ANN modeling of thermal conductivity and viscosity of MXene-based aqueous IoNanofluid
Document Type
Article
Publication Date
2-1-2021
Abstract
Research shows that due to enhanced properties IoNanofluids have the potential of being used as heat transfer fluids (HTFs). A significant amount of experimental work has been done to determine the thermophysical and rheological properties of IoNanofluids; however, the number of intelligent models is still limited. In this work, we have experimentally determined the thermal conductivity and viscosity of MXene-doped MMIM]DMP] ionic liquid. The size of the MXene nanoflakes was determined to be less than 100 nm. The concentration was varied from 0.05 mass% to 0.2 mass%, whereas the temperature varied from 19 degrees C to 60 degrees C. The maximum thermal conductivity enhancement of 1.48 was achieved at 0.2 mass% and 30 degrees C temperature. For viscosity, the maximum relative viscosity of 1.145 was obtained at 0.2 mass% and 23 degrees C temperature. After the experimental data for thermal conductivity and viscosity were obtained, two multiple linear regression (MLR) models were developed. The MLR models' performances were found to be poor, which further called for the development of more accurate models. Then two feedforward multilayer perceptron models were developed. The Levenberg-Marquardt algorithm was used to train the models. The optimum models had 4 and 10 neurons for thermal conductivity and viscosity model, respectively. The values of statistical indices showed the models to be well-fit models. Further, relative deviations values were also accessed for training data and testing data, which further showed the models to be well fit.
Keywords
Aqueous ionic liquid, 1, 3-Dimethyl imidazolium dimethyl-phosphate, Levenberg-Marquardt algorithm, MXene, Thermal conductivity, Viscosity
Divisions
fac_eng
Publication Title
International Journal of Thermophysics
Volume
42
Issue
2
Publisher
Springer/Plenum Publishers
Publisher Location
233 SPRING ST, NEW YORK, NY 10013 USA