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三角形涡发生器综合换热性能全局优化和知识挖掘
陶 志,祝培源,宋立明,李 军,丰镇平
(西安交通大学 能源与动力工程学院,陕西 西安 710049)
摘要:
为了强化布置三角形涡发生器的U型通道综合换热性能,耦合基于子元模型的全局优化算法、三角形涡发生器参数化方法、三维RANS方程求解技术与基于总变差分析的知识挖掘技术,建立了高效的三角形涡发生器综合换热性能优化与知识挖掘方法。在验证本文数值方法正确性的基础上,以综合换热性能最优为目标函数,对布置于U型通道内的三角形涡发生器进行设计优化与知识挖掘。优化后,最优设计的三角形涡发生器诱导产生的下洗涡对的强度和间距增加,使得U型通道的综合换热性能相对提高了14.5%。同时对设计空间进行知识挖掘,筛选对综合换热性能影响显著的设计变量,分析显著变量对目标函数的影响机制。结果表明:三角形涡发生器的高度对通道换热能力和阻力损失的影响最为显著,而三角形涡发生器的宽度对通道综合换热性能的影响最为显著。
关键词:  三角形涡发生器  综合换热性能  全局优化设计  知识挖掘
DOI:
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基金项目:国家自然科学基金(51676149)。
Thermal Performance Global Optimization and Knowledge Discovery of Delta-Shaped Vortex Generators
TAO Zhi,ZHU Pei-yuan,SONG Li-ming,LI Jun,FENG Zhen-ping
(School of Energy and Power Engineering,Xi’an Jiaotong University,Xi’an 710049,China)
Abstract:
In order to enhance thermal performance of a U-shaped channel equipped with delta-shaped vortex generators, a meta-model based design optimization and data mining method is proposed for the thermal performance optimization design of the delta-shaped vortex generator. The method combines a Kriging-based global optimization algorithm with data mining technique of analysis of variance (ANOVA), parameterization method for delta-shaped vortex generator and 3D Reynolds-Averaged Navier-Stokes (RANS) Solver technique. Upon numerical validation, design optimization of a U-shaped channel equipped with delta-shaped vortex generators is carried out for the maximization of its overall thermal performance. After optimization, both the intensity and the space of the down-wash vortex pairs generated by the delta-shaped vortex generators increased, and thus the overall thermal performance of the optimal design increased by 14.5% when compared to that of the reference design. Furthermore, knowledge discovery is carried out to detect the design variables which have significant effects on the thermal performance of U-shaped channel in prescribed design space. The parameter interactions among significant design variables and objective functions are analyzed in detail. It is indicated that the length of delta-shaped vortex generator has most significant effect on heat transfer and friction loss of U-shaped channel, while the width of delta-shaped vortex generator has most significant effect on the thermal performance of U-shaped channel.
Key words:  Delta-shaped vortex generator  Thermal performance  Global optimization design  Knowledge discover