Checking date: 20/01/2021

Course: 2020/2021

Thermal Engineering
Study: Bachelor in Industrial Technologies Engineering (256)

Coordinating teacher: SANCHEZ GONZALEZ, ALBERTO

Department assigned to the subject: Department of Thermal and Fluids Engineering

Type: Compulsory
ECTS Credits: 6.0 ECTS


Students are expected to have completed
- Calculus I - Calculus II - Physics I
Competences and skills that will be acquired and learning results. Further information on this link
At the end of this course, students will be able to: 1. Know and understand about thermodynamics and heat transfer. 2. Apply their knowledge and understanding to identify, formulate and solve thermodynamic and heat transfer problems using the established methodology. 3. Design and carry out experiments, understand experimental data and obtain conclusions. 4. Have technical and laboratory knowledge. 5. Select and use adequate equipments, tools and methods. 6. Combine theory and practice to solve thermodynamic and heat transfer problems. 7. Understand the limitations of the techniques and methodology applied to thermodynamics and heat transfer.
Description of contents: programme
This is a basic course of Thermodynamics and an introduction to Heat Transfer. The program can be divided in 2 main blocks, one about thermodynamics and another about heat transfer. FIRST PART (THERMODYNAMICS AND CYCLES): - Review of previous concepts of thermodynamics acquired by the student, thermodynamic properties, T-s diagram of water, incompressible liquid and ideal gas models. - Mass, energy and entropy balance for closed systems. - Mass, energy and entropy balance for open systems. - Equipments under steady state: nozzles, diffusers, pumps, compressors, turbines, open and closed heat exchangers, and valves. - Thermal engines. Carnot cycle. - Rankine cycle. - Brayton cycle. - Internal combustion engines. - Inverse Carnot cycle. Refrigeration cycle. SECOND PART (HEAT TRANSFER): - Introduction to heat transfer: Fourier's law, Newton's law, Stefan-Boltzmann's law. - One-dimensional steady state conduction with and without heat generation. Plane wall, cyclindrical and spherical geometries. Thermal resistances. - Transient conduction. - Fins: formulation, design and performance analysis. Finned surfaces.
Learning activities and methodology
The learning methodology includes: (1) Lectures covering the main topics described within the course outline. To facilitate the sessions, the students will have available the lecture's notes as well as reference books to complete their learning. (2) Case study and problem solving lectures, where some issues are addressed from a practical point of view. (3) Exercises solved by the student to self-assess their knowledge and acquire the necessary skills. (4) Group projects.
Assessment System
  • % end-of-term-examination 60
  • % of continuous assessment (assigments, laboratory, practicals...) 40
Basic Bibliography
  • F.P. Incropera and D.P. DeWitt. Fundamentals of Heat and Mass Transfer. John Wiley & Sons. 6th edition. 2007
  • M.J. Moran , H.N. Shapiro. Fundamentals of Engineering Thermodynamics. John Wiley & Sons. 6th edition. 2010
Additional Bibliography
  • A. Bejan. Heat Transfer. John Willey & Sons. 1993
  • J.P. Holman. Heat Transfer. McGraw Hill. 1998
  • F. Kreith y M.S. Bohn. Principles of Heat Transfer. Thomson. 2002
  • Y.A. Çengel. Termodinámica. McGraw Hill. 1996.

The course syllabus and the academic weekly planning may change due academic events or other reasons.