course-details-portlet

FENG1011 - Engineering Thermodynamics

About

Examination arrangement

Examination arrangement: School exam
Grade: Letter grades

Evaluation Weighting Duration Grade deviation Examination aids
School exam 100/100 4 hours D

Course content

Thermodynamic systems, properties and processes; closed and open systems, steady-state and transient processes; work and heat. The 1st law of thermodynamics; state change, internal energy, enthalpy and specific heat. The 2nd law of thermodynamics; reversible and irreversible processes, exergy and entropy. Examples related to renewable energy and use of relevant software

Learning outcome

Knowledge: Candidates must understand - Conservation laws for mass and energy, including the 1st law of thermodynamics. - Energy types such as heat and work, internal energy and enthalpy. - Entropy and the 2nd law of thermodynamics. - Causes of thermodynamic losses due to irreversibility. - Quality of different forms of energy measured as the ability to perform work. - Energy quality destruction of processes. - The ideal gas model, its assumptions, applications, and limitations. - Various thermodynamic cycles such as Carnot, Rankine, Otto, Diesel and Brayton. - The relation between energy, work, and heat in thermodynamic systems. - Operation of steam power plants, gas power plants, internal combustion engines, heat pumps, and cooling systems. - The main components of power/heat process systems, such as steam and gas turbines, compressors, pumps, heat exchangers and valves. - Fluids' ability to change state of matter (solid, liquid and gas). - Simple cycle processes and how enthalpy and entropy are used to describe such processes. - Processes related to the combustion of hydrocarbons. Processes related to moist air. Skills: The candidates must be able to - set up mass and energy balances for simple systems with energy, work, and heat. - analyze simple cycle processes. - estimate thermodynamic properties of systems using tables and graphical charts. - calculate efficiencies for power producing and power consuming processes. - describe thermodynamic processes in graphical charts (pv, Tv, Ts, ph). General competence: - Apply basic thermodynamics in renewable energy-related cases related to wind power, hydropower, biopower and thermal machines. - Basic competence included as key elements in other topics focusing on energy systems and industrial processes. - System understanding and the ability to evaluate the energy and exergy efficiencies (energy quality) of systems. - Overview of processes for power generation, heating (heat pumps) and cooling (cooling units).

Learning methods and activities

Lectures, exercises and semester project (analysis and/or laboratory exercises in groups).

Compulsory assignments

  • Exercises
  • Term paper

Further on evaluation

Examination arrangement: Written exam. Re-sit exams will be held in May/June and August, but it is only possible to attend one of the two re-sit exams. For the re-sit exam, the examination form may be changed from written to oral. Permitted examination aids according to Support material code D: No printed or hand-written support material is allowed. A specific basic calculator is allowed. Semester assignment and 2/3 of the exercises are required approved for admission to the examination. Approved compulsory activity (exercises and semester assignment) will be valid for all subsequent exams in the course.

Specific conditions

Admission to a programme of study is required:
Mechanical Engineering (BIMAS-F)
Mechanical Engineering (BIMASKIN)
Renewable Energy - Engineering (BIFOREN)

Course materials

Principles of Engineering Thermodynamics. Moran, Shapiro, Boettner and Bailey

Lecture notes distributed via blackboard

Credit reductions

Course code Reduction From To
FENA1011 7.5 AUTUMN 2019
FENT1011 7.5 AUTUMN 2019
More on the course

No

Facts

Version: 1
Credits:  7.5 SP
Study level: Foundation courses, level I

Coursework

Term no.: 1
Teaching semester:  AUTUMN 2024

Language of instruction: Norwegian

Location: Gjøvik

Subject area(s)
  • Technological subjects
Contact information
Course coordinator: Lecturer(s):

Department with academic responsibility
Department of Manufacturing and Civil Engineering

Examination

Examination arrangement: School exam

Term Status code Evaluation Weighting Examination aids Date Time Examination system Room *
Autumn ORD School exam 100/100 D 2024-11-27 09:00 INSPERA
Room Building Number of candidates
M433-Eksamensrom 4.etg Mustad, Inngang A 57
Spring UTS School exam 100/100 D INSPERA
Room Building Number of candidates
Summer UTS School exam 100/100 D INSPERA
Room Building Number of candidates
  • * The location (room) for a written examination is published 3 days before examination date. If more than one room is listed, you will find your room at Studentweb.
Examination

For more information regarding registration for examination and examination procedures, see "Innsida - Exams"

More on examinations at NTNU