Type A

Code 
Competences Specific 

Common 

Professional 

Research 
Type B

Code 
Competences Transversal 

Common 
Type C

Code 
Competences Nuclear 

Common 
Objectives 
Competences 
1) Obtain the skills to analytically derive exact solutions to common problems in transport phenomena. 



2) Write and solve the momentum balance equation to determine velocity profiles, average velocity, volumetric/mass flow rate, pressure drop, friction loss, resultant forces and shaft work in simple flow systems. 



3) Write and solve the energy balance equations to determine temperature profiles and heat flow rates in media through which heat is being transferred. 



4) Write and solve the component continuity equations to determine concentration profiles and mass transfer rates in systems through which mass is being transferred. 



1) Obtain the skills to analytically derive exact solutions to common problems in transport phenomena.




2) Write and solve the momentum balance equation to determine velocity profiles, average velocity, volumetric/mass flow rate, pressure drop, friction loss, resultant forces and shaft work in simple flow systems.




3) Write and solve the energy balance equations to determine temperature profiles and heat flow rates in media through which heat is being transferred.




4) Write and solve the component continuity equations to determine concentration profiles and mass transfer rates in systems through which mass is being transferred.




1) Obtain the skills to analytically derive exact solutions to common problems in transport phenomena.




2) Write and solve the momentum balance equation to determine velocity profiles, average velocity, volumetric/mass flow rate, pressure drop, friction loss, resultant forces and shaft work in simple flow systems.




3) Write and solve the energy balance equations to determine temperature profiles and heat flow rates in media through which heat is being transferred.




4) Write and solve the component continuity equations to determine concentration profiles and mass transfer rates in systems through which mass is being transferred.




Topic 
Subtopic 
PART I 
Laws of conservation:
Systems, infinitesimal volumes of control and elements. Hypothesis of continuity. Sources, wells and chemical reaction.
Constituent equations:
Newton’s Law of viscosity, Fourier’s Law and Fick’s Law. Differential heat and matter balances in static systems. Differentials heat and matter and angular momentum balances in systems of flux of fluids. Determination of temperature profiles, concentration and speed in conventional systems of simple geometry.

PART II 
Design of an excellent equipment in the fields of the new technologies from the first principles treated in the first part of the subject. The students will be able to choose &quot;case study&quot; of the scope of the bioengineering, environmental engineering and engineering of the materials. Also other fields related to minisystems of flow, or without chemical reaction will be able to be considered. 
Methodologies :: Tests 

Competences 
(*) Class hours 
Hours outside the classroom 
(**) Total hours 
Introductory activities 

0 
0 
0 

Lecture 

0 
0 
0 
Problem solving, classroom exercises 

0 
0 
0 

Personal tuition 

0 
0 
0 

Practical tests 

0 
0 
0 

(*) On elearning, hours of virtual attendance of the teacher. (**) The information in the planning table is for guidance only and does not take into account the heterogeneity of the students. 
Methodologies
:: Guia de metodologies docents

Description 
Introductory activities 
Presentació de l'assignatura. 
Lecture 
Expositive classes. 
Problem solving, classroom exercises 
Group problems. 

Description 
Weight 
Problem solving, classroom exercises 
Activitats en grup. 
25% 
Practical tests 
Proves parcials (25%).
Proves finals (50%). 
75% 

Other comments and second call 

Basic 


Incropera F P and DeWitt D P "Fundamentals of heat and mass transfer" John Wiley & Sons, 1996.

Kundu P K "Fluid Mechanics" Academic Press, 1990.

Fox R and McDonald A T "Introduction to fluid mechanics" John Wiley & Sons, 1994. 
Complementary 


Bird R B, Stewart W. E y Lightfoot E N "Transport phenomena", Wiley and Sons, 1960 (Spanish translation: "Fenómenos de transporte" Reverté, 1982).

Welty J R, Wicks C E y Wilson R E "Fundamentals of momentum, heat and mass transfer" John Wiley, 1984 (Spanish translation: "Fundamentos de transferencia de momento calor y masa" Limusa, 1989). 
