This present research uses artifical neural networks (ANNs) to analyze and estimate the influence of transfer functions and training algorithms on experimentally determined Nusselt numbers, friction factors, entropy generation numbers and irreversibility distribution ratios for nine different baffle plate inserted tubes. Nine baffle-inserted tubes have several baffles with various geometric parameters used in the experiments with a baffle area blockage ratio of two, with different pitch to diameter ratios, different baffle orientation angles and different baffle spacings. The actual experimental data sets were used from previous author’s studies and applied as a input data set of ANNs. MATLAB toolbox was used to search better network configuration prediction by using commonly used multilayer feed-forward neural networks (MLFNN) with back propagation (BP) learning algorithm with thirteen different training functions with adaptation learning function of mean square error and TANSIG transfer function. In this research, eighteen data samples were used in a series of runs for each nine samples of baffle-inserted tube. Reynold number, tube lenght to baffle spacing ratio, baffle orientation angle and pitch to diameter ratio were considered as input variables of ANNs and the time averaged values of Nusselt number, friction factor, entropy generation number and irreversibility distribution ratio were determined as the target data. The total 70% of the experimental data was used to train, 15% was used to test and the rest of data was used to check the validity of the ANNs. The TRAINBR training function was found as the best model for predicting the target experimental outputs. Almost perfect accuracy between the neural network predictions and experimental data was achieved with mean relative error (MRE) of 0,000105816% and correlation coefficient (R) that was 0,999160176 for all datasets, which suggests the reliability of the ANNs as a strong tool for predicting the performance of transient forced convective heat transfer applications.
| Published in | International Journal of Mechanical Engineering and Applications (Volume 4, Issue 6) |
| DOI | 10.11648/j.ijmea.20160406.12 |
| Page(s) | 212-225 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Heat Transfer Enhancement, Transient Forced Convection, Baffle Inserted Tubes, Artifical Neural Network, Training Function
| [1] | M. Mohanraj, S. Jayaraj, and C. Muraleedharan, Applications of artificial neural networks for thermal analysis of heat exchangers – A review, Int. J. Therm. Sci. 90 (2015) 150–172. |
| [2] | G. J. Zdaniuk, L. M. Chamra, D. Keith Walters, Correlating heat transfer and friction in helically-finned tubes using artificial neural networks, Int. J. Heat Mass Transf. 50 (2007) 4713–4723. |
| [3] | M. Rahimi, M. Hajialyani, R. Beigzadeh, A. A. Alsairafi, Application of artificial neural network and genetic algorithm approaches for prediction of flow characteristic in serpentine microchannels, Chem. Eng. Res. Des. 98 (2015) 147–156. |
| [4] | D. Rostamifard, M. Fallahnezhad, S. Zaferanlouei, S. Setayeshi, M. H. Moradi, Empirical correlation study of dryout heat transfer at high pressure using high order neural network and feed forward neural network, Heat Mass Transf. 47 (2011) 439–448. |
| [5] | G. N. Xie, Q. W. Wang, M. Zeng, L. Q. Luo, Heat transfer analysis for shell-and-tube heat exchangers with experimental data by artificial neural networks approach, Appl. Therm. Eng. 27 (2007) 1096–1104. |
| [6] | Y. Islamoglu, A. Kurt, Heat transfer analysis using ANNs with experimental data for air flowing in corrugated channels, Int. J. Heat Mass Transf. 47 (2004) 1361–1365. |
| [7] | A. T. Mohammad, S. Bin Mat, M. Y. Sulaiman, K. Sopian, A. A. Al-abidi, Implementation and validation of an artificial neural network for predicting the performance of a liquid desiccant dehumidifier, Energy Convers. Manag. 67 (2013) 240–250. |
| [8] | M. R. Jafari Nasr, A. Habibi Khalaj, S. H. Mozaffari, Modeling of heat transfer enhancement by wire coil inserts using artificial neural network analysis, Appl. Therm. Eng. 30 (2010) 143–151. |
