Pressure losses in flow components are generally characterized either by pressure loss coefficients or by discharge coefficients. The pressure drop for incompressible flow across a screen of fractional free area a is ...Pressure losses in flow components are generally characterized either by pressure loss coefficients or by discharge coefficients. The pressure drop for incompressible flow across a screen of fractional free area a is often calculated from widely used correlation provided in Perry's Handbook. This correlation was developed based on experimental work which have covered a wide range of fractional free area (a = 0.14 to 0.79). The present work aims at validation for a flow in plain square mesh screen with a particular fractional free area (porosity, a) of 0.25 using CFD (Computational Fluid Dynamics) approach. The simulations are carried out for wide range of screen Reynolds number (Re = 0.1 to 105) covering both laminar and turbulent flow regimes. Initial simulations are carried out for incompressible fluid (water) and further extended to compressible fluid (air). Discharge coefficients obtained from the simulations are compared with experimental values. Effect of compressibility on discharge coefficients is described.展开更多
文摘Pressure losses in flow components are generally characterized either by pressure loss coefficients or by discharge coefficients. The pressure drop for incompressible flow across a screen of fractional free area a is often calculated from widely used correlation provided in Perry's Handbook. This correlation was developed based on experimental work which have covered a wide range of fractional free area (a = 0.14 to 0.79). The present work aims at validation for a flow in plain square mesh screen with a particular fractional free area (porosity, a) of 0.25 using CFD (Computational Fluid Dynamics) approach. The simulations are carried out for wide range of screen Reynolds number (Re = 0.1 to 105) covering both laminar and turbulent flow regimes. Initial simulations are carried out for incompressible fluid (water) and further extended to compressible fluid (air). Discharge coefficients obtained from the simulations are compared with experimental values. Effect of compressibility on discharge coefficients is described.
