1 |
Autoignition and combustion wave propagation in a spatial reactivity gradient environment constructed using the shock-converging method Yang JT, Hou ZH Combustion and Flame, 225, 228, 2021 |
2 |
Effect of Al content and particle size on the combustion of HMX-CMDB propellant Xiao LQ, Fan XZ, Li JZ, Qin Z, Fu XL, Pang WQ, Wang Y Combustion and Flame, 214, 80, 2020 |
3 |
Thermo-physical Properties and Combustion Wave Aspects of RDX Contain Low Aluminium Composite Propellant Kalal RK, Jangid SK, Shekhar H, Alegaonkar PS, Kumar A Combustion and Flame, 218, 12, 2020 |
4 |
Fuel-lean VOCs combustion in a porous burner stacked with alumina balls: A case for ethylene combustion Ling B, Ling ZQ, Kuang M, Zeng XY, Li XJ, Xu Y, Chen YX International Journal of Energy Research, 43(2), 970, 2019 |
5 |
Micro-heterogeneous regimes for gasless combustion of composite materials Pauls JM, Shuck CE, Rogachev AS, Mukasyan AS Combustion Science and Technology, 190(5), 893, 2018 |
6 |
Experimental and numerical investigations on flame stability of methane/air mixtures in mesoscale combustors filled with fibrous porous media Liu Y, Ning DG, Fan AW, Yao H Energy Conversion and Management, 123, 402, 2016 |
7 |
Investigation of structural and chemical transitions in copper oxide microstructures produced by combustion waves in a mixture of CuO-Cu2O-Cu and fuel Hwang H, Lee KY, Yeo T, Choi W Applied Surface Science, 359, 931, 2015 |
8 |
Subadiabatic combustion of premixed gas in ceramic foam burner Dai HM, Lin BQ, Zhai C, Hong YD, Li QZ International Journal of Heat and Mass Transfer, 91, 318, 2015 |
9 |
Experimental study on temperature variation in a porous inert media burner for premixed methane air combustion Wang HM, Wei CZ, Zhao PH, Ye TH Energy, 72, 195, 2014 |
10 |
Hazard effects of high-speed flow from methane-hydrogen premixed explosions Ma QJ, Zhang Q, Pang L Process Safety Progress, 33(1), 85, 2014 |