| [9] | L. V. Kamble, D. R. Pangavhane, T. P. Singh, Neural network optimization by comparing the performances of the training functions -Prediction of heat transfer from horizontal tube immersed in gas–solid fluidized bed, Int. J. Heat Mass Transf. 83 (2015) 337–344. |
| [10] | R. Baby, C. Balaji, Thermal optimization of PCM based pin fin heat sinks: An experimental study, Appl. Therm. Eng. 54 (2013) 65–77. |
| [11] | A. Kumar, C. Balaji, A Principal Component Analysis and neural network based non-iterative method for inverse conjugate natural convection, Int. J. Heat Mass Transf. 53 (2010) 4684–4695. |
| [12] | Ş. Ö. Atayılmaz, H. Demir, Ö. Ağra, Application of artificial neural networks for prediction of natural convection from a heated horizontal cylinder, Int. Commun. Heat Mass Transf. 37 (2010) 68–73. |
| [13] | A. J. Ghajar, L. M. Tam, and S. C. Tam, Improved Heat Transfer Correlation in the Transition Region for a Circular Tube with Three Inlet Configurations Using Artificial Neural Networks, Heat Transf. Eng. 25 ( 2) (2004) 30–40. |
| [14] | H. Peng, X. Ling, Neural networks analysis of thermal characteristics on plate-fin heat exchangers with limited experimental data, Appl. Therm. Eng. 29 (2009) 2251-2256. |
| [15] | M. Gao, Y.-T. Shi, N.-N. Wang, Y.-B. Zhao, F.-Z. Sun, Artificial neural network model research on effects of cross-wind to performance parameters of wet cooling tower based on level Froude number, Appl. Therm. Eng. 51 (2013) 1226-1234. |
| [16] | R. Baby and C. Balaji, Thermal optimization of PCM based pin fin heat sinks: An experimental study, Appl. Therm. Eng. 54 (2013) 65–77. |
| [17] | Jafari Nasr MR, Khalaj AH. Heat transfer coefficient and friction factor prediction of corrugated tubes combined with twisted tape inserts using artificial neural network, Heat Transfer Eng. 31 (2010) 59–69. |
| [18] | G. Diaz and A. Campo, Artificial neural networks to correlate in-tube turbulent forced convection of binary gas mixtures, Int. J. Therm. Sci. 48 (7) (2009) 1392–1397. |
| [19] | G. J. Zdaniuk, R. Luck, and L. M. Chamra, Linear correlation of heat transfer and friction in helically-finned tubes using five simple groups of parameters, Int. J. Heat Mass Transf. 51 (3) (2008) 13–14. |
| [20] | N. Sozbir, I. Ekmekci, Experimental study and artificial neural network modeling of unsteady laminar forced convection in a rectangular duct, Heat Mass Transf. 43 (2007) 749-758. |
| [21] | A. Tandiroglu, Effect of flow geometry parameters on transient heat transfer for turbulent flow in a circular tube with baffle inserts, International Journal of Heat and Mass Transfer 49 (9–10) (2006) 1559–1567. |
| [22] | A. Tandiroglu, Irreversibility minimization analysis of transient heat transfer for turbulent flow in a circular tube with baffle inserts, Journal of Enhanced Heat Transfer 13 (3) (2006) 215-229. |
| [23] | A. Tandiroglu, Effect of flow geometry parameters on transient entropy generation for turbulent flow in circular tube with baffle inserts, Energy Conversion and Management 48 (3) (2007) 898-906. |
| [24] | Vogl, T. P., J. K. Mangis, A. K. Rigler, W. T. Zink, and D. L. Alkon, Accelerating the convergence of the backpropagation method, Biological Cybernetics 59 (1988) 257-263. |
| [25] | Dullette, W. R. and Bejan, A. Conservation of avaliable work (exergy) by using promoters of swirl flow in forced convection heat transfer, Energy 5 (8-9) (1980) 587- 596. |
| [26] | A. Bejan, Entropy Generation Minimization, CRC Pres, Boca Raton, New York, 1996. |
| [27] | Kline, S. J. and McClintock, F. A., Describing Uncertainties in Single Sample Experiments, Mechanical Engineering 75 (1953) 385–387. |
| [28] | C. K. Tan, J. Ward, S. J. Wilcox, R. Payne, Artificial neural network modeling of the thermal performance of a compact heat exchanger, Appl. Therm. Eng. 29 (2009) 3609–3617. |
| [29] | H. Demuth, M. Beale and M. T. Hagan, Neural Network Toolbox for Use with MATLAB, Neural Network Toolbox User’s Guide, The Math Works Inc., Natick, MA, 2005. |
