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The problem of optimizing the heating of petroleum products when draining from railway tanks using microwave heating is considered. It is established that microwave heating can significantly simplify the technological scheme, eliminating all processes and apparatuses associated with the preparation of the coolant. It is determined that currently existing patents and technical solutions proposed for the use of microwave heating for heating petroleum products assume that microwave energy falls on the free surface of the liquid. It is argued that the disadvantage of such schemes is a significant unevenness of heating due to the fact that microwave energy quickly fades out when moving deep into the tank. It is noted that when heated from the surface of the liquid in the tank, the distance from the source to the drain hole is quite large, as a result of which it is impossible to effectively use microwave heating. A method for solving this problem is proposed, which consists in installing a microwave device inside a hollow pipe, which is directly connected to the upper hatch in preparation for pumping and is immersed in the oil product to a depth that correlates with the depth of penetration of the microwave field in a particular product. The depth of penetration of microwave energy into the oil product under study - fuel oil-is estimated, on the basis of which it is recommended to set the distance from the emitter to the drain hole. It is argued that it is advisable to model microwave heating on the basis of the differential equation of thermal conductivity, taking into account internal heat sources. A mathematical model describing the heating of a volume of highly viscous petroleum products as a process of thermal conductivity in an unlimited array under the action of microwave radiation is presented. On the example of fuel oil, calculations were made using the finite difference method, which showed the temperature distribution in the array at different points in time.
Wydawca
Rocznik
Tom
Strony
150--156
Opis fizyczny
Bibliogr. 17 poz., rys., wykr., wzory
Twórcy
autor
- V.S. Martynovsky Institute of Refrigeration, Cryotechnologies and Ecoenergetics, Odessa National Academy of Food Technologies 65039, Оdessa, Kanatnaya, 112, Ukraine
autor
- V.S. Martynovsky Institute of Refrigeration, Cryotechnologies and Ecoenergetics, Odessa National Academy of Food Technologies 65039, Оdessa, Kanatnaya, 112, Ukraine
autor
- V.S. Martynovsky Institute of Refrigeration, Cryotechnologies and Ecoenergetics, Odessa National Academy of Food Technologies 65039, Оdessa, Kanatnaya, 112, Ukraine
autor
- V.S. Martynovsky Institute of Refrigeration, Cryotechnologies and Ecoenergetics, Odessa National Academy of Food Technologies 65039, Оdessa, Kanatnaya, 112, Ukraine
autor
- V.S. Martynovsky Institute of Refrigeration, Cryotechnologies and Ecoenergetics, Odessa National Academy of Food Technologies 65039, Оdessa, Kanatnaya, 112, Ukraine
Bibliografia
- [1] Wenfeng W., Jiakuo Z., Jinshu L., Jialin G., Fan S., Jiajia D., Dongze W., Temperature Field Distribution Analysis for Cargo Oil. Thermal science, 2020, Vol. 24, No. 5B, pp. 3413-3421.
- [2] Porch A., Slocombe D., Beutler J., Edwards P., Kuznetsov V., Microwave treatment in oil refining. Appl Petrochem Res., 2012, Vol. 2, pp. 37-44.
- [3] Jin Z.H., Research on Heating and Heat Preservation Process of Tanker Cargo based on fluent Platform. Dalian Maritime University, 2006, pp. 42-46.
- [4] Akagi S., Kato H., Numerical Analysis of Mixed Convection Heat Transfer of a High Viscosity Fluid in a Rectangular Tank with Rolling Motion. International Journal of Heat and Mass Transfer, 1987, Vol. 30, No. 11, pp. 2423-2432.
- [5] Wei S., Numerical Simulation of Steam Coil Heating Process for Large Floating Roof Oil Tank. Chemical Engineering, 2016, No. 7, pp. 19-23.
- [6] Macagnan M., Natural-Convection in a Tank of Oil: Experimental Validation of a Numerical Code with Prescribed Boundary Condition. Experimental Thermal and Fluid Science, 2005, Vol. 29, No. 6, pp. 671-80.
- [7] Hu W.P., Heat Transfer and Fluidity of Highly Viscous and Solid Crude-Oil in Shipwreck Tanks. Ph. D. thesis, Dalian Maritime University, Dalian, China, 2015, 182 р.
- [8] Zhu X., Numerical Simulation of Flow Characteristics during Oil Tanker Cargo Heating, Journal of Zhejiang Ocean University (Natural Science), 2018, Vol. 37, No. 1, pp. 55-59.
- [9] Yan R.P., Research Progress of Industrial Microwave Sterilization Technology in the Field of Food Processing. Science and Technology of Food Industry, 2018, Vol. 39, No. 8, pp. 302-308.
- [10] Fang C.S., Lai P., Microwave-Heating and Separation of Water-in-Oil Emulsions. Microwave Power Electromagnetic Energy, 1995, Vol. 30, No. 1. pp. 46-57.
- [11] Davidson R.J., Electromagnetic stimulation of Lloydminster heavy oil reservoirs: field test results. Journal of Canadian Petroleum Technology. 1995, Vol. 34, No. 4, pp. 15-24.
- [12] Mukhametshina A., Martynova E., Electromagnetic Heating of Heavy Oil and Bitumen: A Review of Experimental Studies and Field. Applications Journal of Petroleum Engineering. 2013, 7 p.
- [13] Domnin I.F., Rezinkina M.M., Raschetnoye issledovaniye teplovykh protsessov pri vysokochastotnom nagreve nefteproduktov. Vísnik NTU “KHPÍ”, 2013, No. 33, pp. 51-55.
- [14] Vasil'yev E., Morozov O., Stepanov S., Tsybko V., SVCH-razogrev zagustevshikh nefteproduktov v zheleznodorozhnykh tsisternakh. Elektronika dlya TE, 1999, No. 6, 9 p.
- [15] Afanastev B.F., Ustroystvo dlya nagreva zagustevshikh i zastyvshikh nefteproduktov v zheleznodorozhnykh tsisternakh. Patent RU 2 224 387 C2 ot 11.14.2001.
- [16] Bodnarchuk D.A., Ustroystvo dlya razogreva i sliva vysokovyazkikh nefteproduktov iz tsisterny. Patent RU 2 538 657 C2 ot 07.12.2012.
- [17] Sahni A., Kumar M., Knapp R.B., Electromagnetic heating methods for heavy oil reservoirs. Proc. of Society of Petroleum Engineers SPE/AAPG. Western Regional Meeting, Long Beach (CA) 62550, 2000, 12 p.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-2a254a61-9613-417c-9d1d-84aa0fed7da3