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This thesis is aimed at applying the concept of parameter retrieval by optimization
techniques to a few engineering systems involving heat and mass transfer. For this, two
heat transfer systems involving different types of fins and flat-plate solar collectors have
been considered. Furthermore, experimental data based parameter retrieval on a combined
heat and mass transfer system concerning forced and induced draft cooling towers is also
undertaken. Although the main focus is given on unknown parameter retrieval through
inverse analysis, but, many new computational algorithms and empirical correlations for
the forward analysis have been also reported from the present research study. The work
successfully demonstrates the application of evolutionary optimization algorithms such as
the binary-coded Genetic Algorithm (GA) and the real-coded Differential Evolution (DE)
for unknown multi-parameter retrievals. Apart from evolutionary methods, a few
problems have been also solved with the Golden Section Search Method (GSSM) for
single parameter retrieval. Relative merits and limitations of various techniques have been
also highlighted.
Based on the literature survey, the research work begins with the formulation and the
solution of the identified parabolic heat transfer problems on fins involving different
levels of nonlinearities, for which either forward and/or inverse analyses were not found.
Under this purview, four parabolic heat transfer problems are undertaken according to
increase in the difficulty level. Initially for the forward solution, the Adomian
Decomposition Method (ADM) is applied for the straight fin, the moving fin and the
stepped fin involving all temperature-dependent modes of heat transfer and complex
boundary conditions. Furthermore, a comparative study is also conducted on a porous fin.
Subsequently, the DE, the GA and the GSSM are applied on these fin problems to
inversely predict critical parameters such as the rate of internal heat generation, heat
transfer coefficient, fin speed, thermal conductivity. To examine the suitability of
optimization technique for single and multi-parameter inverse retrievals, a comparative
study is done on the porous fin. Realizing the unsuitability of the GSSM for multiparameter
estimation, among the GA and the DE, it is found that the real-coded DE is the
most suitable optimization technique for the multiple parameter retrievals. Besides this,
the GSSM is found to be the befitting method for single parameter retrieval. After retrieving different parameters, the amount of acceptable simulated measurement
errors/noise are also quantified. For the rectangular fin with internal heat generation,
satisfactory interpretations are revealed up to 10% simulated measurement error.
However, for the same fin without internal heat generation, the reconstructed trends are in
satisfactory agreement up to 5% simulated measurement error. Furthermore, for the case
of a rectangular moving fin, the allowable/tolerable simulated measurement error is
found 7.90% .
The concept of heat transfer analysis of fins is next extended to retrieve parameters such
as Fourier number, Vernotte number, heat loss coefficient and incident solar heat flux in
hyperbolic heat transfer problems of flat-plate solar collectors. The estimations of these
parameters lead to determination of the time required to achieve the given temperature,
characterization of the heat velocity and the identification of feasible geographical
locations. During the appraisal of the acceptable measurement error, it is found that for
the solar collector with isothermal boundary condition, the variation between exact and
predicted Fourier numbers is 18.33% and 21% for non-Fourier model and Fourier model,
respectively. From the multi-parameter retrieval analysis involving the binary-coded GA,
it is observed that the reconstructed results obtained with the inversely-estimated
parameters are reasonably accurate. It is found that only 0.78% deviation takes place in
case of Fourier heat conduction model and 0.44% deviation is observed in case of non-
Fourier conduction model. The inverse results using the real-coded DE and the binarycoded
GA are compared for solar collector. The maximum acceptable measurement error
using the real-coded DE is found to be 5% for adequate reconstruction.
In the final chapter, parameter retrieval is accomplished from experiments on a combined
heat and mass transfer system involving two different types of cooling tower. In the first
case, an induced draft type of cooling tower is considered, whereas, in the other case, a
forced draft type of cooling tower is investigated. For the forward analysis, the relevant
and required correlations have been developed using the full factorial method-based
design of experiments. Thereafter, for single parameter retrieval, the GSSM is used,
whereas, for retrieving multiple parameters, the DE is used. Cooling towers’ performance
is specified by different performance parameters such as the range, the approach, the
effectiveness, the water evaporation rate, the global heat and mass transfer coefficient, the rate of heat transfer and the Merkel number. Among these, the Merkel number is found to
be important, because it involves various parameters such as the global heat and mass
transfer coefficient, the mass of water, the dimensions (interfacial area per unit volume)
and the range within itself. Therefore, it is also known as the tower characteristic ratio.
The mass flow rates of air and water are common controlling parameters related to the
performance of a cooling tower, but they do not explicitly appear in the expression for the
Merkel number. Therefore, the first objective is to propose the relevant correlation for the
Merkel number for the present experimental setup as a function of mass flow rates of air
and water. These parameters have been finally estimated using the inverse procedure for
satisfying a desired Merkel number. At first, the experimental setup of an induced draft
cooling tower has been considered which exemplifies a combined heat and mass transfer
system. In this study, the correlation of the Merkel number has been proposed with as a
function of air mass flow rate. Further, the developed correlation in conjunction with the
GSSM has been used to retrieve the unknown controlling parameter (air mass flow rate)
for a desired Merkel number of the cooling tower. For a given water flow rate, this case
study shows that the present inverse procedure is satisfactory for estimating the required
air flow rate to fulfill a desired tower characteristic ratio (Merkel number). It is found that
the maximum deviation is 4.4% for the correlation based on the quadratic approximation,
whereas, the deviation is 2.8% for the correlation based on the Pade approximation. In the
second part of this chapter, a different experimental system involving forced draft cooling
tower has been considered for the simultaneously retrieving multiple and feasible
combinations of water and air flow rates using the DE-based optimization methodology.
In this task, the relevant correlation of the Merkel number as a function of two controlling
parameters such as mass flow rate of air and water has been made using bivariate cubic
polynomial approximation and bicubic approximations. On comparing the goodness of
these two correlations, it is concluded that bivariate cubic polynomial approximation
yields better performance than the bicubic approximation. Excellent reconstruction of the
Merkel number is obtained using the DE with the aid of the bivariate correlation obtained
from the experimental data, with the coefficient of determination of the correlated data
against experimental values as 92.05%. It is also found that the present retrieval
methodology is an effective approach to estimate unknown controlling parameters for
practically satisfying a desired output from a given system. |
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