31 |
Transnational energy flows, capacity building and Greece's quest for energy autarky, 1914-2010 Arapostathis S, Fotopoulos Y Energy Policy, 127, 39, 2019 |
32 |
Influence of pore structure on the gravity separation performance of fine lignite Zhu XN, Wang Q, Lyu XJ, Qiu J, Zhang Y, Li L Energy Sources Part A-recovery Utilization and Environmental Effects, 41(12), 1527, 2019 |
33 |
Unburnt carbon and ashing behavior for slow burning of lignite under oxygen-enriched combustion conditions Haykiri-Acma H, Cekic Y, Yaman S Energy Sources Part A-recovery Utilization and Environmental Effects, 41(11), 1326, 2019 |
34 |
Petrographic composition of the ex-situ lignite gasification residues Bielowicz B, Raszowski M, Maciejonczyk N Energy Sources Part A-recovery Utilization and Environmental Effects, 41(14), 1762, 2019 |
35 |
The reaction behavior of volatiles generated from lignite pyrolysis Yu WH, Han S, Lei ZP, Zhang K, Yan JC, Li ZK, Shui HF, Kang SG, Wang ZC, Ren SB, Pan CX Fuel, 244, 22, 2019 |
36 |
Combined effects of water content and primary air volume on performance of lignite-fired boiler Li ZX, Miao ZQ, Shen XS Fuel, 244, 580, 2019 |
37 |
An experimental investigation into mineral transformation, particle agglomeration and ash deposition during combustion of Zhundong lignite in a laboratory-scale circulating fluidized bed Liu Z, Li JB, Wang QH, Lu XF, Zhang YY, Zhu MM, Zhang ZZ, Zhang DK Fuel, 243, 458, 2019 |
38 |
Experimental and numerical simulation of drying of lignite in a microwave assisted fluidized bed Si CD, Wu JJ, Zhang YX, Liu GJ, Guo QJ Fuel, 242, 149, 2019 |
39 |
Theoretical study of the formation mechanism of sulfur-containing gases in the CO2 gasification of lignite Chen SY, Ding JX, Li GY, Wang JP, Tian Y, Liang YH Fuel, 242, 398, 2019 |
40 |
Preparation of high concentration coal water slurry of lignite based on surface modification using the second fluid and the second particle Chen X, Wang CY, Wang ZY, Zhao H, Liu HF Fuel, 242, 788, 2019 |