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Determination of Thermophysical Properties of Alternative Motor Fuels as an Environmental Aspect of Internal Combustion Engines

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Abstract:

The article analyzes the state of the global problem of the fuel and energy crisis and environmental pollution by the combustion products of hydrocarbon fuels of industrial and transport power plants. To ensure the energy security of the state, the Cabinet of Ministers of Ukraine developed and adopted the «Energy Strategy of Energy Saving of Ukraine for the period until 2030», which was updated in 2008, to protect the country from energy risks. In addition, the Cabinet of Ministers of Ukraine approved the «Concept of a targeted scientific and technical program for the development of the production and use of biological fuels». To increase the efficiency of using alternative motor fuels, as one of the aspects of solving the problem, an original method and results of calculating the thermophysical properties of a wide class of such motor fuels (hydrogen, natural gas, biogas, mine gas, coke, blast furnace and synthesis gas, etc.) are proposed. A description of the developed mathematical model for determining parameters of phase equilibria and thermophysical properties of dense molecular systems (dense gases and liquids) is given. Calculation procedures are based on the thermodynamic theory of disturbances without the involvement of empirical parameters. Features of the proposed method are: limitation of initial information, high accuracy, the possibility of application in any practically important ranges of states. Calculation errors are at the level of traditional experimental errors.

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Periodical:

Engineering Innovations (Volume 7)

Pages:

51-59

DOI:

https://doi.org/10.4028/p-4VM7ff

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Cite this paper

Online since:

October 2023

Authors:

Ksenia Umerenkova, Vitalii Borysenko, Olexandr Kondratenko*, Anton Lievtierov

Keywords:

Alternative Motor Fuels, Ecological Safety, Environment Protection Technologies, Forecasting, Mathematical Model, Perturbation Theory, Phase Equilibrium, Reciprocating Internal Combustion Engines, Thermophysical Properties

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Creative Commons CC BY 4.0

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* - Corresponding Author

References

[1] D. Dubinin, K. Korytchenko, A. Lisnyak, I. Hrytsyna, V. Trigub, Numerical simulation of the creation of a fire fighting barrier using an explosion of a combustible charge. Eastern-European Journal of Enterprise Technologies, 6 10–90 (2017) 11–16.

DOI: 10.15587/1729-4061.2017.114504

Google Scholar

[2] Y. Danchenko, V. Andronov, M. Teslenko, V. Permiakov, E. Rybka, R. Meleshchenko, A. Kosse, Study of the free surface energy of epoxy composites using an automated measurement system. Eastern-European Journal of Enterprise Technologies, 1 12–91 (2018) 9–17.

DOI: 10.15587/1729-4061.2018.120998

Google Scholar

[3] O. Popov, A. Iatsyshyn, V. Kovach, V. Artemchuk, D. Taraduda, V. Sobyna, D. Sokolov, M. Dement, V. Hurkovskyi, K. Nikolaiev, T. Yatsyshyn, D. Dimitriieva, Physical features of pollutants spread in the air during the emergency at NPPs. Nuclear and Radiation Safety, 4 84 (2019) 11.

DOI: 10.32918/nrs.2019.4(84).11

Google Scholar

[4] B. Pospelov, V. Andronov, E. Rybka, O. Krainiukov, K. Karpets, O. Pirohov, I. Semenyshyna, R. Kapitan, A. Promska, O. Horbov, Development of the correlation method for operative detection of recurrent states. Eastern-European Journal of Enterprise, 6/4 (102) (2019) 39–46.

DOI: 10.15587/1729-4061.2019.187252

Google Scholar

[5] S. Vambol, V. Vambol, I. Bogdanov, Y. Suchikova, N. Rashkevich, Research of the influence of decomposition of wastes of polymers with nano inclusions on the atmosphere. Eastern-European Journal of Enterprise Technologies, 6 10–90 (2017) 57–64.

DOI: 10.15587/1729-4061.2017.118213

Google Scholar

[6] O. Rybalova, S. Artemiev, M. Sarapina, B. Tsymbal, A. Bakhareva, O. Shestopalov, O. Filenko, Development of methods for estimating the environmental risk of degradation of the surface water state. Eastern-European Journal of Enterprise Technologies, 2 10–92 (2018)4–17.

