Sluiten Help Print
 Cursus: 201500024
 Cursus informatie
Cursus201500024
Studiepunten (ECTS)5
CursustypeCursus
VoertaalEngels
Contactpersoondr.ir. W.K. den Otter
E-mailw.k.denotter@utwente.nl
Docenten
 Docent dr.ir. R. Hagmeijer Contactpersoon van de cursus dr.ir. W.K. den Otter Docent dr.ir. W.K. den Otter
Collegejaar2021
Aanvangsblok
 1B
AanmeldingsprocedureZelf aanmelden via OSIRIS Student
Inschrijven via OSIRISJa
 Cursusdoelen
 body { font-size: 9pt; font-family: Arial } table { font-size: 9pt; font-family: Arial } After the course, the student is able to: Explain/describe phenomena of flow, heat and fluid properties from the principles of thermodynamics. Describe the thermodynamic behavior of multicomponent fluids in the appropriate mathematical structures. Explain / describe models of gases and liquids, co-existing phase systems, chemical reactions. Describe and analyse the behavior of chemical reaction mechanisms. Apply the knowledge to flow systems with heat exchange, chemical reactions and/or phase transitions. Have knowledge on statistical thermodynamics to deepen the understanding of thermodynamic relations. Have knowledge on statistical thermodynamics to understand how the thermodynamic properties of a system derive from the atomistic composition of the system.
 Inhoud
 body { font-size: 9pt; font-family: Arial } table { font-size: 9pt; font-family: Arial } The course starts with a recapitulation of the three laws of thermodynamics, with an emphasis on the concept of entropy. Subsequently the thermodynamic potentials, like enthalpy and the Helmholtz and Gibbs free energies, are introduced through Legendre transformation. The relations between potentials, their differentials and curvature are described by means of the equations of Euler and Gibbs-Duhem. The acquired knowledge is applied to the combination of heat and mass flow. It is demonstrated that the fundamental quantities sought in the laboratory are those which are required for determining the potentials. A thorough discussion will be provided on models for fluids and gases and their equations of state. Subsequently the course will have a smooth transition to statistical mechanics and its relevance to thermodynamics. As the thermodynamic properties of a system ultimately result from the atomic composition of the system, the fundamental relations coupling the macro level to the micro level are discussed and applied to derive thermodynamic potentials and equations of state for crystals, ideal gasses and non-ideal gasses. Finally chemical reaction rates and equilibrium of heterogeneous systems will be presented. The course will provide a thorough background for students who will be studying fluid mechanics, chemical reactor systems or multiphase systems, either experimentally or theoretically.
Voorkennis
 Basic mathematics of partial derivatives and integration of first order ordinary differential equations.
 Participating study
 Master Mechanical Engineering
Verplicht materiaal
Course material
 Notes on Advanced Thermodynamics, by R. Hagmeijer and W.K. den Otter (available online as pdf).
Aanbevolen materiaal
-
Werkvormen
 Lecture Tutorial
Toetsen
 Written exam
 Sluiten Help Print