Your search keyword '"HONGHI TRAN"' showing total 2 results

1. Supersonic Jet Impingement on a Cylinder and Characterization of the Resulting Deflected Jets.

Author

Pophali, Ameya, Bussmann, Markus, and Honghi Tran

Subjects

JET impingement, ENGINE cylinders, ENGINES, FLOW visualization, FLOW measurement

Abstract

The interaction between a mildly underexpanded supersonic jet and a single cylinder was studied experimentally at laboratory scale by using the schlieren technique coupled with high-speed photography and pitot pressure measurements. This study was motivated by the need to optimize sootblowing operation in krafi recovery boilers. The effects of the transverse distance between the jet and cylinder centerlines (eccentricity), nozzle-cylinder distance, and cylinder size on jet-cylinder interaction were determined. Results show that upon impingement on a cylinder, a supersonic jet deflects at an angle and creates a weaker supersonic jet that we refer to as a "secondary" jet. The angle and strength of the deflected or secondary jet depend on the eccentricity between the primary jet and cylinder centerlines. When a jet impinges on a cylinder of diameter comparable to that of the jet or smaller, secondary jets form not only when the cylinder is placed close to the nozzle (in the stronger portion of the jet) but also when the cylinder is placed far away (in the jet's weaker portion; up to 20-24 nozzle exit diameters in the present study). Changing the eccentricity slightly results in a significant change in the secondary jet characteristics. For a cylinder much larger than the jet, secondary jets do not form at zero eccentricity (head-on impingement); the eccentricity at which they begin to form increases with the cylinder size. A study of the secondary jets shows that they spread out much more than the primary jet and are sheet- or fan-like with an oblong, oval cross section. The centerline pitot pressure of the secondary jets remains as high as the primary jet for a considerable distance from the tube only during weak interaction between the primary jet and the cylinder (i.e., during strongly eccentric/off-centerd impingement). As the interaction between the primary jet and the cylinder intensifies at lower eccentricities, the maximum centerline pitot pressure of the secondary jet decreases, and the pitot pressure decreases more quickly with distance from the tube. [ABSTRACT FROM AUTHOR]

Published

2014

2. Application of Realizability and Shock Unsteadiness to k-ϵ Simulations of Under-Expanded Axisymmetric Supersonic Free Jets.

Author

Emami, Babak, Bussmann, Markus, and Honghi Tran

Subjects

AXIAL flow, SUPERSONIC transport planes, FINITE volume method, TURBULENCE, COMPRESSIBILITY, PROPERTIES of matter

Abstract

An explicit cell-centered finite volume solver coupled to a k- turbulence model corrected for structural compressibility fails to satisfactorily predict the behavior of under-expanded supersonic jets exhausting into still air, because the model does not properly account for the turbulence/shock wave interaction. Two approaches are examined: imposing a realizability constraint and taking into account shock unsteadiness effects. Although both corrections yield better agreement with experimental data of under-expanded jets, the realizability constraint yields better results than the shock unsteadiness correction. [ABSTRACT FROM AUTHOR]

Published

2010