{"leader":"12873nam#a2200937#i#450#","fields":[{"001":"2212"},{"005":"20241123112000.6"},{"008":{"ind1":" ","ind2":" ","subfields":[{"":"20210730d2021####ek#y0rusy0150####ca"}]}},{"020":{"ind1":"#","ind2":"#","subfields":[{"$a":"978-1-4946-0022-8"}]}},{"041":{"ind1":"0","ind2":"#","subfields":[{"$a":"ENG"}]}},{"044":{"ind1":"#","ind2":"#","subfields":[{"$a":"xxu"}]}},{"072":{"ind1":"#","ind2":"7","subfields":[{"$a":"Life Sciences \/ Ecology. SCI020000"},{"$a":"Chemical & Biochemical. TEC009010"},{"$a":"Environmental \/ Water Supply. TEC010030"}]}},{"100":{"ind1":"#","ind2":"1","subfields":[{"$a":"\u00d0\u009a\u00d1\u0081\u00d0\u00b5\u00d0\u00bd\u00d0\u00be\u00d1\u0084\u00d0\u00be\u00d0\u00bd\u00d1\u0082\u00d0\u00be\u00d0\u00b2, \u00d0\u0091\u00d0\u00be\u00d1\u0080\u00d0\u00b8\u00d1\u0081 \u00d0\u00a1\u00d0\u00b5\u00d0\u00bc\u00d0\u00b5\u00d0\u00bd\u00d0\u00be\u00d0\u00b2\u00d0\u00b8\u00d1\u0087"},{"$a":"\u00d0\u009c\u00d0\u0093\u00d0\u00a2\u00d0\u00a3 \u00d0\u00b8\u00d0\u00bc. \u00d0\u009d. \u00d0\u00ad. \u00d0\u0091\u00d0\u00b0\u00d1\u0083\u00d0\u00bc\u00d0\u00b0\u00d0\u00bd\u00d0\u00b0"}]}},{"245":{"ind1":"0","ind2":"0","subfields":[{"$a":"FLOTATION MULTISTAGE AND GENERALIZED MODELS OF THE PROCESS HARVESTERS OF KSENOFONTOV TYPE AND FOR SPECIAL PURPOSE"},{"$c":"\u00d0\u009c\u00d0\u00be\u00d0\u00bd\u00d0\u00be\u00d0\u00b3\u00d1\u0080\u00d0\u00b0\u00d1\u0084\u00d0\u00b8\u00d1\u008f"}]}},{"260":{"ind1":"1","ind2":"#","subfields":[{"$a":"\u00d0\u00a1\u00d0\u00b0\u00d0\u00bd-\u00d0\u00a4\u00d1\u0080\u00d0\u00b0\u00d0\u00bd\u00d1\u0086\u00d0\u00b8\u00d1\u0081\u00d0\u00ba\u00d0\u00be"},{"$b":"Academus Publishing"},{"$c":"2021"}]}},{"300":{"ind1":"#","ind2":"#","subfields":[{"$a":"299 p."}]}},{"500":{"ind1":"#","ind2":"#","subfields":[{"$a":"A multistage and generalised flotation model, suggested more than 30 years ago by the author, is considered in a wide aspect for the first time in world literature for reader\u00e2\u0080\u0099s attention in monography. The possibilities of its usage are shown in different directions of water flotation purification, sediment thickening and enrichment of minerals. We have shed a light widely on matters concerning new flotation equipment as flotation harvesters of KBS type and for special purposes, which are developed on the basis of flotation process multistage and generalized models. Perspectives and intensification ways of water purification flotation processes are pointed out.\r\nIt is suggested for a wide range of readers, including researches, Higher education teachers, PhD students, Masters and Bachelors, Graduate students."},{"$a":"flotation, water purification, sediment thickening, enrichment of minerals, flotation harvesters"},{"$a":"10.31519\/0022-8"}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Grattoni C., Moosai R. and Dawe R.A. (2003). Photographic Observations Showing Spreading and Non-Spreading of Oil on Gas Bubbles of Relevance to Gas Flotation for Oily Wastewater Cleanup. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 214(1\u00e2\u0080\u00933), 151\u00e2\u0080\u0093155."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Galbraith P. and Stillman G. (2006). A Framework for Identifying Student Blockages During Transitions in the Modelling Process. ZDM, 38(2), 143\u00e2\u0080\u0093162."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Mostafa N., Syed H.M., Igor S. and Andrew G. (2009). A Study of Melt Flow Analysis of an ABS-Iron Composite in Fused Deposition Modelling Process. Tsinghua Science & Technology, 14, 29\u00e2\u0080\u009337."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Wills B.A. and Finch J. (2015). Wills\u00e2\u0080\u0099 Mineral Processing Technology: An Introduction to the Practical Aspects of Ore Treatment and Mineral Recovery. Butterworth-Heinemann."