| 1 |
Simulation and heat exchanger network designs for a novel single-column cryogenic air separation process
Zhang QC, Wu ZQ, Cao ZK, Jiang QY, Zhou H
Chinese Journal of Chemical Engineering, 27(7), 1498, 2019 |
| 2 |
Exergy analysis and performance evaluation of a newly developed integrated energy system for quenchable generation
Ishaq H, Dincer I
Energy, 179, 1191, 2019 |
| 3 |
Productivity and energy efficiency assessment of existing industrial gases facilities via data envelopment analysis and the Malmquist index
Fernandez D, Pozo C, Folgado R, Jimenez L, Guillen-Goalbez G
Applied Energy, 212, 1563, 2018 |
| 4 |
Conventional and advanced exergoeconomic assessments of a new air separation unit integrated with a carbon dioxide electrical power cycle and a liquefied natural gas regasification unit
Mehrpooya M, Ansarinasab H, Sharifzadeh MMM, Rosen MA
Energy Conversion and Management, 163, 151, 2018 |
| 5 |
순산소 연소를 위한 초저온 공기분리장치의 최적공정 설계 연구
최형철, 문흥만, 조정호
Korean Chemical Engineering Research, 56(5), 647, 2018 |
| 6 |
Multiperiod model for the optimal production planning in the industrial gases sector
Fernandez D, Pozo C, Folgado R, Guillen-Gosalbez G, Jimenez L
Applied Energy, 206, 667, 2017 |
| 7 |
Optimal design and integration of a cryogenic Air Separation Unit (ASU) with Liquefied Natural Gas (LNG) as heat sink, thermodynamic and economic analyses
Ebrahimi A, Ziabasharhagh M
Energy, 126, 868, 2017 |
| 8 |
Dynamic Modeling and Collocation-Based Model Reduction of Cryogenic Air Separation Units
Cao YA, Swartz CLE, Flores-Cerrillo J, Ma JR
AIChE Journal, 62(5), 1602, 2016 |
| 9 |
A cryogenic air separation process based on self-heat recuperation for oxy-combustion plants
Fu Q, Kansha Y, Song CF, Liu YP, Ishizuka M, Tsutsumi A
Applied Energy, 162, 1114, 2016 |
| 10 |
An elevated-pressure cryogenic air separation unit based on self-heat recuperation technology for integrated gasification combined cycle systems
Fu Q, Kansha Y, Song CF, Liu YP, Ishizuka M, Tsutsumi A
Energy, 103, 440, 2016 |
