last modified:
Course name: Dynamic Modeling and Simulation of Energy
Conversion Systems |
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This concerns a Course |
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ECTS credit points: 3 |
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Faculty of Mechanical
Engineering and Marine Technology |
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Lecturer(s):
Dr. ir. P. Colonna |
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Catalog data:
Physical modeling of dynamic systems,
Simulation, Laws of conservation, Lumped parameters models, Causality, Energy
conversion systems, Thermodynamics, Heat Transfer, Fluid Dynamics, Ordinary
Differential Equations, Numerical Analysis, Modularity, Linearization,
Process components, Power plant, Cogeneration, Trigeneration, Fluid
Properties, Simulation software, Real time Simulation, Model validation,
Simulators. |
Course year: |
MSc 1st year |
Semester: |
2A |
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Hours per week: |
4 |
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Other hours: |
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Assessment: |
Other 1) see remarks |
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Assessment periods: |
After 1A, after 1B, after 2B |
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(see academic
calendar) |
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Prerequisites (course codes): |
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Follow up (course codes): |
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Detailed description of topics:
Part 01 Introduction:
and review of basic concepts of dynamic modeling
Part 02 Numerical methods and
Model Analysis
Part 03 Conservation laws
Part 04 Fluid Properties, Heat
Transfer, Fluid Dynamics, Combustion
Part 05 Modularity
Part 06 Model validation
Part 07 Energy conversion
systems
Part 08 Training in Simulink and
application to energy conversion systems
Part 09 Steam Power Plant
components: examples.
Part 10 Boiler dynamics
Part 11 Distillation column
Part 12 Tools for modeling and
simulation
Part 13 Plant Simulators |
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Course material: |
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References from literature:
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Remarks assessment, entry requirements, etc.:
Students' proficiency is assessed during an
oral exam in which the student presents his technical report detailing the
modeling and simulation project. Theoretical aspects are tested during the
discussion of the submitted report. |
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Learning goals:
The objective of the course is to give students
a method to design and implement complex dynamic models of energy conversion
systems, using basic principles and
fundamental engineering knowledge in the fields of thermodynamics, fluid
dynamics and heat transfer. The theoretical fundamentals of dynamic modeling
are complemented by an initial training in the use of advanced software to
implement the designed models and simulate and analyze the involved
processes. Students acquire tools currently employed in modern engineering
practice.
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Computer use:
The computer is used to build dynamic models of
energy conversion systems and to run simulations for the purpose of
validating and analyzing the response of the system. Specific software for
dynamic modeling of Engineering systems is employed. Due to licenses
availability on campus, Mathworks Simulink is suggested. |
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Laboratory project(s):
Technical Report of the modeling and simulation
project (teams of 2 students are suggested) |
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Design content:
Modeling and simulation of an energy conversion
system formed by several components. |
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