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Title of the article DEVELOPMENT OF ANTI-LOCK BRAKING SYSTEMS OF MODERN CARS, INCLUDING ELECTRIC VEHICLES AND HYBRID VEHICLES
Authors

BAKHMUTOV Sergey V., D. Sc. in Eng., Prof., Deputy CEO for Science (Research), FSUE “NAMI”, Moscow, Russian Federation, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

UMNITSYN Artem A., First Category Design Engineer of the Department “Combined Powerplants” of the Center “Powerplants”, FSUE “NAMI”, Moscow, Russian Federation, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.
In the section MECHANICAL ENGINEERING COMPONENTS
Year 2022
Issue 3(60)
Pages 42–51
Type of article RAR
Index UDK 629.3.017.5
DOI https://doi.org/10.46864/1995-0470-2022-3-60-42-51
Abstract The article provides an analytical overview of the development of automotive anti-lock braking systems (ABS). Some historical aspects of the development of automotive ABS are described. Examples of control algorithms for ABS actuators are given, which demonstrate the practical implementation of various control methods. The change of some technical characteristics of ABS and methods of their control is shown. Predictions are given for the development of anti-lock braking systems in the course of improving road transport and the transition from traditional cars with only an internal combustion engine to hybrid cars and electric vehicles. The experience of the FSUE “NAMI” is shown on the creation of ABS with combined actuators. The possibility of using electric drive machines for driving wheels to work as part of ABS actuators is investigated. Algorithms of joint control of friction braking mechanisms and electric machines have been developed. A set of theoretical and experimental studies of combined ABS actuators has been carried out, confirming the possibility of improving the braking characteristics of a car in various road conditions during emergency braking.
Keywords electric vehicle, anti-lock braking system, combined actuator, control algorithms, comparative evaluation of braking properties
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Bibliography
  1. Vlasov K.P. Teoriya avtomaticheskogo upravleniya [Theory of automatic control]. Kharkiv, Gumanitarnyy tsentr Publ., 2007. 526 p. (in Russ.).
  2. Mamdani E.H., Assilian S. An experiment in linguistic synthesis with a fuzzy logic controller. International journal of man-machine studies, 1975, vol. 7, iss. 1, pp. 1–13.
  3. Erjavec J. Automotive brakes. Delmar Cengage Learning, 2003. 471 p.
  4. Petrany M. Anti-lock brakes, the first technology to help you avoid a crash, turn 40. 2018. Available at: https://www.roadandtrack. com/car-culture/car-accessories/a22811340/anti-lockbrakes- the-first-technology-to-help-you-avoid-a-crash-turn-40/ (accessed 16 July 2022).
  5. ABS module. Available at: https://www.bosch-mobility-solutions. com/en/solutions/driving-safety/abs-module/ (accessed 16 July 2022).
  6. Choi S., Cho D.-W. Control of wheel slip ratio using sliding mode controller with pulse width modulation. Vehicle system dynamics, 1999, vol. 32, iss. 4–5, pp. 267–284.
  7. Wellstead P.E., Pettit N.B.O.L. Analysis and redesign of an antilock brake system controller. IEE Proceedings – Control theory and applications, 1997, vol. 144, iss. 5, pp. 413–426.
  8. Ryazantsev V.A. Metod sovershenstvovaniya upravleniya antiblokirovochnoy sistemoy avtomobilya pri individualnom regulirovanii tormoznykh mekhanizmov. Diss. kand. tekhn nauk [Method of improving the control of the anti-lock braking system of the car with individual regulation of braking mechanisms. Ph. D. Thesis]. Moscow, 2019. 166 p. (in Russ.).
  9. Drakunov S., Ozguner U., Dix P., Ashrafi B. ABS control using optimum search via sliding modes. Proceedings of 1994 33rd IEEE Conference on decision and control. Lake Buena Vista, 1994, vol. 1, pp. 466–471. DOI: https://doi.org/10.1109/CDC.1994.411013.
