Abstract
The review is devoted to non-woven sorption-filtering materials (NSFM) widely used equipment for gas cleaning from toxic gaseous and vaporous substances. The use of ion-exchange fibrous materials (IFM) as NSFM and the peculiarities of their preparation and structure have been analyzed. A lot of attention is paid to the mechanisms of chemisorption processes using IFM and to the role of water in their successful implementation. Individual options and some regularities of fibrous anionites, cationites, and polyampholytes interaction due to exchange reactions, neutralization, reduction-oxidation, complexation and precipitation with gaseous and vaporous substances are considered on specific examples.
References
Kurylenko O.D., Ennan A.A., Nekrjach Je.F., Blinder V.I. Ionoobminni voloknysti materialy na osnovi celjulozy v gazoochystci. Visnyk AN URSR. 1975. 39(7): 37–45. (In Ukrainian).
Zverev M.P. Chemisorption fibers. Moscow, Khimia, 1981. 191 p. (In Russian)
Ennan A.A. Fiziko-himicheskie osnovy
ulavlivanija, nejtralizacii i utilizacii svarochnyh ajerozolej. Book of 1st International Science-Practical Conference “Protection of Environment, Health, and Safety in Welding”, Odessa, Astroprint, 2002. P. 10–37. (In Russian).
Ennan A.A., Asaulova T.A. Razrabotka, proizvodstvo i vnedrenie ionoobmennyh voloknistyh materialov na osnove cellljulozy i polikaproamida. Book of 1st International Science-Practical Conference “Protection of Environment, Health, and Safety in Welding”, Odessa, Astroprint, 2002. P. 286–295. (In Russian).
Zverev M.P., Zakharov S.V. Hemosorbcionnye volokna – materialy dlja zashhity sredy obitanija ot vrednyh vybrosov. Book of 1st International Science-Practical Conference “Protection of Environment, Health, and Safety in Welding”, Odessa, Astroprint, 2002. P. 296–304. (In Russian).
Economy J., Dominguez L., Mangun C.L. Polymeric Ion-Exchange Fibers. Ind. Eng. Chem. Res. 2002; 41: 6436–6442. doi: 10.1021/ie0204641
Zverev M.P. Fibre Chemisorbents – Material for Environmental Protection. A Review. Fibre Chemistry. 2002; 34: 456–465. doi: 10.1023/A:1022972511231
Baidenko V.I., Ennan A.A., Zakharenko Yu.S. Razrabotka i primenenie voloknistyh hemosorbentov v praktike individual’noj protivogazovoj zashhity. Vіsn. Odes. nac. unіv., Hіm. 2003; 8(7): 24–39. (In Russian).
Ennan A.A., Baidenko V.I. Sorbcionno fil’trujushhie voloknistye ionity dlja individual’noj protivogazovoj zashhity (Obzor). Ekotehnologii i resursosberezhenie. 2004; (5): 43–54. (In Russian).
Druzhinina T.V., Kobrakov K.I., Abaldueva E.V., Zhigalov I.B. Chemisorption Fibers for Sorption of Metal ions and Acid Gases. Bezopasnost Zhiznedeyatel’nosti. 2004; (11): 31–34. (In Russian).
Kim Y.-S., Hwang T.-S., Lee H.-K., Park J.-W., Kim S.-M. Removal of Toxic Gases on Strong/and Weak-Base Anion Exchange Fibers. J. Ind. Eng. Chem. 2004; 10(4): 504–510.
Ennan A.A., Asaulova T.A., Baidenko V.I. The Production of Nonwoven Needle-Punched Sorbtion and Filtering Materials from Ion Exchange Fibrous Wastes. Jenergotehnologii i resursosberezhenie. 2010; (2): 42–46. (In Russian).
