Author:
Li Ruichuan,Ding Xinkai,Lin Jianghai,Chi Feng,Xu Jikang,Cheng Yi,Liu Jilu,Liu Qi
Abstract
In this study, a structurally improved spool was designed. The diameter of one side of the spool stem was reduced, making the spool stem into a rounded table shape. A triangular groove was circumscribed on the step and on the same side. After liquid flow was guided through the triangular groove, the flow direction changed. A flow component in the negative direction was generated, which reversely impacted the liquid flow in the positive direction. The liquid flow angle at the outlet increased; that is, jet angle increased and flow force decreased. The simulation results show that, increasing the depth, H, of the triangular groove has a positive effect on flow-force compensation and was conducive to the stability of the valve core. Properly increasing the groove’s bottom diameter, D1, of the triangular groove was conducive to the stability of the spool, but when D1 was too large, the flow force increased. The experimental results are consistent with the simulation results, which proves that the improved structure can effectively reduce the flow force of the spool.
Funder
Industrial foundation strengthening project of the Ministry of industry and in-formation technology of the people's Republic of China
Subject
Fluid Flow and Transfer Processes,Computer Science Applications,Process Chemistry and Technology,General Engineering,Instrumentation,General Materials Science
Reference25 articles.
1. Simulation research on dynamic performance of cartridge two position four way directional valve;Jiang;Mach. Tool Hydraul.,2021
2. Numerical study on hydrodynamic oscillation and forced vibration in front stage of pressure servo valve;Kang;J. Vib. Shock,2021
3. Position control of direct-acting high-frequency proportional valve;Chen;Chin. Hydraul. Pneum.,2021
4. Design and simulation of high-flow high-speed on/off valve driven by piezoelectric;Yun;J. Mech. Eng.,2020
5. Modeling the Dynamic Behavior of a Pilot-Operated Solenoid Valve for an Ultra-High Pressure Vessel
Cited by
4 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献