| 1 |
Tribological Testing of Metallurgical Coke: Coefficient of Friction and Relation to Coal Properties
Lomas H, Roest R, Thorley T, Wells A, Wu H, Jiang ZY, Sakurovs R, Wotherspoon S, Pearson RA, Mahoney MR
Energy & Fuels, 32(12), 12021, 2018 |
| 2 |
Estimating coke fracture toughness using acoustic emissions and changes in coefficient of friction during scratch testing
Lomas H, Roest R, Wells A, Wu H, Jiang ZY, Sakurovs R, Stuart R, North L, Thorley T, Mahoney MR
Fuel, 226, 564, 2018 |
| 3 |
Tribological Approach to Investigate the Interface Properties in Metallurgical Coke
Roest R, Lomas H, Hockings K, Mahoney MR
Energy & Fuels, 31(2), 1422, 2017 |
| 4 |
Petrographic analysis and characterisation of a blast furnace coke and its wear mechanisms
Lomas H, Roest R, Gupta S, Pearson RA, Fetscher R, Jenkins DR, Pearce R, Kanniala R, Mahoney MR
Fuel, 200, 89, 2017 |
| 5 |
Fractographic approach to metallurgical coke failure analysis. Part 1: Cokes of single coal origin
Roest R, Lomas H, Hockings K, Mahoney MR
Fuel, 180, 785, 2016 |
| 6 |
Fractographic approach to metallurgical coke failure analysis. Part 2: Cokes from binary coal blends
Roest R, Lomas H, Mahoney MR
Fuel, 180, 794, 2016 |
| 7 |
Fractographic approach to metallurgical coke failure analysis. Part 3: Characterisation of fracture mechanisms in a blast furnace coke
Roest R, Lomas H, Gupta S, Kanniala R, Mahoney MR
Fuel, 180, 803, 2016 |