Soldatov V.S., Kosandrovich E.H. Ion Exchangers for Air Purification. Ion Exchange and Solvent Extraction. A Series of Advances. CRC Press. 2011; 20: 45–115. doi: 10.1201/b10813-3
Kosandrovich E.G., Soldatov V.S. Fibrous Ion Exchangers. Ion Exchange Technology I. Theory and Materials. Springer. 2012; 22: 299–371. doi: 10.1007/978-94-007-1700-8_9
Rustamov M.K., Gafurova D.A., Karimov M.M., Rustamova N.M., Bekchonov D.Zh., Mukhamediev M.G. Application of ion-exchange materials with high specific surface area for solving environmental problems. Russ. J. Gen. Chem. 2014; 84(13): 2545–2551. doi: 10.1134/s1070363214130106
Polikarpov A.P., Shunkevich A.A., Grachek V.I., Medyak G.V. FIBAN fibrous ion exchangers: Synthesis, modification, application. Russ. J. Gen. Chem. 2017; 87(6): 1418–1427. doi: 10.1134/S1070363217060457
SenGupta A.K. Ion Exchange in Environmental Processes: Fundamentals, Applications and Sustainable Technology. Wiley. 2017. 550 p. doi: 10.1002/9781119421252
Genis A.V., Kuznetsov A.V. Perspective Developments In The Production Of Fibrous Polymeric Sorbents. Rossijskij Himicheskij Zhurnal. 2019; 63(1): 27–45. doi: 10.6060/rcj.2019631.2 (In Russian).
Perepelkin K.E. Chemical Fibers with Specific Properties for Industrial Application and Personnel Protection. J. Ind. Textiles. 2001; 31(2): 87–102. doi: 10.1106/xu8h-c5j5-8blt-2eao
Chen W. Synthesis of Polypropylene Strong Acid Cationic Exchange Fiber. Adv. Mater. Res., 2015; 1088: 434–438. doi: 10.4028/www.scientific.net/amr.1088.434
Henmi M., Yoshioka T. Studies of ion-exchange fiber “IONEX” for precoating material. Desalination. 1993; 91(3): 319–332. doi: 10.1016/0011-9164(93)80068-x
Matsumoto H., Wakamatsu Y., Minagawa M., Tanioka A. Preparation of ion-exchange fiber fabrics by electrospray deposition. J. Colloid Interface Sci. 2006; 293(1): 143–150. doi: 10.1016/j.jcis.2005.06.022
Lee C.H., Kang S.K., Lim J.A., Kwark Y.-J., Lim H.S., Kim J., Cho J.H. Counterions-exchangeable, multifunctional polyelectrolyte fabrics. J. Mater. Chem. 2012; 22(29): 14656. doi: 10.1039/c2jm31718d
Park H.-J., Na C.-K. Preparation of anion exchanger by amination of acrylic acid grafted polypropylene nonwoven fiber and its ion-exchange property. J. Colloid Interface Sci. 2006; 301(1): 46–54. doi: 10.1016/j.jcis.2006.05.003
Zargaran M., Shoushtari A.M., Abdouss M. Diametric swelling and hydrophilic characteristics of fibrous acrylic ion exchanger. J. Appl. Polym. Sci. 2008; 110(6): 3843–3847. doi: 10.1002/app.28497
Gafurova D.A. Physico-chemical characteristic of formation, properties of anion exchangers and polycomplexones on the basis of acrylic fiber. Abstract of Doctor’s degree dissertation, 02.00.04, 02.00.06. Tashkent, 2014, 70 p.
Toropіn V.M., Kremenchutskiy G.M., Burmіstrov K.S., Shunkevich O.A., Polіkarpov O.P. Synthesis and antibacterial properties of 4-aminophenylsulfonamide immobilized on the polymeric carrier. Pharm. Rev. 2017; (1): 5–10. (In Ukrainian).
Kosandrovich E.G., Shachenkova L.N., Nesteronok P.V., Yakubel V.N., Soldatov V.S. Synthesis and Properties of the New Fibrous Anion Exchanger with Aminoethylpiperazine Functional Groups. Proc. National Acad. Sci. Belarus. Chem. Ser. 2016; 52(4): 16–23. (In Russian).
Kosandrovich E.G. Physical chemical processes during the sorption of gaseous acids and bases by ion exchangers. Abstract of Doctor’s degree dissertation, 02.00.04. Minsk, 2020, 43 p. (In Russian).
IMT – Ion-exchange Materials and Technologies. Available at http://imt-filter.com
Kopylova V.D., Bychkovskaya G.I., Zverev O.M. Statics and kinetics of interaction of acids and alkalis with VION AN-1 fibrous pyridine-containing chemisorbent. Russ. J. Phys. Chem. A. 2008; 82(3): 410–414. doi: 10.1134/S0036024408030151
Medyak G.V., Shunkevich A.A., Polikarpov A.P., Pansevich V.V., Akulich Z.I. Evaluation of factors affecting the sorption of sulfur dioxide by FIBAN fibrous anion exchangers. Proc. National Acad. Sci. Belarus. Chem. Ser. 2021; 57(1): 101–108. doi: 10.29235/1561-8331-2021-57-1-101-108 (In Russian).
