Author(s):
Bakhmutov S.V., D.Sc. (Eng), professor
Deputy CEO for Science (Research)1
Affiliated:
1Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Bakhmutov S.V. [IASF-2020 and Autonet-2020 Joint Forum. Results and prospects]. Trudy NAMI, 2020, no. 4 (283), pp. 6–10. DOI: 10.51187/0135-3152-2020-4-6-10. (In Russian)
Received:
2020.11.18
Published:
2020.12.07
Abstract:
On October 14-15, 2020, the joint international automotive scientific forum of IASF-2020 “Intelligent ground vehicles and systems” and Autonet-2020 “Forum of innovative transport technologies” was held online. The joint event based on the IASF and Autonet forums, well-known and recognized in Russia and abroad, took place for the first time, having aroused an increased interest both of traditional participants and a great number of new specialists, as evidenced by the number of participants (over 1000 people). The opening of the joint forum started with introductory reports of the well-known leaders largely determining the trends and ways of key industries development in the country. The list of the discussed issues turned out to be rather wide: from the future of services for connected vehicles and mobility after the pandemic to 5G technology and satellite communications for highly automated vehicles including the formation of a promising interaction system between road infrastructure and unmanned vehicles. Special attention was paid to the training of specialists in priority areas of development, creation, testing and operation of intelligent vehicles and systems. The “AUTONET AWARDS 2020” awards were handed out and the final competition of scientific works of students, graduate students and young specialists was held. More than 180 reports were presented within the joint forum. Its participants got acquainted with FSUE “NAMI” developments in the field of intelligent vehicles and their components.
Key words:
IASF-2020
Autonet-2020
intelligent transport systems
transport technologies
unmanned vehicles
road infrastructure
autonomous traffic
Author(s):
Kichzhi A.S., PhD (Eng)
Senior expert1
Girutskiy O.I., D.Sc. (Eng), professor
Vice-chairman1
Affiliated:
1Expert Council of Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Kichzhi A.S., Girutskiy O.I. [An analytical review of the vehicle auxiliary brake systems design (retarders)]. Trudy NAMI, 2020, no. 4 (283), pp. 11–26. DOI: 10.51187/0135-3152-2020-4-11-26. (In Russian)
Received:
2020.08.04
Published:
2020.12.07
Abstract:
Introduction. This work is devoted to the structure development of one of the most important elements of active safety – auxiliary braking systems of vehicles operating in difficult road conditions.
The purpose of the study was to identify the current trend in the retarders development taking into account both the experience of leading automobile countries and the developments of FSUE “NAMI” of the past years, with the purpose to stimulate the research in this area, which has not been carried out for more than 30 years.
Methodology and research methods. The material of the article is the result of both the domestic regulatory base analysis of active safety equipment, and the relevant legislative acts of the European Union countries, which oblige to equip some categories of vehicles with retarder brakes. The terminology used for this type of aggregates has been clarified.
Scientific novelty and results. The conducted studies of modern retarder brakes properties and designs from leading manufacturers allow us to determine the main directions of domestic developments in the field of energy-intensive brake systems.
The practical significance lies in the systematization of advantages and disadvantages of various retarder types, which makes it possible to determine the optimization of the design choice for a specific type of vehicle.
Key words:
brake retarder
motor
decompression
transmission
hydrodynamic
electrodynamic
power balance of a vehicle
power loss
deceleration
References:
1. Gusakov N.V., Kisulenko B.V. [Technical regulation in the automotive industry. Dictionary-reference]. Moscow, Mashinostroenie Publ., 2008, p. 169, p. 187. (In Russian)
2. Novichkova A. [Components “Driver, press the brakes”]. Avtoperevozchik, 2008, no. 11 (98). Available at: http://transler.ru/content/arxiv_perevozhic/perevozhic_08/perevozhic_98/Komponenty_quotVoditel_nazhmi_na_tormozaquot (accessed 04 August 2020). (In Russian)
3. Kichzhi A.S. [Retarders for trucks and buses]. Avtomobil’naya promyshlennost’, 1984, no. 7, pp. 38–40. (In Russian)
4. [Other brakes]. AVTOTRAK, 2012, 01.02.2012. Available at: http://www.autotruck-press.ru/articles/4298/ (дата обращения: 04.08.2020). (In Russian)
5. Detroit Repair Manuals. Section 1.36. Jake Brake. Available at: http://www.detroitmanuals.info/series-60/040224.html# (accessed 04 August 2020).
6. Gapoyan D.T., D’yachkov N.K. [Automotive vane hydraulic retarders]. Moscow, NIINAvtoprom Publ., 1968, pp. 9–11, 30–33. (In Russian)
7. Gapoyan D.T., Kichzhi A.S., Garonin L.S. [Study of transmission losses caused by retarders]. Avtomobil’naya promyshlennost’, 1973, no. 10, pp. 22–24. (In Russian)
8. Kichzhi A.S., Gapoyan D.T. [Calculation of cooling systems for hydrodynamic retarders]. Trudy NAMI, 1974, no. 150, pp. 20–34. (In Russian)
9. Fogelzang K., Khaylinger P. [Drive unit with retarder brake]. Patent RF, no. 2314946, 2003. (In Russian)
10. Zhukov S. [Mercedes-Benz tests “perpetual” grip for Arocs]. Available at: https://dvizhok.su/komtrans/mercedes-benz-ispyityivaet-vechnoe-sczeplenie-dlya-aroksa/ (accessed 04 August 2020). (In Russian)
11. Girutskiy O.I., Tarasik V.P., Rynkevich S.A. [Development of designs and prospects of automatic transmissions]. Nauka i obrazovanie: nauchnoe izdanie MGTU im. N.E. Baumana, 2014, no. 3, pp. 59–94. (In Russian)
12. Kichzhi A.S., Girutsky O.I., Esxenovsky-Lashkov Ju.K. [Kühlsystem des Strönunosgetriebes und der Hydraulikbremse von Transportfahrzeugen], Deutsche Demokratische Republik AMT Patentschrift no. 133844, 24.01.79, int. Cl. F 16 H 41/30.
13. Tamoyan G.S., Nurmukhametov M.I. [Experimental studies of an automotive electrodynamic retarder with a massive disk rotor]. Trudy MEI. Elektricheskie mashiny, 1972, no. 138, pp. 118–119. (In Russian)
14. Global Vehicle Retarder Market, 2017. Available at: https://in.pinterest.com/pin/415597871853915337/ (accessed 04 August 2020).
Author(s):
Korovkin I.A., PhD (Econ)
Executive Director1
Affiliated:
1NP “Association of Russian Automakers”, Moscow 127106, Russian Federation
For citation:
Korovkin I.A. [On the issue of spare parts circulation in the Russian Federation]. Trudy NAMI, 2020, no. 4 (283), pp. 27–31. DOI: 10.51187/0135-3152-2020-4-27-31. (In Russian)
Received:
2020.09.04
Published:
2020.12.07
Abstract:
Introduction. The tendency to a long inexpensive maintenance and repair of the car has led to the widespread application of parts, assemblies and assemblies from the out-of-service cars. As a result, vehicles with unpredictable safety indicators appeared on the road.
The purpose of the study was to find ways to reduce the negative impact of previously used spare parts on the road safety.
Methodology and research methods. The analysis of the used spare parts made it possible to determine the legal conditions of their practical application.
