Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

ZENG Jianan; ZHU Qinghua; WANG Kun; ZHU Zhenhua; SHEN Suiyuan

doi:10.13224/j.cnki.jasp.2019.08.013

Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

doi: 10.13224/j.cnki.jasp.2019.08.013

College of Aeronautics,Nanjing University of Aeronautics and Astronautics,Nanjing 210016,China

计量
- 文章访问数: 431
- HTML浏览量: 2
- PDF量: 358
- 被引次数: 0
出版历程
- 收稿日期: 2018-12-25
- 刊出日期: 2019-08-28

Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

College of Aeronautics,Nanjing University of Aeronautics and Astronautics,Nanjing 210016,China

摘要

摘要: A surrogate-model-based aerodynamic optimization design method for cycloidal propeller in hover was proposed, in order to improve its aerodynamic efficiency, and analyze the basic criteria for its aerodynamic optimization design. The reliability and applicability of overset mesh method were verified. An optimization method based on Kriging surrogate model was proposed to optimize the geometric parameters for cycloidal propeller in hover with the use of genetic algorithm. The optimization results showed that the thrust coefficient was increased by 3.56%, the torque coefficient reduced by 12.05%, and the figure of merit (FM) increased by 19.93%. The optimization results verified the feasibility of this design idea. Although the optimization was only carried out at a single rotation speed, the aerodynamic efficiency was also significantly improved over a wide range of rotation speeds. The optimal configuration characteristics for micro and small-sized cycloidal propeller were: solidity of 0.2-0.22, maximum pitch angle of 25°-35°, pitch axis locating at 35%-45% of the blade chord length.
- cycloidal propeller /
- aerodynamic shape optimization /
- key design parameters /
- surrogate-based optimization /
- dynamic overset mesh
Abstract: A surrogate-model-based aerodynamic optimization design method for cycloidal propeller in hover was proposed, in order to improve its aerodynamic efficiency, and analyze the basic criteria for its aerodynamic optimization design. The reliability and applicability of overset mesh method were verified. An optimization method based on Kriging surrogate model was proposed to optimize the geometric parameters for cycloidal propeller in hover with the use of genetic algorithm. The optimization results showed that the thrust coefficient was increased by 3.56%, the torque coefficient reduced by 12.05%, and the figure of merit (FM) increased by 19.93%. The optimization results verified the feasibility of this design idea. Although the optimization was only carried out at a single rotation speed, the aerodynamic efficiency was also significantly improved over a wide range of rotation speeds. The optimal configuration characteristics for micro and small-sized cycloidal propeller were: solidity of 0.2-0.22, maximum pitch angle of 25°-35°, pitch axis locating at 35%-45% of the blade chord length.
- cycloidal propeller /
- aerodynamic shape optimization /
- key design parameters /
- surrogate-based optimization /
- dynamic overset mesh

HTML

参考文献(22)