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Grammatika M. and Zimmerman W.B. (2001). Micro-hydro-dynamics of Flotation Processes in the Sea Surface Layer. Dynamics of Atmospheres and Oceans, 34(2\u00e2\u0080\u00934), 327\u00e2\u0080\u0093348."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Van der Westhuizen A.P. and Deglon D.A. (2007). Evaluation of Solids Suspension in a Pilot-Scale Mechanical Flotation Cell: The Critical Impeller Speed. Minerals Engineering, 20(3), 233\u00e2\u0080\u0093240."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Szpyrkowicz L. (2005). Hydrodynamic Effects on the Performance of Electro-Coagulation\/Electro-Flotation for the Removal of Dyes from Textile Wastewater. Industrial & Engineering Chemistry Research, 44(20), 7844\u00e2\u0080\u00937853."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Yianatos J.B. (2007). Fluid Flow and Kinetic Modelling in Flotation Related Processes: Columns and Mechanically Agitated Cells \u00e2\u0080\u0094 a Review. Chemical Engineering Research and Design, 85(12), 1591\u00e2\u0080\u00931603."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Rodrigues R.T. and Rubio J. (2007). DAF \u00e2\u0080\u0093 dissolved Air Flotation: Potential Applications in the Mining and Mineral Processing Industry. International Journal of Mineral Processing, 82(1), 1\u00e2\u0080\u009313."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Miettinen T., Ralston J. and Fornasiero D. (2010). The Limits of Fine Particle Flotation. Minerals Engineering, 23(5), 420\u00e2\u0080\u0093437."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Flotation Processing of Water, Waste and Soil. M.: Novel Technologies. 2010. P. 272 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Water and Soil Purification by Flotation. M.: Novel Technologies, 2004. P 224 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Process Modelling of Electroflotation Cleaning of Wastewaters. Express-Information. Series \u00e2\u0080\u009cIndustry of Mining-Chemical Raw\u00e2\u0080\u009d NIITECHEM 1987. No. 4. P. 1\u00e2\u0080\u00938 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Gvozdev V.D., Ksenofontov B.S. Industrial Wastewater Purification and Sediment Utilization. \u00d0\u009c.: Chemistry, 1988. P. 112 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S., Vinogradov M.S. Usage of Generalized Flotatotion Model of Ksenofontov for Calculation of Water Purification Processes. \u00d0\u00a2ver: \u00d0\u00a2ver State University. 2019. P. 185 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification: Flotation and Sediment Thickening. \u00d0\u009c: Chemistry, 1992. P. 144 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Deryagin B.V. Micro-flotation: Water Purification, Enrichment \/ Deryagin D.V., Dukhin S.S., Rulev S.S. \u00d0\u009c.: Chemistry, 1986. P. 112 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Natural Environment Safety: Biotechnical Bases. \u00d0\u009c.: Publishing House \u00c2\u00abForum\u00c2\u00bb: INFRA-\u00d0\u009c. 2016. P. 200 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Treatment of Wastewater Sediments. \u00d0\u009c.: INFRA-\u00d0\u009c. 2019. P. 262 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification Intensification by Flotation. Saarbr\u00c3\u00bccken: LAP LAMBERT, 2012. P. 99."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Water Systems Flotation Treatment. Saarbr\u00c3\u00bccken (Germany): LAP LAMBERT, 2011. P. 189."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Kolesnikov V.A., Ilyin V.I., Kapustin Yu.I., Varaksin S.O., Kisilenko P.N., Kokarev G.A. Electroflotation Technology for Purification of Wastewater of Industrial Enterprises \/ Editor Kolesnikov V.A. \u00e2\u0080\u0094 \u00d0\u009c.: Chemistry, 2007. P. 303 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Bondareva GM Development of Flotation Process of Extraction of Surfactants and Motor Fuels from Water Drainages: Dissertation for PhD in Chemistry: Moscow 2010. P. 174 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Nazarov M.V., Vineshtock P.N., Voronina A.N. Preparation of Under-Commodity Waters for Low-Permeability Collectors of Oil by Electroflotation Method \/\/ Oil and Gas Business: scientific Electronic Journal. 