Influence of change of hydraulic machine control parameter during braking of the tractor with the continuously variable transmission

Authors

DOI:

https://doi.org/10.15587/2312-8372.2017.109025

Keywords:

wheeled tractor, continuously variable transmission, dynamic model, shape of change, hydraulic machine control parameter during braking

Abstract

The influence of the hydraulic machine control parameter in the braking process of a wheeled tractor with a GMT is established. The relationship between the form of the change in the control parameter of the HMG hydrostatic machine and the kinematic, power and energy indicators of the wheeled tractor during braking is determined. The expediency of using the curved shape of the hydraulic control parameter change during braking due to the more effective intensity of the change is proved, which leads to a decrease in the braking and braking distances. The main disadvantage of this research is the need to confirm by experimental tests, obtained theoretically the results.

The article presents a dynamic model of a wheeled tractor with a mathematical description of engine operation, GMT, interaction of wheels with a supporting surface, makes theoretical calculations more approximate to the experimental one.

Making the characteristic evaluation results obtained when implementing a curved, linear and convex shapes of the hydraulic control parameter changes in the HMG should be noted that when compared linear with convex and linear with curved, there are:

– reduction (for linear with curved) of braking time by 11.4 % and an increase (linear with convex) 3.8 %;

– decrease (for linear with curved) of braking distance by 23.3 % and an increase (linear with convex) by 21.7 %.

Comparing the qualitative results (calculation of the area) during the tractor braking, using the linear form of the change with a convex-curved shape of the change in the hydraulic machine control parameter, let’s observe:

– curved with linear: a reduction in the HMG efficiency by 9.3 %, a decrease in the GMT efficiency by 8.7 %, a decrease in the power consumption by 43 %;

– convex with linear: an increase in the HMG efficiency by 11.1 %, an increase in GMT efficiency by 7.4 %, an increase in the power consumption by 50.6 %.

These observations indicate that using the curved shape of the hydraulic control parameter for the tractor KhTZ-21021 during braking, the power losses in the HMG hydraulic link are increasing that is directly related to the efficiency of the braking of the tractor.

Author Biographies

Vadim Samorodov, National Technical University «Kharkiv Polytechnic Institute», 2, Kyrpychova str., Kharkiv, Ukraine, 61002

Doctor of Technical Sciences, Professor, Head of Department

Department of Car and Tractor Industry 

Andrey Kozhushko, National Technical University «Kharkiv Polytechnic Institute», 2, Kyrpychova str., Kharkiv, Ukraine, 61002

PhD, Senior Lecturer

Department of Car and Tractor Industry

Eugene Pelipenko, National Technical University «Kharkiv Polytechnic Institute», 2, Kyrpychova str., Kharkiv, Ukraine, 61002