Ennan A.A., Abramova N.N., Khoma R.E. Katalog vigotovljaєmih zasobіv іndivіdual’nogo zahistu. Physical-Chemical Institute for Environment and Human Protection of MES of Ukraine and NAS of Ukraine. Ed. by A.A. Ennan. Odesa, Astroprint, 2017. 52 p. (in Ukrainian).
Air filters and dust eliminators. Gas Phase filtration. Available at http://airff.cz
Ennan A.A., Gelmboldt V.O. Silicon tetrafluoride in reactions with organic bases. Odessa, Ecology, 2005. 160 p. (In Russian)
Ashirov A. Ion exchange purification of wastewater, solution and gases. Leningrad, Khimiya, 1983. 295 p. (In Russian).
Hwang T.-S., Kim Y.-S., Park J.-W., Lee H.-K. Adsorption properties of SO2 on PAN-based fibrous ion exchanger and its potential for air purification. J. Ind. Eng. Chem. 2004; 10(1): 139–145.
Wasag H., Soldatov V., Kosandrovich E., Sobczuk H. Odour Control By Fibrous Ion Exchangers. Chem. Eng. Trans. 2008; 35(3): 293–304.
Arakeljan I.A. Himzashhitnyj material na osnove neuglerodnyh sorbentov dlja fil’trujushhej zashhitnoj odezhdy. Abstract of Ph.D dissertation, 05.19.01. Kazan, 2009, 20 p. (In Russian).
Chikin G.A., Myagkoy O.N. Ion Exchange Methods for Purification of Substances, Voronezh, Voronezh State University, 1984. 372 p. (In Russian).
Garipov I., Khaydarov R., Gapurova O., Khaydarov R., Evgrafova S. The Application of Fiber Ion Exchange Sorbents for Wastewater Treatment and Purification of Gas Mixtures. J. Energ. Env. Chem. Eng. 2020; 5(1): 10–13. doi: 10.11648/j.jeece.20200501.12
Marinina O.N., Burkhanova R.A., Marinin N.A. Investigation into the Regularities of Hydrogen Fluoride Collection by the Developed Fibrous Ion-Exchange Material Under Dynamic and Static Conditions. IOP Conference Series: Materials Science and Engineering. 2021; 1079(5): 052081. doi: 10.1088/1757-899x/1079/5/
Japar S.M., Brachaczek W.W. Artifact sulfate formation from SO2 on nylon filters. Atmos. Environ. 1984; 18(11): P. 2479–2482. doi: 10.1016/0004-6981(84)90018-0
Khoma R.E. Acid-base interaction and sulfooxidation at chemosorption of sulfur dioxide by alkylamines aqueous solutions. Abstract of Doctor’s degree dissertation, 02.00.01. Kyiv, 2019, 50 p. (In Ukrainian).
Kosandrovich E.G., Doroshkevich O.N. Fibrous amino carboxylic sorbent for air purification from sulfur dioxide. Proc. National Acad. Sci. Belarus. Chem. Ser. 2014; 50(1): 91–95. (In Russian).
Ennan A.A.-A., Khoma R.E., Impregnated Fibrous Chemosorbents of Acid Gases for Respiratory Purpose. Vіsn. Odes. nac. unіv., Hіm. 2017; 22(4): 53–68. doi: 10.18524/2304-0947.2017.4(64).115924 (In Ukrainian).
Ennan A.A.-A., Khoma R.E., Dlubovskiy R.M., Zakharenko Y.S., Abramova N.N., Mikhaylova T.V., Barbalat D.O. Effect of Modifying Additives on Chemosorption of Sulfur (IV) Oxide by Fibrous Material Impregnated with Polyethylenepolyamine. Vіsn. Odes. nac. unіv., Hіm. 2020; 25(4): 56–73. doi: 10.18524/2304-0947.2020.4(76).216927 (In Russian).
Kiselev A.V. Intermolecular Interactions in Adsorption and Chromatography. Moscow, Vysshaya Shkola, 1986. 360 p. (In Russian).
