Hydroacoustic modelling applied in hydraulic components: a test rig based experiment

Arnaud Maillard; Éric Noppe; Benoît Eynard; Xavier Carniel

doi:10.1051/meca/2020055

All issues

Volume 21 / No 5 (2020)

Mechanics & Industry, 21 5 (2020) 528

References

Open Access

Issue		Mechanics & Industry Volume 21, Number 5, 2020


Article Number		528
Number of page(s)		10
DOI		https://doi.org/10.1051/meca/2020055
Published online		03 September 2020

A. Maillard, E. Noppe, B. Eynard, X. Carniel, Ingénierie système et modélisation hydroacoustique appliquées aux composants hydrauliques de puissance, in 22ème Congrès Français de Mécanique, 24–28 aoÛt2015, Lyon, France (FR), AFM, 2015 [Google Scholar]
A. Maillard, E. Noppe, B. Eynard, X. Carniel, Systems engineering and hydroacoustic modelling applied in simulation of hydraulic components, in Proceedings of the International Joint Conference on Mechanics, Design Engineering & Advanced Manufacturing (JCM 2016), Catania, Italy , 2016, 687–696 [Google Scholar]
ISO 15086-1, Hydraulic Fluid Power: Determination of the Fluid-Borne Noise Characteristics of Components and Systems-Part 1: Introduction, 2001 [Google Scholar]
D.N. Johnston, K.A. Edge, M. Brunelli, Impedance and stability characteristics of a relief valve, Proc. Inst. Mech. Eng. I 216 , 371–382 (2002) [CrossRef] [Google Scholar]
K.K. Lau, K.A. Edge, D.N. Johnston, Impedance characteristics of hydraulic orifices, Proc. Inst. Mech. Eng. I 209 , 241–253 (1995) [Google Scholar]
K.A. Edge, D.N. Johnston, The impedance characteristics of fluid power components: relief valves and accumulators, Proc. Inst. Mech. Eng. I 205 , 11–22 (1991) [Google Scholar]
D.N. Johnston, K.A. Edge, The impedance characteristics of fluid power components: restrictor and flow control valves, Proc. Inst. Mech. Eng. I 205 , 3–10 (1991) [Google Scholar]
ISO 15086-3, Hydraulic Fluid Power: Determination of the Fluid-Borne Noise Characteristics of Components and Systems-Part 3: Measurement of Hydraulic Impedance, 2008 [Google Scholar]
ISO 15086-2, Hydraulic Fluid Power: Determination of the Fluid-Borne Noise Characteristics of Components and Systems-Part 2: Measurement of the speed of sound in a Fluid in a Pipe, 2000 [Google Scholar]
S.E.M. Taylor, D.N. Johnston, D.K. Longmore, Modelling of transient flow in hydraulic pipelines, Proc. Inst. Mech. Eng. I 211 , 447–455 (1997) [Google Scholar]
P. Wongputorn, D. Hullender, R. Woods, J. King, Application of MATLAB functions for time domain simulation of systems with lines with fluid transients, J. Fluids Eng. 127 (2005) [Google Scholar]
S.V.H. Tummescheit, Implementation of a transmission line model for fast simulation of fluid flow dynamics, in Proceedings 8th Modelica Conference, Dresden, Germany , 2011, pp. 446–453 [Google Scholar]
N. Johnston, The Transmission Line Method for Modelling Laminar Flow of Liquid in Pipelines, Proc. Inst. Mech. Eng. I 226 , 586–589 (2012) [Google Scholar]
D.N. Johnston, An enhanced transmission line method for modelling laminar flow of liquid in pipelines, Proc. Inst. Mech. Eng. I 228 , 193–206 (2014) [CrossRef] [Google Scholar]
M. Soumelidis, D.N. Johnston, K.A. Edge, D.G. Tilley, A comparative study of modelling techniques for laminar flow transients in hydraulic pipelines, in Proceedings of the 6th JFPS International Symposium on Fluid Power, TSUKUBA, Japan , 2005, 100–105 [CrossRef] [Google Scholar]
B. Gustavsen, A. Semlyen, Rational approximation of frequency domain responses by vector fitting, IEEE Trans. Power Del. 14 , 1052–1061 (1999) [CrossRef] [Google Scholar]
B. Gustavsen, Improving the pole relocating properties of vector fitting, IEEE Trans. Power Del. 21 , 1587–1592 (2006) [CrossRef] [Google Scholar]
D. Deschrijver, M. Mrozowski, T. Dhaene, D. De Zutter, Macromodeling of multiport systems using a fast implementation of the vector fitting method, IEEE Microw. Wireless Comp. Lett. 18 , 383–385 (2008) [CrossRef] [Google Scholar]

