Local heat/mass transfer distributions in rotating two-pass square channels Park, Chan Wook /

The detailed local heat transfer distributions in rotating

Bibliographic Details
Main Author: Park, Chan Wook, 1956-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1996.
Subjects:
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Description
Summary:The detailed local heat transfer distributions in rotating
two-pass square channels are investigated using the
naphthalene mass transfer technique and the heat/mass
transfer analogy. Reynolds number is varied from 5,500 to
14,500, and rotation number up to 0.24, for air flows through
a smooth channel and rib-roughened channels with ribs on the
leading and trailing walls. With the rib-roughened channels,
the effects of rib blockage and rib angle (90' and 60') are
studied. Since the test channel walls and the air flow are
both at room temperature during the mass transfer
experiments, there is very small density variation in the
flow field. Attention is therefore focused on the sole
effect of the rotational Coriolis force under the zero
buoyancy condition, and its coupling with the effects of the
turn-induced secondary flows and the rib-induced local flow
fields. The normalized local Sherwood number distributions
on the leading and trailing walls are presented as well as
the streamwise distributions of the spanwise averaged
Sherwood number ratios. Results show significant spatial
variations of the local mass transfer around the turn and
between the ribs on the rib-roughened surfaces. In the first
straight pass, the mass transfer on the leading wall
decreases with increasing rotation number, and, in the smooth
channel case, it decreases monotonically along the streamwise
direction. Published heat transfer results showed the
strongly coupled effects of Coriolis forces and buoyancy
forces caused an increase of the downstream heat transfer at
high rotation numbers. Comparison of the present results
with published heat transfer results reveals that buoyancy
effects are far less significant in a ribbed channel than in
a smooth channel. The complex flow field in the turn region
is characterized by the interactions between the turn-induced
and the rotation-induced vortices, which produce the highly
complicated mass transfer distributions around the turn and
in the upstream half of the second pass, in the case of the
smooth channel. However, the pattern of the spanwise
averaged mass transfer distribution remains almost invariant
with change of the rotation number from 0.09 to 0.24. This
implies a strong dependency of the flow field on the local
geometry of a sharp turn. Ribs on the trailing wall alter
the whole flow field in the first pass at high rotation
numbers. Larger ribs on the trailing wall make the
streamwise velocity profile more symmetric, weakening the
rotational effects, and enhance the opposite leading wall
mass transfer significantly. Skewed ribs (60') enhance more
mass transfer than normal ribs (90') in the first pass. In
the first pass of a channel roughened with skewed ribs, the
coupling effects of the rotational vortices and the rib-
induced secondary flows cause very high mass transfer that
increases along the streamwise direction. Reynolds number
effects are evident in the turn with a substantial increase
of the Sherwood number ratios at lower Reynolds numbers. In
the first pass of a rotating smooth channel, the differences
between the Sherwood number ratios on the leading wall and
those on the trailing wall become greater as the Reynolds
number decreases.
Item Description:Vita.
"Major Subject: Mechanical Engineering."
Physical Description:xiv, 111 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references: pages 93-97.