| 1 |
High-efficient production of biofuels using spent fluid catalytic cracking (FCC) catalysts and high acid value waste cooking oils
Nguyen LP, Tran TV, Phan TT, Ngo PT, Ha QLM, Luong TN, Tran TH, Phan TT
Renewable Energy, 168, 57, 2021 |
| 2 |
A Two-Zone Model for Fluid Catalytic Cracking Riser with Multiple Feed Injectors
He PF, Zhu C, Ho TC
AIChE Journal, 61(2), 610, 2015 |
| 3 |
Single and combined Fluidized Catalytic Cracking (FCC) catalyst deactivation by iron and calcium metal-organic contaminants
Mathieu Y, Corma A, Echard M, Bories M
Applied Catalysis A: General, 469, 451, 2014 |
| 4 |
Interactions of Flow and Reaction in Fluid Catalytic Cracking Risers
Zhu C, Jun Y, Patel R, Wang DW, Ho TC
AIChE Journal, 57(11), 3122, 2011 |
| 5 |
Dependence of chemical composition of calcined hydrotalcite-like compounds for SOx reduction
Sanchez-Cantu M, Perez-Diaz LM, Maubert AM, Valente JS
Catalysis Today, 150(3-4), 332, 2010 |
| 6 |
Gas-solids flow patterns in a novel dual-loop FCC riser
Wang XH, Gao SQ, Xu YH, Zhang JS
Powder Technology, 152(1-3), 90, 2005 |
| 7 |
Feed and process effects on the in situ reduction of sulfur in FCC gasoline
Valla JA, Lappas AA, Vasalos IA, Kuehler CW, Gudde NJ
Applied Catalysis A: General, 276(1-2), 75, 2004 |
| 8 |
Selective kinetic deactivation model for methanol synthesis from simultaneous reaction of CO2 and CO with H-2 on a commercial copper/zinc oxide catalyst
Rahimpour MR, Fathikalajahi J, Jahanmiri A
Canadian Journal of Chemical Engineering, 76(4), 753, 1998 |
| 9 |
Kinetic Modeling for Selective Deactivation in the Skeletal Isomerization of N-Butenes
Gayubo AG, Llorens FJ, Cepeda EA, Olazar M, Bilbao J
Chemical Engineering Science, 52(16), 2829, 1997 |