Results. The legislative regulation ways of spare parts and remanufactured units use have been proposed.
Practical significance. Road safety and economic efficiency of small businesses in the field of maintenance and repair of wheeled vehicles will be improved.
Key words:
disposal
refurbishment
auto components
spare parts
References:
1. [RD 37.009.026-92 Regulations on the maintenance and repair of vehicles owned by citizens (cars and trucks, buses, minitractors)]. Moscow, Ministry of Industry of the Russian Federation, Department of Automotive Industry, 1992. (In Russian)
2. [Information service of the JETRO Representative Office in Moscow. “Vehicle recycling business in Japan”]. Zhurnal avtomobil’nykh inzhenerov, 2007, no. 6 (47). (In Russian)
3. [Technical Regulations of the Customs Union “On the safety of wheeled vehicles” no. 018/2011]. (In Russian)
4. UN Regulation No. 133. Uniform provisions concerning the approval of motor vehicles with regard to their reusability, recyclability and recoverability. Available at: http://www.unece.org/fileadmin/DAM/trans/main/wp29/wp29regs/2015/R133e.pdf (accessed 04 September 2020).
5. [Agreement on the Adoption of Harmonized United Nations Technical Regulations for Wheeled Vehicles, Items of Equipment and Parts That Can Be Fitted and / or Used on Wheeled Vehicles, and on the Conditions for the Reciprocal Recognition of Approvals Based on These Requirements]. UN, 1998. (In Russian)
6. [Federal Law of 07.02.1992 No. 2300-1 “On Protection of Consumer Rights” (revision from 24 April 2020)]. (In Russian)
Author(s):
Chichekin I.V., PhD (Eng)
associate professor1
Levenkov Ya.Yu., PhD (Eng)
associate professor1
Vol’skaya N.S., D.Sc. (Eng)
professor1
Shiryaev K.N., design engineer of department “Tractors” of the Center “Tractors and Vehicles”2
Yastrebov G.Yu., PhD (Eng)
associate professor3
Affiliated:
1Department “Wheeled vehicles”, Bauman Moscow State Technical University, Moscow 105005, Russian Federation
2Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
3Department “Ground Transport Systems”, Rubtsovsk Industrial Institute (branch) of Altai State Technical University named after I.I. Polzunov, Rubtsovsk 658207, Russian Federation
For citation:
Chichekin I.V., Levenkov Ya.Yu., Vol'skaya N.S., Shiryaev K.N., Yastrebov G.Yu. [Modeling the high cross-country motion ability of a wheeled vehicle on deformable soil]. Trudy NAMI, 2020, no. 4 (283), pp. 32–41. DOI: 10.51187/0135-3152-2020-4-32-41. (In Russian)
Received:
2019.04.17
Published:
2020.12.07
Abstract:
Introduction. The improvement of the wheeled vehicles (WV) design intended for operation in areas with a poorly developed road network is an important task. The increase of vehicle operation efficiency allows significant reducing both the cost of freight traffic to remote areas of our country and development of new territories. The variety of soil surfaces on the territory of the Russian Federation makes it difficult to choose vehicle parameters at the early stages of vehicle design. Thanks to the high level of computer technology development, it is advisable to use the methods of WV motion simulation.
Purpose of the study. The use of new approaches to the interaction calculation parameters of a wheel propeller with the ground, when the main features of the WV design are taken, allows to more accurately model the process of vehicle movement on a soil surface and take into consideration the mutual influence of various systems on the vehicle's cross-country ability when driving on deformable supporting surfaces.
Methodology and research methods. The article presents a method for imitating the motion of a high passability WV on the deformable soil. The method is based on the principle of creating a mathematical model of WV in the environment of rigid body dynamics, extended by new models. The interaction modeling peculiarities of an elastic tire with deformable soil are to create an additional dynamic sphere. The algorithm of this sphere uses a model of the elastic tire interaction with deformable soil, developed by Professor Ya.S. Ageikin and supplemented by his students.
Scientific novelty and results. The article considers an example of rectilinear motion of a WV on loam, the results of the study are presented. The approach makes it possible to comprehensively investigate the passability of the WV when moving on deformable support surfaces. The mathematical model takes into account the main WV systems and their characteristics: engine, transmission, power flow distribution mechanisms (differentials) and their condition, wheel propeller, massive inertial properties of WV links.
Practical significance. The developed method makes it possible to analyze the passability of, both existing and newly developed WVs. It also allows you to study the mutual influence of WV systems on the ability to move on various soil surfaces. At that the loads on the load-bearing elements of the WVs are determined, the loading history for resource assessment included.
Key words:
wheeled vehicle of high cross-country ability
road and soil conditions
mutual deformations of the tire and soil
calculation of the dynamics of solids
dynamic processes “tire – soil”
References:
1. Ageykin Ya.S. [All-terrain wheeled and combined propulsors. Theory and calculation]. Moscow, Mashinostroenie Publ., 1972. 184 p. (In Russian)
2. Ageykin Ya.S. [Passability of vehicles]. Moscow, Mashinostroenie Publ., 1981. 232 p. (In Russian)
3. Bekker M.G. Introduction to terrain-vehicle systems. Ann Arbor, University of Michigan Press, 1969. 520 p.
4. Wong J.Y. Theory of Ground Vehicles. New York, Wiley IEEE, 2001. 560 p.
5. Babkov V.F., Birulya A.K., Sidenko V.M. [Ground passability of wheeled vehicles]. Moscow, Avtotransizdat Publ., 1959. 189 p. (In Russian)
6. Barakhtanov L.V., Belyakov V.V., Kravets V.N. [Passability of vehicle]. Nizhny Novgorod, NGTU Publ., 1996. 200 p. (In Russian)
7. Larin V.V. [Theory of motion of all-wheel drive vehicles: textbook]. Moscow, BSTU Publ., 2010. 391 p. (In Russian)
8. Kotiev G.O., Sharipov V.M., Shchetinin Yu.S., Khashem M.Sh. [Selection of low pressure tires for agricultural tractors and all-terrain vehicles]. Sovremennye tendentsii razvitiya nauki i tekhnologiy, 2016, issue 7-2, pp. 46–51. (In Russian)
9. Gorbatovskiy A.V., Kotiev G.O., Chulyukin A.O., Vasil’ev V.V. [Theoretical study of slipping of propulsor at the beginning of car movement on the deformable ground, equipped with different types of transmissions]. Zhurnal avtomobil’nykh inzhenerov, 2016, no. 2, pp. 12–14. (In Russian)
10. Gorelov V.A., Padalkin B.V., Chudakov O.I. [Mathematical model of linear motion on the deformable supporting surface of the two-link road train with an active semitrailer]. Vestnik Moskovskogo gosudarstvennogo tekhnicheskogo universiteta im. N.E. Baumana. Seriya “Mashinostroenie”, 2017, no. 2, pp. 121–138. (In Russian)
11. Padalkin B.V., Gorelov V.A., Chudakov O.I. [Increasing of road train energy efficiency in heavy road conditions by means of rational parameters selection of trailer drive system]. Trudy NAMI, 2017, no. 1 (268), pp. 60–66. (In Russian)
12. Gorelov V.A., Kartashov A.B., Kovtun K.I., Komissarov A.I. [Development of a mathematical model of an articulated cross-country vehicle for the Arctic zones of the Russian Federation, regions of the Far North and the Far East]. Izvestiya Moskovskogo gosudarstvennogo tekhnicheskogo universiteta MAMI, 2017, no. 2 (32), pp. 16–24. (In Russian)
13. Kosharnyy N.F. [Technical and operational properties of cross-country vehicles]. Kiev, Vishcha shkola Publ., 1981. 207 p. (In Russian)
14. Shukhman S.B., Solov’ev V.I., Prochko E.I. [The theory of power drive of wheels of cross-country vehicles]. Moscow, Agrobiznestsentr Publ., 2007. 333 p. ISBN 978-5-902792-15-4. (In Russian)
15. Volskaya N.S., Zhileykin M.M. and Zakharov A.Y. Mathematical model of rolling an elastic wheel over deformable support base. IASF-2017. IOP Conf. Series: Materials Science and Engineering 315 (2018) 012028. DOI: 10.1088/1757-899X/315/1/012028.
