To facilitate the use of carbon dioxide separation technology in industrial hydrogen production, we have developed a device that can increase the carbon dioxide gas recovery rate to 95% under existing production conditions. This device solves the issues associated with the complex operation of traditional industrial gas separation spherical tanks, including their complex operation, inefficient gas recovery rates ranging from 60%-70%, as well as the toxicity and difficulty in disposing of carbon dioxide treatment agents. The device utilizes the selective permeability of an iron mordenite-containing sieve plate for direct gas injection. The sieve plates are welded to a carbon dioxide gas tank for sample injection, forming an integrated structure. The sieve plate and the sample injection structure are then fixed and sealed using an ultra-high vacuum sealant.

Qiumin Zheng, Jiawen Xu, Hao Yang, Hao Chen, Zhe Liu. A Carbon Dioxide Gas Separation Device for Industrial Hydrogen Production Process. Academic Journal of Environment & Earth Science (2023) Vol. 5 Issue 6: 22-30. https://doi.org/10.25236/AJEE.2023.050605.

[1] Haoming Ma, Zhe Sun, Zhenqian Xue, Chi Zhang, Zhangxing Chen. A systemic review of hydrogen supply chain in energy transition. Frontiers in Energy, 2023(prepublish). 

[2] Bu Xuepeng. CO 2 capture technologies and application . Clean Coal Technology, 2014, 20(5):9 -13, 19. 

[3] Lin Wenlong, Zhang Yuzhu, Liu Chao, Liu Donghui, Xing Hongwei, Kang Yue. Advances In Sintering Flue Gas Pollutant Treatment Process . Environmental Engineering:1-14[2023-03-14]. 

[4] Hu Zheming. A Study of How Soaring Energy Prices Affect the Economy. 7th International Conference on Economy, Management, Law and Education (EMLE 2021), 2022. 

[5] Chen Jiayu, Hu Yuanchuang, Yu Yushi, Zhang Yuzi. Transformation of Traditional Energy Company under the Peak Carbon Dioxide Emissions and Carbon Neutrality Targets:Evidence from China Shenhua. 2022 2nd International Conference on Enterprise Management and Economic Development (ICEMED 2022), 2022. 

[6] Fan Hong, Yang Zhongquan, Xia Shiwei. Low Carbon Economic Operation of Hydrogen Enriched Compressed Natural Gas Integrated Energy System Considering Step Carbon Trading Mechanism. . Journal of Shanghai Jiaotong University: 1-21[2023-03-20]. 

[7] Liu Wei, Shen Yedan, Razzaq Asim. How renewable energy investment, environmental regulations, and financial development derive renewable energy transition: Evidence from G7 countries. Renewable Energy, 2023, 206. 

[8] Wei Wanru. Research on the sustainable development of energy and environment in Tianjin. IOP Conference Series Earth and Environmental Science, 2020, 512(1). 

[9] Saygin Deger, Blanco Herib, Boshell Francisco, Cordonnier Joseph, Rouwenhorst Kevin, Lathwal Priyank, Gielen Dolf. Ammonia Production from Clean Hydrogen and the Implications for Global Natural Gas Demand[ J]. Sustainability, 2023, 15(2). 

[10] Hou Meifang. Current Situation, Challenges and Countermeasures of China's Energy Transformation and Energy Security Under the Goal of CarbonNeutrality . Journal of Southwest Petroleum University (Science & Technology Edition), 2021, 5(6): 1–10. 

[11] Liu Y, Ren G, Shen H, et al. Technology of CO_2 capture and storage// Shanghai University of Electric Power. Proceedings of 2019 4th International Conference on Advances in Energy and Environment Research (ICAEER 2019), 2019:253-256. 

[12] Chen Haojia. Research progress of carbon dioxide capture technology. Cleaning World, 2022, 38(11):69-71+74. 

[13] Tsuchiya B., Kodera T., Miyaoka H., Ichikawa T., Kojima Y. Thermal desorption processes of H2 and CH4 from Li2ZrO3 and Li4SiO4 materials absorbed H2O and CO2 in air at room temperature. International Journal of Hydrogen Energy, 2023, 48(24). 