DOI: 10.15587/1729-4061.2018.127829

Google Scholar

[7] V.M. Loboichenko, A.E. Vasyukov, T.S. Tishakova, Investigations of mineralization of water bodies on the example of river waters of ukraine. Asian Journal of water, environment and pollution, 14(4) (2017) 37–41.

DOI: 10.3233/ajw-170035

Google Scholar

[8] S. Vambol, V. Vambol, O. Kondratenko, Y. Suchikova, O. Hurenko, Assessment of improvement of ecological safety of power plants by arranging the system of pollutant neutralization. Eastern-European Journal of Enterprise Technologies, 3 10–87 (2017) 63–73.

DOI: 10.15587/1729-4061.2017.102314

Google Scholar

[9] B. Pospelov, V. Andronov, E. Rybka, O. Krainiukov, N. Maksymenko, R. Meleshchenko, Yu. Bezuhla, I. Hrachova, R. Nesterenko, А. Shumilova, Mathematical model of determining a risk to the human health along with the detection of hazardous states of urban atmosphere pollution based on measuring the current concentrations of pollutants. Eastern-European Journal of Enterprise, 4/10 (106) (2020) 37–44.

DOI: 10.15587/1729-4061.2020.210059

Google Scholar

[10] B. Pospelov, R. Meleshchenko, O. Krainiukov, K. Karpets, O. Petukhova, Y. Bezuhla, T.Butenko, V. Horinova, P. Borodych, E. Kochanov, A method for preventing the emergency resulting from fires in the premises through operative control over a gas medium. Eastern-European Journal of Enterprise Technologies,10–103 (2020) 6–13.

DOI: 10.15587/1729-4061.2020.194009

Google Scholar

[11] O. Rybalova, S. Artemiev, Development of a procedure for assessing the environmental risk of the surface water status deterioration. Eastern-European Journal of Enterprise Technologies, 5 10–89 (2017) 67–76.

DOI: 10.15587/1729-4061.2017.112211

Google Scholar

[12] O. Kondratenko, S. Vambol, O. Strokov, A. Avramenko, Mathematical model of the efficiency of diesel particulate matter filter. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 6 (2015) 55–61.

Google Scholar

[13] O. Popov, A. Iatsyshyn, V. Kovach, V. Artemchuk, D. Taraduda, V. Sobyna, D. Sokolov, M. Dement, T. Yatsyshyn, Conceptual approaches for development of informational and analytical expert system for assessing the NPP impact on the environment. Nuclear and Radiation Safety, (2018)

DOI: 10.32918/NRS.2018.3(79).09

Google Scholar

[14] Y. Danchenko, V. Andronov, A. Kariev, V. Lebedev, E. Rybka, R. Meleshchenko, D. Yavorska, Research into surface properties of disperse fillers based on plant raw materials. Eastern-European Journal of Enterprise Technologies, 5 12–89 (2017) 20–26.

DOI: 10.15587/1729-4061.2017.111350

Google Scholar

[15] S. Vambol, V.Vambol, Y. Suchikova, N. Deyneko, Analysis of the ways to provide ecological safety for the products of nanotechnologies throughout their life cycle. Eastern-European Journal of Enterprise Technologies, 1 10–85 (2017) 27–36.

DOI: 10.15587/1729-4061.2017.85847

Google Scholar

[16] A. Teslenko, A. Chernukha, O. Bezuglov, O. Bogatov, E. Kunitsa, V. Kalyna, A. Katunin, V. Kobzin, S. Minka, Construction of an algorithm for building regions of questionable decisions for devices containing gases in a linear multidimensional space of hazardous factors. Eastern-European Journal of Enterprise Technologies, 5 10–101 (2019) 42–49.

DOI: 10.15587/1729-4061.2019.181668

Google Scholar

[17] I. Parsadanov I., P. Kanilo P., O. Strokov, Evaluation of the performance of city bus diesels using alternative fuels. Internal Combustion Engines, 2 (2010) 104–109.

