VISCOUS DAMPING COEFFICIENT AND EFFECTIVE BULK MODULUS ESTIMATION IN A HIGH PERFORMANCE HYDROSTATIC ACTUATION SYSTEM USING EXTENDED KALMAN FILTER

Authors

  • Yuvin Chinniah Department of Mechanical Engineering, University of Saskatchewan, 57 Campus Drive, Saskatoon, Saskatchewan, Canada S7N 5A9
  • Richard Burton Department of Mechanical Engineering, University of Saskatchewan, 57 Campus Drive, Saskatoon, Saskatchewan, Canada S7N 5A9
  • Saeid Habibi Department of Mechanical Engineering, University of Saskatchewan, 57 Campus Drive, Saskatoon, Saskatchewan, Canada S7N 5A9

Keywords:

electrohydraulic actuation, extended kalman filter, viscous damping coefficient, effective bulk modulus

Abstract

Increasing demands on reliability and safety of fluid power devices have brought much attention to methods for improving condition monitoring of these devices. Whereas faults in hydraulic systems were detected only when limit values of measurable output signals were transgressed, recently, attempts have been made to detect them earlier and to locate them better by the use of measurable signals. The Extended Kalman Filter can be used for real-time estimation of parameters in system models. Changes in model parameters may be tracked and, in turn, be used for determining the condition of the system. In this paper, the Extended Kalman Filter (EKF) is applied to a novel hydrostatic actuation system referred to as the Electrohydraulic Actuator (EHA). A state space model of the EHA is developed and the Extended Kalman Filter is used to estimate unmeasurable but critical parameters such as viscous damping coefficient of the actuator and the effective bulk modulus of the system. The proof of concept of applying the EKF for parameter and state is demonstrated through both simulation and experimental evidence. Changes in the viscous damping coefficient at the actuator at a known temperature may be good indication that the fluid is degrading or that the dynamic seal of the actuator is experiencing wear. The effective bulk modulus has a large impact on the system response, affecting the natural frequency and stability and can have implications on the safety of operation. These two parameters cannot be measured directly and hence need to be estimated. Based on this estimation, corrective actions may be taken in safety critical applications for the EHA such as Flight Surface Actuation.

Downloads

Download data is not yet available.

Author Biographies

Yuvin Chinniah, Department of Mechanical Engineering, University of Saskatchewan, 57 Campus Drive, Saskatoon, Saskatchewan, Canada S7N 5A9

Yuvin Chinniah Ph.D. Candidate in the Mechanical Engineering Department, University of Saskatchewan, Canada. He was the recipient of a Canadian Commonwealth Scholarship in 1999. He obtained his B.Eng. (Hons), First Class, in Electrical and Electronic Engineering in Mauritius (1997). He also worked as an electrical engineer at Dynamotors Ltd in Mauritius for two years. His research interest includes fluid power control, control systems and estimation techniques such as the Kalman Filter.

Richard Burton, Department of Mechanical Engineering, University of Saskatchewan, 57 Campus Drive, Saskatoon, Saskatchewan, Canada S7N 5A9

Richard Burton P.Eng, Ph.D, Assistant Dean, Professor, Mechanical Engineering, University of Saskatchewan. Burton is involved in research pertaining to the application of intelligent theories to control and monitoring of hydraulics systems, component design, and system analysis. He is a member of the executive of ASME, FPST Division, a member of the hydraulics' advisory board of SAE and NCFP and one of members of the international editorial board for FPNI.

Saeid Habibi, Department of Mechanical Engineering, University of Saskatchewan, 57 Campus Drive, Saskatoon, Saskatchewan, Canada S7N 5A9

Saeid Habibi Obtained his Ph.D. in Control Engineering and Robotics from the University of Cambridge, UK. He worked as a project manager and senior consultant for Cambridge Control Ltd, UK and as manager of Systems Engineering for Allied Signal Aerospace Canada. His academic background includes research into design and analysis of hydraulic actuation systems, sensors and instrumentation and advanced multivariable control. He is on the Editorial Board of the CSME and a member of IEEE. He is currently an Associate Professor in Mechanical Engineering at the University of Saskatchewan, Canada.

