•  
  •  
 

Abstract

The development of a holistic, effective, and scalable structure of economic management, as well as the introduction of a program to improve the technical level and efficiency of machinery, are two of the most important concepts for the deep reconstruction of the Republic of Uzbekistan's economic process. Vehicles with diesel engines are gradually being introduced to our country's car fleet. Modern diesel engines are being developed by boosting them: increasing the average effective pressure and speed. Therefore, high reliability and service life, fuel efficiency and environmental performance are the main criteria for their quality. Forcing diesels leads to an increase in thermal and mechanical stresses on the main parts of the cylinder-piston group (CPG) (piston, liner, cylinder head), a significant increase in their temperature, as well as the temperature of piston rings and valves. Overheating of components causes the creation of temperature fields with pronounced irregularities in temperature distribution and, as a consequence, the development of thermal strains, which causes the material's mechanical properties to deteriorate, the formation of fractures, and, eventually, the part's destruction. The task of shielding parts from the undue effects of high thermal loads from the working body, or, in other words, the task of designing a diesel engine with reduced heat recovery from the working body, becomes important in this regard. However, creating a highly efficient engine with reduced heat dissipation from the working body is associated with solving a number of other issues, primarily with meeting today's environmental requirements. First and foremost, this relates to the reduction of nitrogen oxides in the combustion products, while at the same time reducing specific fuel consumption. Prospects for the development of the diesel engine industry can be seen in a consistent increase in the specific performance by boosting the mean effective pressure with a simultaneous reduction in combustion heat losses, thermal insulation of the combustion chamber and use of the exhaust gas energy. All these measures are taken in order to bring the actual thermodynamic cycle closer to the theoretical adiabatic cycle. Existing assessments of the effectiveness of combustion chamber thermal insulation of diesel engines on the level of thermodynamic adiabatic cycle were based on qualitative rather than quantitative indicators, due to which the achieved effects were interpreted ambiguously by various researchers. The introduction of uniformity in methodology, metrics, and quantitative parameters for estimating the efficiency of using heat from fuel combustion in a diesel working cycle helps not only to identify the reached stage, but also to forecast future progress of the engine-building branch, demonstrating the problem's urgency.