| [30] | Foresee, F. D., and M. T. Hagan, Gauss-Newton approximation to Bayesian regularization, Proceedings of the 1997 International Joint Conference on Neural Networks, 1997. |
| [31] | D. J. C. Markay, Bayesian interpolation, Neural Comput. 4 (1992) 415–447. |
| [32] | Powell, M. J. D.,“Restart procedures for the conjugate gradient method,” Mathematical Programming, vol. 12, pp. 241-254, 1977. |
| [33] | Moller, M. F., “A scaled conjugate gradient algorithm for fast supervised learning,” Neural Networks, vol. 6, pp. 525-533, 1993. |
| [34] | M. T. Hagan, H. B. Demuth, M. H. Beale, Neural Network Design, PWS Publishing, Boston, MA, 1996. |
| [35] | Scales, L. E., Introduction to Non-Linear Optimization, New York: Springer-Verlag, 1985. |
| [36] | F. D. Foresee, M. T. Hagan, Gauss–Newton approximation to Bayesian regularization, in: Proceedings of the International Joint Conference on Neural Networks, IEEE Press, Piscataway, NJ, 1997, pp. 1930–1935. |
| [37] | M. T. Hagan, M. Menhaj, Training feed forward networks with the Marquardt algorithm, IEEE Trans. Neural Networks 5 (1994) 989–993. |
| [38] | Riedmiller, M., and H. Braun, “A direct adaptive method for faster backpropagation learning: The RPROP algorithm,” Proceedings of the IEEE International Conference on Neural Networks, San Francisco,1993. |
| [39] | Gill, P. E., W. Murray, and M. H. Wright, Practical Optimization, New York: Academic Press, 1981. |
| [40] | J. E. Dennis, R. B. Schanabel, Numerical Methods for Unconstrained Optimization and Nonlinear Equations, Prentice-Hall, Englewood Cliffs, NJ, 1983. |
| [41] | G. E. Nasr, E. A. Badr, C. Joun, Back propagation neural networks for modeling gasoline consumption, Energy Convers. Manage. 44 (2003) 893–905. |
| [42] | Sanjay C, Jyothi C, Chin CW. A study of surface roughness in drilling using mathematical analysis and neural Networks, Int. J. Adv. Manu. Technol. 29 (2006) 846–52. |
| [43] | G. E. Nasr, E. A. Badr, C. Joun, Back propagation neural networks for modeling gasoline consumption, Energy Convers. Manage. 44 (2003) 893–905. |
| [44] | Rostamifard Dariush, Fallahnezhad Mehdi, Zaferanlouei Salman, Setayeshi Saeed and Moradi Mohammad Hassan, Empirical correlation study of dryout heat transfer at high pressure using high order neural network and feed forward neural network, Heat Mass Transfer 47 (2011) 439–448. |
APA Style
Ahmet Tandiroglu. (2016). Artificial Neural Network Approach for Transient Forced Convective Heat Transfer Optimization. International Journal of Mechanical Engineering and Applications, 4(6), 212-225. https://doi.org/10.11648/j.ijmea.20160406.12
ACS Style
Ahmet Tandiroglu. Artificial Neural Network Approach for Transient Forced Convective Heat Transfer Optimization. Int. J. Mech. Eng. Appl. 2016, 4(6), 212-225. doi: 10.11648/j.ijmea.20160406.12
AMA Style
Ahmet Tandiroglu. Artificial Neural Network Approach for Transient Forced Convective Heat Transfer Optimization. Int J Mech Eng Appl. 2016;4(6):212-225. doi: 10.11648/j.ijmea.20160406.12
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.ijmea.20160406.12,
author = {Ahmet Tandiroglu},
title = {Artificial Neural Network Approach for Transient Forced Convective Heat Transfer Optimization},
journal = {International Journal of Mechanical Engineering and Applications},
volume = {4},
number = {6},
pages = {212-225},
doi = {10.11648/j.ijmea.20160406.12},
url = {https://doi.org/10.11648/j.ijmea.20160406.12},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijmea.20160406.12},
abstract = {This present research uses artifical neural networks (ANNs) to analyze and estimate the influence of transfer functions and training algorithms on experimentally determined Nusselt numbers, friction factors, entropy generation numbers and irreversibility distribution ratios for nine different baffle plate inserted tubes. Nine baffle-inserted tubes have several baffles with various geometric parameters used in the experiments with a baffle area blockage ratio of two, with different pitch to diameter ratios, different baffle orientation angles and different baffle spacings. The actual experimental data sets were used from previous