[1]	JARUGUMILLI T.An experimental investigation of a micro air vehicle-scale cycloidal rotor in forward flight［D］.College Park:University of Maryland,2013.
[2]	LIND H A,JARUGUMILLI T,BENEDICT M,et al.Flow field studies on a micro-air-vehicle-scale cycloidal rotor in forward flight［J］.Experiment in Fluids,2014,55:1826-1843.
[3]	WALTHER C M.Fundamental understanding of the unsteady aerodynamics of cycloidal rotors in hover at ultra-low Reynolds numbers［D］.Calgary,Texas,US:College Station Texas A&M University,2017.
[4]	SIEGEL S,SEIDEL J,COHEN K,et al.A cycloidal propeller using dynamic lift［R］.Miami,Florida,US:the 37th AIAA Fluid Dynamics Conference and Exhibit,2007.
[5]	BENEDICT M,JARUGUMILLI T,CHOPRA I.Effects of asymmetric blade-pitching kinematics on forward-flight performance of a micro-air-vehicle-scale cycloidal-rotor［J］.Journal of Aircraft,2016,53(5):1567-1572.
[6]	JARUGUMILLI T,LIND H A,BENEDICT M,et al.Experimental and computational flow field studies of a MAV-scale cycloidal rotor in forward flight［R］.Phoenix,Arizona,US:the 69th Annual Forum,2013.
[7]	BENEDICT M,JARUGUMILLI T,LAKSHMINARAYAN V.Effect of flow curvature on forward flight performance of a micro-air-vehicle-scale cycloidal-rotor［J］.AIAA Journal,2014,52(6):1159-1169.
[8]	LEGER J,PSCOA J,XISTO C.3D effects in cyclorotor propulsion systems［R］.Houston,Texas:the ASME International Mechanical Engineering Congress and Exposition,2015.
[9]	TANG J W,HU Y,SONG B F.Influence of key design parameters on aerodynamics performance of cycloidal propeller［J］.Journal of Aerospace Power,2015,30(2):297-305.(in Chinese)
[10]	HU Y,ZHANG H L,WANG G Q.Two dimensional and three-dimensional numerical simulation of cycloidal propellers in hovering status［R］.San Diego,California:the 54th AIAA Aerospace Sciences Meeting,2016.
[11]	TANG J W,HU Y,SONG B F.Advances in the aerodynamics research of cylcoidal propeller［J］.Acta Aerodynamica Sinica,2013,31(5):677-684.(in Chinese)
[12]	TANG J W,HU Y,SONG B F.Unsteady aerodynamic optimization of airfoil for cycloidal propellers based on surrogate model［J］.Journal of Aircraft,2017,54(4):1241-1256.
[13]	KAN Y.Aerodynamic analysis of an MAV-scale cycloidal rotor system using a structured overset RANS solver［D］.College Park:University of Maryland,2010.
[14]	SHEN Y,XIAO T H,LI Z Z,et al.Numerical study on the aerodynamics of micro/small cycloidal propeller［J］.Aeronautical Science and Technology,2015,26(11):56-66.
[15]	KELLEN A,BENEDICT M.Effect of rotor geometry on uav-scale cycloidal rotor hover performance［R］.Phoenix,Arizona,US:the American Helicopter Society (AHS) International 74th Annual Forum and Technology Display,2018.
[16]	HU Y,DU F,ZHANG H L.Investigation of unsteady aerodynamics effects in cycloidal rotor using RANS solver［J］.Aeronautical Journal,2016,120(1228):956-970.
[17]	BENEDICT M,JARUGUMILLI T,CHOPRA I.Experimental optimization of MAV-scale cycloidal rotor performance［R］.California,US San Francisco:the 56th American Helicopter Society (AHS) Aeromechanics Specialists Conference,2011.
[18]	CARLOS M,LEGER J,PSCOA J,et al.Parametric analysis of a large-scale cycloidal rotor in hovering conditions［J］.Journal of Aerospace Engineering,2017,30(1):04016066.1-04016066.14.
[19]	MCELREATH J,BENEDICT M,TICHENOR N.Tip vortex measurements on a cycloidal rotor blade at ultralow reynolds numbers［R］.Fort Worth,Texas,US:the American Helicopter Society (AHS) International 74th Annual Forum and Technology Display,2018.
[20]	ZHAO Q J,JIANG S,LI P,et al.Aerodynamic optimization analyses of tiltrotor/propeller based on CFD method［J］.Acta Aerodynamica Sinica,2017,50(2):167-172.(in Chinese)
[21]	WANG B,XU G H,ZHAO Q J.CFD simulation of airfoil effect on hovering rotor aerodynamic performance［J］.Journal of Nanjing University of Aeronautics and Astronautics,2012,44(4):479-484.(in Chinese)
[22]	HAN Z H.Kriging surrogate model and its application to design optimization:a review of recent progress［J］.Acta Aeronautica et Astronautica Sinica,2016,37(11):3197-3225.(in Chinese)

施引文献

资源附件(0)

访问统计

点击查看大图

计量

文章访问数: 431
HTML浏览量: 2
PDF量: 358
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

留言板

Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

doi: 10.13224/j.cnki.jasp.2019.08.013

计量

Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

计量

目录

留言板

Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

doi: 10.13224/j.cnki.jasp.2019.08.013

计量

出版历程

Aerodynamic optimization design of general parameters for cycloidal propeller in hover based on surrogate model

计量

出版历程

目录