Pressure impact characteristic of vane type continuous rotary motor under different buffer structures

Xiao-jing Wang; Shan-liang Hu; Zhi-qi Shen

doi:10.1007/s11771-020-4571-z

Journal of Central South University ›› 2021, Vol. 27 ›› Issue (12) : 3652 -3666. DOI: 10.1007/s11771-020-4571-z

Article

Pressure impact characteristic of vane type continuous rotary motor under different buffer structures

Author information +

History +

PDF

Abstract

In order to solve the problem of pressure shock on the continuous rotary electro-hydraulic servo motor, the mathematical models of pressure gradient under the structure of pre-compressed chamber and U-shaped groove were established. The optimal structure dimensions of the pre-compressed chamber and the U-shaped groove were determined. The fluid models were established by Solidworks under the four structures of triangular groove, triangular groove with pre-compression chamber, U-shaped groove and U-shaped groove with pre-compression chamber. Simulation analysis of depressurization process of fluid models was performed based on FLUENT. The pressure nephograms of different buffer structures were compared and analyzed, and the pressure change curves and pressure gradient change curves in the process of depressurization were obtained. The results show that the optimal edge length of the pre-compressed chamber of continuous rotary electro-hydraulic servo motor is 20 mm in the process of decompression. The pressure reduction effect is the best when the width of the U-shaped groove is 1.5 mm and the depth is 1.65 mm. The U-shaped groove structure with pre-compression chamber is more conducive to alleviate the pressure shock phenomenon of the motor compared with different combine buffer structures.

Keywords

continuous rotary electro-hydraulic servo motor / pressure impact / pre-compression chamber / U-shaped groove

Cite this article

Download citation ▾

Xiao-jing Wang, Shan-liang Hu, Zhi-qi Shen. Pressure impact characteristic of vane type continuous rotary motor under different buffer structures. Journal of Central South University, 2021, 27(12): 3652-3666 DOI:10.1007/s11771-020-4571-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	XuD-d, SunZ-p, HanH-bin. Modeling and research implementation of dual motor synchronous drive control under large bias load [J]. Aviation Manufacturing Technology, 20158689

[2]	HanS-b, JiaoZ-x, WangC-wen. Nonlinear integral sliding mode control of electro-hydraulic turntable based on neural network. Journal of Beijing University of Aeronautics and Astronautics, 2014, 40(3): 321-326

[3]	ChenShuaiStudy on the sealing and reversing impact characteristics of blade type continuous rotary electro-hydraulic servo motor [D], 2019, Harbin, Harbin University of Technology

[4]	JiaX-h, GuoF, HuangL, WangL-k, GaoZ, WangY-ming. Effects of the radial force on the static contact properties and sealing performance of a radial lip seal [J]. Science China: Technological Sciences, 2014, 57(6): 1175-1182

[5]	KimJ K, KimH G, JungJ Y. Relation between pressure variations and noise in axial type oil piston pumps [J]. KSME International Journal, 2004, 18(6): 1019-1025

[6]	JohanssonA, BlackmanL D. Prediction of pump dynamics utilizing computer simulation model-with special reference to noise reduction [C]. International Off-Highway and Powerplant Congress and Exposition, 2000

[7]	PetterssonM E, WeddfeltK G, PalmbergJ S. Methods of reducing flow ripple from fluid power Pumps-A theoretical approach [C]. International Off-Highway and Powerplant Congress and Exposition, 1991

[8]	WeddfeltK G, PetterssonM E, PalmbergO S. Methods of reducing flow ripple from fluid power piston pumps-an experimental approach [C]. International Off-Highway and Powerplant Congress and Exposition, 1991

[9]	HamJ G, KimS W, OhJ Y. Theoretical investigation of the effect of a relief groove on the performance of a gerotor oil pump [J]. Journal of Mechanical Science and Technology, 2018, 32(8): 3687-3698

[10]	NiW W, BartholmeD, CassM. The CFD analysis of pressure pulsation in the aircraft engine and control systems lubrication pump [J]. SAE International Journal of Aerospace, 2013, 6(1): 49-55

[11]	InagumaY, NakamuraK. Influence of leakage flow variation on delivery pressure ripple in a vane pump [J]. Proceedings of the Institution of Mechanical Engineers, 2014, 228(2): 342-357

[12]	OhJ K, MoonH B, ChoH. Theoretical study on performance characteristics of a variable displacement vane pump according to a variable amount occurrence [J]. Journal of Mechanical Science and Technology, 2015, 29(9): 3717-3726

[13]	ZhangX-j, ZhanY-h, ZhouZ-jin. The influence of axial piston pump parameters on its flow and pressure pulsation [J]. Machine Tool and Hydraulics, 2018, 46(13): 120

[14]	LiX-junAnalysis of the influence of internal structure of double acting vane pump on flow pulsation and noise [D], 2016, Lanzhou, Lanzhou University of Technology

[15]	LiuC-q, LiuY-s, YangG-zhong. New type of swash plate piston hydraulic transformer’s noise [J]. Hydraulic and Pneumatic, 20171-4

[16]	WuX-m, MaL-r, WangX-peng. Simulation research on pressure pulsation compensation mechanism for a new grooved vane pump [J]. Hydraulic and Pneumatic, 20175257

[17]	XuB, SongY-c, YangH-yong. Pre-compression volume on flow ripple reduction of a piston pump [J]. Chinese Journal of Mechanical Engineering, 2013, 26(6): 1259-1266

[18]	XuB, YeS-g, ZhangJ-hui. Flow ripple reduction of an axial piston pump by a combination of cross-angle and pressure relief grooves: Analysis and optimization [J]. Journal of Mechanical Science and Technology, 2016, 30(6): 2531-2545

[19]	LvZ, HouR-g, TianY-b, HuangC-z, ZhuH-tao. Investigation on flow field of ultrasonic-assisted abrasive waterjet using CFD with discrete phase model [J]. The Internationl Journal of Advanced Manufacturing Technology, 2018, 96(1–4): 963-972

[20]	WangZ-q, GaoD-r, FeiJ-huan. Analysis and numerical simulation of leakage flow of low speed high torque water hydraulic motor’s plain flow distribution pair [C]. Chinese Association of Fluid Power Control Engineering. Fluid Dynamic and Mechanical & Electrical Control Engineering, 2012217220

[21]	ChenQ-p, ShuH-y, FangW-q, HeL-l, YangM-ju. Fluid structure interaction for circulation valve of hydraulic shock absorber [J]. Journal of Central South University, 2013, 20(3): 648-654

[22]	XianC-fuFluid-solid coupling analysis and experimental study of An continuous rotary electro-hydraulic servo motor [D], 2016, Harbin, Harbin University of Technology