In this paper, a novel active control of fluid pressure pulsation (ACFPP) is proposed, which meets the need of the high-pressure and high-speed hydraulic pipe system. A piezoelectric direct-drive slide valve (PDDSV) is designed and used as the active vibration absorber. Two ports of the PDDSV both connect to a bypass near the pump outlet and the other two ports both connect to the oil tank. By the bilateral-overflow through the shoulder of the PDDSV, the overflow wave generated in one cycle of spool motion can cancel two cycles of flow ripple. An adaptive-optimum control method based on the rotate-vector optimization method (RVOM) is adopted to adjust the control parameters in order to minimize the amplitude of the pressure pulsation. The biggest advantage of the proposed ACFPP is that it can eliminate the pressure pulsation when PDDSV only works at half of the pressure pulsation's frequency. The simulation and experimentation both verify the proposed ACFPP. By the proposed ACFPP, the suppression for the single-frequency component and dual-frequency components of the pressure pulsation have been both realized.
References
1.
Manring
, N. D.
, and Zhang
, Y.
, 2001
, “The Improved Volumetric-Efficiency of an Axial-Piston Pump Utilizing a Trapped-Volume Design
,” ASME J. Dyn. Syst. Meas. Control
, 123
, pp. 479
−487
.10.1115/1.13893112.
Harrison
, K.
, and Edge
, K. A.
, 2000
, “Reduction of Axial Piston Pump Pressure Ripple
,” Proc. IMechE, Part I: J. Syst. Control Eng.
, 214
, pp. 53
−64
.10.1243/09596510015405193.
Cheah
, S.
, 1993
, “Design Considerations of Aircraft Piping System
,” Proceeding of the Aerospace Technological Seminar
, Singapore, pp. 51
−66
.4.
Ouyang
, P.
, Jiao
, Z.
, Liu
, H.
, Li
, S.
, and Li
, Y.
, 2006
, “Active Control on Fluid Borne Pulsation Using Piezoelectric Valve as Absorber
,” IEEE Conference on Robotics, Automation and Mechatronics
, Bangkok, pp. 1
−5
.5.
Kim
, K. H.
, Jang
, J. S.
, Jung
, D. S.
, and Kim
, H. E.
, 2005
, “Reduction of Pressure Ripples Using a Parallel Line in Hydraulic Pipeline
,” Int. J. Autom. Technol.
, 6
(1
), pp. 65
−70
.6.
Kojima
, E.
, and Ichiyanagi
, T.
, 1998
, “Development Research of New Types of Multiple Volume Resonators
,” Bath Workshop on Power Transmission and Motion Control
, pp. 193
−206
.7.
Strunk
, R. D.
, 1991
, “Silencer for Hydraulic Piston Pump Pressure Pulsations
,” Soc. Autom. Eng.
, 100
, pp. 135
−141
.8.
Jiao
, Z.
, Chen
, P.
, Hua
, Q.
, and Wang
, S.
, 2003
, “Adaptive Vibration Active Control of Fluid Pressure Pulsations
,” Proc. IMechE, Part I: J. Syst. Control Eng.
, 217
, pp. 311
−318
.10.1177/0959651803217004079.
Harper
, M.
, and Leung
, R.
, 1993
, “Active Vibration Control in Pipes
,” Proceedings on Inter-Noise
, Leuven, pp. 871
−874
.10.
Brennan
, M.
, Elliott
, S.
, and Pinnington
, R.
, 1996
, “A Non-Intrusive Fluid-Wave Actuator and Sensor Pair for the Active Control of Fluid-Borne Vibrations in a Pipe
,” Smart Mater. Struct.
, 5
, pp. 281
−296
.10.1088/0964-1726/5/3/00611.
Maillard
, J.
, Lagö
, T. L.
, Winberg
, M.
, and Fuller
, C.
, 1999
, “Fluid Wave Actuator for the Active Control of Hydraulic Pulsations in Piping Systems
,” Proc. Int. Modal Anal. Exhib.
, 6
, pp. 1806
−1812
. Available at: http://sem-proceedings.com/17i/sem.org-IMAC-XVII-17th-174302-FluidWave-Actuator-Active-Control-Hydraulic-Pulsations-Piping-Systems.pdf12.
Kiyar
, M. B.
, Johnson
, M.
, and Fuller
, C.
, 2002
, “Experiments on the Active Control of Multiple Wave Types in Fluid Filled Piping Systems
,” ASME International Mechanical Engineering Congress and Exposition
, New Orleans, Paper No. IMECE2002-33041.13.
Kojima
, E.
, and Shinada
, M.
, 1991
, “Development of an Active Attenuator for Pressure Pulsation in Liquid Piping Systems: A Real Time-Measuring Method of Progressive Wave in a Pipe
,” JSME Int. J., Ser. B
, 34
, pp. 466
−473
. Available at: http://ci.nii.ac.jp/naid/110002493413/14.
Yokota
, S.
, Somada
, H.
, and Yamaguchi
, H.
, 1996
, “Study on an Active Accumulator (Active Control of High-Frequency Pulsation of Flow Rate in Hydraulic Systems)
,” JSME Int. J., Ser. B
, 39
, pp. 119
−124
.10.1299/jsmeb.39.11915.