16. Ageykin Ya.S., Vol’skaya N.S., Chichekin I.V. [Passability of vehicle]. Moscow, MGIU Publ., 2010. 275 p. (In Russian)
17. Vol’skaya N.S. [Development of methods for calculating the support and traction characteristics of wheeled vehicles for the required road and soil conditions in the areas of operation. Dr. eng. sci. diss. abstr.]. Moscow, BSTU, 2008. 35 p. (In Russian)
18. Chichekin I.V. [Development of spatial dynamic models of wheeled vehicles for the analysis of passability when driving on uneven ground surfaces. Cand. eng. sci. diss. abstr.]. Moscow, Moscow State Industrial University, 2010. 25 p. (In Russian)
19. Sapozhnikov V.V. [A method for assessing the passability of multi-wheeled vehicles of heavy carrying capacity along the surveyed routes on layered soils. Cand. eng. sci. diss. abstr.]. Moscow, Technical University at the ZIL, 1985. 18 p. (In Russian)
20. Yastrebov G.Yu. [Assessment of traction capabilities of wheeled vehicles on soils with low bearing capacity. Cand. eng. sci. diss. abstr.]. Moscow, Moscow Automotive Industry Institute, 1990. 17 p. (In Russian)
21. Kul’chitskiy-Smetanka V.M. [Assessment of the dynamics of interaction of a wheeled vehicle with an uneven ground surface. Cand. eng. sci. diss.]. Moscow, Moscow State Industrial University, 2002. 180 p. (In Russian)
22. Vol’skaya N.S., Kuznetsov A.V., Levenkov Ya.Yu., Palaguta K.A., Shiryaev K.N. [Automated test stand for determining the soil deformation under cyclic interaction with an elastic wheel]. Trudy FGUP “NPTsAP”. Sistemy i pribory upravleniya, 2016, no. 3, p. 19–27. (In Russian)
23. Vol’skaya N.S., Ageykin Ya.S., Chichekin I.V., Shiryaev K.N. [Method for determining the depth of the track under the wheels of a multi-axle vehicle, taking into account the physical and mechanical state of the soil]. Zhurnal avtomobil’nykh inzhenerov, 2013, no. 2 (79), pp. 22–25. (In Russian)
24. Babiychuk A.E., Ageykin Ya.S., Vol’skaya N.S. [Method for determining the rolling power losses of a wheel propeller taking into account the type of transmission and air pressure in the tires of the machine]. Zhurnal avtomobil’nykh inzhenerov, 2013, no. 2 (79), pp. 44–47. (In Russian)
25. Chichekin I.V., Levenkov Ya.Yu., Zuenkov P.I., Maksimov R.O. [The formation of the law of steering angle control to maintain a given vehicle trajectory]. Trudy NAMI, 2019, no. 3 (278), pp. 53–61. (In Russian)
Author(s):
Biksaleev R.Sh., postgraduate1
Karpukhin K.E., PhD (Eng), associate professor
project director1
Klimov A.V., PhD (Eng)
Senior Lecturer1
Malikov R.R., postgraduate1
Affiliated:
1Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
2Moscow Automobile and Road Construction State Technical University (MADI), Moscow 125319, Russian Federation
For citation:
Biksaleev R.Sh., Karpukhin K.E., Klimov A.V., Malikov R.R. [Thermostating system simulation model of the passively cooled traction battery]. Trudy NAMI, 2020, no. 4 (283), pp. 42–51. DOI: 10.51187/0135-3152-2020-4-42-51. (In Russian)
Received:
2020.08.13
Published:
2020.12.07
Abstract:
Introduction. Electrified vehicles (EVs) have been actively developed in the Russian Federation megalopolises in recent years. Due to the specific climatic conditions of our country, EVs manufacturers encounter difficulties in the design and creation of simulation models, as well as in the model design selection. The main criterion for the safety and degree of degradation (SoH) of a traction battery (TB) is the temperature range in which it is operated.
The purpose of the study was to calculate the thermal state of TB when exposed to extreme temperatures in a given region.
Methodology and research methods. The research method is the creation of a TB thermostating system model, as well as the analysis of the climatic conditions of the region.
Scientific novelty and results. The operating temperature affects the operational characteristics of the EVs, in particular, the mileage on one charge, the degree of capacity reduction during operation, and other technical parameters of the TB. In turn, the creation of complex cooling schemes is not economically feasible both during production and maintenance of electrical vehicles. Taking into account the climatic conditions of our country, the possible regions of operation were selected. The article provides a sequence of design cases selection for the simulation model. After determining the design and heating parameters of the TB, a full factorial experiment was partially used to assess the efficiency of the thermostating system with passive cooling. The discharge currents and the state of charge components of the traction electrical equipment were obtained as well as the state of charge for a single battery, including TB while simulating the operation and the movement of an EV.
Practical significance. The article highlights the problems of safe long-term operation, and also indicates the optimal, working and critical temperature ranges during the operation of single lithium-ion batteries.
Key words:
electrified vehicles
simulation
passive battery cooling
electromobile
lithium-ion battery
References:
1. Bakhmutov S.V., Gaysin S.V., Terenchenko A.S., Karpukhin K.E., Kurmaev R.Kh., Zinov’ev E.V. [Method for increase of energy efficiency of electromobile transport]. Zhurnal avtomobil’nykh inzhenerov, 2015, no. 4 (93), pp. 4–10. (In Russian)
2. Warner J. The Handbook of Lithium-Ion Battery Pack Design. Amsterdam, Boston, Heidelberg, London, New York, Oxford, Paris, San Diego, San Francisco, Singapore, Sydney, Tokyo: Elsevier, 2015..
3. Karnatsevich I.V., Berezin E.B. [New calculated characteristics of air temperature and its statistical forcasting]. Omskiy nauchnyy vestnik, 2009, no. 84, pp. 79–82. (In Russian)
4. Schmidt G., Hansen J., Menne M., Persin A., Rue R. Improvements in the GISTEMP uncertainty model. J. Geophys. Res. Atmos, 2019, no. 124 (12), pp. 6307–6326.
