Mathematical Modeling of Pneumatic Artificial Muscle Actuation via Hydrogen Driving Metal Hydride-LaNi5

doi:10.1016/S1672-6529(11)60103-0

摘要/Abstract

摘要：

Quantitative understanding of mechanical actuation of intricate Pneumatic Artificial Muscle (PAM) actuators is technically required in control system design for effective real-time implementation. This paper presents mathematical modeling of the PAM driven by hydrogen-gas pressure due to absorption and desorption of metal hydride. Empirical models of both mechanical actuation of industrial PAM and chemical reaction of the metal hydride-LaNi5 are derived systematically where their interac-tions comply with the continuity principle and energy balance in describing actual dynamic behaviors of the PAM actuator (PAM and hydriding/dehydriding-reaction bed). Simulation studies of mechanical actuation under various loads are conducted so as to present dynamic responses of the PAM actuators. From the promising results, it is intriguing that the heat input for the PAM actuator can be supplied to, or pumped from the reaction bed, in such a way that absorption and desorption of hydrogen gas take place, respectively, in controlling the pressure of hydrogen gas within the PAM actuator. Accordingly, this manipulation results in desired mechanical actuation of the PAM actuator in practical uses.

关键词: mathematical model, pneumatic artificial muscle, metal hydride storage

Abstract:

Key words: mathematical model, pneumatic artificial muscle, metal hydride storage

Thananchai Leephakpreeda. Mathematical Modeling of Pneumatic Artificial Muscle Actuation via Hydrogen Driving Metal Hydride-LaNi5[J]. J4, 2012, 9(1): 110-118.

参考文献

[1] Kao P, Lewis C L, Ferris D P. Invariant ankle moment patterns when walking with and without a robotic ankle exoskeleton. Journal of Biomechanics, 2010, 43, 203–209.

[2] Cullell A, Moreno J C, Rocon E, Forner-Cordero A, Pons J L. Biologically based design of an actuator system for a knee-ankle-foot orthosis. Mechanism and Machine Theory, 2009, 44, 860–872.

[3] Wickramatunge K C. Modeling and Control of Pneumatic Artificial Muscle Actuator, MS thesis, Thammasat University, Hua Hin, Thailand, 2008.

[4] Lioyd G M, Kim K J, Razani A, Shahinpoor M. Investigation of a solar-thermal bio-mimetic metal hydride actuator. ASME Journal of Solar Energy Engineering, 2003, 125, 95–100.

[5] Vanderhoff A, Kim K J. Experimental study of a metal hydride driven braided artificial pneumatic muscle. Journal of Smart Materials and Structures, 2009, 18, 125014.

[6] Ino S, Sato M. A novel soft actuator using metal hydride materials and its applications in quality-of-life technology, in New Developments in Biomedical Engineering, Domenico Campolo (Ed.), InTech, Charlotte, NC, USA, 2010, 499–515.

[7] Ino S, Sato M, Hosono M, Izumi T. Development of a soft metal hydride actuator using a laminate bellows for rehabilitation systems. Sensors and Actuators: B. Chemical, 2009, 136, 86–91.

[8] Kim J, Park I, Kim K J, Gawlik K. A hydrogen-compression system using porous metal hydride pellets of LaNi₅₋_xAl_x. International Journal of Hydrogen Energy, 2008, 33, 870–877.

[9] Wickramatunge K C, Leephakpreeda T. Study on mechanical behaviors of pneumatic artificial muscle. International Journal of Engineering Science, 2010, 48, 188–198.

[10] Askri F, Jemni A, Nasrallah S B. Prediction of transient heat and mass transfer in a closed metal-hydrogen reaction bed. International Journal of Hydrogen Energy, 2004, 29, 195–208.

[11] Dhaou H, Askri F, Salah M B, Jemni A, Nasrallah S B, Lamloumi J. Measurement and modeling of kinetics of hydrogen sorption by LaNi₅ and two related pseudobinary compounds. International Journal of Hydrogen Energy, 2007, 32, 576–587.

[12] Mat M D, Kaplan Y. Numerical study of hydrogen absorption in a LaNi₅ hydride bed. International Journal of Hydrogen Energy, 2001, 26, 957–963.

[13] Førde T, Næss E, Yartys V A. Modelling and experimental results of heat transfer in a metal hydride store during hydrogen charge and discharge. International Journal of Hydrogen Energy, 2009, 34, 5121–5130.

[14] Yang F, Meng X, Deng J, Wang Y, Zhang Z. Identify heat and mass transfer characteristics of metal hydride reactor during adsorption-parameter analysis and numerical study. International Journal of Hydrogen Energy, 2008, 33, 1014–1022.

Laurencelle F, Goyette J. Simulation of heat transfer in metal hydride reactor with aluminum foam. International Journal of Hydrogen Energy, 2007, 32, 2957–2964.