Modelling In Modelica Of A Pneumatic Muscle: Application To Model An Experimental Set-Up

Pujana-Arrese, Aron; Pinzón-Arenas, Javier Orlando; Retolaza, Iban; Martínez-Esnaola, A.; Landaluze, Joseba

doi:10.7148/2007-0466

Cited by 16 publications

(9 citation statements)

References 9 publications

(7 reference statements)

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“…Utilizing the energy conservation principle, the PAM simple geometric force Fg can be calculated as the gauge relative pressure P' multiplied by the change in volume with respect to length (this model can also be found in [17]):…”

Section: Fundamental Pam Modelingmentioning

confidence: 99%

A Survey on applications of Pneumatic Artificial Muscles

Ανδρικόπουλος

Nikolakopoulos

Manesis

2011

2011 19th Mediterranean Conference on Control &Amp; Automation (MED)

149

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The aim of this article is to present a survey on applications of Pneumatic Artificial Muscles (PAMs). PAMs are highly non-linear pneumatic actuators where their elongation is proportional to the interval pressure. During the last decade, there has been a significant increase in the industrial and scientific utilization of PAMs due to their advantages such as high strength and small weight, while various types of PAMs with different technical characteristics have been appeared in the relative scientific literature. This article will summarize the key enabling applications in PAMs that are focusing in the following areas: a) Biorobotic, b) Medical, c) Industrial, and d) Aerospace applications.

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Section: Fundamental Pam Modelingmentioning

confidence: 99%

A Survey on applications of Pneumatic Artificial Muscles

Ανδρικόπουλος

Nikolakopoulos

Manesis

2011

2011 19th Mediterranean Conference on Control &Amp; Automation (MED)

149

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“…Another simple and widely-used geometrical model of PMA is that of Tondu and Lopez [46]. Based on this approach and by: (1) utilizing similar geometric description of the muscle [45]; (2) assuming inextensibility of the mesh material; and (3) angle changes during the alteration of PMA's length, the following expression of the contraction force F generated by the muscle, as a function of the control pressure P and the contraction ratio , based on the theorem of virtual work , is deduced [46,48,49]:…”

Section: Geometrical Model Of Pmamentioning

confidence: 99%

A survey on pneumatic muscle actuators modeling

Kelasidi

Ανδρικόπουλος

Nikolakopoulos

et al. 2011

2011 IEEE International Symposium on Industrial Electronics

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The aim of this article is to provide a survey on the most popular modeling approaches for PMAs (pneumatic muscle actuators). PMAs are highly non-linear pneumatic actuators where their elongation is proportional to the interval pressure. During the last decade, there has been an increase in the industrial and scientific utilization of PMAs, due to their advantages such as high strength and small weight, while various types of PMAs with different technical characteristics have appeared in the literature. This article will: (a) analyse the PMA's operation from a mathematical modeling perspective; (b) present their merits and drawbacks of the most common PMAs; and (c) establish the fundamental basis for developing industrial applications and conducting research in this field.

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“…A free-piston-engine modelled in Modelica is described in Pohl and Gräf [7], containing detailed submodels of several physical domains. In Pujana-Arrese et al [8], a Modelica-model of a pneumatic muscle is presented, combining fluid with mechanical modelling.…”

Section: Introductionmentioning

confidence: 99%

Modelling and simulation of self-regulating pneumatic valves

Pollok

Casella

2017

Mathematical and Computer Modelling of Dynamical Systems

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In conventional aircraft energy systems, self-regulating pneumatic valves (SRPVs) are used to control the pressure and mass flow of the bleed air. The dynamic behaviour of these valves is complex and dependent on several physical phenomena. In some cases, limit cycles can occur, deteriorating performance. This article presents a complex multi-physical model of SRPVs implemented in Modelica. First, the working principle is explained, and common challenges in control-system design-problems related to these valves are illustrated. Then, a Modelica-model is presented in detail, taking into account several physical domains. It is shown, how limit cycle oscillations occurring in aircraft energy systems can be reproduced with this model. The sensitivity of the model regarding both solver options and physical parameters is investigated. ARTICLE HISTORY

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Modelling In Modelica Of A Pneumatic Muscle: Application To Model An Experimental Set-Up

Cited by 16 publications

References 9 publications

A Survey on applications of Pneumatic Artificial Muscles

A Survey on applications of Pneumatic Artificial Muscles

A survey on pneumatic muscle actuators modeling

Modelling and simulation of self-regulating pneumatic valves

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