利用烟气废热的LiBr制冷液化粗CO2节能新工艺

doi:10.16085/j.issn.1000-6613.2017-1460

化工进展 ›› 2018, Vol. 37 ›› Issue (05): 1985-1991.DOI: 10.16085/j.issn.1000-6613.2017-1460

利用烟气废热的LiBr制冷液化粗CO₂节能新工艺

阮雪华, 辛月, 张宁, 焉晓明, 代岩, 贺高红

大连理工大学盘锦校区石油与化学工程学院, 精细化工国家重点实验室, 辽宁省石化行业高效节能分离技术工程实验室, 辽宁盘锦 124221

收稿日期:2017-07-17 修回日期:2017-11-04 出版日期:2018-05-05 发布日期:2018-05-05
通讯作者: 贺高红,教授,研究方向为化学工程。
作者简介:阮雪华(1982-),男,副教授。
基金资助:
国家自然科学基金（21606035，U1663223，51606025）及长江学者项目（T2012049）。

Low-grade heat utilization and CO₂ liquefaction process based on LiBr absorption refrigeration

RUAN Xuehua, XIN Yue, ZHANG Ning, YAN Xiaoming, DAI Yan, HE Gaohong

School of Petroleum and Chemical Engineering, State Key Laboratory of Fine Chemicals, Liaoning Province Engineering Laboratory for Petrochemical Separation Technologies, Dalian University of Technology at Panjin, Panjin 124221, Liaoning, China

Received:2017-07-17 Revised:2017-11-04 Online:2018-05-05 Published:2018-05-05

摘要/Abstract

摘要： 二氧化碳液化是衔接碳捕集与封存利用（CCSU）的重要环节。传统的低温液化工艺，操作温度低于-20℃，为避免水结冰冻堵，脱水预处理过程复杂、制冷能耗高，显著增加了CCSU的成本。对此，本研究提出利用烟气废热的LiBr制冷液化CO₂新工艺。以烟气携带的低温废热为热源驱动LiBr吸收式制冷机，制取4℃左右的冷媒；同时，提高粗二氧化碳的压力，使液化温度升高至7℃以上，与冷媒温度匹配。本工艺二氧化碳液化温度高于水的冰点以及水合物形成的临界温度，不再需要复杂的脱水预处理过程。Aspen Plus过程模拟分析表明，本项目提出的新工艺，全过程的压缩功耗（二氧化碳压缩+制冷压缩）为123.7 kW·h/t液态二氧化碳，比传统工艺节省约23.9%。以20万吨/年工业级二氧化碳生产装置为例，新工艺通过综合利用低温废热，每年可减少电耗7.70×10⁶ kW·h，节省运行成本约225万元，具有显著的节能效果和经济效益。

关键词: 碳捕集, CO₂液化, 低温废热, 吸收式制冷, 优化设计

Abstract: CO₂ liquefaction is a crucial procedure for carbon capture,utilization and storage (CCUS). The conventional cryogenic technique,running with the temperature lower than -20℃ and to prevent water from freezing,requires a complicated dehydration unit and consumes numerous mechanical power for refrigeration,and consequently the total running cost for CCUS is increased greatly. In this instance,a novel liquefaction technique based on LiBr absorption refrigeration system using flue gas waste heat was proposed in this research. The LiBr absorption refrigeration system driven by flue gas waste heat was used for generating the cold source at about 4℃. At the same time,the liquefaction temperature is increased to about 7℃ via upgrading the pressure of crude CO₂,so that it can be well matched with the refrigeration condition. Moreover,the increase in liquefaction temperature can avoid the holdback relating to water freezing and CO₂ hydration,and it is beneficial that the complicated dehydration unit is no longer demanded. Afterwards,process simulation and optimization was carried with ASPEN Plus. The simulation results revealed that the novel liquefaction technique can reduce the ecific power consumption to 123.7kW·h/tCO₂,and the energy saving degree is about 23.9% compared to the conventional technique. For a 200kt/a liquefaction plant,it is expected that this new-type technique can save electricity 7.70×10⁶ kW·h and running cost 2.25 million CNY per year. On the whole,the novel liquefaction technique behaves excellent in energy saving and economic benefit.

