Experimental Investigation of Oscillatory Flow Pressure and Pressure Drop Through Complex Geometries
Proceedings of the 2nd International Energy Conversion Engineering Conference
A series of experiments have been performed to investigate the oscillatory flow pressure and pressure drop through complex geometries. These experiments were conducted at the CSU-SLRE facility which is a horizontally opposed, two-piston, single-acting engine with a split crankshaft driving mechanism. Flow through a rectangular duct, with no insert (obstruction), was studied first. Then four different inserts were examined: Abrupt, Manifold, Diverging Short and Diverging Long. The inserts were mounted in the center of the rectangular duct to represent different type of geometries that could be encountered in Stirling machines. The pressure and pressure drop of the oscillating flow was studied for: 1) different inserts, 2) different phase angle between the two pistons of the engine (zero, 90 lead, 180, and 90 lag), and 3) for different piston frequencies (5, 10, 15, and 20 Hz). It was found that the pressure drop of the oscillatory flow increases with increasing Reynolds number. The pressure drop was shown to be mainly due to the gas inertia for the case of oscillatory flow through a rectangular duct with no insert. On the other hand, for the cases with different inserts into the rectangular duct, the pressure drop has three sources: inertia, friction, and local losses. The friction pressure drop is only a small fraction of the total pressure drop. It was also shown that the dimensionless pressure drop decreases with increasing kinetic Reynolds number.
Ibrahim, Mounir B.; Wang, Meng; and Gedeon, David, "Experimental Investigation of Oscillatory Flow Pressure and Pressure Drop Through Complex Geometries" (2005). Mechanical Engineering Faculty Publications. 253.
Public Domain - NASA Technical Documents - nasa_techdoc_20050182918
Paper-AIAA-2004-5560 presented at the 2nd International Energy Conversion Engineering Conference, Providence, RI, August 16-19, 2004.