| 1 |
A comparison of random forest and support vector machine approaches to predict coal spontaneous combustion in gob
Lei CK, Deng J, Cao K, Xiao Y, Ma L, Wang WF, Ma T, Shu CM
Fuel, 239, 297, 2019 |
| 2 |
Effect of co-flow oxygen concentration on the MILD combustion of pulverised coal
Saha M, Dally BB, Chinnici A, Medwell PR
Fuel Processing Technology, 193, 7, 2019 |
| 3 |
Evaluation of the spontaneous combustion characteristics of coal of different metamorphic degrees based on a temperature-programmed oil bath experimental system
Zhang YN, Chen L, Zhao JY, Deng J, Yang H
Journal of Loss Prevention in The Process Industries, 60, 17, 2019 |
| 4 |
A method for evaluating the spontaneous combustion of coal by monitoring various gases
Guo J, Wen H, Zheng XZ, Liu Y, Cheng XJ
Process Safety and Environmental Protection, 126, 223, 2019 |
| 5 |
A random forest approach for predicting coal spontaneous combustion
Lei CK, Deng J, Cao K, Ma L, Xiao Y, Ren LF
Fuel, 223, 63, 2018 |
| 6 |
Experimental studies of spontaneous combustion and anaerobic cooling of coal
Deng J, Xiao Y, Li QW, Lu JH, Wen H
Fuel, 157, 261, 2015 |
| 7 |
Time/temperature combustion profiles of various wood-based biofuels
Smit HC, Meincken M
Biomass & Bioenergy, 39, 317, 2012 |
| 8 |
A laboratory study on the temperature dependence of the radon concentration in coal
Xue S, Wang J, Xie J, Wu J
International Journal of Coal Geology, 83(1), 82, 2010 |
| 9 |
Temperature and time effect on the concentrations of free radicals in coal: Evidence from laboratory pyrolysis experiments
Qiu NS, Li HL, Jin ZJ, Zhu YK
International Journal of Coal Geology, 69(3), 220, 2007 |
| 10 |
Effect of cleaning process on combustion characteristics of lignite
Ozbas KE, Hicyilmaz C, Kok MV, Bilgen S
Fuel Processing Technology, 64(1-3), 211, 2000 |