Postgraduate Student, Assistant

Department of Car and Tractor Industry 

References

  1. Shcheltsyn, N. A., Frumkin, L. A., Ivanov, I. V. (2011). Sovremennye besstupenchatye transmissii sel'skohoziaistvennyh traktorov. Traktory i sel'hozmashiny, 11, 18–26.
  2. Beunk, H., Wilmer, H. (2002). So Arbeiten «Auto Powr» und «Eccom». Profi, 5.
  3. Renius, K. T., Resch, R. (2005). Continuously Variable Tractor Transmissions. St. Joseph, MI: American Society of Agricultural Engineers, 37.
  4. Rydberg, K. (2010). Hydro-Mechanical Transmissions. Fluid and Mechatronic Systems, 2, 51–60.
  5. Aitzetmuller, H. (1999). Steyr S-Matic – The Future Continuously Variable Transmission for all Terrain Vehicles. Proceedings of the International Conference-International Society for Terrain Vehicle Systems, 2, 463–470.
  6. Pusha, A., Deldar, M., Izadian, A. (2013). Efficiency analysis of hydraulic wind power transfer system. IEEE International Conference on Electro-Information Technology, EIT 2013. IEEE, 1–7. doi:10.1109/eit.2013.6632717
  7. Ijas, M., Makinen, E. (2008). Improvement of total efficiency of hydrostatic transmission by using optimized control. Proceedings of the JFPS International Symposium on Fluid Power, 2008 (7–2), 271–276. doi:10.5739/isfp.2008.271
  8. Coombs, D. (2012). Hydraulic Efficiency of a Hydrostatic Transmission with a Variable Displacement Pump and Motor. Mechanical and Aerospace Engineering, 82.
  9. Dasgupta, K., Kumar, N., Kumar, R. (2013). Steady State Performance Analysis of Hydrostatic Transmission System using Two Motor Summation Drive. Journal of The Institution of Engineers (India): Series C, 94 (4), 357–363. doi:10.1007/s40032-013-0084-y
  10. Ahn, S., Choi, J., Kim, S., Lee, J., Choi, C., Kim, H. (2015). Development of an integrated engine-hydro-mechanical transmission control algorithm for a tractor. Advances in Mechanical Engineering, 7 (7), 168781401559387. doi:10.1177/1687814015593870
  11. Mittsel, M. O. (2014). Eksperymentalne doslidzhennia osoblyvyi zony roboty dvokhpotochnoi hidroobiemno-mekhanichnoi transmisii. Proceedings of the International Scientific and Practical Conference «Innovative Foundations of Sustainable Development of the National Economy», November 21-22, 2014, Kamianets-Podilskyi. Kamianets-Podilskyi: Podilskyi State Agrarian-Technical University, 185–188.
  12. Samorodov, V. B. (2001). Vyvod obshchego zakona upravleniia gidroob#emno-mehanicheskih transmissii transportnyh mashin v protsesse priamolineinogo razgona i sposob ego tehnicheskoi realizatsii. Integrirovannye tehnologii i energosberezhenie, 4, 112–120.
  13. Samorodov, V. B. (2000). Issledovanie vliianiia razlichnyh zakonov regulirovaniia gidroobiemno-mehanicheskoi transmissii na protsess priamolineinogo razgona gusenichnoi mashiny. Mekhanika ta mashynobuduvannia, 2, 86–92.
  14. Kozhushko, A. (2014). Determining the optimal parameters for controlling law change of hydraulic fluidtransferduring acceleration wheeled tractors hydrostatic mechanical transmissions. Visnyk Sumskoho natsionalnoho ahrarnoho universytetu. Seriia: Mekhanizatsiia ta avtomatyzatsiia vyrobnychykh protsesiv, 11 (26), 108–114.
  15. Samorodov, V., Kozhushko, A., Mittsel, N., Pelipenko, E., Burlyga, M. (2017). Experimental confirmation of the rational change parameter of the hydraulic transmission during acceleration and braking of the hydraulic volume mechanical transmission (HVMT). International Collection of Scientific Proceedings «European Cooperation», 7 (26), 9–24.
  16. Samorodov, V., Kozhushko, A., Pelipenko, E. (2016). Formation of a rational change in controlling continuously variable transmission at the stages of a tractor’s acceleration and braking. Eastern-European Journal of Enterprise Technologies, 4(7(82)), 37–44. doi:10.15587/1729-4061.2016.75402
  17. Bondarenko, A. I. (2011). Matematychna model protsesu halmuvannia kolisnoho traktora. Bulletin of the National Technical University «Kharkiv Polytechnic Institute», 43, 78–83.

Published

2017-07-25

How to Cite

Samorodov, V., Kozhushko, A., & Pelipenko, E. (2017). Influence of change of hydraulic machine control parameter during braking of the tractor with the continuously variable transmission. Technology Audit and Production Reserves, 4(1(36), 11–18. https://doi.org/10.15587/2312-8372.2017.109025

Issue

Section

Mechanical Engineering Technology: Original Research