Abstract

Constriction devices contain an element inserted into the fluid stream, which changes the local streamwise distribution of the flow area. One such element is the orifice-like obstruction with sharp corners, basically a back-to-back abrupt contraction and expansion, which could trigger flow separation. A series of microchannels, 40 /spl mu/m/spl times/1 /spl mu/m/spl times/4000 /spl mu/m in dimensions, with orifice element at the centers of the channels has been fabricated using standard micromachining techniques. The channel width at the orifice section varied from 10 /spl mu/m to 34 /spl mu/m, and each channel was integrated with a set of pressure sensors. Nitrogen gas was passed through the microdevices under inlet pressure up to 50 psi. Mass flow rate was first measured for all the devices as a function of the pressure drop, showing a monotonic decrease of the flow rate with decreasing orifice width. Then, the pressure distributions along the microchannel with the narrowest orifice were recorded, showing a pressure jump across the 10 /spl mu/m-wide orifice. The mass flow rate and pressure measurements indicate the existence of flow separation in the microchannels.