Key words: carbon capture, CO₂ liquefaction, low-grade heat, LiBr refrigeration, optimal design

中图分类号:

TQ116.3

阮雪华, 辛月, 张宁, 焉晓明, 代岩, 贺高红. 利用烟气废热的LiBr制冷液化粗CO₂节能新工艺[J]. 化工进展, 2018, 37(05): 1985-1991.

RUAN Xuehua, XIN Yue, ZHANG Ning, YAN Xiaoming, DAI Yan, HE Gaohong. Low-grade heat utilization and CO₂ liquefaction process based on LiBr absorption refrigeration[J]. Chemical Industry and Engineering Progress, 2018, 37(05): 1985-1991.

参考文献

[1] 阎海宇,付强,周言,等.真空变压吸附捕集烟道气中二氧化碳的模拟、实验及分析[J].化工学报,2016, 67(6):2371-2379. YAN Haiyu,FU Qiang,ZHOU Yan,et al.Simulation,experimentation and analyzation of vacuum pressure swing adsorption process for CO₂ capture from dry flue gas[J]. CIESC Journal,2016,67(6):2371-2379.
[2] Working group I contribution to the IPCC fifth assessment report climate change 2013:the physical science basis[M].Stockholm:Scientific-Technical Assessment,2013.
[3] 靖宇,韦力,王运东.吸附法捕集二氧化碳吸附剂的研究进展[J].化工进展,2011,30(s2):133-138. JING Yu,WEI Li,WANG Yundong. The advances of adsorbents in the field of CO₂ capture[J]. Chemical Industry and Engineering Progress,2011,30(s2):133-138.
[4] HASAN M M F,BALIBAN R C,ELIA J A,et al. Modeling,simulation,and optimization of postcombustion CO₂ capture for variable feed concentration and flow rate. 1. Chemical absorption and membrane processes[J]. Industrial & Engineering Chemistry Research,2012,51(48):15642-15664.
[5] ZHANG K,LIU Z,WANG Y,et al. Flash evaporation and thermal vapor compression aided energy saving CO₂ capture systems in coal-fired power plant[J]. Energy,2014,66:556-568.
[6] RAKSAJATI A,HO M T,WILEY D E. Reducing the cost of CO₂ capture from flue gases using aqueous chemical absorption[J]. Industrial & Engineering Chemistry Research,2013,52(47):16887-16901.
[7] SEO Y,HUH C,LEE S,et al. Comparison of CO₂ liquefaction pressures for ship-based carbon capture and storage(CCS)chain[J]. International Journal of Greenhouse Gas Control,2016,52:1-12.
[8] OI L E,ELDRUP N,ADHIKARI U,et al. Simulation and cost comparison of CO₂ liquefaction[J]. Energy Procedia,2016,86:500-510.
[9] FERRARI P F,GUEMBAROSKI A Z,MARCELINO N M A,et al. Experimental measurements and modelling of carbon dioxide hydrate phase equilibrium with and without ethanol[J]. Fluid Phase Equilibria,2016,413:176-183.
[10] NAGASHIMA H D,FUKUSHIMA N,OHMURA R. Phase equilibrium condition measurements in carbon dioxide clathrate hydrate forming system from 199.1 K to 247.1K[J]. Fluid Phase Equilibria,2016,413:53-56.
[11] YANG S O,YANG I M,KIM Y S,et al. Measurement and prediction of phase equilibria for water+CO₂ in hydrate forming conditions[J]. Fluid Phase Equilibria,2000,175(1/2):75-89.
[12] LAW R,HARVEY A,REAY D. A knowledge-based system for low-grade waste heat recovery in the process industries[J]. Applied Thermal Engineering,2016,94:590-599.
[13] ZHAO X,FU L,YUAN W,et al. the Potential and approach of flue gas waste heat utilization of natural gas for space heating[J]. Procedia Engineering,2016,146:494-503.
[14] BEAUSOLEIL-MORRISON I,JOHNSON G,KEMERY B P. The experimental characterization of a lithium bromide-water absorption chiller and the development of a calibrated model[J]. Solar Energy,2015,122:368-381.
[15] AVANESSIAN T,AMERI M. Energy,exergy,and economic analysis of single and double effect LiBr-H₂O absorption chillers[J]. Energy and Buildings,2014,73:26-36.
[16] SIDDIQUI M U,SAID S A M. A review of solar powered absorption systems[J]. Renewable and Sustainable Energy Reviews,2015,42:93-115.

