Nowadays,
new materials are developed with the aim to reduce heat transfer and energy
loss. Thus, energy can be reduced and heat energy can be transferred
efficiently. Many researches on the field of heat transfer have been made in
the literature. However, there are few studies on the determination of
insulation material thickness using heuristic algorithms and there is no study
on finding the thermal boundary layer thickness using heuristic algorithms. One
of the heuristic algorithms used in the field of computer science is Genetic Algorithm
(GA), which is frequently applied in optimization problems. We propose that GA
could be used to solve heat transfer problems of insulation material selection
and laminar thermal boundary layer thickness determination. The goal of the
proposal is to estimate the optimal parameters using a GA. In the first case,
the thickness of insulation material selection and the maximum amount of heat
loss that can be caused by different thicknesses of the insulating material
under the boundary conditions and assumptions are calculated using GAs. It is
shown that, using the heat-transfer coefficient and unit length cylinder, GAs
can be used in everyday problems, such as determining the thickness of the
insulating material or the outer temperature of the insulating material. In the
second case, the boundary layer thickness is determined using GA for air flow
with a laminar flow, where its characteristics are constant, irradiation is
neglected, and plate and air temperatures are constant in the continuous regime
on the plate. For both cases, the GA results are repeated 5 times and it is
observed that the results are very close to each other. The experimental
results demonstrate that, for both cases GA gives optimal target, minimum and
maximum values, thus, GAs are applicable in heat-transfer problems that require
optimization.
Primary Language | English |
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Subjects | Computer Software |
Journal Section | Research Articles |
Authors | |
Publication Date | December 1, 2019 |
Submission Date | December 21, 2018 |
Acceptance Date | July 9, 2019 |
Published in Issue | Year 2019 |
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.