First Page

273

Last Page

280

References

  1. Kavtaradze R.Z. Local heat exchange in piston engines. Moscow: Publishing house of Bauman Moscow State Technical University. 2001. 592 p.
  2. Bengt Palm.: On the use of ceramics in diesel engines «Ceramic in advanced energy technologies». 1982. С. 178-207.
  3. Us Patent 1, 462, 654, July 24, 1923 (Internal Combustion Engine and Parts thereof).
  4. Pohlman, H.J. et al: Untersuchungen an Werkstoffen im System AL2O3-TiO2-SiO2 (Bericht der Keramischen Gesselschaft, Band 52 (1975) Nr 6, s 179-183).
  5. Internal combustion engines. - In the book "Results of Science and Technology. VINITI- VOL.4. -M., 1985. -246 p.
  6. Hat heads take over in a diesel engine revolution. Ward Daniel. «Engineer», 1982, 255, №6592/3, 22…24.
  7. Ceramic engine research and development in Sweden. Kronogard S.O., Malmrup L. «Ceram. High Performance Appl. 3: Reliab. Proc. 6th Army. Mater. Technol. Conf., Orcas Island, Wash., 10...13 July, 1979». New York: London, 1983, 51-80.
  8. Ceramics heat uр. Harmon Robert A., Beordsley Charles. «Mach. Eng.», 1984, 106, №5, 22-35.
  9. Report on research work: "Development of working processes and prototype of perspective diesel engine", MADI, Moscow, 1988, state registration number: 0186.0076.125, 0186.0076.127.
  10. Technical note on the works performed under the contract with NAMI "Development of working processes and assemblies of economically clean 450hp compound plant" (theme E 4221-89). -M., 1989, MADI.
  11. Internal combustion engines. Republican interdepartmental scientific and technical collection. Kharkov, 1986, Vyshcha Shkola. Issue 43, pp. 42-55.
  12. Engines of internal combustion. National Interdepartmental Scientific and Technical Collection. Kharkov, 1987, Vyshcha Shkola. Issue 46, pp. 25-31.
  13. Engines of internal combustion. National Interdepartmental Scientific and Technical Collection. Kharkiv, 1987, Vyshcha Shkola, Issue 45, pp. 3-16.
  14. Kadyrov S.M. et al. Development of Manufacturing Technology of Ceramic Parts for Machine-Building Industries, Research and Development of T-62-1 Diesel Engine with Ceramic Parts. State budget theme No.34.6.1. Interim Report, Tashkent, TADI, 1994, 45 pp.
  15. Kadyrov S.M. et al. Development of Technology of Ceramic Parts for Mechanical Engineering and Research and Development of Diesel Engine T-62-1 with Ceramic Parts. State budget theme #34.6.1. Interim report, Tashkent, TADI, 1995, 28 p.
  16. Kavtaradze R.Z. Local heat exchange in piston engines. Moscow: Publishing house of Moscow State Technical University named after N.E. Bauman. 2001. 592 p.
  17. Ivashchenko, N.A.; Petrukhin, N.V. Technique of the joint modelling of the operation process and the thermal state of the cylinder block of an "adiabatic engine" (in Russian). Izvestia Vuzov. Mechanical Engineering, No2, 1987. pp. 61-65.
  18. Grekhov L.V., Ivashchenko N.A., Petrukhin N.V. Peculiarities of Working Processes in Diesel Engines with Reduced Heat Discharge. Engines Engineering, No 8, 1989. №8 pp. 3-6.
  19. Aripjanov M.M. Reduction of thermal loads and concentration of harmful emissions by influencing the diesel workflow. Collection of works devoted to 175-th anniversary of N.E. Bauman Moscow State Technical University. 2005. pp. 34-35.
  20. Thermal barriers adaption in D.L. Diesel Engines, Effect on Smoke and gaseons emmissions. Belardini P., Bertoli С., Corcione F.E., Police G “SAE Technical Paper Series”, 1984, № 840995, 9 pp.
  21. Ismatov J.F., Abdurahmonov H.I. Use of ceramic materials for diesel engines. TSTU. Republican scientific-technical conference. 2018 pp. 150-151.
  22. Aripjanov M.M. Development of a multi-zone model of the working process to calculate the local and total concentrations of nitrogen oxides in the combustion chamber of a diesel engine // Tashkent State Technical University Bulletin. - 2006. - № 3. - pp. 90-93.
  23. Aripjanov M.M. Ways of influence on the working process in order to reduce the thermal loads and emissions of nitrogen oxides into the atmosphere (in Russian) // Tashkent State Technical University Bulletin. - 2006. - № 4. - pp. 84-88.
  24. Daminov O.O., Khushnaev O.A., Yangibaev A.I., Kucharenok G.M. Improving the performance indicators of diesel engines by enhancing the cooling system. Journal: Technical science and innovation. 2020, №1. - pp. 172-177.
  25. Khakimov J.O., Shatrov M.G., Turdiev J.P. Investigation of diesel engine`s working process on light fuel. Journal: Technical science and innovation. 2020, №1. - pp. 88-96.
  26. Mirzaabdullaev J.B., Viarshyna H.A., Mirzaev A.A. Specificities of service maintenance of gas-truck vehicles, created on the basis of autotractor diesel engines. Journal: Technical science and innovation. 2020, №1. - pp. 192-198.
  27. M.M. Aripjanov, S.M. Kadyrov, A.A. Mirakhmedov, Studies of heat stress of piston with ceramic lining. Transport Science, Technology, Management, VINITI, No.7, 2002, pp. 48-49.

Share

COinS
 
 

To view the content in your browser, please download Adobe Reader or, alternately,
you may Download the file to your hard drive.

NOTE: The latest versions of Adobe Reader do not support viewing PDF files within Firefox on Mac OS and if you are using a modern (Intel) Mac, there is no official plugin for viewing PDF files within the browser window.