Khoma R.E., Ennan A.A., Baumer V.N., Puzan A.N., Koksharova T.V., Mazepa A.V. Onium salts of sulfur-containing oxyanions resulting from reaction of sulfur(IV) oxide with aqueous solutions of 1,2-diamines and morpholine. Russ. J. Inorg. Chem. 2017; 62(6): 751–760. doi: 10.1134/S0036023617060109
Kosandrovich E.G., Pushkarchuk A.L., Bezyazychnaya T.V., Soldatov V.S. Peculiarities of sulfur dioxide sorption from air by weak base anion exchangers. Proc. National Acad. Sci. Belarus. Chem. Ser. 2020; 56(3): 263–270. doi: 10.29235/1561-8331-2020-56-3-263-270 (In Russian).
Christensen J.J., Izatt R.M., Wrathall D.P., Hansen L.D. Thermodynamics of proton ionization in dilute aqueous solution. Part XI. pK, ΔH°, and ΔS° values for proton ionization from protonated amines at 25°. J. Chem. Soc. 1969; A0(0): 1212−1223. doi: 10.1039/j19690001212
Nielsen E., Ladefoged O., Soborg I. Evaluation of health hazards by exposure to N,N-Dimethyl-1,3-propanediamine and proposal of a health-based quality criterion for ambient air. Copenhagen. 2013. Available at https://www2.mst.dk/Udgiv/publications/2013/08/978-87-93026-33-9.pdf
Abdulkhakova Z.Z., Sochilin V.E., Zverev M.P. Capture of nitrogen oxides with a fibre chemisorbent. Fibre Chem. 2000; 32(5): 374–376. doi: 10.1007/bf02360646
Asaulova T.A., Ennan A.A., Zhbankov R.G., Alimov I.F. Study of products of interaction of hydrogen fluoride with a polycaproamide-based fibrous sorbent. Zhurnal Prikladnoi Khimii. 1989; 62(8): 1896–1899. (In Russian).
Asaulova T.A., Baidenko V.I., Ennan A.A. Hydrogen fluoride absorption under static conditions by a polycaproamide-based fibrous anion-exchange resin. Zhurnal Prikladnoi Khimii. 1991; 64(6): 1359–1361. (In Russian).
Korshunova T.A., Kosandrovich E.G., Soldatov V.S. Hydrogen Chloride Absorption FROM THE Air with the Fibrous Ion Exchangers FIBAN. Russ. J. Appl. Chem. 2010; 83(7): 1159–1169. doi: 10.1134/s1070427210070013
Elinson I.S., Tsygankov V.I., Martinovich V.I., Soldatov V.S. Air purification from hydrogen fluoride by FIBAN ion-exchange fibers. Book of 1st International Science-Practical Conference “Protection of Environment, Health, and Safety in Welding”, Odessa, Astroprint, 2002. P. 377–383. (In Russian).
Song R., Zhang A. Study on dynamic adsorption of HF gas by ion-exchange fiber. J. Hyg. Res. 2002; 31(5): 382–384.
Ennan A.A., Baidenko V.I. Mechanism of silicon tetrafluoride sorption by anionites. I. Role of water. Issues of Chemistry and Chemical Technology. 2005; (6): 64–68. (In Russian).
Chebotarev A.N., Cachan S.V. Potentiometric titration of HF dilute aqueous solutions by nitrogen-containing organic bases. I. Monoamines. Zhurnal Fizicheskoi Khimii.1991; 65(3): 682–687. (In Russian).
Baidenko V.I., Ennan A.A. On mechanism of silicon tetrafluoride sorption by anionites. 2. Composition of the interaction products. Issues of Chemistry and Chemical Technology. 2005; (11): 50–53. (In Russian).
Chebotaryov A.N., Rakhlickaya E.М., Khoma R.E., Kachan S.V. Potentiometric Investigation of the Acid-Basic Equilibria IN System “Hexafluorosilicic Acid – Water – Nitrogen-Containing Organic Base”. Vіsn. Odes. nac. unіv., Hіm. 2005; 10(8): 121–130. (In Russian).
Polyakov V.A., Barash A.N., Zverev M.P., Viglin V.E., Belenkov E.M., Alikberova L.Y., Kostina T.F., Sycheva N.A. Method of cleaning air from cyanic components. Patent SU, no 1338876, 23.09.1987. (In Russian).
