of hydrocyclone has been mainly limited to single-parameter size optimization. Generally,the optimization process is dependent upon the method of separate simulation with multiple sets of grid. Nevertheless,the approach is time-consuming and not capable of controlling the micro size deformation. Besides,further improvement on the separation efficiency of cyclone is rather difficult once a certain maximum optimization is achieved. To solve this problem,mesh deformation-based shape optimization method was proposed. Aimed at improving the hydrocyclone separation efficiency with ANSYS Fluent mesh deformation method,the hydrocyclone sharp structure was optimized and the hydrocyclone separation efficiency was increased from 95.69% to 99.18%. A comparative analysis involved with pressure drop,velocity and oil phase volume distributions before and after optimization was then conducted. The results indicated that the smoothing mesh deformation driven grid nodes by Fluent mesh morpher could concurrently contribute to the optimal combination of structural parameters in the deformation zone,and the optimization of the automation and intelligentization of the iteration process. Besides,it had a considerable capability of global searching and strong robustness. Fluent mesh morphing optimization algorithm can shorten CAD modeling time,avoid mesh reconstruction and further improve the separation efficiency of hydrocyclone within a certain range on the basis of single-parameter size optimization.

Key words: sharp optimization, mesh morphing, separation efficiency, axial cyclone, objective function

中图分类号:

TQ028.4

蒋明虎, 谭放, 金淑芹, 龙桂兰, 陈桂芹, 徐保蕊. 基于Fluent网格变形的旋流器的形状优化[J]. 化工进展, 2016, 35(08): 2355-2361.

JIANG Minghu, TAN Fang, JIN Shuqin, LONG Guilan, CHEN Guiqin, XU Baorui. Sharp optimization of hydrocyclone based on Fluent mesh morphing[J]. Chemical Industry and Engineering Progree, 2016, 35(08): 2355-2361.

参考文献

[1] 赵立新,宋民航,蒋明虎,等.轴流式旋流分离器研究进展[J].化工机械,2014,41(1):20-25.
[2] 聂涛. 轴流式液液旋流器内流场的数值模拟[D]. 东营:中国石油大学(华东),2008:47-51.
[3] 俞接成,陈家庆,韩景. 轴向入口油水分离水力旋流器及其数值模拟[J]. 北京石油化工学院学报,2009,17(2):19-23.
[4] GONG Guangcai,YANG Zhouzhou,ZHU Shaolin. Numerical investigation of the effect of helix angle and leaf margin on the flow pattern and the performance of the axial flow cyclone separator[J]. Applied Mathematical Modelling,2012,36(8):3916-3930.
[5] 王云峰,刘仁桓,王金花,等. 2种锥段结构的轴流式旋流器内的流场模拟[J]. 流体机械,2013,41(6):22-26.
[6] 宋民航,韩佳轩. 轴流式脱水型旋流器的流场分析与结构优化[J]. 石油矿场机械,2012,41(12):56-60.
[7] 蒋明虎,陈世琢,李枫,等. 紧凑型轴流式除油旋流器模拟分析
与实验研究[J]. 油气田地面工程,2010,29(9):18-20.
[8] 蒋明虎,宫磊磊,徐保蕊,等. 含气条件对井下油水分离旋流器性能影响的数值模拟[J]. 化工机械,2014,41(5):629-632.
[9] 蒋明虎,李永山,徐保蕊,等. 轴流式脱气除砂三相旋流分离器操作参数优选[J]. 化工机械,2015,42(1):68-71.
[10] 赵立新,代佳鑫,郭现臣. 叶片式水力旋流器操作参数优选[J]. 流体机械,2013,41(10):7-9.
[11] 赵立新,宋民航,蒋明虎,等. 新型轴入式脱水型旋流器的入口结构模拟分析[J]. 石油机械,2013,41(1):68-71.
[12] 史仕荧,吴应湘,许晶禹,等. 导流片型管道式分离器油水分离结构优化[C]//第十三届全国水动力学学术会议暨第二十六届全国水动力学研讨会,青岛,2014:1063-1067.
[13] 黄龙,邓松圣,王斌,等. 新型轴流导叶式气液旋流器流场数值模拟[J]. 机床与液压,2015,43(1):164-167.
[14] 杨磊,李宝军,胡平. 网格变体方法的工程应用与进展综述[C]//中国计算力学大会2014暨第三届钱令希计算力学奖颁奖大会,贵阳,2014.
[15] BIANCOLINI Marco Evangelos. Mesh morphing accelerates design optimization[E/OL]. Rome,Italy,2010. http://www.ansys.com/staticassets/ANSYS/staticassets/resourcelibrary/article/AA-V4-I1-Mesh-Morphing-Accelerates-Design-Optimization.pdf.
[16] JEMCOV Aleksandar,MARUSZEWSKI Joseph. Shape optimization based on downhill simplex optimizer and free-form deformation in general purpose CFD code[C]// 17th Annual Conference of CFD Society of Canada,Ottawa,Ontario,Canada,2009.
[17] MURUGAN S,WOODS B K S,FRISWELL M I. Hierarchical modeling and optimization of camber morphing airfoil[J]. Aerospace Science and Technology,2015,42(2):31-38.
[18] BIANCOLINI Marco Evangelos. Advanced mesh morphing for automotive applications using RBF Morph[C]//Automotive Simulation World Congress,Frankfurt am Main,Germany,2013.
[19] RAIDL Günther R,WUTM Christian. Approximation with evolutionary optimized tensor product Bernstein Polynomials[A]. Karlsplatz 13,1040 Vienna,Austria,2003.
[20] KOLDA Tamara G,LEWIS Robert Michael,TORCZON Virginia. Optimization by direct search:new perspectives on some classical and modern methods[J]. SIAM Review,2003,45(3):385-482.
[21] ZASLAVSKI Alexander,POWELL M J D. The NEWUOA software for unconstrained optimization without derivatives[M]. US:Springer,2004:255-297.
[22] MCKINNON K I M. Convergence of the Nelder-Mead simplex method to a nonstationary point[J]. SIAM J. Optimization,1998,9(1):148-158.
[23] TORCZON Virginia. On the convergence of the multidirectional search algorithm [J]. SIAM J. Optimization,1991,1(1):123-145.
[24] PRESS William H,TEUKOLSKY Saul A,VETTERLING William T. Numerical recipes:the art of scientific computing[M]. 3rd Ed. Cambridge,England:Cambridge University Press,2007.
[25] ROSENBROCK H H. An automatic method for finding the greatest or least value of a function[J]. Computer Journal,1960,3(3):175-184.
[26] 王仁芳,许秋儿,汪沁,等. 基于最小二乘网格的模型变形算法[J]. 计算机辅助设计与图形学学报,2010,22(5):777-783.
[27] ELSAYED Khairy. Design of a novel gas cyclone vortex finder using the adjoint method[J]. Separation and Purification Technology,2015,142:274-284.
[28] OLSONT T J,VAN OMMEN R. Optimizing hydrocyclone design using advanced CFD model[J]. Minerals Engineering,2004,17(5):713-720.
[29] 袁惠新,李双双,付双成,等. 三相分离旋流器内流场及分离性能的研究[J]. 流体机械,2015,43(1):28-32.
[30] 盛庆娇. 新型螺旋入口水力旋流器模拟分析及实验研究[D]. 大庆:东北石油大学,2012:39-45.

基于Fluent网格变形的旋流器的形状优化

Sharp optimization of hydrocyclone based on Fluent mesh morphing

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