Extraction of helium from neon-helium mixture by the adsorption method

Lingran Yang; Ян Линжань; Maksim Yu. Kupriyanov; Куприянов Максим Юрьевич; Victoria D. Kononova; Кононова Виктория Дмитриевна

doi:10.17816/RF321518

Extraction of helium from neon-helium mixture by the adsorption method

作者: Yang L.¹, Kupriyanov M.Y.¹, Kononova V.D.¹
隶属关系:
1. Bauman Moscow State Technical University
期: 卷 111, 编号 4 (2022)
页面: 245-252
栏目: Reviews
URL: https://journal-vniispk.ru/0023-124X/article/view/132748
DOI: https://doi.org/10.17816/RF321518
ID: 132748

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Helium is an important natural resource and it has great importance for scientific research. It is currently extracted mainly from natural gas or in large air separation units. Helium and neon are usually separated from an separation column together. In order to obtain pure neon and helium they are further purified. This article discusses the main methods of extracting helium from the neon-helium mixture. Having compared rectification, freezing, membrane separation and sorption methods, the authors concluded that the adsorption method allows separation at relatively high temperature intervals and is more energy-efficient than the other methods considered. The paper presents existing examples of the application of the adsorption method for the purification of helium from neon, which have been implemented in China and in the CIS. An overview of adsorption separation on new adsorbents, both on metal-organic bases and on single-walled carbon nanotubes, is also presented. In the future, the authors will conduct experiments to fill in the data gaps on adsorption and desorption of neon-helium mixture on different adsorbents.

关键词

noble gas, adsorption, gas separation and purify

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作者简介

Lingran Yang

Bauman Moscow State Technical University

编辑信件的主要联系方式.
Email: yanl@student.bmstu.ru
ORCID iD: 0000-0001-7097-1898
俄罗斯联邦, Moscow

Maksim Kupriyanov

Bauman Moscow State Technical University

Email: kupriyanov.m@bmstu.ru
ORCID iD: 0000-0003-2180-1221
SPIN 代码: 2716-2525

Cand. (Tech.) Sci

俄罗斯联邦, Moscow

Victoria Kononova

Bauman Moscow State Technical University

Email: viktoriadmitrievna@live.ru
ORCID iD: 0009-0008-8609-6205
SPIN 代码: 5369-7308
俄罗斯联邦, Moscow

参考

Wang P, Zhang X, Zhao J. Study on the purification process of helium exhausted from the industry. Cryo. Supercond. 2013;41(8):83–88. (In Chinese). doi: 10.16711/j.1001-7100.2013.08.018
Bondarenko VL, Chigrin A.A., Pilipenko B.A., Yu.M. Simonenko. Industrial plants for separating mixtures at temperatures of 68...78 K by freezing. Inzhenernyy zhurnal: nauka i innovatsii. 2017;8(68). (In Russ). doi: 10.18698/2308-6033-2017-8-1648
Peng G, Gong Z, Zhang X. Present situation and prospect of helium purification. Cryo. Supercond. 2012;40(6):4–7. (In Chinese). doi: 10.16711/j.1001-7100.2012.06.019
Fastovskii VG (editor) Nizkie temperatury i redkie gazy. Trudy VEI. 1958;61. (In Russ).
Yuan JH, Bai H. Helium purification in large cryogenic system. Chinese Cryogenics. 2006;4-2:28–32. (In Chinese)
Arkharov IA, Navasardyan ES. Sravnenie sposobov razdeleniya neonogelievoj smesi s poziczij tekhniko-e`konomicheskogo analiza. Vestnik MGTU im. N.E. Baumana. Ser. Mashinostroenie. 2010. Special Issue. 61–69. (In Russ).
Wang Ch. Extraction of high purity helium from air separation plants. Cryogenic technology. 1980;3:11–14. (In Chinese).
Zhang Y. Refining of helium. Cryogenic technology. 1983;1:12–16. (In Chinese).
Simonenko Yu. Energosberegayushhie tekhnologii v ustanovkakh dlya polucheniya neona i geliya vy’sokoj chistoty. Refrigeration Technology. 2014;4(150): 4–12. (In Russ).
Liu Y, Liu J, Hu J. Noble gas separation by a MOF with one-dimensional channels. BMC Chem. Eng. 2019;1(3). doi: 10.1186/s42480-019-0003-y
Bolboli NZ, Abbas RA, Majid HS, et al. Predicting helium and neon adsorption and separation on carbon nanotubes by Monte Carlo simulation. Mol. Model. 2011;17(4):785–794. doi: 10.1007/s00894-010-0769-6
Sha H., Faller R. Molecular simulation of adsorption and separation of pure noble gases and noble gas mixtures on single wall carbon nanotubes. Computational Materials Science. 2016;114:160–166.
Bondarenko VL, Nikiforov YuV, Vorotyntsev VB. Comparative Analysis of Various Adsorbents for Low-Temperature Separation of a 20Ne–22Ne Isotopic Mixture. Chemical and Petroleum Engineering. 2016;51(11–12):743–748. (In Russ).

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2. Fig 1. Scheme of separation of Ne and He via condensation with liquid hydrogen 1 – Mixture gas receiver. 2 – Compressor; 3 – Heat exchanger; 4 – Nitrogen bath: 5 – Heat exchanger; 6 – Hydrogen bath; 7 – Desublimator; 8 – Helium cylinder.

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3. Fig. 2. Scheme of diffusion of a gaseous molecule on an adsorbent 1 – Internal surface diffusion of adsorbent; 2 – Surface adsorption; 3 – Diffusion of mobile phase into other pores; 4 – Diffusion of mobile phase on and around external surface [5].

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4. Fig. 4 Adsorption isotherms of a neon gel mixture with various component proportions [12].

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5. Fig. 3 Classical scheme of a complex for producing high-purity neon and helium Units V – rectification unit; VI – adsorption unit. TO1–TO4 – heat exchangers; AB – nitrogen bath; ИК – coil in the cube of the column, serving as an evaporator–condenser; ФС – phase separator; РК – rectification column; A - adsorber; РВД1, РВД2 – high-pressure receivers; R1, R2 – reducers; K1...K5 – diaphragm compressors [9].

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