利用烟气废热的LiBr制冷液化粗CO₂节能新工艺

Low-grade heat utilization and CO₂ liquefaction process based on LiBr absorption refrigeration

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	戴欢涛, 曹苓玉, 游新秀, 徐浩亮, 汪涛, 项玮, 张学杨. 木质素浸渍柚子皮生物炭吸附CO₂特性[J]. 化工进展, 2023, 42(S1): 356-363.
[2]	孙玉玉, 蔡鑫磊, 汤吉海, 黄晶晶, 黄益平, 刘杰. 反应精馏合成甲基丙烯酸甲酯工艺优化及节能[J]. 化工进展, 2023, 42(S1): 56-63.
[3]	李季桐, 王刚, 熊亚选, 徐钱. 不同工质单效吸收式制冷系统的能量和㶲分析[J]. 化工进展, 2023, 42(S1): 104-112.
[4]	王胜岩, 邓帅, 赵睿恺. 变电吸附二氧化碳捕集技术研究进展[J]. 化工进展, 2023, 42(S1): 233-245.
[5]	陈匡胤, 李蕊兰, 童杨, 沈建华. 质子交换膜燃料电池气体扩散层结构与设计研究进展[J]. 化工进展, 2023, 42(S1): 246-259.
[6]	刘炫麟, 王驿凯, 戴苏洲, 殷勇高. 热泵中氨基甲酸铵分解反应特性及反应器结构优化[J]. 化工进展, 2023, 42(9): 4522-4530.
[7]	王晨, 白浩良, 康雪. 大功率UV-LED散热与纳米TiO₂光催化酸性红26耦合系统性能[J]. 化工进展, 2023, 42(9): 4905-4916.
[8]	白亚迪, 邓帅, 赵睿恺, 赵力, 杨英霞. 变温吸附碳捕集机组标准化测试方案探讨及性能实验[J]. 化工进展, 2023, 42(7): 3834-3846.
[9]	薛凯, 王帅, 马金鹏, 胡晓阳, 种道彤, 王进仕, 严俊杰. 工业园区分布式综合能源系统的规划与调度[J]. 化工进展, 2023, 42(7): 3510-3519.
[10]	周龙大, 赵立新, 徐保蕊, 张爽, 刘琳. 电场-旋流耦合强化多相介质分离研究进展[J]. 化工进展, 2023, 42(7): 3443-3456.
[11]	李蓝宇, 黄新烨, 王笑楠, 邱彤. 化工科研范式智能化转型的思考与展望[J]. 化工进展, 2023, 42(7): 3325-3330.
[12]	顾诗亚, 董亚超, 刘琳琳, 张磊, 庄钰, 都健. 考虑中间节点的碳捕集管路系统设计与优化[J]. 化工进展, 2023, 42(6): 2799-2808.
[13]	李雪, 王艳君, 王玉超, 陶胜洋. 仿生表面用于雾水收集的最新研究进展[J]. 化工进展, 2023, 42(5): 2486-2503.
[14]	符乐, 杨阳, 徐文青, 耿錾卜, 朱廷钰, 郝润龙. 新型相变有机胺吸收捕集CO₂技术研究进展[J]. 化工进展, 2023, 42(4): 2068-2080.
[15]	尚玉, 肖满, 崔秋芳, 涂特, 晏水平. CO₂捕集工艺中热再生气余热的PVDF/BN-OH平板复合膜回收特性[J]. 化工进展, 2023, 42(3): 1618-1628.