Abstract
Experimental and numerical analysis of cavitation flow in the U-shaped throttle valve is presented in this article. Cavitation flow has been analyzed numerically using the volume of fluid model while the pictures are captured by a high-speed camera. The results reveal that the distribution of pressure is extremely inhomogeneous, and the pressure drop zone is mainly distributed in the narrow U-shaped groove. Cavitation bubble occurs around the orifice and develops continuously since the pressure drops. The nascent, developed, and collapsed zone of the cavitation within U-shaped throttle valve are also presented. In addition, a high-speed jet flow is formed when the oil flows out the U-shaped orifice, a vortex appears and cavitation bubbles appear. Then, cavitation evolution and the effect of back pressure and the valve opening on cavitation behavior have been discussed. Increasing back pressure will weaken the cavitation intensity and suppress the cavitation effectively. The valve opening also affects the cavitation flow and performance of the U-shaped throttle valve. With the increase of valve opening, cavitation area first increases and then decreases. The results and conclusions presented in this article give the basis for better understanding the cavitation phenomenon in a throttle valve.
Highlights
Throttle valves are popular on modern hydraulic systems, which needs high-precision control and long lifetime
The aim of this study is to evaluate on cavitation evolution in the U-shaped throttle valve and the effects of back pressure and the valve opening
This narrow pressure drop zone is mainly distributed in the narrow U-shaped groove, which become the locations of cavitation source
Summary
Throttle valves are popular on modern hydraulic systems, which needs high-precision control and long lifetime. Cavitation phenomena should be often found in throttle valves due to the complicated internal structure and high-speed flow. Investigation on cavitation flow inside the throttle valve is of great significance to the designing and optimization of the throttle valve with a long operational lifetime.[2,3,4]. Many scholars have focused their studies on cavitation phenomena inside hydraulic valves experimentally and numerically. Oshima et al.[6] studied cavitation flow characteristic using a transparent hemisection model of poppet valve. They obtained the effects of cavitation on the characteristics of flow rate, noise level, and pressure distributions.
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