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[1] A. Maillard, E. Noppe, B. Eynard, X. Carniel, Ingénierie système et modélisation hydroacoustique appliquées aux composants hydrauliques de puissance, in 22ème Congrès Français de Mécanique, 24–28 aoÛt2015, Lyon, France (FR), AFM, 2015 [Google Scholar]

[2] A. Maillard, E. Noppe, B. Eynard, X. Carniel, Systems engineering and hydroacoustic modelling applied in simulation of hydraulic components, in Proceedings of the International Joint Conference on Mechanics, Design Engineering & Advanced Manufacturing (JCM 2016), Catania, Italy , 2016, 687–696 [Google Scholar]

[3] ISO 15086-1, Hydraulic Fluid Power: Determination of the Fluid-Borne Noise Characteristics of Components and Systems-Part 1: Introduction, 2001 [Google Scholar]

[4] D.N. Johnston, K.A. Edge, M. Brunelli, Impedance and stability characteristics of a relief valve, Proc. Inst. Mech. Eng. I 216 , 371–382 (2002) [CrossRef] [Google Scholar]

[5] K.K. Lau, K.A. Edge, D.N. Johnston, Impedance characteristics of hydraulic orifices, Proc. Inst. Mech. Eng. I 209 , 241–253 (1995) [Google Scholar]

[6] K.A. Edge, D.N. Johnston, The impedance characteristics of fluid power components: relief valves and accumulators, Proc. Inst. Mech. Eng. I 205 , 11–22 (1991) [Google Scholar]

[7] D.N. Johnston, K.A. Edge, The impedance characteristics of fluid power components: restrictor and flow control valves, Proc. Inst. Mech. Eng. I 205 , 3–10 (1991) [Google Scholar]

[8] ISO 15086-3, Hydraulic Fluid Power: Determination of the Fluid-Borne Noise Characteristics of Components and Systems-Part 3: Measurement of Hydraulic Impedance, 2008 [Google Scholar]

[9] ISO 15086-2, Hydraulic Fluid Power: Determination of the Fluid-Borne Noise Characteristics of Components and Systems-Part 2: Measurement of the speed of sound in a Fluid in a Pipe, 2000 [Google Scholar]

[10] S.E.M. Taylor, D.N. Johnston, D.K. Longmore, Modelling of transient flow in hydraulic pipelines, Proc. Inst. Mech. Eng. I 211 , 447–455 (1997) [Google Scholar]

[11] P. Wongputorn, D. Hullender, R. Woods, J. King, Application of MATLAB functions for time domain simulation of systems with lines with fluid transients, J. Fluids Eng. 127 (2005) [Google Scholar]

[12] S.V.H. Tummescheit, Implementation of a transmission line model for fast simulation of fluid flow dynamics, in Proceedings 8th Modelica Conference, Dresden, Germany , 2011, pp. 446–453 [Google Scholar]

[13] N. Johnston, The Transmission Line Method for Modelling Laminar Flow of Liquid in Pipelines, Proc. Inst. Mech. Eng. I 226 , 586–589 (2012) [Google Scholar]

[14] D.N. Johnston, An enhanced transmission line method for modelling laminar flow of liquid in pipelines, Proc. Inst. Mech. Eng. I 228 , 193–206 (2014) [CrossRef] [Google Scholar]

[15] M. Soumelidis, D.N. Johnston, K.A. Edge, D.G. Tilley, A comparative study of modelling techniques for laminar flow transients in hydraulic pipelines, in Proceedings of the 6th JFPS International Symposium on Fluid Power, TSUKUBA, Japan , 2005, 100–105 [CrossRef] [Google Scholar]

[16] B. Gustavsen, A. Semlyen, Rational approximation of frequency domain responses by vector fitting, IEEE Trans. Power Del. 14 , 1052–1061 (1999) [CrossRef] [Google Scholar]

[17] B. Gustavsen, Improving the pole relocating properties of vector fitting, IEEE Trans. Power Del. 21 , 1587–1592 (2006) [CrossRef] [Google Scholar]

[18] D. Deschrijver, M. Mrozowski, T. Dhaene, D. De Zutter, Macromodeling of multiport systems using a fast implementation of the vector fitting method, IEEE Microw. Wireless Comp. Lett. 18 , 383–385 (2008) [CrossRef] [Google Scholar]