  10. Fang Y., Chu L., Shang M., Zhou F., Guo J. Identification and control of split-μ road for antilock braking system. Proc. 2010 2nd International conference on advanced computer control. Shenyang, 2010, pp. 298–301. DOI: https://doi.org/10.1109/ICACC.2010.5486616.
  11. Savitski D., Ivanov V., Augsburg K., Shyrokau B., Wragge-Morley R., Pütz T., Barber P. The new paradigm of an anti-lock braking system for a full electric vehicle: experimental investigation and benchmarking. Proceedings of the institution of mechanical engineers, Part D: Journal of automobile engineering, 2016, vol. 230, iss. 10, pp. 1364–1377. DOI: https://doi.org/10.1177/0954407015608548.
  12. Digital auto report 2019. Available at: https://www.strategyand. pwc.com/gx/en/insights/2019/digital-auto-report.html.
  13. Bera T.K., Bhattacharya K., Samantaray A.K. Bond graph model-based evaluation of a sliding mode controller for a combined regenerative and antilock braking system. Proceedings of the institution of mechanical engineers, Part I: Journal of systems and control engineering, 2011, vol. 225, iss. 7, pp. 918–934. DOI: https://doi.org/10.1177/2041304110394558.
  14. Zhang J.L., Yin C.L., Zhang J.W. Improvement of drivability and fuel economy with a hybrid antiskid braking system in hybrid electric vehicles. International journal of automotive technology, 2010, vol. 11, iss 2, pp. 205–213. DOI: https://doi.org/10.1007/s12239-010-0026-0.
  15. Mi C., Lin H., Zhang Y. Iterative learning control of antilock braking of electric and hybrid vehicles. IEEE transactions on vehicular technology, 2005, vol. 54, iss. 2, pp. 486–494. DOI: https://doi.org/10.1109/TVT.2004.841552.
  16. Umnitsyn A.A., Bakhmutov S.V. Otsenka vypolneniya trebovaniy deystvuyushchikh standartov v voprose effektivnosti antiblokirovochnoy sistemy elektromobilya s podderzhkoy smeshannogo tormozheniya [Evaluation of compliance with the current standards requirements regarding the anti-lock braking system effectiveness of an electric vehicle with mixed braking support]. Trudy NAMI, 2022, no. 2, pp. 51–59. DOI: https://doi.org/10.51187/0135-3152-2022-2-51-59.
  17. Fujimoto H., Saito T., Noguchi T. Motion stabilization control of electric vehicle under snowy conditions based on yaw-moment observer. Proc. the 8th IEEE International workshop on advanced motion control. Kawasaki, 2004, pp. 35–40. DOI: https://doi.org/10.1109/AMC.2004.1297637.
  18. Zhou Y. Control strategy for ABS of EV with independently controlled four in-wheel motors. Proc. 2009 4th IEEE Conference on industrial electronics and applications. Xi’an, 2009, pp. 2471–2476. DOI: https://doi.org/10.1109/ICIEA.2009.5138647.
  19. Lin C.-L., Lin W.-C. ABS control design for two-wheel drive electric vehicles. Proc. Second international conference on mechanic automation and control engineering. Inner Mongolia, 2011, pp. 1011–1014. DOI: https://doi.org/10.1109/MACE.2011.5987104.
  20. Semmler S. Regelung der Fahrzeugbremsdynamik mit kontinuierlich einstellbaren Radbremsen. Ph. D. Thesis. Düsseldorf, 2006.
  21. Umnitsyn A.A., Bakhmutov S.V. Intelligent anti-lock braking system of electric vehicle with the possibility of mixed braking using fuzzy logic. Journal of physics: conference series, 2021, vol. 2061. DOI: https://doi.org/10.1088/1742-6596/2061/1/012101.
  22. State Standard R 41.13-99. Edinoobraznye predpisaniya kasayushchiesya ofitsialnogo utverzhdeniya transportnykh sredstv v otnoshenii tormozheniya [Uniform provisions concerning the approval of vehicles of categories M, N and О with regard to braking]. Moscow, IPK standartov Publ., 2000 (in Russ.).