| 1 |
Effect of co-feeding HDPE on the product distribution in the hydrocracking of VGO
Vela FJ, Palos R, Bilbao J, Arandes JM, Gutierrez A
Catalysis Today, 353, 197, 2020 |
| 2 |
A carbon-number lump based model for simulation of industrial hydrotreaters: Vacuum gas oil (VGO)
Srinivas BK, Pant KK, Gupta SK, Saraf DN, Choudhury IR, Sau M
Chemical Engineering Journal, 358, 504, 2019 |
| 3 |
Effect of vacuum gas oil hydrotreating reactor on multiple reactors and hydrogen network
Lu DH, Wang YJ, Huang LJ, Zhang D, Liu GL, Li W, Wang P
Chinese Journal of Chemical Engineering, 27(10), 2498, 2019 |
| 4 |
Kinetics of the synergy effects in heavy oil upgrading using novel Ni-p-tert-butylcalix[4]arene as a dispersed catalyst with a supported catalyst
Al-Attas TA, Zahir MH, Ali SA, Al-Bogami SA, Malaibari Z, Razzak SA, Hossain MM
Fuel Processing Technology, 185, 158, 2019 |
| 5 |
Nine-lumped kinetic model for VGO catalytic cracking; using catalyst deactivation
Ebrahimi AA, Mousavi H, Bayesteh H, Towfighi J
Fuel, 231, 118, 2018 |
| 6 |
8-Lump kinetic model for fluid catalytic cracking with olefin detailed distribution study
Sani AG, Ebrahim HA, Azarhoosh MJ
Fuel, 225, 322, 2018 |
| 7 |
Hydrocracking catalysts based on hierarchical zeolites: A recent progress
Galadima A, Muraza O
Journal of Industrial and Engineering Chemistry, 61, 265, 2018 |
| 8 |
Hydrotreatment modeling for a variety of VGO feedstocks: A continuous lumping approach
Becker PJ, Celse B, Guillaume D, Dulot H, Costa V
Fuel, 139, 133, 2015 |
| 9 |
Composition of stacked bed for VGO hydrocracking with maximum diesel yield
Dik PP, Klimov OV, Koryakina GI, Leonova KA, Pereyma VY, Budukva SV, Gerasimov EY, Noskov AS
Catalysis Today, 220, 124, 2014 |
| 10 |
Core-shell structured zeolite-zeolite composites comprising Y zeolite cores and nano-beta zeolite shells: Synthesis and application in hydrocracking of VGO oil
Zhao QQ, Qin B, Zheng JJ, Du YZ, Sun WF, Ling FX, Zhang XW, Li RF
Chemical Engineering Journal, 257, 262, 2014 |
