Estimation of gross calorific value of coals using artificial neural networks

The gross calorific value (GCV) is an important property defining the energy content and thereby efficiency of fuels, such as coals. There exist a number of correlations for estimating the GCV of a coal sample based upon its proximate and/or ultimate analyses. These correlations are mainly linear in character although there are indications that the relationship between the GCV and a few constituents of the proximate and ultimate analyses could be nonlinear. Accordingly, in this paper a total of seven nonlinear models have been developed using the artificial neural networks (ANN) methodology for the estimation of GCV with a special focus on Indian coals. The comprehensive ANN model developed here uses all the major constituents of the proximate and ultimate analyses as inputs while the remaining six sub-models use different combinations of the constituents of the stated analyses. It has been found that the GCV prediction accuracy of all the models is excellent with the comprehensive model being the most accurate GCV predictor. Also, the performance of the ANN models has been found to be consistently better than that of their linear counterparts. Additionally, a sensitivity analysis of the comprehensive ANN model has been performed to identify the important model inputs, which significantly affect the GCV. The ANN-based modeling approach illustrated in this paper is sufficiently general and thus can be gainfully extended for estimating the GCV of a wide spectrum of solid, liquid and gaseous fuels.

[1]  David M. Skapura,et al.  Neural networks - algorithms, applications, and programming techniques , 1991, Computation and neural systems series.

[2]  J. Zurada,et al.  Determining the Significance of Input Parameters using Sensitivity Analysis , 1995, IWANN.

[3]  L. Jiménez,et al.  Study of the physical and chemical properties of lignocellulosic residues with a view to the production of fuels , 1991 .

[4]  S. Channiwala,et al.  A correlation for calculating HHV from proximate analysis of solid fuels , 2005 .

[5]  Yinghua Lin,et al.  A new approach to fuzzy-neural system modeling , 1995, IEEE Trans. Fuzzy Syst..

[6]  P. Fernàndez,et al.  Correlations of properties of Spanish coals with their natural radionuclides contents , 1997 .

[7]  Sadriye Küçükbayrak,et al.  Estimation of calorific values of Turkish lignites , 1991 .

[8]  E. Clothiaux,et al.  Neural Networks and Their Applications , 1994 .

[9]  Jacek M. Zurada,et al.  Sensitivity analysis for minimization of input data dimension for feedforward neural network , 1994, Proceedings of IEEE International Symposium on Circuits and Systems - ISCAS '94.

[10]  Anuradda Ganesh,et al.  Heating value of biomass and biomass pyrolysis products , 1996 .

[11]  A. Demirbas,et al.  Calculation of higher heating values of biomass fuels , 1997 .

[12]  S. Channiwala,et al.  A UNIFIED CORRELATION FOR ESTIMATING HHV OF SOLID, LIQUID AND GASEOUS FUELS , 2002 .

[13]  Geoffrey E. Hinton,et al.  Learning representations by back-propagating errors , 1986, Nature.

[14]  Andrew H. Sung,et al.  Ranking importance of input parameters of neural networks , 1998 .

[15]  Tomás Cordero,et al.  Predicting heating values of lignocellulosics and carbonaceous materials from proximate analysis , 2001 .

[16]  D. Marquardt An Algorithm for Least-Squares Estimation of Nonlinear Parameters , 1963 .

[17]  Yinghua Lin,et al.  Building a Fuzzy System from Input-Output Data , 1994, J. Intell. Fuzzy Syst..

[18]  B. K Mazumdar,et al.  Theoretical oxygen requirement for coal combustion: relationship with its calorific value , 2000 .