Title page for ETD etd-06222000-22310027


Type of Document Dissertation
Author Yuan, Yiqing
Author's Email Address yyuan888@home.com
URN etd-06222000-22310027
Title Jet Fluid Mixing Control Through Manipulation Jet Fluid Mixing Control Through Manipulation of Inviscid Flow Structures
Degree PhD
Department Mechanical Engineering
Advisory Committee
Advisor Name Title
Vandsburger, Uri Committee Chair
Brown, Eugene F. Committee Member
Dancey, Clinton L. Committee Member
Mungal, M. Godfrey Committee Member
Telionis, Demetri P. Committee Member
Keywords
  • jet
  • jet control
  • flow control
  • fluid mechanics
  • mixing control
Date of Defense 2000-05-31
Availability unrestricted
Abstract
Rapid mixing is crucial for the efficient and environment-friendly operation of many

industrial and propulsion devices involving jet flows. In this dissertation, two methodologies,

self-excited nozzles and radially lobed nozzles, are studied and presented in order to enhance

mixing in the near field of coflowing, subsonic, turbulent, free jet flows.

The characteristics of the concentration field and the mixing performance are examined,

mainly in quantitative manner. Two new parameters, mixing index and mixing efficiency index,

are defined for free jets, allowing quantitative analysis of the mixing performance and efficiency.

The flow fields are studied with hot wire anemometry, and with CFD simulation for some of the

radially lobed nozzles. Due to the large vectoring angle of the jet flows from these nozzles, a

new definition for the entrainment ratio is also adopted in order to take the large radial velocity

component into consideration.

Self-excited nozzles, rectangular and square shaped, are examined at Reynolds numbers

of 17,000 and 31,000. The self-excited square jet has fastest mixing and highest mixing

efficiency, with 400% higher mixing index at 4 diameters downstream than the unexcited square

jet. The mixing is improved as the excitation frequency or coflow velocity increases. The study

of flow field shows the presence of one pair of periodic, coherent array of large-scale,

streamwise, counter-rotating inviscid vortices shedding from each of the two flaps which

dominate the mean flow and the mixing process. The coflow is primarily entrained into the jet in

the minor plane while the jet fluid vectors in the major plane. Significant increase in turbulent

kinetic energy immediately downstream the nozzle exit improves small-scale mixing.

Radially lobed nozzles, a cross-shaped and a clover-shaped with four lobes each, are

analyzed in comparison to a conical nozzle. In addition, a few modified radially lobe nozzles,

including a 6-lobe nozzle and an 8-lobe nozzle, two type of fully penetrating nozzles, and a

cross-shaped nozzle with centerbody, are examined in order to achieve better mixing than the

cross-shaped nozzle. At 4 diameters downstream, the mixing index of the cross-shaped nozzle is

650% higher than that of the conical nozzle. The cross-shaped nozzle with centerbody, the 6-

lobe and 8-lobe nozzles have slower mixing and lower efficiency than the cross-shaped nozzle,but the fully-penetrating nozzles are generally better than the cross-shaped nozzle, especially at

low coflow velocities and in the far field. The flow field study shows that parallel lobe walls and

deep penetration of the coflow are importance factors responsible for the observed mixing

enhancement.

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