3MAI3 | Non-equilibrium thermodynamics | Materials and Chemistry | S9 | ||||||
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Lessons : 14 h | TD : 12 h | TP : 0 h | Project : 0 h | Total : 26 h | |||||
Co-ordinator : Julien Cardin |
Prerequisite | |
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General thermodynamics. Statistical thermodynamics. General physics. |
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Course Objectives | |
Summary presentation of global and national energy balances, prospective balance sheets, and the place of renewable energies. Presentation of environmental and climatic issues. Energy management in industry (thermal energy, mechanics, cogeneration) improvement of energy efficiency, heat exchanger networks. This course aims to give students the basics of applied thermodynamics and out of linear equilibrium necessary to understand the mechanisms of production and transport of energy and matter. | |
Syllabus | |
General and basic thermodynamics. Thermodynamic cycles Exergy analysis Thermoelectricity applied to energy conversion (solar, thermoelectricity ...) Thermodynamics and transport Non-equilibrium thermodynamics. |
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Practical work (TD or TP) | |
Energy conversion systems. Energy efficiency of domestic and industrial systems. Thermodynamics of transport phenomena. |
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Acquired skills | |
At the end of the course, students will be able to design and optimize energy conversion systems in a static and out of equilibrium approach. From a fundamental point of view, they will be able to consider the optimization of conversion materials (photovoltaic, thermoelectric, heat pump, etc.) on the basis of the optimization of the working fluid (perfect gas, real gas, electron gas, photon gas). | |
Bibliography | |
Engineering thermodynamics P. Chattopadhyay Thermodynamics and introduction de thermostatistic, H. Callen, Wiley Introduction to Modern Thermodynamics, D. Kondepudi, Wiley Thermodynamique et énergétique vol. 1 & 2, Presses polytechniques et universitaires romandes |
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