5. Kurmaev R.Kh., Terenchenko A.S., Karpukhin K.E., Struchkov V.S., Zinov’ev E.V. [Methods of support of required temperature of high-voltage storage batteries of electromobiles and automobiles with combined power plants]. Vestnik mashinostroeniya, 2015, no. 6, pp. 52–55. (In Russian)
6. Rusin Yu.S., Glikman I.Ya., Gorskiy A.N. [Directory. Electromagnetic elements of radio electronic equipment]. Moscow, Radio i svyaz’ Publ., 1991. 224 p. (In Russian)
7. Slabospitskiy R.P., Khazhmuradov M.A., Luk’yanova V.P. [Analysis of promising battery cooling systems]. Radioelektronika i informatika, 2013, no. 2 (61), pp. 8–12. (In Russian)
[“Raspisanie Pogody” Ltd, Weather archive in Moscow (VDNKh) Meteorological station no. 27612]. Available at: https://rp5.ru/%D0%90%D1%80%D1%85%D0%B8%D0%B2_%D0%BF%D0%BE%D0%B3%D0%BE%D0%B4%D1%8B_%D0%B2_%D0%9C%D0%BE%D1%81%D0%BA%D0%B2%D0%B5(%D0%92%D0%94%D0%9D%D0%A5) (accessed 19 June 2020). (In Russian)
Author(s):
Kositsyn B.B., PhD (Eng)1
Affiliated:
1 Department “Wheeled vehicles”, Bauman Moscow State Technical University, Moscow 105005, Russian Federation
For citation:
Kositsyn B.B. [The effect of an additional braking system on the working brakes loading and the average speed of highly mobile wheeled vehicles and its assessment]. Trudy NAMI, 2020, no. 4 (283), pp. 52–61. DOI: 10.51187/0135-3152-2020-4-52-61. (In Russian)
Received:
2020.10.26
Published:
2020.12.07
Abstract:
Introduction. The main property to assess in multi-purpose wheeled vehicles is their mobility, characterized by cross-country pass ability, high-speed and autonomy. At the same time, the main factor of assessment is the high speed (high average speed) which can ensure a high wheeled vehicles mobility. One of the promising ways to increase the speed of highly mobile wheeled vehicles is to increase their braking efficiency due to the use of an additional deceleration system preserving the service brake system operability during intensive driving..
The purpose of the study was to increase the mobility speed of wheeled vehicles by improving the braking properties with the help of an additional braking system.
Methodology and research methods. A set of full-scale mathematical modeling was used to assess the additional braking system effect on the working brakes loading and the average speed of highly mobile wheeled vehicles in the totality of road and soil conditions. The use of the mathematical modeling complex made it possible to study and control the movement of a car by a driver-operator along statistically specified routes in “real time”. The following indicators were used to assess the additional braking system effectiveness: the working brakes temperature; reduction of energy dissipated by the service braking system during the drive; the dependence of the average travel speed on the transmission units effecting its deceleration.
Scientific novelty and results. The method presented in this work allowed assessing the effect of the additional braking system on the working brakes load and the average speed of highly mobile wheeled vehicles motion at the design stage in the conditions close to real operation.
Practical significance. The high efficiency of the additional braking system application for highly mobile wheeled vehicles has been proven. The degree of the working brake system loading reduction, as well as the level of the considered machines average speed in the totality of road conditions were determined.
Key words:
mobility
speed
wheeled vehicle
complex of full-scale mathematical modeling
additional braking system
service braking system
References:
1. Kotiev G.O., Gumerov I.F., Stadukhin A.A., Kositsyn B.B. [Determination of the mechanical characteristics of the units of the wear-resistant brake system of highly mobile wheeled vehicles]. Trudy NGTU im. R.E. Alekseeva, 2020, no. 1 (128), pp. 131–141. (In Russian)
2. Kositsyn B.B., Kotiev G.O., Miroshnichenko A.V., Padalkin B.V., Stadukhin A.A. [Characterization of transmissions of wheeled and tracked vehicles with individual drive wheels]. Trudy NAMI, 2019, no. 3 (278), pp. 22–35. (In Russian)
3. Skotnikov G.I., Jileykin M.M., Komissarov A.I. Increasing the stability of the articulated lorry at braking by locking the fifth wheel coupling. IOP Conference Series: Materials Science and Engineering. 2017 International Automobile Scientific Forum, IASF 2017, Volume 315, Issue 1, 22 February 2018.
4. Chudakov O.I., Gorelov V.A., Gartfelder V.A., Sekletina L.S. Mathematical model of curvilinear motion of an active road train with electromechanical transmission. IOP Conference Series: Materials Science and Engineering. 2019 International Automobile Scientific Forum on Technologies and Components of Land Intelligent Transport Systems, IASF, Volume 819, Issue 1, 29 May 2020.
5. Chudakov O.I., Gorelov V.A. Design features of the steering control systems of road trains and articulated buses. IOP Conference Series: Materials Science and Engineering. International Conference on Modern Trends in Manufacturing Technologies and Equipment 2019, ICMTME 2019, Sevastopol. Volume 709, Issue 4, 3 January 2020.
6. Rozhdestvenskiy Yu.L., Mashkov K.Yu. [On the formation of reactions when an elastic wheel rolls on a non-deformable base]. Trudy MVTU, 1982, no. 390, pp. 56–64. (In Russian)
7. Zhukov I.S., Dygalo V.G. [Assessment of the thermal loading of friction pairs of the automated braking system of a vehicle]. Trudy NGTU im. R.E. Alekseeva, 2018, no. 3 (122), pp. 147–152. (In Russian)
8. Aleksandrov M.P., Lysyakov A.G., Fedoseev V.N., Novozhilov M.V. [Braking devices: Directory. Ed. by Aleksandrov M.P.]. Moscow, Mashinostroenie Publ., 1985. 312 p. (In Russian)
9. Shalygin A.S., Palagin Yu.I. [Applied methods of statistical modeling]. Leningrad, Mashinostroenie Publ., Leningrad branch, 1986. 320 p. (In Russian)
Author(s):
Shelginskikh I.N.,
head sector “Integration” of the department of active security systems of the Center “Intelligent Systems”1
Bokarev A.I., PhD (Eng)
leading design engineer, Center “Numerical Analysis and Virtual Validation”1
Affiliated:
1 Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Shelginskikh I.N., Bokarev A.I. [A comprehensive development methodology for testing and evaluating algorithms for a vehicle suspension control system]. Trudy NAMI, 2020, no. 4 (283), pp. 62–71. DOI: 10.51187/0135-3152-2020-4-62-71. (In Russian)
Received:
2020.07.14
Published:
2020.12.07
Abstract:
Introduction. Full-scale tests remain the most important quality indicator of the developed design solutions. At the same time, high-performance simulation computational systems are becoming more and more relevant, which can significantly reduce field tests of newly developed prototypes of vehicles. The task of building a transparent connection between full-scale and virtual tests is always relevant for a high-quality and effective study of the tested object behavior. This article touches on topical engineering issues in the development of complex assessment techniques for controlled vehicle systems.
The purpose of the study was to solve the problem of the cumulative assessment of various control algorithms for the suspension system for solving the integration problem of comparing control algorithms, regardless of their implementation. The results of solving this problem are recommendations for improving the vehicle movement algorithms in various conditions and modes.
Methodology and research methods. The article provides a rationale and general description of a comprehensive methodology for a controlled suspension system for a vehicle chassis, a sequence of planning experiments and the analysis of the results achieved. The sequence of construction of the estimated “conflict diagram” (Carpet plot) from the test data is given. The analysis of the results is presented and considered in the diagram as an example.
