The motivation behind this study is to simulate high pressure gas flow through the clearance between a valve seat and disc when in a closed position using a representative model. This leakage phenomenon is common in metal-to-metal seal pressure relief valves. As a pressure relief valve reaches the set pressure, it is known for the leakage to increase. The representative model that we studied is of an ideal-gas flow through a 2D microchannel in the slip flow regime. We used a laminar continuum flow solver which solved the mass, momentum and energy equations. In addition, we applied low pressure slip boundary conditions at the wall boundaries which considered Maxwells model for slip. The channel height was varied from 1μm to 5μm while the length remained at 1.25 mm, this means the length to height ratio varied from 1250 to 250. Inlet pressure was varied from a low pressure (0.05 MPa) to a high pressure (18.6 MPa), while the outlet remained constant at atmospheric. The calculated mass flow rate is compared to an analytical solution giving very good agreement for low pressure ratios and high length to height ratios.
Microflow Leakage Through the Clearance of a Metal-Metal Seal
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Anwar, AA, Ritos, K, Gorash, Y, Dempster, W, & Nash, D. "Microflow Leakage Through the Clearance of a Metal-Metal Seal." Proceedings of the ASME 2016 Pressure Vessels and Piping Conference. Volume 7: Operations, Applications and Components. Vancouver, British Columbia, Canada. July 17–21, 2016. V007T07A021. ASME. https://doi.org/10.1115/PVP2016-63848
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