Google Scholar

[18] K. Umerenkova, V. Borysenko, Prospects for the use of alternative fuels and methods of determining their thermophysical characteristics: monograph. Kharkiv. Publ. NUCDU, (2021)101 p.

Google Scholar

[19] V. Marinin (1999) Thermal physics of alternative energy carriers. Kharkiv. Publ. Fort. 212 p.

Google Scholar

[20] K. Umerenkova, A. Lievtierov, O. Kondratenko, Determination of thermophysical properties of alternative motor fuels as an aspect of greening of internal combustion engines. All-Ukrainian Scientific and Practical Conference «Problems of Technogenic and Ecological Safety in the Field of Civil Defence»: Collection of Materials. December 08–09, 2022. Kharkiv. NUCDU, (2022) 162–165.

DOI: 10.20998/0419-8719.2023.1.04

Google Scholar

[21] O. Kondratenko, V. Koloskov, S. Kovalenko, Yu. Derkach, Research of Technical and Economic Properties of Material of Porous Fuel Briquettes from the Solid Combustible Waste Impregnated with Liquid Combustible Waste. Materials Science Forum, 1038 (2021) 303–314.

DOI: 10.4028/www.scientific.net/msf.1038.303

Google Scholar

[22] S. Vambol, V. Vambol, O. Kondratenko, V. Koloskov,  Y. Suchikova, Substantiation of expedience of application of high-temperature utilization of used tires for liquefied methane production. Journal of Achievements in Materials and Manufacturing Engineering, 87 2 (2018) 77–84.

DOI: 10.5604/01.3001.0012.2830

Google Scholar

[23] S. Vambol, V. Vambol, V. Sobyna, V. Koloskov, L. Poberezhna, Investigation of the energy efficiency of waste utilization technology, with considering the use of low-temperature separation of the resulting gas mixtures. Energetika, 64 4 (2018) 186–195.

DOI: 10.6001/energetika.v64i4.3893

Google Scholar

[24] N. Sytnik, E. Kunitsia, V. Mazaeva, A. Chernukha, P. Kovalov, N. Grigorenko, S. Gornostal, O. Yermakova, M. Pavlunko, M. Kravtsov Rational parameters of waxes obtaining from oil winterization waste, Eastern-European Journal of Enterprise Technologies, 6 10 (108) (2020) 29–35.

DOI: 10.15587/1729-4061.2020.219602

Google Scholar

[25] O. Kondratenko, V. Koloskov, S. Kovalenko, Y. Derkach, O. Strokov, Criteria based assessment of efficiency of conversion of reciprocating ICE of hybrid vehicle on consumption of biofuels, 2020 IEEE KhPI Week on Advanced Technology, KhPI Week 2020 (05–10 October 2020, Kharkiv, Ukraine), Conference Proceedings, (2020) 177–182.

DOI: 10.1109/khpiweek51551.2020.9250118

Google Scholar

[26] B. Pospelov, E. Rybka, R. Meleshchenko, P. Borodych, S. Gornostal, Development of the method for rapid detection of hazardous atmospheric pollution of cities with the help of recurrence measures. Eastern-European Journal of Enterprise Technologies, 1 10 (97) (2019) 29–35.

DOI: 10.15587/1729-4061.2019.155027

Google Scholar

[27] V. Sadkovyi, B. Pospelov, V. Andronov, E. Rybka, O. Krainiukov, А. Rud, K. Karpets, Yu Bezuhla, Construction of a method for detecting arbitrary hazard pollutants in the atmospheric air based on the structural function of the current pollutant concentrations. Eastern-European Journal of Enterprise, 6/10 (108) (2020) 14–22.

DOI: 10.15587/1729-4061.2020.218714

Google Scholar

[28] P. Kanilo, K. Kostenko, Analysis of the efficiency of using alternative fuels in vehicles, Problems of mechanical engineering, 14 1 (2011) 69–73.

Google Scholar

[29] A. Lievtierov, V. Marinin, K. Umerenkova, Estimated assessment of the thermophysical properties of biogas used as a fuel for transport, Industrial heat engineering, 32 1 (2010) 35–41.

Google Scholar

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