References

Merrit, H. E. 1967. Hydraulic Control System. John

Wiley & Sons Publisher.

Hunt, T. M. 1986. A review of condition monitoring

techniques applicable to fluid power systems. Proceedings

of the 7th International Fluid Power Symposium

Bath University, UK, pp. 285-293.

Esposito, A. 2000. Fluid Power with Application. Fifth

Edition, Prentice Hall.

Burton, R. and Sargent. 1990. Some Experiences with

Expert System for the Design, Monitoring and

Maintenance of Hydraulic Circuits. SAE Transactions,

pp. 532-540.

Stecki, J. and Garbacik, A. 2000. Hydraulic Control

System Design and Analysis. Fluid Power Net Publications,

Melbourne.

Habibi, S. R. and Goldenberg, A. A. 1999. Design

and Analysis of a New Symmetrical Linear Actuator

For Hydraulic and Pneumatic Systems. Transactions

of the CSME, Vol. 23, pp. 337-395.

Habibi, S. R. and Singh, G. 2000. Derivation of Design

Requirements for Optimization of a High Performance

Hydrostatic Actuation System. International

Journal of Fluid Power, V1, No 2, pp. 11-27.

Habibi, S. R., Pastrakuljic, V. and Goldenberg, A. A.

Model Identification of a High performance

Hydrostatic Actuation System. International Mechanical

Eng. Congress and Exhibition, Orlando,

Fl.

Chinniah, Y., Burton, R. and Habibi, S. 2001. Parameter

Estimation in a Hydrostatic System Using

Extended Kalman Filter. ASME-IMECE Conference,

New York.

Chinniah, Y., Habibi, S. and Burton, R. 2001. Simulation

of a Nonlinear Model of a new High Performance

Electrohydraulic Actuator. CANCAM 01

Conference, St John’s NF.

Chinniah, Y., Burton, R. and Habibi, S. 2003. Modelling

of a Hydrostatic System Using Measured Parameters.

CANCAM 03 Conference, Calgary.

Brown, R., and Hwang, P. 1997. Introduction to Random

Signals and Applied Kalman Filtering. 3rd edition,

John Wiley & Sons.

Ljung and Lennart 1979. Asymptotic Behavior of the

Extended Kalman Filter as a Parameter Estimator

for Linear Systems. IEEE Transactions on Automatic

Control, Vol. AC-24 No 1.

Chen, G. and Chui, C. K. 1987. Kalman Filtering with

Real Time Applications. Springer Verlag.

Grewal, M. and Andrews, A. 1993. Kalman Filtering:

Theory and Practice. Prentice Hall.

Zavaheri, K. M. 1997. On-line Condition Monitoring

and Fault Diagnosis in Hydraulic System Components

Using Parameter Estimation and Pattern

Classification. Ph.D. Thesis University of British

Columbia, Canada.

Cao and Huan. 2001. Parameter Estimation Using

Extended Kalman Filter For the Swash Plate Assembly

and Control Piston in a Load Sensing

Pump. MSc Thesis, University of Saskatchewan,

Canada.

Downloads

Published

2003-11-01

How to Cite

Chinniah, Y., Burton, R., & Habibi, S. (2003). VISCOUS DAMPING COEFFICIENT AND EFFECTIVE BULK MODULUS ESTIMATION IN A HIGH PERFORMANCE HYDROSTATIC ACTUATION SYSTEM USING EXTENDED KALMAN FILTER. International Journal of Fluid Power, 4(3), 27–34. Retrieved from https://journals.riverpublishers.com/index.php/IJFP/article/view/600

Issue

2003: Vol 04 Iss 3

Section

Original Article