Kartha
, S. C.
, 2000
, “Active, Passive and Active/Passive Control Techniques for Reduction of Vibrational Power Flow in Fluid Filled Pipes
,” Master dissertation, Virginia Polytechnic Institute and State University, Blacksburg, VA.16.
Manring
, N. D.
, 2000
, “The Discharge Flow Ripple of an Axial-Piston Swash-Plate Type Hydrostatic Pump
,” ASME J. Dyn. Syst. Meas. Control
, 122
, pp. 263
−268
.10.1115/1.48245217.
Duan
, J.
, Li
, M. F.
, and Lim
, T. C.
, 2011
, “Active Control of Vehicle Transient Powertrain Noise Using a Twin-FXLMS Algorithm
,” ASME J. Dyn. Syst. Meas. Control
, 133
, p. 034501
.10.1115/1.400338618.
Yoon
, H.
, Bateman
, B. E.
, and Agrawal
, B. N.
, 2011
, “Laser Beam Jitter Control Using Recursive-Least-Squares Adaptive Filters
,” ASME J. Dyn. Syst. Meas. Control
, 133
, p. 041001
.10.1115/1.400337219.
Scribner
, K. B.
, Sievers
, L. A.
, and von Flotow
, A. H.
, 1993
, “Active Narrowband Vibration Isolation of Machinery Noise From Resonant Substructures
,’’ J. Sound Vib.
, 167
(1
), pp. 17
–40
.10.1006/jsvi.1993.131920.
Guan
, Y. H.
, Shepard
, W. S.
, and Lim
, T. C.
, 2003
, “Direct Hybrid Adaptive Control of Gear Pair Vibration
,” ASME J. Dyn. Syst. Meas. Control
, 125
, pp. 585
−594
.10.1115/1.163677121.
Lee
, C.-H.
, and Jee
, W.-H.
, 1996
, “H∞ Robust Control of Flexible Beam Vibration by Using a Hybrid Damper
,” ASME J. Dyn. Syst. Meas. Control
, 118
, pp. 643
−648
.10.1115/1.280119622.
Schoen
, M. P.
, Hoover
, R. C.
, Chinvorarat
, S.
, and Schoen
, G. M.
, 2009
, “System Identification and Robust Controller Design Using Genetic Algorithms for Flexible Space Structures
,” ASME J. Dyn. Syst. Meas. Control
, 131
, p. 031003
.10.1115/1.307210623.
Yazici
, H.
, Guclu
, R.
, Kucukdemiral
, I. B.
, and Parlakci
, M. N. A.
, 2012
, “Robust Delay-Dependent H∞ Control for Uncertain Structural Systems With Actuator Delay
,” ASME J. Dyn. Syst. Meas. Control
, 134
, p. 031013
.10.1115/1.400550024.
Shoureshi
, R.
, Brackney
, L.
, Kubota
, N.
, and Batta
, G.
, 1993
, “A Modern Control Approach to Active Noise Control
,” ASME J. Dyn. Syst. Meas. Control
, 115
, pp. 673
−678
.10.1115/1.289919525.
Trikha
, A. K.
, 1975
, “An Efficient Method for Simulating Frequency-Dependent Friction in Transient Liquid Flow
,” ASME J. Fluids Eng.
, 97
, pp. 97
−105
.10.1115/1.344722426.
Streeter
, V. L.
, and Wylie
, E. B.
, 1967
, Hydraulic Transients
, McGraw-Hill
, New York
.27.
Johnston
, D.
, and Edge
, K.
, 1991
, “The Impedance Characteristics of Fluid Power Components: Restrictor and Flow Control Valves
,” Proc. IMechE, Part I: J. Sys. Control Eng.
, 205
, pp. 3
−10
.10.1243/PIME_PROC_1991_205_084_0228.
Meeker
, T.
, 1996
, “ANSI/IEEE Standard on Piezoelectricity
,” IEEE Trans. Ultrason. Ferroelectr. Freq. Control
, 43
, pp. 717
−772
.10.1109/TUFFC.1996.53547729.
Jalili
, N.
, Wagner
, J.
, and Dadfarnia
, M.
, 2003
, “A Piezoelectric Driven Ratchet Actuator Mechanism With Application to Automotive Engine Valves
,” Mechatronics
, 13
, pp. 933
−956
.10.1016/S0957-4158(03)00009-630.
Arafa
, H.
, and Rizk
, M.
, 1987
, “Spool Hydraulic Stiffness and Flow Force Effects in Electrohydraulic Servo-Valves
,” Proc. IMechE, Part C: J. Mech. Eng. Sci.
, 201
, pp. 193
−199
.10.1243/PIME_PROC_1987_201_106_0231.
Physik Instrumente,
2009
, PI Catalog V2: Piezo Drivers/Servo Controllers, Karlsruhe, Germany
.32.
Merritt
, H. E.
, 1967
, Hydraulic Control Systems
, John Wiley & Sons Inc
, New York
.33.
Jiao
, Z.
, and Lu
, Y.
, 1996
, “A Novel Engineering Optimization Method: Rotate Vector Method
,” Chin. J. Mech. Eng.
, 32
, pp. 45
−50
.Copyright © 2014 by ASME
You do not currently have access to this content.