author’s studies and applied as a input data set of ANNs. MATLAB toolbox was used to search better network configuration prediction by using commonly used multilayer feed-forward neural networks (MLFNN) with back propagation (BP) learning algorithm with thirteen different training functions with adaptation learning function of mean square error and TANSIG transfer function. In this research, eighteen data samples were used in a series of runs for each nine samples of baffle-inserted tube. Reynold number, tube lenght to baffle spacing ratio, baffle orientation angle and pitch to diameter ratio were considered as input variables of ANNs and the time averaged values of Nusselt number, friction factor, entropy generation number and irreversibility distribution ratio were determined as the target data. The total 70% of the experimental data was used to train, 15% was used to test and the rest of data was used to check the validity of the ANNs. The TRAINBR training function was found as the best model for predicting the target experimental outputs. Almost perfect accuracy between the neural network predictions and experimental data was achieved with mean relative error (MRE) of 0,000105816% and correlation coefficient (R) that was 0,999160176 for all datasets, which suggests the reliability of the ANNs as a strong tool for predicting the performance of transient forced convective heat transfer applications.},
year = {2016}
}
TY - JOUR T1 - Artificial Neural Network Approach for Transient Forced Convective Heat Transfer Optimization AU - Ahmet Tandiroglu Y1 - 2016/11/23 PY - 2016 N1 - https://doi.org/10.11648/j.ijmea.20160406.12 DO - 10.11648/j.ijmea.20160406.12 T2 - International Journal of Mechanical Engineering and Applications JF - International Journal of Mechanical Engineering and Applications JO - International Journal of Mechanical Engineering and Applications SP - 212 EP - 225 PB - Science Publishing Group SN - 2330-0248 UR - https://doi.org/10.11648/j.ijmea.20160406.12 AB - This present research uses artifical neural networks (ANNs) to analyze and estimate the influence of transfer functions and training algorithms on experimentally determined Nusselt numbers, friction factors, entropy generation numbers and irreversibility distribution ratios for nine different baffle plate inserted tubes. Nine baffle-inserted tubes have several baffles with various geometric parameters used in the experiments with a baffle area blockage ratio of two, with different pitch to diameter ratios, different baffle orientation angles and different baffle spacings. The actual experimental data sets were used from previous author’s studies and applied as a input data set of ANNs. MATLAB toolbox was used to search better network configuration prediction by using commonly used multilayer feed-forward neural networks (MLFNN) with back propagation (BP) learning algorithm with thirteen different training functions with adaptation learning function of mean square error and TANSIG transfer function. In this research, eighteen data samples were used in a series of runs for each nine samples of baffle-inserted tube. Reynold number, tube lenght to baffle spacing ratio, baffle orientation angle and pitch to diameter ratio were considered as input variables of ANNs and the time averaged values of Nusselt number, friction factor, entropy generation number and irreversibility distribution ratio were determined as the target data. The total 70% of the experimental data was used to train, 15% was used to test and the rest of data was used to check the validity of the ANNs. The TRAINBR training function was found as the best model for predicting the target experimental outputs. Almost perfect accuracy between the neural network predictions and experimental data was achieved with mean relative error (MRE) of 0,000105816% and correlation coefficient (R) that was 0,999160176 for all datasets, which suggests the reliability of the ANNs as a strong tool for predicting the performance of transient forced convective heat transfer applications. VL - 4 IS - 6 ER -
Information
Email: