Course code: 252601 | Subject title: HEAT TRANSFER | ||||
Credits: 3 | Type of subject: Mandatory | Year: 3 | Period: 2º S | ||
Department: Ingeniería | |||||
Lecturers: | |||||
ARAIZ VEGA, MIGUEL (Resp) [Mentoring ] |
Study of the conduction, convection and radiation heat transfer phenomena. General Heat Conduction Equation: convection and radiation boundary conditions. Convective coefficient estimation: dimensionless numbers. Thermal radiation study: laws, view factor, net radiation heat transfer.
CG1: Ability to develop and complete industrial engineering projects whose objective is to build, repair, maintain, install, and assemble structures, mechanical equipment, energy installations, electric and electronic installations, facilities, and production and assembly processes.
CG2: Project, calculate and design products, processes, facilities and plants.
CG3: Knowledge of basic and technological subjects to have the ability to learn new methods and theories, and versatility to adapt to new situations.
CG4: Problem solving proficiency with personal initiative, decision making, creativity and critical reasoning. Ability to elaborate and communicate knowledge, abilities and skills in industrial engineering.
CG5: Knowledge to perform measurements, calculations, assessments, appraisals, surveys, studies, reports, work plans and similar work.
CM3: Get applied thermal engineering knowledge.
CTA1: Ability to use, set and maintain thermal systems and equipment.
After the training, the students is able to:
Acquire knowledge in matters related to thermotechnology
Solve heat transfer systems and apply their knowledge to the design and estimation of heat exchangers and insulation devices.
Acquire knowledge which would be the basis of future subjects related to heat transfer as a min phenomenon.
Express and communicate ideas related to thermal and heat transfer systems.
Methodology-Activity | On-site hours | Off-site hours |
A-1 Lectures | 20 | |
A-2 Practical sessions | 10 | |
A-3 Discussions and seminar | ||
A-4 Assigned work development | ||
A-5 Reading materials | ||
A-6 Self-study | 40 | |
A-7 Exams and assessment | ||
A-8 Tutoring | ||
Total | 30 | 40 |
Methodology - Activity | Weight (%) |
Short-answer exam | 0 |
Long- answer exam | 100 |
Multiple-choice exam | 0 |
Oral presentation | 0 |
Teamwork projects | 0 |
Reports of experimental work | 0 |
There will be one ordinary final exam which include a theoretical part as well as a practical one. Those students who have not passed the subject before or those who want to get a better mark could sit for an extraordinary final exam, with the same structure. These exams could include some long-answer theoretical and practical questions, or several shot-answer questions (that could be multiple choice as well).
It would be necessary to get a 5 out of 10, in order to pass the subject.
Only those who have not attended any of the final exams could appear as No presentado in the minute of the subject
Chapter 1: Introduction
Chapter 2: Steady one-dimensional heat conduction
Chapter 3: Transient heat conduction
Chapter 4: Fundamentals of convection
Chapter 5: Forced convection
Chapter 6: Natural convection
Chapter 7: Fundamentals of thermal radiation
Chapter 8: Radiation heat transfer
Access the bibliography that your professor has requested from the Library.
Reference books: