Conduction Model Compatible for Multi-Physical Domain Dynamic Investigations: Bond Graph Approach
Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33093
Conduction Model Compatible for Multi-Physical Domain Dynamic Investigations: Bond Graph Approach

Authors: A. Zanj, F. He

Abstract:

In the current paper, a domain independent conduction model compatible for multi-physical system dynamic investigations is suggested. By means of a port-based approach, a classical nonlinear conduction model containing physical states is first represented. A compatible discrete configuration of the thermal domain in line with the elastic domain is then generated through the enhancement of the configuration of the conventional thermal element. The presented simulation results of a sample structure indicate that the suggested conductive model can cover a wide range of dynamic behavior of the thermal domain.

Keywords: Multi-physical domain, conduction model, port-based modeling, dynamic interaction, physical modeling.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1123576

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1300

References:


[1] F. Cellier, Continuous System Modeling, New York: Springer-Verlag, 1991.
[2] w. k. Nowacki, "Progress in Thermoelasticity," European Mechanics Colloquium, 1967.
[3] J. Thoma, Simulation by Bond graph, Verlag: Springer, 1990.
[4] A. Mukherjee, R. Karmakar, Modeling and Simulation of Engineering Systems through Bon dgraph, New Delhi, India: Narosa Publishing House, 2000.
[5] D.C. Karnopp, R.C. Rosenburg, System Dynamics: A Unified Approach, Wiley Inter sciences, 1975.
[6] H. Afshari, A. Zanj, "Dynamic Analysis of a Nonlinear Pressure Regulator Using Bond graph Simulation Technique," Journal of Simulation Modeling Practice and Theory, 2010.
[7] A. Zanj, H. Karimi, A.J. Gholi, M. Shafiee, "Dynamic Modeling of Indirect Hydro-Control Valve – Bond graph Approach," Journal of Simulation, Modeling, Practice and Theory, 2012.
[8] E. L. Wilson, Three-Dimensional Static and Dynamic Analysis of Structures, California: Conputers and Structures, Inc, Berkeley, 2002.
[9] H. F. Brinson, L. C. Brinson, "Stress and Strain Analysis and Measurement," in Polymer Engineering Science and Viscoelasticity an Introduction, Springer, 2008, pp. 16-53.
[10] J. Peraire, P. O. Persson, "High-Order Discontinuous Galerkin Methods for CFD, In Adaptive High-Order Methods in Computational Fluid Dynamics," World Scientific series in Advances in Computational Fluid Dynamics, vol. 2, pp. 119-152, 2010.
[11] W. Borutzky, Bond Graph Methodology: Development and Analysis of Multidisciplinary Dynamic System Models, Springer, 2010.
[12] P. Breedveld, Physical System Theory in Terms of Bond graphs, Enschede: Univercity of Twente, 1984.
[13] J. U. Thoma, Simulation by Bondgraph, springer, 1990.
[14] A. Mukherjee, R. Karmakar, Modeling and Simulation of Engineering System through Bondgraph, New Dehli: Narosa Publishing House, 2000.
[15] D.C. Karnopp, R.C. Rosenburg, System Dynamics: A Unified Approach, Wiley Inter sciences, 1975.
[16] A. Zanj, F. He " A Thermomechnical Enhanced Elastic Model: Bond Graph Approach, "23rd International Congress on Sound and Vibration, Athens, Greece, July, 2016.
[17] A. Zanj, H. Afshari, "Dynamic Analysis of a Complex Pneumatic Valve Using Pseudobond Graph Modeling Technique," Journal of Dynamic System, Measurement, and Control, vol. 135, no. 3, 2013.