Scientific novelty and results. The approaches outlined in the article were used by the authors at the initial stages of the controlled chassis suspension system development, which made it possible to improve the quality and efficiency of the achieved result in the shortest possible time. The developed and approved comprehensive test method and methods for assessing the controlled chassis suspension system is a scientific novelty, since such methods and approaches have not been used before.
Practical significance. The developed complex test methodology and assessment methods are used at FSUE “NAMI” at the initial stages of designing controlled chassis suspension systems.
Key words:
smoothness and safety criteria
simulation
controlled suspension systems
References:
1. Khachaturov A.A. [System dynamics tire – road – vehicle – driver]. Moscow, Mashinostroenie Publ., 1976. 536 p. (In Russian)
2. Van Iersel S.S. Passive and semi-active truck cabin suspension systems for driver comfort improvement. Eindhoven, Eindhoven University of Technology, Department of Mechanical Engineering Dynamics & Control, 2010. 90 p.
3. Hrovat D. Survey of Advanced Suspension Developments and Related Optimal Control Application. Automatica, 1997, vol. 33, no. 10, pp. 1781–1817.
4. Guido P.A.K. Adaptive Control of Mechatronic Vehicle Suspension system: Doktor-Ingenieurs genehmigten Dissertation. Munchen, 2011. 250 p.
5. Agrawal A. Performance Improvement of Automotive Suspension Systems using Inerters and an Adaptive Controller: Master of Applied Science in Mechanical and Mechatronics Engineering. Ontario, University of Waterloo, 2013. 84 p.
6. Pevzner Ya.M. [Vibrations of the vehicle. Test and research]. Moscow, Mashinostroenie Publ., 1979. 208 p. (In Russian)
7. Zhileykin M.M. [Increasing the speed of multi-axle vehicles by adaptive control of elastic-damping elements of the suspension system. Dr. eng. sci. diss.]. Moscow, BMSTU, 2012. 280 p. (In Russian)
8. Zheglov L.F. [Spectral method for calculating suspension systems for wheeled vehicles: textbook. Moscow, BMSTU Publ., 2013. 210 p. (In Russian)
9. Rotenberg R.V. [Vehicle suspension. Oscillation and smoothness]. Moscow, Mashinostroenie Publ., 1972. 394 p. (In Russian)
10. Shelginskikh I.N. [Analysis of measuring the ride and driving safety applied in a vehicle suspension controlled system]. Trudy NAMI, 2018, no. 4 (275), pp. 98–104. (In Russian)
11. Road and off-Road Vehicle System dynamics. Handbook. Edited by Mastinu G. and Ploechl M. Taylor & Francis Group, LLC, 2014. 1708 p.
12. Van der Sande T.P.J. Control of semi-active suspension and steer-by-wire for comfort and handling. Eindhoven, HTAS Technische Universiteit Eindhoven, 2005. 164 p.
13. Belousov B.N., Shukhman S.B. [Applied mechanics of ground traction vehicles with mechatronic systems. Monograph. Ed. by Belousov B.N.]. Moscow, Agrokonsalt Publ., 2013. 612 p. (In Russian)
Автор(ы):
Ulchenko I.A.,
postgraduate
software engineer of the Center “Intelligent Systems”1
Affiliated:
1 Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Ulchenko I.A. [Comparative study of path-tracking regulators based on a geometric method]. Trudy NAMI, 2020, no. 4 (283), pp. 72–81. DOI: 10.51187/0135-3152-2020-4-72-81. (In Russian).
Received:
2020.08.25
Published:
2020.12.07
Abstract:
Introduction. The article describes elaboration, modeling and comparative study of vehicle path-tracking regulators based on a geometric method. Regulators of this type belong to the major components of vehicle driving automation systems. Estimation of the regulators’ accuracy and control quality was carried out in different driving conditions using a mathematical model of vehicle dynamics whose adequacy was substantiated through a comparison with experimental data.
The purpose of the study is to develop the path-tracking regulators based on a geometric method and perform a comparative analysis of these regulators.
Methodology and research methods. The performance of the path-tracking regulators was analyzed with methods of automatic control theory. The testing of the regulators was carried out using a mathematical model of vehicle dynamics. The model accuracy was estimated using root mean square errors and maximum differences between the simulation results and the experimental data.
Scientific novelty and results. The conducted study allowed drawing a number of conclusions regarding the operating quality and accuracy of the path-tracking regulators based on the geometric method.
Key words:
vehicle automated driving systems
path-tracking regulators
geometric control method
mathematical modeling
References:
1. Eskandarian A. Handbook of Intelligent Vehicles. – London: Springer-Verlag London, 2012. – 1599 p.
2. Bishop R. Intelligent Vehicle Technology and Trends. – Norwood: Artech House Publishers, 2005. – 210 p.
3. Koh K.C., Cho H.S. A path tracking control system for autonomous mobile robots: an experimental investigation // Mechatronics. – 1994. – Vol. 4 (8). – P. 799–820.
4. Barton M.J. Controller Development and Implementation for Path Planning and Following in an Autonomous Urban Vehicle // Australian Centre for Field Robotics. – 2001. – P. 1–153.
5. Coulter R.C. Implementation of the Pure Pursuit Path Tracking Algorithm. Carnegie Mellon University, 1992. – P. 1–15.
6. Wit J.S. Vector Pursuit Path Tracking for Autonomous Ground Vehicles: PhD thesis. – University of Florida, 2000. – 314 p.
7. Thrun S., Montemerlo M. Stanley: The robot that won the DARPA grand challenge // Journal of Field Robotics. – 2006. – Vol. 23 (9). – P. 661–692.
8. Snider J.M. Automatic Steering Methods for Autonomous Automobile Path Tracking. – Carnegie Mellon University, 2009. – P. 1–78.
9. Guldner J., Tan H., Pathwardhan S. Analysis of Automatic Steering Control for Highway Vehicles with Look-down Lateral Reference Systems // Vehicle System Dynamics: International Journal of Vehicle Mechanics and Mobility. – 1996. – Vol. 26 (4). – P. 243–269.
10. Kulikov I., Ulchenko I. Performance analysis of the sliding mode control for automated vehicle path tracking at low adhesion surfaces // ICTLE 2019. – 2019. – 5 p.
11. Kulikov I., Ulchenko I., Chaplygin A. Using Real World Data in Virtual Development and Testing of a Path Tracking Controller for an Autonomous Vehicle // International Journal of Innovative Technology and Exploring Engineering (IJITEE). – 2019. – Vol. 8 (12). – P. 720–726.
12. Hellström T., Ringdahl O. Follow the Past: a pathtracking algorithm for autonomous vehicles // International Journal of Vehicle Autonomous Systems. – 2006. – Vol. 4. – P. 216–224.
