Pressure compensator design, simulation and performance evaluation of a variable displacement swash plate type axial piston pump
Yıl 2021,
Cilt: 39 Sayı: 2, 123 - 130, 02.06.2021
Nitesh Mondal
Rana Saha
Dipankar Sanyal
Öz
This work presents a simple design procedure of a pressure compensator of a swash plate type variable displacement axial piston pump (VDAPP). The route of the work mainly focuses on static design through balancing the torque given by the pump pistons, rate cylinder and stroking cylinder on the swash plate during cut-in (maximum flow) and cut-off (minimum flow) pressure condition of the system with an objective of minimizing the output pressure ripples. The outcome in terms of pressure from the dynamic simulation of the designed compensator with pump has been compare with experimental result obtained from a reference commercial pump has compensator with duel spool. The model has been used for performance prediction for wide variations of the load valve area settings.
Kaynakça
- [1] Wei J, Guo K, Fang J, et al. Nonlinear supply pressure control for a variable displacement axial piston pump. Proc IMechE Part I: J. Systems Control and Engineering 2015; 229 (7): 614-624.
- [2] Daher N and Ivantysynova M. Energy analysis of an original steering technology that saves fuel and boosts efficiency. Energy Conversion and Management 2014; 86: 1059–1068.
- [3] Kemmetmuller W, Fuchshumer F and Kugi A. Nonlinear pressure control of self-supplied variable displacement axial piston pumps. Control Eng Pract 2010; 18: 84–93.
- [4] Norhirni MZ, Hamdi M, et al. Load and Stress Analysis for the Swash Plate of an Axial Piston Pump/Motor. ASME J. Dyn Syst Meas Contrl 2011; 133:064505:1-10.
- [5] Mandal NP, Saha R, Mookherjee S, Sanyal D. Pressure compensator design for an axial piston pump. T ASME J. Dyn Syst Meas Contr. 2014; 136 (2) 021001, DS-12-1356.
- [6] Manring, N. D. Valve-plate design for an axial piston pump operating at low displacements. ASME J. Mech. Des. 2003; V200, 200–205.
- [7] Manring, N. D. The discharge flow ripple of an axial-piston swash-plate type hydrostatic pump. ASME J. Dyn. Syst. Meas. Contr. 2000; 122, 263–268.
- [8] Ericson, L., March. Swash plate oscillations due to piston forces in variable in-line pumps. In The 9th International Fluid Power Conference; 9. IFK, 2014.
- [9] Rexroth Bosch Group – Industrial Hydraulics Catalogue. Variable Axial Piston Pump,Type - A10VSO, series31/DR,RA92711,http://dcamerica.resource.bosch.com/media/us/products_13/product_groups_1/industrial_hydraulics_5/pdfs_4/ra-a92711.pdf (accessed 02 Eeb 2019).
- [10] Massey BS and Ward-Smith J. Mechanics of Fluids, 8th ed., Taylor & Francis, 2006; 201-205.
- [11] Acxess Spring. Online Spring Calculator, http://www.acxesspring. com/spring-force-constant-calculator.html ( accessed 02Feb 2019).
- [12] Mondal, N., Saha, R., Mookherjee, S., & Sanyal, D. A novel method to design pressure compensator for variable displacement axial piston pump. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering 2019; 233(2), 314-334.
- [13] Achten, P. Dynamic high-frequency behaviour of the swash plate in a variable displacement axial piston pump. Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering 2013; 227(6), 529-540.
Yıl 2021,
Cilt: 39 Sayı: 2, 123 - 130, 02.06.2021
Nitesh Mondal
Rana Saha
Dipankar Sanyal
Kaynakça
- [1] Wei J, Guo K, Fang J, et al. Nonlinear supply pressure control for a variable displacement axial piston pump. Proc IMechE Part I: J. Systems Control and Engineering 2015; 229 (7): 614-624.
- [2] Daher N and Ivantysynova M. Energy analysis of an original steering technology that saves fuel and boosts efficiency. Energy Conversion and Management 2014; 86: 1059–1068.
- [3] Kemmetmuller W, Fuchshumer F and Kugi A. Nonlinear pressure control of self-supplied variable displacement axial piston pumps. Control Eng Pract 2010; 18: 84–93.
- [4] Norhirni MZ, Hamdi M, et al. Load and Stress Analysis for the Swash Plate of an Axial Piston Pump/Motor. ASME J. Dyn Syst Meas Contrl 2011; 133:064505:1-10.
- [5] Mandal NP, Saha R, Mookherjee S, Sanyal D. Pressure compensator design for an axial piston pump. T ASME J. Dyn Syst Meas Contr. 2014; 136 (2) 021001, DS-12-1356.
- [6] Manring, N. D. Valve-plate design for an axial piston pump operating at low displacements. ASME J. Mech. Des. 2003; V200, 200–205.
- [7] Manring, N. D. The discharge flow ripple of an axial-piston swash-plate type hydrostatic pump. ASME J. Dyn. Syst. Meas. Contr. 2000; 122, 263–268.
- [8] Ericson, L., March. Swash plate oscillations due to piston forces in variable in-line pumps. In The 9th International Fluid Power Conference; 9. IFK, 2014.
- [9] Rexroth Bosch Group – Industrial Hydraulics Catalogue. Variable Axial Piston Pump,Type - A10VSO, series31/DR,RA92711,http://dcamerica.resource.bosch.com/media/us/products_13/product_groups_1/industrial_hydraulics_5/pdfs_4/ra-a92711.pdf (accessed 02 Eeb 2019).
- [10] Massey BS and Ward-Smith J. Mechanics of Fluids, 8th ed., Taylor & Francis, 2006; 201-205.
- [11] Acxess Spring. Online Spring Calculator, http://www.acxesspring. com/spring-force-constant-calculator.html ( accessed 02Feb 2019).
- [12] Mondal, N., Saha, R., Mookherjee, S., & Sanyal, D. A novel method to design pressure compensator for variable displacement axial piston pump. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering 2019; 233(2), 314-334.
- [13] Achten, P. Dynamic high-frequency behaviour of the swash plate in a variable displacement axial piston pump. Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering 2013; 227(6), 529-540.