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| TMMV25 | Fluid Mechanics and Heat Transfer, 4 p (sw) /Mekanisk värmeteori och strömningslära gk/ Advancement level: C | |
| Aim: The course will provide basic knowledge of energy technology, as well as examples of technological applications within various fields. Further, an overview is provided of the structure and design of power and thermo-technical plants as well as the machinery and equipment found there. Another objective of the course is to create understanding of the factors influencing the design of energy systems ("boundary conditions").Prerequisites: Analysis, Algebra, Classical physics and Engineering mechanicsSupplementary courses: Energy Technology - project, Aerodynamics, Heat Transfer and Fluid Mechanics, Mechatronics, Models of Mechanics, Computational of Heat Transfer, Computational of Fluid Mechanics, Hydraulic Servo System, Fluid Power Systems and Transmissions , Renewable Energy, Simulation of Energy Systems, Industrial Energy Systems Course organization: The allotted course time is divided into five main sections: I Applied thermodynamics, II Science of Motions III Heat Transfers IV Energy Supply and Distribution, V Energy ConsumptionCourse content: Applied Thermodynamics. Summary of introductory thermodynamics. The first and second principles of thermodynamics applied to technical processes. Constitutional diagrams for true media. Technological processes such as gas turbine, steam power and refrigerating machine processes. Science of motion: Fundamental relationships for flowing fluids. Boundary layers. Impulse batches. Boundary layer separation. Flow around bodies. Flow in pipes and channels. Heat transfer. Basic theories for heat exchange. Thermal conduction, convection and radiation. Thermal transmittance. Technical applications of heat exchange, such as a heat exchanger. Power supply and distribution. Introductory concepts and definitions. Fossil fuels and renewable energy. Thermal power and combined power and heating. Structure of the electrical system. Costs for production and distribution of electricity. Duration. Electricity trade and networks. Structure of municipal heating networks. Energy consumption. Energy consumption in industry, housing, and transportation. Building heating and ventilation. Industrial energy consumption. Energy planning, energy tracking. Efficiency, refueling, and load control. Course literature: Literature: Introduction to Thermal Science, F.W. Schmidt, R.E. Henderson, C.H. Wolgemuth, Wiley, Articles from Mechanical heat theory and science of motion as well as Energy Systems, IKP, LiTH. | ||
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