Barash A.N., Zverev M.P. Malinovskii E.K., Kalyanova N.F. Sorption of hydrogen sulfide by VION anion-exchange fibres. Fibre Chem. 1989; 20(6): 372–374. doi: 10.1007/BF00547139
Li Q., Lancaster J.R. Chemical foundations of hydrogen sulfide biology. Nitric Oxide, 2013; 35: 21–34. doi:10.1016/j.niox.2013.07.001
Voronova L.V., Gorlenko L.E., Emel’janova G.I., Zverev M.P., Lunin V.V. Method of gas scrubbing from hydrogen sulfide. Patent RU, no 2048865, 27.11.1995. (In Russian).
Egiazarov Yu.G., Potapova L.L., Radkevich V.Z., Soldatov V.S., Shunkevich A.A., Cherches B.Kh. New catalytic systems based on fibrous ion exchangers. Chemistry for Sustainable Development. 2001; 9(3): 417–431. (In Russian).
Soldatov V.S., Kashinskii A.V., Martinovich V.I. Catalytic removal of hydrogen sulfide from air using FIBAN ion-exchange fibers. Theor. Found. Chem. Eng. 2010; 44(4): 623–627. doi: 10.1134/s0040579510040482
Wasag H. Removal of Hydrogen Sulphide from Air by Means of Fibrous Ion Exchangers. Int. J. Environ. Ecol. Eng. 2012; 6(4): 219–223. doi: 10.5281/zenodo.1070999
Grachek V.I., Shunkevich A.A., Isakovich O.I., Marstynkevich R.V., Pansevich V.V. Synthesis and properties of new N,S-containing fibrous ion exchangers. Russ. J. Appl. Chem. 2013; 86(11): 1707–1712. doi: 10.1134/s1070427213110128
Miller M.B., Dunham-Cheatham S.M., Gustin M.S., Edwards G.C. Evaluation of cation exchange membrane performance under exposure to high Hg0 and HgBr2 concentrations. Atmos. Meas. Tech. 2019; 12(2): 1207–1217. doi: 10.5194/amt-12-1207-2019
Wasąg H., Pawłowski L , Soldatov V., Kosandrovich E. Removal of ammonia from air by fibrous ion exchangers. Chem. Eng. Trans. 2009; 35(3): 387–394.
Kosandrovich E.G. Sorption of ammonia and sulfur dioxide by fibrous ion exchangers. Abstract of Ph.D dissertation, 02.00.04. Minsk, 2005, 20 p. (In Russian).
Ennan A.A.-A., Khoma R.E., Dlubovskiу R.M., Gridyaev V.V., Mikhaylova T.V. Fibrous Chemisorbent of Sulfur Dioxide Based on the Complex Compounds of Cooper (II) Sulphate and Polyethylenepolyamine. Vіsn. Odes. nac. unіv., Hіm. 2018; 23(2): 95–105. doi: 10.18524/2304-0947.2018.2(66).132053 (In Russian).
Ennan A.A.-A., Khoma R.E., Dlubovskiу R.M., Abramova N.N., Mikhaylova T.V. Fibrous Chemisorbent-Amfolite Based on the Complex Compounds of Nickel (II) Chloride and Ethylenediamine.. Vіsn. Odes. nac. unіv., Hіm. 2019; 24(3): 90–102. doi: 10.18524/2304-0947.2019.3(71).177739 (In Russian).
Kosandrovich E.G. Sorption of ethylamines from air by fibrous ion exchangers. 1. Fiban K-1, a strong acid cation exchanger. Proc. National Acad. Sci. Belarus. Chem. Ser. 2014; 50(4): 11–15. (In Russian).
Doroshkevich O.N., Kosandrovich E.G., Kashinskii A.V., Shachenkova L.N., Zelenkovskii V.M. Sorption of ethylamines from air by fibrous ion exchangers. 2. FIBAN K-4, a weak acid cation exchanger. Proc. National Acad. Sci. Belarus. Chem. Ser. 2014; 50(4): 16–20. (In Russian).
Kosandrovich E.G., Shachenkova L.N., Pushkarchuk A.L., Bez’yazychnaya T.V., Soldatov V.S. Mathematical description of ethylamine sorption from air by fibrous cation exchangers under conditions of limited sorbate permeability. Proc. National Acad. Sci. Belarus. Chem. Ser. 2020; 56(1): 7–14. doi: 10.29235/1561-8331-2020-56-1-7-14 (In Russian).