Main Catalog Power, Metallurgic and Chemical Engineering Hydraulic Machines and Hydropneumatic units

The method of combating the mutual load of hydraulic drives by changing the control law

Authors: Vdovin D.A.
Published in issue: #9(50)/2020
DOI: 10.18698/2541-8009-2020-9-639
Category: Power, Metallurgic and Chemical Engineering \| Chapter: Hydraulic Machines and Hydropneumatic units
Keywords: hydraulic cylinder, flow rate, differential pressure, mathematical model, slider crank mechanism, hydraulic valve, mutual loading, reference model
Published: 19.10.2020

The paper considers a hydraulic drive with separate control of piston groups. Mathematical functions are found that describe changes in differential pressure corresponding to positive torques from each piston at a nearly constant torque on the output shaft. A law has been developed for controlling hydraulic distributors in the angular velocity tracking mode. The control law takes into account the load on the output shaft, and also uses feedback on the difference between real and reference differential pressure. Mathematical modeling was performed in the MATLAB software package for a nonlinear model of a hydraulic drive, the effectiveness of the applied control law was proved. It is shown that the mutual influence of pistons from different groups was significantly reduced without worsening the uneven rotation of the output shaft at different loads.

References

[1] Tarasov O.I., Shcherbachev P.V. Development of BLDC electric motor control system in hydraulic servo drive based on variable hydrostatic transmission. Nauka i obrazovanie: nauchnoe izdanie [Science and Education: Scientific Publication], no. 12. URL: https://elibrary.ru/download/elibrary_22794723_68540322.pdf (in Russ.).

[2] Shcherbachev P.V., Tarasov O.I., Semenov S.E. Energy efficiency of electrohydraulic actuators in dynamic mode. Sovremennye problemy nauki i obrazovaniya [Modern problems of science and education], 2014, no. 6. URL: http://www.science-education.ru/ru/article/view?id=16374 (in Russ.).

[3] Shcherbachev P.V., Tarasov O.I. Comparative characteristics of small-scale hydraulic and mechanical transmissions. Sovremennye problemy nauki i obrazovaniya [Modern problems of science and education], 2014, no. 6. URL: https://science-education.ru/ru/article/view?id=16352 (in Russ.).

[4] Linjama Moscow, Huhtala K. Digital hydraulic power management system – towards lossless hydraulics. The Third Workshop on Digital Fluid Power, Tampere, 2010, pp. 5–22.

[5] Breidi F., Helmus T., Lumkes J. High efficiency digital pump/motor. FPIRC15. Chicago, 2015, pp. 23–26.

[6] Merril K., Breidi F. Simulation based design and optimization of digital pump/motors. ASME/BATH Symp. Fluid Power and Motion Control. Sarasota, 2013, pp. 122–130. DOI: https://doi.org/10.1115/FPMC2013-4475

[7] Rampen W. Gearless transmissions for large wind turbines – the history and future of hydraulic drives. artemisip.com: website. URL: http://www.artemisip.com/wp-content/uploads/2016/03/2006-11-Gearless-Transmissions-Bremen.pdf (accessed: 15.06.2020).

[8] Armstrong B., Qinghui Y. Multi-level control of hydraulic gerotor motors and pumps. American Control Conf., 2006, pp. 4619–4626. DOI: https://doi.org/10.1109/ACC.2006.1657450

[9] Sniegucki M., Gottfried M., Klingauf U. Optimal control of digital hydraulic drives using mixed-integer quadratic programming. IFAC Proc. Vol., 2013, vol. 46, no. 23, pp. 827–832. DOI: https://doi.org/10.3182/20130904-3-FR-2041.00013

[10] Linjama M. Digital fluid power, state of the art. Proc. SICFP’11, Tampere, 2011, pp. 331–354.

[11] Linjama Moscow, Huhtala K. Digital pump-motor with independent outlets. Proc. SICFP’09, Linkoping, 2009, p. 16.

[12] Shcherbachev P.V. Razrabotka i issledovanie elektrogidravlicheskogo privoda s razdel’nym upravleniem gruppami porshney. Diss. kand. tekhn. nauk [Development and study on electro hydraulic drive with separate control on piston groups. Kand. tech. sci. diss.]. Moscow, Bauman MSTU Publ., 2017 (in Russ.).

[13] Shcherbachev P., Vdovin D. Methods of dealing with mutual loading of joint hydraulic actuators. IOP Conf. Ser.: Mater. Sci. Eng., 2019, vol. 589, art. 012023. DOI: https://doi.org/10.1088/1757-899X/589/1/012023

[14] Shcherbachev P.V. Elektrogidravlicheskiy privod s drossel’nym regulirovaniem s povyshennoy energoeffektivnost’yu. Nauka i obrazovanie: nauchnoe izdanie [Science and Education: Scientific Publication], 2012, no. 10. DOI: http://dx.doi.org/10.7463/1012.0465528 (in Russ.).

[15] Solodovnikov V.V., Shramko L.S. Raschet i proektirovanie samonastraivayushchikhsya sistem s etalonnymi modelyami [Calculation and design of self-adjusting system with reference model]. Moscow, Mashinostroenie Publ., 1972 (in Russ.).