Screening Supported Amine Sorbents in the Context of Post-combustion Carbon Capture by Vacuum Swing Adsorption

被引：13

作者：

Krishnamurthy, Shreenath ^{[1
]}

Boon, Juriaan ^{[2
]}

Grande, Carlos ^{[1
]}

Lind, Anna ^{[1
]}

Blom, Richard ^{[1
]}

de Boer, Robert ^{[2
]}

Willemsen, Hans ^{[3
]}

de Scheemaker, Gabriel ^{[3
]}

机构：

[1] SINTEF Ind, Forskningsveien 1, N-0373 Oslo, Norway

[2] TNO Sustainable Proc Technol, POB 15, NL-1755 ZG Petten, Netherlands

[3] 3D Cat BV, Kerkelaan 28, NL-1861 EB Bergen, Norway

来源：

CHEMIE INGENIEUR TECHNIK | 2021年 / 93卷 / 06期

关键词：

Energy vs productivity Pareto; Post‐ combustion carbon capture; Process simulation; Supported amine sorbents; Vacuum swing adsorption; METAL-ORGANIC FRAMEWORKS; CO2; CAPTURE; POWER-PLANTS; OPTIMIZATION; ADSORBENTS; SIMULATION; SEPARATION; CYCLE; TEMPERATURE; MEMBRANES;

D O I：

10.1002/cite.202000172

中图分类号：

TQ [化学工业];

学科分类号：

0817 ;

摘要：

The aim of this work was to evaluate the performance of three different supported amine sorbents in a 6-step vacuum swing adsorption (VSA) cycle through process simulation and optimization for a representative post-combustion CO2 capture system. Detailed process optimization revealed that all the adsorbents were able to achieve the desired purity-recovery targets. The best performing adsorbent in terms of productivity was Lewatit with a productivity of 0.48 mol m(-3) ads s(-1). All the adsorbents exhibited similar minimum specific energy value of around 1 MJ kg(-1) on an electric basis.

引用

页码：929 / 940

页数：12

共 56 条

[1] Emerging CO2 capture systems
Abanades, J. C.
Arias, B.
Lyngfelt, A.
Mattisson, T.
Wiley, D. E.
Li, H.
Ho, M. T.
Mangano, E.
Brandani, S.
[J]. INTERNATIONAL JOURNAL OF GREENHOUSE GAS CONTROL, 2015, 40 : 126 - 166
[2] New Kinetic Model That Describes the Reversible Adsorption and Desorption Behavior of CO2 in a Solid Amine Sorbent
Abdollahi-Govar, Anahita
Ebner, Armin D.
Ritter, James A.
[J]. ENERGY & FUELS, 2015, 29 (07) : 4492 - 4502
[3] A Superstructure-Based Optimal Synthesis of PSA Cycles for Post-Combustion CO2 Capture
Agarwal, Anshul
Biegler, Lorenz T.
Zitney, Stephen E.
[J]. AICHE JOURNAL, 2010, 56 (07) : 1813 - 1828
[4] [Anonymous], 2018, Global Warming of 1.5 C
[5] Nanocellulose-based membranes for CO2 capture
Ansaloni, Luca
Salas-Gay, Jesus
Ligi, Simone
Baschetti, Marco Giacinti
[J]. JOURNAL OF MEMBRANE SCIENCE, 2017, 522 : 216 - 225
[6] Adsorption of CO2-Containing Gas Mixtures over Amine-Bearing Pore-Expanded MCM-41 Silica: Application for Gas Purification
Belmabkhout, Youssef
Serna-Guerrero, Rodrigo
Sayari, Abdelhamid
[J]. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 2010, 49 (01) : 359 - 365
[7] Oxidative Degradation of Aminosilica Adsorbents Relevant to Postcombustion CO2 Capture
Bollini, Praveen
Choi, Sunho
Drese, Jeffrey H.
Jones, Christopher W.
[J]. ENERGY & FUELS, 2011, 25 (05) : 2416 - 2425
[8] Evaluating Regeneration Options of Solid Amine Sorbent for CO2 Removal
Bos, Martin J.
Kroeze, Vincent
Sutanto, Stevia
Brilman, Derk W. F.
[J]. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 2018, 57 (32) : 11141 - 11153
[9] Prediction of MOF Performance in Vacuum Swing Adsorption Systems for Postcombustion CO2 Capture Based on Integrated Molecular Simulations, Process Optimizations, and Machine Learning Models
Burns, Thomas D.
Pai, Kasturi Nagesh
Subraveti, Sai Gokul
Collins, Sean P.
Krykunov, Mykhaylo
Rajendran, Arvind
Woo, Tom K.
[J]. ENVIRONMENTAL SCIENCE & TECHNOLOGY, 2020, 54 (07) : 4536 - 4544
[10] Technology Innovation & Advancements for Shell Cansolv CO2 capture solvents
Campbell, Matthew
[J]. 12TH INTERNATIONAL CONFERENCE ON GREENHOUSE GAS CONTROL TECHNOLOGIES, GHGT-12, 2014, 63 : 801 - 807

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