internal flow: forced convection -...
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Internal Flow:
Forced Convection
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Entrance Conditions
Entrance Conditions
• Must distinguish between entrance and fully developed regions.
• Hydrodynamic Effects: Assume laminar flow with uniform velocity profile at
inlet of a circular tube.
– Velocity boundary layer develops on surface of tube and thickens with increasing x.
– Inviscid region of uniform velocity shrinks as boundary layer grows.
– Subsequent to boundary layer merger at the centerline, the velocity profile
becomes parabolic and invariant with x. The flow is then said to be
hydrodynamically fully developed.
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Entrance Conditions (cont)
• Thermal Effects: Assume laminar flow with uniform temperature, , at
inlet of circular tube with uniform surface temperature, , or heat flux, . ,0 iT r T
s iT T sq
– Thermal boundary layer develops on surface of tube and thickens with increasing x.
– Isothermal core shrinks as boundary layer grows.
– Subsequent to boundary layer merger, dimensionless forms of the temperature
profile become independent of x. Conditions are then said to be
thermally fully developed. for and s sT q
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Derivations
• Refer to class notes for derivations
– Laminar flow through a circular tube
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Fully Developed Flow
Fully Developed Flow
• Laminar Flow in a Circular Tube:
The local Nusselt number is a constant throughout the fully developed
region, but its value depends on the surface thermal condition.
– Uniform Surface Heat Flux : ( )sq
4.36DhDNuk
– Uniform Surface Temperature : ( )sT
3.66DhDNuk
• Turbulent Flow in a Circular Tube:
– For a smooth surface and fully turbulent conditions , the
Dittus – Boelter equation may be used as a first approximation: Re 10,000D
4 / 50.023Re Prn
D DNu
1/ 2 2 / 3
/8 Re 1000 Pr
1 12.7 /8 Pr 1
DD
fNu
f
– The effects of wall roughness and transitional flow conditions
may be considered by using the Gnielinski correlation:
Re 3000D
0.3
0.4s m
s m
n T T
n T T
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Fully Developed (cont.)
Smooth surface:
2
0.790 1n Re 1.64Df
Surface of roughness : 0e
• Noncircular Tubes:
– Use of hydraulic diameter as characteristic length:4 c
h
AD
P
– Since the local convection coefficient varies around the periphery of a tube,
approaching zero at its corners, correlations for the fully developed region
are associated with convection coefficients averaged over the periphery
of the tube.
– Laminar Flow:
The local Nusselt number is a constant whose value depends on
the surface thermal condition and the duct aspect ratio. s sT or q
– Turbulent Flow:
As a first approximation, the Dittus-Boelter or Gnielinski correlation may be used
with the hydraulic diameter, irrespective of the surface thermal condition.
f Moody chart
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Entry Region
Effect of the Entry Region
• The manner in which the Nusselt decays from inlet to fully developed conditions
for laminar flow depends on the nature of thermal and velocity boundary layer
development in the entry region, as well as the surface thermal condition.
Laminar flow in a
circular tube.
– Combined Entry Length:
Thermal and velocity boundary layers develop concurrently from uniform
profiles at the inlet.
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Entry Region (cont)
– Thermal Entry Length:
Velocity profile is fully developed at the inlet, and boundary layer development
in the entry region is restricted to thermal effects. Such a condition may also
be assumed to be a good approximation for a uniform inlet velocity profile if
Pr 1.
• Average Nusselt Number for Laminar Flow in a Circular Tube with Uniform
Surface Temperature:
– Combined Entry Length:
1/ 3 0.14
Re Pr/ / / 2 :D sL D
0.141/ 3Re Pr
1.86/D
D
s
NuL D
1/ 3 0.14
Re Pr/ / / 2 :D sL D
3.66DNu
– Thermal Entry Length:
2 / 3
0.0668 / Re Pr3.66
1 0.04 / Re Pr
DD
D
D LNu
D L
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Entry Region (cont)
• Average Nusselt Number for Turbulent Flow in a Circular Tube :
– Effects of entry and surface thermal conditions are less pronounced for
turbulent flow and can be neglected.
– For long tubes : / 60L D
,D D fdNu Nu
– For short tubes : / 60L D
,
1/
Dm
D fd
Nu C
Nu L D
12/3
Cm
• Noncircular Tubes:
– Laminar Flow:
depends strongly on aspect ratio, as well as entry region and surface
thermal conditions. Refer to table shown in classhDNu
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Entry Region (cont)
• When determining for any tube geometry or flow condition, all
properties are to be evaluated at
DNu
, , / 2m m i m oT T T
Refer to the problem solved in class that involved iteration for exit temperature
– Turbulent Flow:
As a first approximation, correlations for a circular tube may be used
with D replaced by .hD
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Annulus The Concentric Tube Annulus
• Fluid flow through
region formed by
concentric tubes.
• Convection heat transfer
may be from or to inner
surface of outer tube and
outer surface of inner tube.
• Surface thermal conditions may be characterized by
uniform temperature or uniform heat flux . , ,,s i s oT T ,i oq q
• Convection coefficients are associated with each surface, where
,i i s i mq h T T
,o o s o mq h T T
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Annulus (cont)
i h o hi o
h D h DNu Nu
k k
• Fully Developed Laminar Flow
Nusselt numbers depend on and surface thermal conditions (standard tables
available)
/i oD D
• Fully Developed Turbulent Flow
Correlations for a circular tube may be used with replaced by .DhD
h o iD D D