Experimental Study of Heat Transfer and Pressure Drop Phenomena in
Kerosene-Graphene Nanoplatelets in a Mini Channel Heat Sink 2022-01-5093
Our work intends to conduct experiments on kerosene-graphene nanoplatelets (GNP)
nanofluid in a mini channel heat sink (MCHS) in two concentrations of graphene
to verify the heat transfer and other hydrothermal phenomena. Many experiments
have already been carried out on cooling electronic devices using mini channels
along with various water-based nanofluids. The experiments with kerosene-GNP
nanofluid are conducted in two different weight percentages of graphene, 0.01
and 0.03. The surfactant used for best visual stability is oleylamine, with an
optimum mass ratio of 0.6 between it and graphene nanoparticles. A Peltier
heater is attached to the bottom of the mini channel and provided with three
different heat supplies of 8 W, 10 W, and 12 W, respectively, by varying the
current and voltage of the direct current (DC) source. The GNP-based nanofluid
is passed at three different flow rates of 0.3 l/min, 0.4 l/min, and 0.5 l/min.
The temperature values at the inlet, outlet, and the other two passes are
collected in a data acquisition (DAQ) system by imposing four k-type
thermocouples. Pressure transducers are placed at the inlet and outlet of the
mini channel to read the pressure reading for the pressure drop calculation. A
total of 27 experiments were carried out with varying flow rates, heat supply,
and nanoparticle concentration. For each parameter, the ratio of the total heat
transfer coefficient to the pressure drop
(h/∆P) is estimated. Our observation
concluded that there is an improvement in thermal performance by using
kerosene-GNP nanofluid as a coolant instead of pure kerosene. It is also
observed that the heat transfer coefficient increases the nanofluid discharge
rate and nanoparticle concentration and increases pressure drop in the
channel.
Citation: Dhar, S. and Hassan, M., "Experimental Study of Heat Transfer and Pressure Drop Phenomena in Kerosene-Graphene Nanoplatelets in a Mini Channel Heat Sink," SAE Technical Paper 2022-01-5093, 2022, https://doi.org/10.4271/2022-01-5093. Download Citation
Author(s):
Suraj Narayan Dhar, M.A. Hassan
Affiliated:
National Institute of Technology Jamshedpur, Department of M
Pages: 10
Event:
Automotive Technical Papers
ISSN:
0148-7191
e-ISSN:
2688-3627
Related Topics:
Heat transfer
Data acquisition and handling
Electronic equipment
Coolants
Pressure
Data exchange
Materials properties
Nanomaterials
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