Module Notes

Chemical Reaction Engineering ΙΙ

0
This module will not be offered for this semester
Faculty Member (Members)
kyriakg,simeon
Undergraduate
Fall
4th Year
7th Semester (4th Year, Fall)
Module Type
Core Chemical Engineering
Module Category
Compulsory Modules
Course Code:
CHM_841
Course URL:
Credits:
4
ECTS Credits:
6
Module Availability on Erasmus Students:
No
Teaching Language:
Greek
Laboratory:
Lectures:
3h/W
Τutorial:
2h/W
Project/Homework:
Teaching Type
Student's office hours:
Module Details

A good understanding of the basic principles and applications of heterogeneous catalysis and of the structure of solid catalysts.

A good understanding of the concept of the intrinsic rate of catalytic reactions and of the concept of the global (overall) rate.

Ability to develop the intrinsic rate of catalytic reactions through their mechanism and to test it with experimental data.

Ability to incorporate phenomena of external and/or internal mass and heat transfer to the intrinsic rate and develop the global rate of catalytic reactions.

Familiarization with the different models of simulation of catalytic reactors and their basic assumptions

Chemical Reaction Engineering I

  1. Qualitative description of various types of heterogeneous reactors.
  2. The catalytic action, catalytic reactions, preparation and characterization of catalysts.
  3. Mechanisms of catalytic reactions and development of the intrinsic rate.
  4. Mass and heat transport phenomena in various reactor types.
  5. Internal mass and heat transport phenomena. Effectiveness factor.
  6. Catalytic reactor models and basic principleas of their simulation.

Teaching Organization

LECTURES: 3 h/w
RECITATION: 2 h/w

Total Module Workload (ECTS Standards):

150 Hours

Problem solving through the entire semester (mandatory)

One or two quizzes during the term.

Final written exam at the end of the term

1. X. E. Verykios, “ Heterogeneous Catalytic Reactions and Reactors”, Kostarakis Publications, Athens 2004 (in Greek)

2. M. Smith, “Chemical Engineering Kinetics”, McGraw-Hill, New York 1981.