Author(s):
Ter-Mkrtich’yan G.G.,
D.Sc. (Eng)
head of department “Fuel Systems”1
Mikerin N.A.,
design engineer of department “Fuel Systems”1
Glaviznin V.V.,
head of the division for the design and prototyping of fuel control systems of department “Fuel Systems”1
Balashov D.Yu.,
chief specialist of department “Vehicles”1
Arabyan M.E.,
lead research engineer of department “Fuel Systems”1
Affiliated:
1 Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Ter-Mkrtich’yan G.G., Mikerin N.A., Glaviznin V.V., Balashov D.Yu., Arabyan M.E. [The thermodynamic system “fuel tank of a vehicle” energy model. Processes of unsteady heat transfer at constant fuel mass]. Trudy NAMI, 2020, no. 4 (283), pp. 82–93. DOI: 10.51187/0135-3152-2020-4-82-93. (In Russian)
Received:
2020.09.08
Published:
2020.12.07
Abstract:
Introduction. Along with the toxic substances formed during the combustion of fuel in the engine, a certain amount of hydrocarbons is emitted by a vehicle into the atmosphere in the form of fuel vapors evaporated from the fuel tank and fuel system components. The energy balance in the fuel tank determines the overall level and change in fuel temperature. The higher their values, the more vapors are formed in the fuel tank, which increases the load on the fuel vapor recovery system.
The purpose of the study was to develop an energy model of a vehicle fuel tank describing the nonstationary heat transfer processes for steadily operating modes; formulate criteria for the fuel tank energy efficiency depending on the formation of fuel vapors.
Methodology and research methods. The analysis of heat fluxes supplied to and removed from the fuel tank has been carried out. As a result of solving the energy balance equation the thermal properties parameters of the fuel tank were obtained.
Scientific novelty and results. The change in the temperature of the fuel in the tank has been substantiated in accordance to the time determined by the exponential law. Complex parameters were proposed, the main of which were: equilibrium temperature head, time constant, maximum of temperature speed and heat flux supplied to the fuel, as well as the value of the temperature head flux developed during one hour of idling – hourly fuel consumption.
Practical significance. The results of six variants of “UMP” family sedan cars testing, differing in characteristic parameters of fuel tanks and fuel modules, have been presented. It is shown that the implementation of gasoline pumps frequency control can reduce fuel heating by 30%..
Key words:
low-pressure fuel system
fuel tank
energy balance
heat flow
equilibrium temperature
temperature head
time constant
fuel pump control
References:
1. Saykin A.M., Ter-Mkrtich'yan G.G., Karpukhin K.E., Pereladov A.S., Zhuravlev A.V., Yakunova E.A. [Ecological problems of modern transport vehicles including electromobiles]. Vestnik mashinostroeniya, 2017, no. 2, pp. 84–87. (In Russian)
2. Saykin A.M., Ter-Mkrtichyan G.G., Karpukhin K.E., Pereladov A.S., Zhuravlev A.V., Yakunova E.A. Air quality within vehicles. Russian Engineering Research, 2017, vol. 37, no. 5, pp. 424–427.
3. Matyukhin L.M., Prishvin S.A., Ter-Mkrtich’yan G.G. [Heat and gas supply and ventilation with the basics of heat engineering. Textbook.]. Moscow, MADI (TU) Publ., 2016. 136 p. (In Russian)
4. Arabyan M.E., Glaterman A.V., Nikitin A.A., Polikarpov V.V., Starkov E.E., Ter-Mkrtich’yan G.G. [Twochamber fuel tank]. Patent RF, no. 2633090, 2016. (In Russian)
5. Glaterman A.V., Ter-Mkrtich’yan G.G., Nikitin A.A., Terenchenko A.S., Balashov D.Yu., Arabyan M.E. [Two-chamber vehicle fuel tank]. Utility model patent RF No. 190796, 2019. (In Russian)
6. Ter-Mkrtich’yan G.G., Terenchenko A.S., Balashov D.Yu., Glaterman A.V., Arabyan M.E. [The main flow dependencies of the pumps in low-pressure fuel systems in tanks of complex configuration]. Trudy NAMI, 2018, no. 4 (275), pp. 57–66. (In Russian)
7. Ter-Mkrtich’yan G.G., Terenchenko A.S., Balashov D.Yu., Glaterman A.V., Arabyan M.E. [Comparative analysis of automobile engines low-pressure fuel systems controlling on the basis of material and energy balances]. Trudy NAMI, 2019, no. 1 (276), pp. 12–22. (In Russian)
Author(s):
Kozlov A.V.,
D.Sc. (Eng)
head of department1
Milov K.V.,
postgraduateengineer1
Affiliated:
1 Department “Energy-saving technologies and alternative fuel”, Center “Power units”, Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Kozlov A.V., Milov K.V. [Increasing the energy efficiency of the 6ChN13/15 duelfuel engine using the Miller thermodynamic cycle]. Trudy NAMI, 2020, no. 4 (283), pp. 94–100. DOI: 10.51187/0135-3152-2020-4-94-100. (In Russian)
Received:
2020.07.02
Published:
2020.12.07
Abstract:
Introduction. Currently, the issue of fuel efficiency, emissions regulation of harmful substances and the search for alternative fuels is especially relevant. The choice of natural gas for an engine as an alternative to traditional fuels imposes its limitations, which can be avoided by applying the Miller cycle.
The purpose of the study was to determine and compare the potential for improving 6ChN13/15 diesel engine converted for an energy efficient duel-fuel engine operating according to the Miller cycle with early closing of the intake valve and the engine potential of Otto thermodynamic cycle.
Methodology and research methods. The research was carried out by a natural experiment method.
Scientific novelty and results. A comparative analysis of various experimental results studies of engines thermodynamic cycles running on natural gas has been carried out. The results obtained will be used to create and further optimize a duel-fuel engine by controlling its workflow and the air supply system.
Practical significance. The indicators results of Otto engines and engines operating according to Miller's thermodynamic cycles with early closing of the intake valve have been compared. The results obtained may be of interest to truck manufacturers and engine specialists.
Key words:
internal combustion engine
natural gas
Otto's thermodynamic cycle
Miller's thermodynamic cycle
bench tests
References:
1. Aleksandrov A.A., Markov V.A. [Alternative fuels for internal combustion engines]. Moscow, NITs “Inzhener” Ltd. Publ., “Oniko-M” Ltd. Publ., 2012. 791 p. (In Russian)
2. Aslam M.U., Masjuki H.H., Kalam M.A., Abdesselam H., Mahlia T.M.I., Amalina M.A. An experimental investigation of CNG as an alternative fuel for a retrofitted gasoline vehicle. Fuel, 2006, vol. 85, pp. 717–724.
3. Kato T., Saeki K., Nishide H., Yamada T. Development of CNG fueled engine with lean burn for small size commercial van // JSAE Review. – 2001. – Vol. 22. – P. 365–368.
4. Luksho V.A. [Comprehensive method for improving the energy efficiency of gas engines with high compression ratios and shortened intake and exhaust strokes. Dr. eng. sci. diss.]. Moscow, 2015. 369 p. (In Russian)
5. Moro D., Ponti F., Serra G. Thermodynamic Analysis of Variable Valve Timing Influence on SI Engine Efficiency // SAE Paper. – 2001. – No. 2001-01-0667.
6. Bakhmutov S.V., Kozlov A.V., Luksho V.A., Terenchenko A.S. [Problematic issues of creation of highpowered gas and gas-diesel engines]. Mekhanika mashin, mekhanizmov i materialov, 2018, no. 4, pp. 13–23. (In Russian)
7. Wei H., Shao A., Hua J., Zhou L., Feng D. Effects of applying a Miller cycle with split injection on engine performance and knock resistance in a downsized gasoline engine // Fuel. – No. 214 (2018). – P. 98–107.
8. Ferrera M. Highly Efficient Natural Gas Engines // SAE Technical Paper. – 2017. – No. 2017-24-0059.
9. Kovacs D., Eilts P. Potentials of Miller Cycle on HD Diesel Engines Using a 2-Stage Turbocharging System // SAE Technical Paper. – 2018. – No. 2018-01-0383.
