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Transient thermal performance prediction method for parabolic trough solar collector under fluctuating solar radiation
Tohru Suwa1, Shye Yunn Heng2.
As the effect of the global warming is becoming noticeable, the importance for
environmental sustainability has been raised. Parabolic trough solar thermal collector
system, which is one of the solutions to reduce the carbon dioxide emission, is a mature
technology for electricity generation. Malaysia is a tropical country with long daytime,
which makes suitable for solar thermal applications with parabolic trough solar thermal
collectors. However, the high humidity causes the solar radiation to fluctuate. In order to
simulate the solar thermal collectors’ performance at an early design stage of solar
thermal power generation systems, fast still accurate transient thermal performance
prediction methodis required. Although multiple transient thermal simulation
methodologies exist, they are not suited especially at an early design stage where quick
but reasonably accurate thermal performance prediction is needed because of their long
calculation time. In this paper, a transient thermal prediction method is developed to
predict exit temperature of parabolic trough collectors under fluctuating solar radiation.
The method is governed by simple summation operations and requires much less
calculating time than the existing numerical methods. If the radiation heat loss at the
parabolic trough collector tube surface is small, the working fluid temperature rise may be
approximated as proportional to the receiving heat flux. The fluctuating solar radiation is
considered as a series of heat flux pulses applied for a short period of time. The time
dependent solar collector exit temperature is approximated by superimposing the exit
temperature rise caused by each heat flux pulse. To demonstrate the capabilities of the
proposed methodology, the solar collector exit temperature for one-day operation is
predicted. The predicted solar collector exit temperature captures the trend of a finite
element analysis result well. Still, the largest temperature difference is 38.8K and accuracy
is not satisfactory. Currently, the accuracy of the proposed method is being improved. At
the same time, its capabilities are being expanded.
Affiliation:
- Malaysia-Japan International Institute of Technology, Malaysia
- Malaysia-Japan International Institute of Technology, Malaysia
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Indexation |
Indexed by |
MyJurnal (2021) |
H-Index
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6 |
Immediacy Index
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0.000 |
Rank |
0 |
Indexed by |
Scopus 2020 |
Impact Factor
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CiteScore (1.4) |
Rank |
Q3 (Engineering (all)) |
Additional Information |
SJR (0.191) |
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