2014. No. 1. 2014 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Innovation No. 2108974 \u00c2\u00abWay of Wastewater Purification\u00c2\u00bb, accepted 04\/22\/1996, registered 04\/20\/1998. Author and Applier Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S., Senik E.V. Cleaning of Wastewaters on Flotation Decanters. Life Safety. 2018. No. 5 (209). Pp 21\u00e2\u0080\u009326 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Golman A.M. Ionic Flotation. \u00d0\u009c.: Subsoils, 1982. P. 143 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Flotation Purification. \u00d0\u009c.: New Technologies. 2003. P. 160 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Multistage Model of Flotation and Flotoharvesters: Monography. Tver: Tver State University 2019. P. 194 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 183320. Ejector-Mixer, accepted 07\/16\/2018, registered 09\/18\/2018. Author and Applier Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification: Flotation Kinetics and Flotation Harvesters. \u00d0\u009c.: PH: \u00c2\u00abForum\u00c2\u00bb: INFRA-\u00d0\u009c. 2015. P. 256 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S., Kapitonova C.N., Senik E.V. The Usage of Ksenofontov\u00e2\u0080\u0099s Multistage Model in the Processes of Flotation Purification of Wastewaters: Monograph \u00d0\u00a2ver: Tver State University, 2019. P. 162 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 170182. Flotation Harvester for Wastewater Purification, accepted 07\/25\/2016, registered 04\/18\/2017. Author and Applier Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent No. 2658411. Flotation Harvester for Wastewater Purification, accepted 04\/11\/2017, registered 06\/21\/2018. Author and Applier Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent No. 2669842. Flotation Harvester for Wastewater Purification, accepted 11\/17\/2017, registered 10\/16\/2018. Author and Applier Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification in Flotation Columns. Water Purification. 2018, No. 1\u00e2\u0080\u00932. P. 18\u00e2\u0080\u009323 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Mathematical Models of Complex Articulated Processes in Flotation Harvesters for Wastewater Purification. Water Purification. 2018, No. 10. P. 7\u00e2\u0080\u009311 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Industrial Wastewater Purification from Mineral Oils by Flotation with Out-Extraction of Micro-flotocomplexes. Water Purification. 2018, No. 10. P. 12\u00e2\u0080\u009318 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Intensification of Wastewater Purification with the Use of Combined Flotation Technique. Water Purification 2018, No. 4. P. 8\u00e2\u0080\u009313 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Models of Complex Flotation Processes of Wastewater Purification. Water Purification. 2018. No. 6. P. 59\u00e2\u0080\u009369 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification: Multistage Flotation Model and Flotoharvesters. Water Purification. 2018, No. 12. P. 5\u00e2\u0080\u009321 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification with the Use of Ionic Flotation. Water Purification, 2018, No. 6. P. 5\u00e2\u0080\u009315 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S., Stelmach E.S. Ejectors qua Mixers for Reagent Treatment of Water. Water Purification. 