Free and Forced Convection description, and equations needed.
heat
Free and Forced Convection
Forced convection lab report
Forced convection lab report
important questions on Forced convectionFull description
nk tulisnape
Full description
Thermodynamic study of free and forced convection.
Engineering
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ME3122-2 Lab Forced Convection Heat Transfer
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This slide covers basics of forced vibration, including homogenous and particular solutions of a number of situationsDescription complète
converction chaleur echangeurDescription complète
Thermalfluids Lab-MEC 554/ LS 4/ THOMAS Rev. 01-2007
UNIVERSITI TEKNOLOGI MARA FACULTY OF MECHANICAL MECHANICAL ENGINEERING ___________________ _________ ____________________ ___________________ ___________________ ___________________ ____________________ _______________ ____ Program : Bachelor Of Engineering ( Hons ) Mechanical Course : Thermalfluids Lab Code : MEC 554 ___________________ _________ ____________________ ___________________ ___________________ ___________________ ____________________ _______________ ____ LAB SHEET NO:
4
HEAT TRANSFER LABORATORY SHEET TITLE : FORCED CONVECTION 1.
OBJECTIVE
Demonstrate the use of a fin (extended surface) to improve the heat transfer in forced convection.
2.
THEORY Heat Heat transf transfer er from from an objec objectt can be impro improved ved by increasing the surface area in contact with the air by adding fins or pins normal to the surface. This can be seen in Newton’s Law of Cooling, which defines the convection heat transfer rate:
Q
=
h A s ( T s
−
T
∞
)
The effect of the surfaces can be demonstrated by comparin comparing g finned finned and unfinned unfinned surfaces surfaces with a flat plate under the same conditions of power and flow.
1
Thermalfluids Lab-MEC 554/ LS 4/ THOMAS Rev. 01-2007 3.
EQUIPMENT
The surfaces are shown in the figure below. The finned surface consists of 9 fins that are each 0.1 m high and 0.068 m wide. The pinned surface consists of 17 pins that each have a diameter of 0.013 m and are 0.068 m long.
2
Thermalfluids Lab-MEC 554/ LS 4/ THOMAS Rev. 01-2007 4.
PROCEDURES Place the heat exchanger into the test duct and record the ambient temperature ( T ). b. Set the heater power control to 75 W. Allow the temperature to rise to 80°C then adjust the heater power control to 20 W. c. Start stopwatch wait 5 minute and record the heated plate surface temperature ( T s). d. Repeat step (b). Then set the fan speed control to give a reading of 1.0 m/s on the thermal anemometer. Allow 5 min for the reading to stabilize and then again record T s. e. Then adjust the fan speed to 2.0 m/s and then 2.5 m/s, recording the T s for each speed. [Same Procedure at step (d) ]. a.
5.
∞
RESULTS 1.
Start with the unfinned flat plate. Using the data tables shown below, record the ) ambient temperature ( T ) and the power input ( Q ∞
Ambient air temperature ( T ) = __________ °C ∞
) Power input ( Q Table A Air
Heater
Velocity
Temperature (T s)
[m/s]
[°C]
= __________ W
Flat Base Plate (Unfinned) Ts-T
h
[°C]
[W/(m·°C)]
0 1.0 2.0 2.5
2.
Calculate the temperature difference (T s T ) and record on the data table.
3.
Calculate the surface area of the base plate (A base).
−
3
∞
Thermalfluids Lab-MEC 554/ LS 4/ THOMAS Rev. 01-2007
4.
Calculate the convection heat transfer coefficient (h) from the equation:
h
5.
=
Q A s (T s
−
T
∞
)
Replace the flat plate with the finned surface plate and repeat the experiment. Then replace the finned surface with the pinned surface plate and repeat the experiment. An equation for the surface areas ( As) of the finned and pinned plates are shown below:
A finned = 9 × L w + Abase plate
A pinned = 17 ×
π
2
plate
Table B Air
Heater
Velocity
Temperature (T s)
[m/s]
[°C]
D L
+ Abase
Finned Plate Ts-T
h
[°C]
[W/(m·°C)]
0 1.0 2.0 2.5
Table C Air
Heater
Velocity
Temperature (T s)
[m/s]
[°C]
Pinned Plate Ts-T
h
[°C]
[W/(m·°C)]
0 1.0 2.0 2.5
6.
Plot graphs of air velocity versus surface temperature (T s-T ) of each plate. Compare the ability of each plate surface to disseminate heat by convection. ∞