Simulation of dynamic phenomena in a high pressure variable displacement axial piston hydraulic pump
DOI:
https://doi.org/10.24423/cames.246Keywords:
hydrostatic machine, axial multi-piston pump, dynamic phenomenaAbstract
Substituting a valve plate-based commutation unit with a hydrostatic-load-free commutation bushing controllable with a signal of negligible power, that could be applied in constant and variable displacement pumps introduced a different approach to the design of commutation units in multi-piston axial hydraulic pumps.
Conducted research showed that valve plate-based commutator is responsible for over 50% energy loss. The new idea assumed a stationary cylinder block and the replacement of the valve plate with a camdriven commutation unit that would be totally unloaded hydrostatically. That eliminated main source of mechanical losses as well as a flow resistance loss. Additionally, the dead volume was significantly reduced, which helped to reduce the pump noise level and resulted in a great decrease in power needed to control the pump displacement. That allowed to eliminate a servomechanism and the direct control of the pump displacement with a low power element. However, the new design presented a challenge in the form of pressure peaks occurring in the working chamber, which were difficult to eliminate. This article presents attempts to solve problems connected with those dynamic phenomena.
References
[2] A. Osiecki. Hydrostatic Machine Drive [in Polish: Hydrostatyczny Naped Maszyn]. Wydawnictwa Naukowo-Techniczne, Warszawa, Poland, 2004.
[3] A. Osiecki. Drive and Hydraulic Control of Machines – Theory, Calculation and Systems [in Polish: Naped i Sterowanie Hydrauliczne Maszyn – Teoria, obliczanie i układy]. Politechnika Gdanska, Gdansk, Poland, 1995.
[4] A. Osiecki. Piston Pump with a Constant Working Volume. International Patent PL191366 (A1. 07 31), 1978.
[5] A. Osiecki, L. Osiecki. Hydrostatic Axial Piston Machine. International Patent EP0742870A1. 04 14, 1999.
[6] L. Osiecki. Mechanisms of the Timing of Hydraulic Axial Multi-Piston Machines [in Polish: Mechanizmy Rozrzadu Hydraulicznych Maszyn Wielotłoczkowych Osiowych]. Politechnika Gdanska, Gdansk, 2006.
[7] L. Osiecki. Multipiston Axial Hydrostatic Machine. International Patent PL387933A1. 08 11, 2010.
[8] L. Osiecki. Multipiston Axial Hydrostatic Machine. International Patent PL215652B1. 01 31, 2014.
[9] L. Osiecki, P. Patrosz, T. Zawistowski, B. Landvogt, J. Piechna, B. Zylinski. Compensation of pressure peaks in PWK-type hydraulic pumps. Key Engineering Materials, 490: 33–44, 2011.
[10] P. Patrosz. Compensation of pressure peaks in a variable displacement piston pump with cam driven commutation [in Polish: Kompensacja skoków cisnienia w pompie tłoczkowej o zmiennej wydajnosci z rozrzadem krzywkowym]. D.Sc. Thesis, 2017.
[11] T. Zawistowski, M. Kleiber. Gap flow simulation methods in high pressure variable displacement piston pumps. Archives of Computational Methods in Engineering, 24: 519–542, 2017.
[12] S.K. Maity, R. Kawalla. Ultrahigh Strength Steel: Development of Mechanical Properties Through Controlled Cooling, http://cdn.intechweb.org/.
Issue
Section
License
Copyright © The Author(s).
This work is licensed under the Creative Commons Attribution 4.0 International CC BY 4.0.
How to Cite
