THERMAL SCIENCE

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Subramanian Sundararaj

,

Velappan Selladurai

THE EFFECTS OF ARBITRARY INJECTION ANGLE AND FLOW CONDITIONS ON VENTURI-JET MIXER

ABSTRACT
This paper describes the effect of jet injection angle, cross flow Reynolds number and velocity ratio on entrainment and mixing of jet with incompressible cross flow in venturi-jet mixer. Five different jet injection angles 45o, 60o, 90o, 125o, 135o are tested to evaluate the entrainment of jet and mixing performances of the mixer. Tracer concentration along the downstream of the jet injection, cross flow velocity, jet velocity and pressure drop across the mixer are determined experimentally to characterize the mixing performance of the mixer. The experiments show that the performance of a venturi-jet-mixer substantially improves at high injection angle and can be augmented still by increasing velocity ratio. The jet deflects much and penetrates less in the cross flow as the cross flow Reynolds number is increased. The effect could contribute substantially to the better mixing index with moderate pressure drop. Normalized jet profile, concentration decay, jet velocity profile are computed from equations of conservation of mass, momentum and concentration written in natural co-ordinate systems. The comparison between the experimental and numerical results confirms the accuracy of the simulations. Correlations for jet trajectory and entrainment ratio of the mixer are obtained by multivariate-linear regression analysis using power law.
KEYWORDS
jet injection, static mixer, incompressible flow, proportional mixing, concentration decay
PAPER SUBMITTED: 2010-10-23
PAPER REVISED: 2011-06-02
PAPER ACCEPTED: 2011-06-29
DOI REFERENCE: https://doi.org/10.2298/TSCI101023059S
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2012, VOLUME 16, ISSUE Issue 1, PAGES [207 - 221]
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The effects of arbitrary injection angle and flow conditions on venturi-jet mixer

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