ArticleName |
Influence of power fluid temperature in hydraulics on operating efficiency of hydraulic mining excavators |
ArticleAuthorData |
College of Mining, National University of Science and Technology—MISIS, Moscow, Russia:
A. E. Krivenko, Associate Professor, Candidate of Engineering Sciences, tdlit@mail.ru Zhang Kuok Khanh, Post-Graduate Student |
Abstract |
The Republic of Vietnam has great mineral resources. Open pit mines use hydraulic excavators. In hot climate, the excavators lose capacity, and the number of the hydraulics failures grows. To identify the causes of unstable operation of the hydraulics, the authors analyze the capacity reduction factors, namely, hydraulic pump leaks. The test subject is pump HPV95 for Komatsu hydraulic excavators. The axial-piston pump leaks take place in clearances of control and injection gears, and only have mutable and cyclic behavior in the piston and cylinder clearances. This has an adverse effect on uniformity of the pump flow and on stability of the injection pressure. Generally, leaks can be evaluated from the Reynolds equation of fluid flow rate in the ring clearance. The input data are the design variables of axial-piston pump HPV95 and power fluid temperature range of Komatsu hydraulic mining excavators operated in open pit mining in the south in the Republic of Vietnam. Matlab-based Simulink modeling shows that with increasing temperature of power fluid, leaks in the injection gear grow nonlinearly in the absolute value and so does the surging amplitude in the pump flow. As a consequence, the pressure fluctuations and vibrations in the hydraulic gear elevate. The modeling also exhibits higher surge and reduced net capacity of the hydraulics with rising temperature of power fluid. These changes are caused by reduction in the flow friction in the ring channel between the piston and block of cylinders. Thus, the power fluid cooling system engineering subject to hydraulics capacity, operating conditions and cooling methods is highly critical for the efficient operation of hydraulic mining excavators. |
References |
1. Komissarov A. P., Lagunova Yu. A., Shestakov V. S., Ivanov I. Yu. Single-bucket excavator energy demand. Gornyi Zhurnal. 2018. No. 1. pp. 73–77. DOI: 10.17580/gzh.2018.01.13 2. Pobegaylo P. A., Ilina A. N. Physical model of evaluation of the hydraulic excavators dynamics at early stages of project activities. Ugol. 2018. No. 12. pp. 33–37. 3. Gabov V. V., Zadkov D. A., Stebnev A. V. Evaluation of structure and variables within performance rating of hydraulically powered roof support legs with smooth roof control. Eurasian Mining. 2016. No. 2. pp. 37–40. DOI: 10.17580/em.2016.02.09 4. Iungmeister D. A., Korolev R. I., Karlov V. A. Improvement of shock system of hydraulic drill to increase drilling intensification. IOP Conference Series: Earth and Environmental Science. 2018. Vol. 194, Iss. 3. 032006. DOI: 10.1088/1755-1315/194/3/032006 5. Pobegaylo P. A., Ilina A. N. Baselines of the procedure for estimating velocity and acceleration of singlebucket hydraulic excavator attachments at early design stages. GIAB. 2018. No. 11. pp. 129–135. 6. Sekretov M. V., Rakhutin M. G., Gubanov S. G. Prospects for percussion sawing machines in production of high-strength dimension stone. Gornyi Zhurnal. 2019. No. 8. pp. 65–69. DOI: 10.17580/gzh.2019.08.12 7. Koval P. V. Hydraulics and hydraulic drives of mining machines : Textbook. Moscow : Mashinostroenie, 1979. 319 p. 8. Keropyan A. M., Kuziev D. A., Krivenko A. E. Process Research of Wheel-Rail Mining Machines Traction. Proceedings of the 5th International Conference on Industrial Engineering. Ser. Lecture Notes in Mechanical Engineering. Cham : Springer, 2020. Vol. II. pp. 703–709. 9. Redelin R. A., Kravchenko V. A., Kamanin Y. N., Panichkin A. V., Bozhanov A. A. Study of effect of in-line hydropneumatic accumulators on output characteristics of hydraulic hammer. IOP Conference Series: Earth and Environmental Science. 2017. Vol. 87, Iss. 2. 022016. DOI: 10.1088/1755-1315/87/2/022016 10. Mitusov A. A., Kyzyrov K. B., Reshetnikova O. S. Analysis and substantiation of two-stage distribution system parameters for hydraulic hammers. Gornyi Zhurnal. 2019. No. 8. pp. 73–76. DOI: 10.17580/gzh.2019.08.14 11. Wang Wei. Analysis on the side leakage amount of the friction between piston and cylinder block in axial piston pump. Journal Applied Mechanics and Materials. 2014. Vol. 635-637. pp. 341–345. 12. Xingjian Wang, Siru Lin, Shaoping Wang, Zhaomin He, Chao Zhang. Rema ining useful life prediction based on the Wiener process for an aviation axial piston pump. Chinese Journal of Aeronautics. 2016. Vol. 29, Iss. 3. pp. 779–788. 13. Nie S. L., Huang G. H., Li Y. P. Trib ological study on hydrostatic slipper bearing with annular orifice damper for water hydraulic axial piston motor. Tribology International. 2005. Vol. 39, Iss. 11. pp. 1342–1354. 14. Hydraulic design of fluid power drive with reciprocating output element : Instructional guidelines. Tambov : Izdatelstvo VPO TGTU, 2010. 32 p. |