%0 Journal Article %A Bhoopal, Rajpal S. %A Tripathi, Dharmendra %A Kole, Madhusree %A Dey, T.K. %A Singh, Ramvir %D 2012 %I Begell House %K effective thermal conductivity, artificial neural network, feedforward backpropagation, low-density polyethylene/Ni and NiO %N 1 %P 79-93 %R 10.1615/CompMechComputApplIntJ.v3.i1.60 %T EXPERIMENTAL AND NUMERICAL INVESTIGATIONS OF EFFECTIVE THERMAL CONDUCTIVITY OF LOW-DENSITY POLYETHYLENE FILLED WITH Ni AND NiO PARTICLES %U https://www.dl.begellhouse.com/journals/36ff4a142dec9609,14af4249098ca0fd,7adc07d954a53ef9.html %V 3 %X In the present communication, we report our experimental results of Ni and NiO particles as a filler material to enhance the effective thermal conductivity (ETC) of low-density polyethylene (LDPE) composites. ETC of the present composites with varying volume fraction of fillers is measured using a 30-mm-long dual needle sensor (SH-1), which consists of two parallel needles spaced 6 mm apart. An artificial neural network (ANN) model is developed to predict ETC of these materials based on feedforward backpropagation (FFBP) networks with the training functions, i.e., Gradient descent (GD), Gradient descent with adaptive learning rate (GDA), Gradient descent with momentum (GDM), and Gradient descent with momentum and adaptive learning rate (GDX). The best outcome for the use of artificial neural network appertained to feedforward backpropagation network with different training and threshold functions, i.e., Tangent sigmoid (TANSIG) and Pure-linear (PURELIN) functions. %8 2012-04-17