2018, No. 1\u00e2\u0080\u00932. P. 70\u00e2\u0080\u009374 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S., Stelmach E.S. Intensification of Wastewater Flotation Purification with the Use of Jet Aerators and Ejectors. Water Purification, 2018, No. 6. P. 25\u00e2\u0080\u009335 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Possibilities of Usage of Pressure-head Flotation Skimmers for Thickening and Inactivation of Active"}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Flotation Method of Active Silt Thickening with the Use of Carbon Dioxide \/Ksenofontov B.S., Kozodaev A.S., Dulina L.A. \/\/ 7th International Congress \u00c2\u00abWater: Ecology and Technology\u00c2\u00bb (EQUATEC-2006), V2. \u00d0\u009c. 2006. P. 830 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Water Preparation and Water Offtake. \u00d0\u009c.: Publishing House \u00c2\u00abForum\u00c2\u00bb \u00e2\u0080\u0094 INFRA-\u00d0\u009c. 2018.. P. 298 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S., Titov K. Multistage Ksenofontov Model of Flotation und uts. Saarbrucken: LAP LAMBERT Acad. Publ, 2019. P. 57."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Wastewater Purification: Multistage Flotation Model and Flotation Harvesters. Water Purification, 2018. No. 12. P. 5\u00e2\u0080\u009321 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Generalized Multistage Flotation Model and Development of Flotoharvesters of KBS Type and of Special Purpose for Purification of Water and Soil: Monograph. Tver State University, 2019. P. 104 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Multistage Model of Flotation Process for Water Purification. IOP Conference Series: Materials Science and Engineering. 2019. Vol. 492, Issue 1. Art. No 012033. DOI: 10. 1088\/1757 -899\u00d0\u00a5\/492\/1\/012033."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"Ksenofontov B.S. Simulation of Wastewater Treatment in Flotation Machine. AIP Conference Proceedings. 2019. Vol. 2195. Art. No 020070. DOI: 10. 1063\/1.5140170."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model 123 001. Flotation Machine for Wastewater Purification, accepted 07\/24\/12, registered 12\/20\/12. Authors: Ksenofontov B.S., Sazonov D.V. Applier: Bauman State Technical University (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model 143 014. Flotation Machine for Wastewater Purification, accepted 12\/30\/13, registered 07\/10\/14. Authors: Ksenofontov B.S., Petrova E.V., Vinogradova M.S. Applier: Bauman State Technical University (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 149273. Flotation Machine for Wastewater Purification \/\/ Ksenofontov B.S., Antonova E.S., applied 02\/24\/2014, published 12\/27\/2014 (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 192973 \u00e2\u0080\u009cBioflotoharvester\u00e2\u0080\u009d, taken 06\/18\/2019, registered 10\/08\/2019. Applier and author Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 194987 \u00e2\u0080\u009cChemoflotoharvester\u00e2\u0080\u009d, taken 08\/09\/2019, registered 01\/10\/2020. Applier and author Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 194985 \u00e2\u0080\u009cElectroflotoharvester\u00e2\u0080\u009d, taken 08\/22\/2019, registered 01\/10\/2020. Applier and author Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 194986 \u00e2\u0080\u009cDeminoflotoharvester\u00e2\u0080\u009d, taken 09\/16\/2019, reg"}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 195481 \u00e2\u0080\u009cSilt-flotoharvester\u00e2\u0080\u009d, taken 10\/25\/2019, registered 01\/29\/2020. Applier and author Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 195504 \u00e2\u0080\u009cSoil-flotoharvester\u00e2\u0080\u009d, taken 11\/05\/2019, registered 01\/29\/2020. Applier and author Ksenofontov B.S. (in Russian)."}]}},{"510":{"ind1":"0","ind2":"#","subfields":[{"$a":"RF Patent on Useful Model No. 199049 \u00c2\u00abAquaflotoharvester\u00c2\u00bb, accepted 02\/05\/2020, registered 08\/11\/2020. Applier and author Ksenofontov B.S. (in Russian)."}]}},{"533":{"ind1":"#","ind2":"#","subfields":[{"$a":"There is an electronic copy"}]}},{"856":{"ind1":"4","ind2":"#","subfields":[{"$a":"academuspub.com"},{"$u":""}]}}]}