| 1 |
Enhanced exergy cost optimization of operating conditions in FCCU main fractionator
Zhong CL, Zheng Y, Xu SH, Li SY
Chinese Journal of Chemical Engineering, 26(8), 1750, 2018 |
| 2 |
Mechanistic understanding of size-based fiber separation in coiled tubes
Redlinger-Pohn JD, Jagiello LA, Bauer W, Radl S
International Journal of Multiphase Flow, 83, 239, 2016 |
| 3 |
A Novel Strategy for Simulating the Main Fractionator of Delayed Cokers by Separating the De-superheating Process
Lei Y, Zhang BJ, Hou XQ, Chen QL
Chinese Journal of Chemical Engineering, 21(3), 285, 2013 |
| 4 |
Predictive tools for the estimation of downcomer velocity and vapor capacity factor in fractionators
Baliadori A, Vuthaluru HB
Applied Energy, 87(8), 2615, 2010 |
| 5 |
Simple equations to correlate theoretical stages and operating reflux in fractionators
Bahadori A, Vuthaluru HB
Energy, 35(3), 1439, 2010 |
| 6 |
Combining microscale solution-phase isoelectric focusing with multiplexed Proteomics((R)) dye staining to analyze protein post-translational modifications
Schulenberg B, Patton WF
Electrophoresis, 25(15), 2539, 2004 |
| 7 |
Product quality estimation and operating condition monitoring for industrial ethylene fractionator
Kamohara H, Takinami A, Takeda M, Kano M, Hasebe S, Hashimoto I
Journal of Chemical Engineering of Japan, 37(3), 422, 2004 |
| 8 |
Anionic and cationic surfactant recovery from water using a multistage foam fractionator
Boonyasuwat S, Chavadej S, Malakul P, Scamehorn JF
Chemical Engineering Journal, 93(3), 241, 2003 |
| 9 |
System limit - The ultimate capacity of fractionators
Stupin WJ, Kister HZ
Chemical Engineering Research & Design, 81(1), 136, 2003 |