10. Liao S., Jiang D., Cheng Q. Determination of laminar burning velocities for natural gas // Fuel. – 2004. – No. 83. – P. 1247–1250.
11. Kozlov A.V., Terenchenko A.S. [Modern requirements to energy efficiency of vehicles and the analysis of technologies for their providing]. Zhurnal avtomobil’nykh inzhenerov, 2014, no. 1 (84), pp. 28–33. (In Russian)
Author(s):
Evdonin E.S.,
Head of Department for the Russian Federation
Dushkin P.V.,
PhD (Eng)Associate Professor2
Kuzmin A.I.,
Leading Engineer3
Affiliated:
1 ETAS GmbH, г. Штутгарт 70469, Германия
2 Moscow Automobile and Road Construction State Technical University (MADI), Moscow 125319, Russian Federation
3 Center for Electronic Devices, Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Evdonin E.S., Dushkin P.V., Kuzmin A.I. [Development and application of empirical models to optimize the control of an internal combustion engine]. Trudy NAMI, 2020, no. 4 (283), pp. 101–108. DOI: 10.51187/0135-3152-2020-4-101-108. (In Russian)
Received:
2020.07.03
Published:
2020.12.07
Abstract:
Introduction. The quality of the engine control units software (SW) significantly determines the output performance of the internal combustion engine (ICE). An important component of the software development process is its adaptation or calibration, which includes a large amount of work to select specific values of control actions to improve the performance of the internal combustion engine operating cycle under toxicity restrictions.
The purpose of the work was to reduce time and material costs during the initial calibration work.
Methodology and research methods. To achieve the goal the application of the calibration technique to the gasoline engine control system was proposed which was to be carried out by using empirical (obtained experimentally) ICE models. The main tool used in the work was the ASCMO software, which was used with ETAS technical support. The calibration process presented in the article was divided into stages: development of an experiment plan, testing (carried out on a gasoline engine model), analysis and processing of the results with the construction of an empirical ICE model, optimization of controlled influences and preparation of calibration maps taking into account the restrictions of harmful emissions during car cycle testing.
Scientific novelty and results. The technique of initial ICE calibration based on the use of an empirical engine model has been formulated. The presented results were obtained without taking into account the statutory norms and rules, the imposed restrictions were formed in an arbitrary way..
Practical significance. The presented method is of practical importance, since it allows to optimize labor costs for carrying out calibration work. A brief assessment of the effectiveness and applications of the technique is provided in the publication.
Key words:
ETAS
ASCMO
Matlab MBC
engine control system
optimization
experiment planning
calibration
empirical model
References:
1. Giryavets A.K. [Automotive gasoline engine control theory]. Moscow, Stroyizdat Publ., 1997. 161 p. (In Russian)
2. Yooshin Cho, Hube Th., Lauff U., Reddy R. Optimisation of gasoline engines automation and machine learning techniques in calibration // ATZelektronik worldwide. – 2017. – No. 03. – P. 48–53.
3. Farraen M.A., Rutledge J., Winward E. Using a statistical machine learning tool for diesel engine air path calibration // SAE Technical Paper. – 2014. – No. 2014-01-2391. – 17 p.
4. Sobol’ I.M. [Numerical Monte Carlo Methods]. Moscow, Nauka Publ., 1973. 311 p. (In Russian)
5. Farraen M.A. Benefiting from Sobol Sequences Experiment Design Type for Model-based Calibration // SAE Technical Paper. – 2015. – No. 2015-01-1640. – 5 p.
6. [Internal combustion engines. In 3 books. Book. 3. Computer workshop. Modeling processes in internal combustion engines. Ed. by Lukanin V.N. and Shatrov M.G.]. Moscow, Vysshaya shkola Publ., 2007. 414 p. (In Russian)
7. Savenkov N.V. [Method for choosing gear ratios of the power unit of a vehicle of category N1 based on the driving cycle. Cand. eng. sci. diss.]. Moscow, MADI, 2017. 206 p. (In Russian)
Author(s):
Sonkin V.I.,
engineer
head of the Research department for spark ignition engines of center “Power unit”1
Affiliated:
1Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Sonkin V.I. [Energy efficiency of automotive gasoline engine: current approaches]. Trudy NAMI, 2020, no. 4 (283), pp. 109–122. DOI: 10.51187/0135-3152-2020-4-109-122. (In Russian)
Received
2020.06.22
Published:
2020.12.07
Annotation:
Introduction. To meet the promising requirements fuel consumption and CO2 emissions of passenger cars and commercial vehicles of 2025–2030 further improvement of the design and workflow of a gasoline internal combustion engine (ICE) is required in the full range of the working map, especially at high loads.
The purpose of the study was to review and analyze ways to improve the indicator efficiency of a gasoline ICE and approaches aimed at increasing efficiency by reducing heat losses.
Methodology and research methods. The review of barriers to increasing the indicator efficiency of a gasoline ICE was based on the analysis of the ideal and real Otto cycle and the results of experimental and calculated foreign and domestic studies of recent years aimed at increasing fuel efficiency by reducing heat losses.
Scientific novelty and results. It was shown that effective new approaches to reduce the heat losses of the ICE of the future were: organization of combustion of a stoichiometric mixture diluted with a large amount of cooled recirculated exhaust gases (up to 25–35%) at high loads; increasing the ratio of the piston stroke to the cylinder diameter S/D to a value of the order of 1.5; the use of thin thermal barrier coatings that provide a “temperature swing” of the combustion chamber surface. Combined with proven modern technologies (direct fuel injection, variable valve drive, etc.), they can significantly increase the optimal geometric compression ratio, significantly reduce heat loss to the walls of the combustion chamber and the tendency of the ICE to detonate, and provide an increase in the indicator efficiency up to 49–53%.
The practical significance lies in the possibility of using the results of the work when choosing a scheme and design solutions for a promising gasoline ICE with reduced fuel consumption and CO2 emissions.
Key words:
gasoline engine
indicator efficiency
stroke-to-diameter ratio
thermal insulation
temperature swing coating
cooled exhaust gas recirculation
turbocharging
turbo lag
direct injection
References:
1. Insights into Future Mobility. A report from the Mobility of the Future study. – Cambridge, MA, 2019. – 220 р. URL: http://energy.mit.edu/insightsintofuturemobility (дата обращения: 22.06.2020)
2. Kutenev V.F., Sonkin V.I. [Analysis of vehicles electrical drive development trends]. Trudy NAMI, 2018, no. 2 (273), pp. 6–15. (In Russian)
3. Catalog der “Automibil Revue”. – Berne: Motorbuch Verlag, 1997–2019.
4. Sonkin V.I. [Downsizing gasoline engine – modern concept]. Trudy NAMI, 2015, no. 261, pp. 68–84. (In Russian)
5. Sonkin V.I. [High-pressure gasoline engine problems: turbo lag. Part 1]. Trudy NAMI, 2019, no. 4 (279), pp. 70–81. (In Russian)
6. [Automobile engines. Ed. by Howah M.S.]. Moscow, Mashinostroenie Publ., 1977. 591 p. (In Russian)
7. Heywood J.B. Internal Combustion Engine Fundamentals. – McGraw-Hill, Inc., 1988. – 930 р.
8. Ferguson C.R., Kirkpatrick A.T. Internal combustion engines: applied thermodynamics. – John Wiley & Sons, 2001. – 367 р.