[14] Zhang Kai, Chen Zhangxing, Lan Haifan, Ma Haoming, Jiang Liangliang, Xue Zhenqian, Zhang Yuming, Cheng Shixuan. Current situation and prospect of carbon capture, utilization and storage technology. Special Oil & Gas Reservoirs:1-12[2023-03-18]. 

[15] Dong Hongbin, Zhang Tao, Zhang Jianhui, Wang Jinxia, Li Xueyan. Manufacture and installation of 3 000 m3 stainless steel clad plate spherical tank. Pressure Vessel Technology, 2023, 40(01):82-88. 

[16] Liu Xiaocheng, Guo Haiyan, Chen Yifeng, Ye Daoyuan, Wan Yiqing, Zhang Bojie, Bi Xiaofei, Zou Jilong, Zhao Weining. Analysis of Tube Bundle Corrosion in Heat Exchanger Outlet of Product Gas Compressor in Propane Dehydrogenation Unit. Zhejiang Chemical Industry, 2022, 53(07):30-36. 

[17] Guo Derui. Phased Array Ultrasonic Testing of Tube Socket Fillet Weld of Pressure Pipeline . NDT, 2023, 47(01):26-30+35. 

[18] Meng Ruijiong. Design of hydrogen separation tank in product separation section. Petroleum and chemical equipment, 2016, 19(08):37-39+43. 

[19] Yang Yi, Wang Jing, Li Huiping, Du Xianlu, Xie Jin. . Comparison of mechanical properties test items of GB150. 1 ~ 4-2011 and ASME Ⅷ-1 2015 Steel pressure vessel welding simulation specimens . Petroleum and chemical equipment, 2018, 21(06):61-63+65. 

[20] Zhou Qiang, Yang Jing, Ni Wenlong, Ma Zhongming. Fatigue analysis and discussion of welded joint of skirt and head based on ASME Ⅷ-2 Structural stress method. Petroleum and chemical equipment, 2022, 25(11):166-170+159. 

[21] Jiang Xiaowen, Ye Rixin, Zhao Shuanzhi. Understanding and Cognizance of 2014 Edition Column Standard. Process Equipment& Piping, 2015, 52(06):7-14. 

[22] Pumpyanskii D. A., Pyshmintsev I. Yu., Maltseva A. N., Uskov D. P. , Smirnov M. A, Arsenkin A. M. Structure and Properties of Steel for Producing Hydrogen Sulfide Resistant Oil and Gas High Strength Pipes. Metallurgist, 2023, 66:9-10. 

[23] Chen Xuedong, Fan Zhichao, Zheng Jinyang, Chen Yongdong, Cui Jun, Zhang Xiaohu, Ai Zhibin, Xu Shuangqing, Guo Xiaolu, Nie Defu, Chen Wei, Dong Jie, Zhou Yu, Zhu Jianxin, Zhou Bing. Pressure vessel green manufacturing technology. China Machine Press: National Publishing Fund Project · Green Manufacturing Series, 202206. 216. 

[24] Lu Xiaowei. Analysis of Welding Quality Control Method in Pressure Pipeline Construction. Jiangxi Building Materials, 2021(11):65-66. 

[25] Gao Xin, Wang Wei. Research on Anti-slip Performance and Design Method of Slip Critical Bolted Connection Considering Stress Concentration. Progress in Steel Building Structures: 1-11 [2023-03-21]

[26] Cui Dongliang, Cheng Liang, Xie Fei, Han Wenchao. Research on Type Test Status of Transportable Pressure Vessel. China Special Equipment Inspection & Research Institute, 2023, 39(02): 21-25+39. 

[27] Jin Feng, Zhu Lin, Yang Fang. The "acid hydrolysis" synthesis path eliminates the pain point of carbon capture in zeolite adsorbent. Science and Technology Daily, 2021-07-22(005)