ESTABLISHING THE PARAMETERS OF THE OPERATION MODE OF THE ELECTRIC PULSE AUTOMOBILE MUFFLER

Aliya Kukesheva; Adil  Kadyrov; Yevgeniy  Kryuchkov

doi:10.5937/jaes0-45196

Aliya Kukesheva Abylkas Saginov Karaganda Technical University NPJSC, Transport and Road faculty, The department of “Transport equipment and logistic systems” Karaganda, The Republic of Kazakhstan
Adil Kadyrov Abylkas Saginov Karaganda Technical University NPJSC, Transport and Road faculty, The department of “Transport equipment and logistic systems” Karaganda, The Republic of Kazakhstan
Yevgeniy Kryuchkov Abylkas Saginov Karaganda Technical University NPJSC, Transport and Road faculty, The department of “Transport equipment and logistic systems” Karaganda, The Republic of Kazakhstan

DOI: https://doi.org/10.5937/jaes0-45196

Keywords: automobile, internal combustion engine, muffler, exhaust gas, electric pulse

Abstract

The purpose of the research in the article is to obtain analytical and experimental results on the purification of internal combustion engine exhaust gases by an electric pulse, allowing us to determine the main parameters of the muffler operation. The set goal was achieved by performing the following methodology. A mathematical model of the motion of a gas particle in a muffler has been developed and investigated, the relationship between the capacity of the engine combustion chamber, the number of revolutions of the crankshaft, the pulse intensity, and the dynamic viscosity of the medium has been established. The condition of the muffler operation is determined through the parameter – the distance between the electrodes. The optimality criterion is justified – the smokiness of the gas before and after purification. A nonlinear experimental plan has been compiled using the methods of similarity theory and dimension analysis. An experimental stand has been developed and results linking the process parameters have been obtained. The results obtained are the basis for the methodology for calculating the design of electric pulse mufflers with optimal smoke ratios.

References

Twigg M. V. (2007). Progress and future challenges in controlling automotive exhaust gas emissions. Applied Catalysis B: Environmental, vol. 70, no.1, 2-15, DOI: https://doi.org/10.1016/j.apcatb.2006.02.029

ZHANG, Y., YANG, W., SIMPSON, I, HUANG, X., YU, J., HUANG, Z., WANG, Z., ZHANG, Z., LIU, D., HUANG, Z., WANG, Y., PEI, CH., SHAO, M., BLAKE, D. R., ZHENG, J., HUANG, Z., WANG, X. (2019). Decadal changes in emissions of volatile organic compounds (VOCs) from on-road vehicles with intensified automobile pollutioncontrol: case study in a busy urban tunnel in south China. Environmental Pollution, vol. 233, no.5, 806-819, DOI: https://doi.org/10.1016/j.envpol.2017.10.133

OSPANOV, O., ELEUOV, G., KADYROVA, I., BEKMURZINOVA, F. (2019). The life expectancy of patients with metabolic syndrome after weight loss: study protocol for a randomized clinical trial (LIFEXPE-RT). Trials, vol. 20, no.1, 202-206, DOI: https://doi.org/10.1186/s13063-019-3304-9.

Yegorov, S., Kadyrova, I., Negmetzhanov, B., Hortelano, G.H., Babenko, D. (2022). Sputnik-V reactogenicity and immunogenicity in the blood and mucosa: a prospective cohort study. Scientific Reports, vol. 12, no.1, 1-13. DOI:10.1038/s41598-022-17514-3

Isaksson, C., Pongolini, M. (2024). Do we really consider their concerns? User challenges with electric car sharing. Mobilities, vol. 23, no.1, 70-86, DOI: https://doi.org/10.1080/17450101.2023.2206045

Ahmed M. Y. (2019). Recovery and Then Individual Separation of Platinum, Palladium, and Rhodium from Spent Car Catalytic Converters Using Hydrometallurgical Technique followed by Successive Precipitation Methods. Journal of Chemistry, vol. 2019, no.3, 1-8. DOI: https://doi.org/10.1155/2019/2318157

Kadyrov, A., Sarsembekov, B., Ganyukov, A., Suyunbaev, S., Sinelnikov, K. (2022). Communications - Scientific Letters of the University of Žilina, vol. 24, no.3, 189-198, DOI: https://doi.org/10.26552/com.C.2022.3.B189-B198

Anatol J., Andrzej K., Tadeusz Cz. (2007). Modern electrostatic devices and methods for exhaust gas cleaning: A brief review. Journal of Electrostatics, vol. 65, no. 3, 133-155, DOI: https://doi.org/10.1016/j.elstat.2006.07.012

Akinobu, O. (2011). Green muffler. Patent US, No. US 2011/0099986 A1.

Volnov A.S., Gerasimov E.M., Tretiak L.N. (2014). Method of internal combustion engine exhaust gas cleaning and device for its implementation. Patent RF. No. 2563950.

Vinogradov J., Rivin B., Sher E. (2008). NOx reduction from compression ignition engines with pulsed corona discharge. Energy, vol. 33, no. 3, 480-491, DOI: https://doi.org/10.1016/j.energy.2007.06.004

Moreau, E., Audier, P., Orriere, T., Benard, N. (2019). Electrohydrodynamic gas flow in a positive corona discharge. Journal of Applied Physics, vol. 125, no.13,1-6, DOI: https://doi.org/10.1063/1.5056240

Kadyrov, A., Kryuchkov, Y, Sinelnikov, K, Ganyukov, A., Sakhapov, R., Kukesheva, A. (2022). Studying the process of the internal combustion engine exhaust gas purification by an electric pulse. Communications - Scientific Letters of the University of Zilina, vol. 24, no.4, 275-287, DOI:https://doi.org/10.26552/com.C.2022.4.B275-B287

Kadyrov, A., Kukesheva, A., Kryuchkov, Y., Kurmasheva, B., Kabikenov, S. (2024). Communications - Scientific Letters of the University of Žilina, vol. 26, no.1, 41-53, DOI: https://doi.org/10.26552/com.C.2024.011

GOST 21393-75 “Avtomobili s dizelyami. Dymnost' otrabotavshih gazov. Normy i metody izmerenij. Trebovaniya bezopasnosti».