9. Wu W., Ross M. Spark-Ignition Engine Fuel Consumption Modeling // SAE Technical Paper. – 1999. – No. 1999-01-0554. – P. 1–15.
10. Sonkin V.I. [Problems of the gasoline engine with high supercharging: abnormal combustion]. Trudy NAMI, 2017, no. 3 (270), pp. 16–31. (In Russian)
11. Caris D.F., Nelson E.E. A New Look at High Compression Engines // SAE Transactions. – 1959. – Vol. 67. – P. 112–124.
12. Muranaka S., Takagi Y., Ishida T. Factors Limiting the Improvement in Thermal Efficiency of SI Engine at Higher Compression Ratio // SAE Technical Paper. – 1987. – No. 870548. – P. 1–11.
13. Ayala F.A., Gerry M.D., Heywood J.B. Effects of Combustion Phasing, Relative Air-fuel Ratio, Compression Ratio, and Load on SI Engine Efficiency // SAE Technical Paper. – 2006. – No. 2006-01-0229. – P. 3–21.
14. Ozimov P.L., Vanin V.K. [On the problems and prospects of creating adiabatic diesel engines]. Avtomobil’naya promyshlennost’, 1984, no. 3, pp. 3–5. (In Russian)
15. Fujimoto H., Yamamoto H., Fujimoto M., Yamashita H. A Study on Improvement of Indicated Thermal Efficiency of ICE Using High Compression Ratio and Reduction of Cooling Loss // SAE Technical Paper. – 2011. – No. 2011-01-1872. – P. 1–14.
16. Kawaguchi A., Iguma H., Yamashita H., Takada N., Nidhikawa N., Yamashita C., Wakisaka Y., Fukui K. Thermo-Swing Wall Insulation Technology – A Novel Heat Loss Reduction Approach on Engine Combustion Chamber // SAE Technical Paper. – 2016. – No. 2016-01-2333.
17. Yan Z., Gainey B., Gohn J., Hariharan D., Saputo J., Schmidt C., Caliari F., Sampath S., Lawler B. The Effects of Thick Thermal Barrier Coatings on Low-Temperature Combustion // SAE Technical Paper. – 2020. – No. 2020-01-0275.
18. Kosaka H., Wakisaka Y., Nomura Y., Hotta Y., Koike M., Nakakita K., Kawaguchi A. Concept of “Temperature Swing Heat Insulation” in Combustion Chamber Walls, and Appropriate Thermo-Physical Properties for Heat Insulation Coat // SAE Technical Paper. – 2013. – No. 2013-01-0274. – P. 142–149.
19. Kogo T., Hamamura Y., Nakatani K., Toda T., Kawaguchi A., Shoji A. High Efficiency Diesel Engine with Low Heat Loss Combustion Concept – Toyota’s Inline 4-Cylinder 2,8-Liter ESTEC 1GD-FTV Engine // SAE Technical Paper. – 2016. – No. 2016-01-0658.
20. Gatti D., Jansons M. One-Dimensional Modelling and Analysis of Thermal Barrier Coating for Reduction of Coolling Loads in Military Vehicles // SAE Technical Paper. – 2018. – No. 2018-01-1112.
21. Nakata K., Nogawa S., Takahashi D., Yoshihara Y., Kamugai A., Suzuki T. Engine Technologies for Achieving 45% Thermal Efficiency of S.I. Engine // SAE Technical Paper. – 2015. – No. 2015-01-1896. – P. 179–192.
22. Sens M., Guenther M., Hunger M., Mueller J., Nicklitzsch S., Walther U., Zwahr S. Achieving the Max – Potential from a Variable Compression Ratio and Early Intake Valve Closure Strategy by Combination with a Long Stroke Engine Layout // SAE Technical Paper. – 2017. – No. 2017-24-0155. – P. 1–14.
23. Filipi Z.S., Assanis D.N. The effect of the stroke-tobore ratio on combustion, heat transfer and efficiency of a homogeneous charge spark ignition engine of given displacement // International Journal of Engine Research. – 2000. – Vol. 1, No. 2. – P. 191–208.
24. Ikeya K., Takazawa M., Yamada T., Park S., Tagishi R. Thermal Efficiency Enhancement of a Gasoline Engine // SAE Technical Paper. – 2015. – No. 2015-01-1263. – P. 1579–1586.
25. Cho S., Oh S., Song C., Shin W., Song S., Song H., Min K., Lee B., Jung D., Woo S. Effects of Bore-to-Stroke Ratio on the Efficiency and Knock Characteristics in a Single-Cylinder GDI Engine // SAE Technical Paper. – 2019. – No. 2019-01-1138.
26. Sonkin V.I. [Aerodynamics of intake ports: helical ports. Part 2]. Trudy NAMI, 2016, no. 4 (267), pp. 85–96. (In Russian)
27. Zvonov V.A. [Toxicity of internal combustion engines]. Moscow, Mashinostroenie Publ., 1973. 200 p. (In Russian)
28. Sonkin V.I. [Variable valve drive of vehicle engine]. Moscow, Mashinostroenie Publ., 2015. 124 p. (In Russian)
29. Yonekawa A., Ueno., Watanabe O., Ishikawa N. Development of New Gasoline Engine for ACCORD Plug-in Hybrid // SAE Technical Paper. – 2013. – No. 2013-01-1738. – P. 1–9.
30. Matsuo S., Ikeda E., Ito Y., Nishiura H. The New Toyota Inline 4 Cylinder 1.8L ESTEC 2ZR-FXE Gasoline Engine for Hybrid Car // SAE Technical Paper. – 2016. – No. 2016-01-0684. – P. 1–6.
31. Kawamoto N., Naiki K., Kawai T., Shikida T., Tomatsuri M. Development of New 1.8-Liter for Hybrid Vehicles // SAE Technical Paper. – 2009. – No. 2009-01-1061. – P. 1–9.
32. Bassett M., Vogler C., Hall J., Taylor J., Cooper A., Reader S. Analysis of the Hardware Requirements for a Heavily Downsized Gasoline Engine Capable of Whole Map Lambda 1 Operation // SAE Technical Paper. – 2018. – No. 2018-01-0975.
33. De Petris C., Diana S., Giglio V., Police G. High Efficiency Stoichiometric Spark Ignition Engines // SAE Technical Paper. – 1994. – No. 941933. – P. 1–9.
34. Takaki D., Tsuchida H., Kobara T., Akagi M., Tsuyuki T., Nagamine M. Study of an EGR System for Downsizing Turbocharged Gasoline Engine to Improve Fuel Economy // SAE Technical Paper. – 2014. – No. 2014-01-1199. – P. 1–8.
Author(s):
Ozimov P.L.
leading expert of the Expert Council1
Affiliated:
1 Federal State Unitary Enterprise “Central Scientific Research Automobile and Automotive Engines Institute” (FSUE “NAMI”), Moscow 125438, Russian Federation
For citation:
Ozimov P.L. [Engine]. Trudy NAMI, 2020, no. 4 (283), pp. 123–128. DOI: 10.51187/0135-3152-2020-4-123-128. (In Russian)
Received:
2020.10.05
Published:
2020.12.07