Module Notes
Faculty Member (Members):
Undergraduate, 5th Semester (3rd Year, Fall)
Module Category: Compulsory Modules
Module Type: Core Chemical Engineering
Teaching Language: English/Greek
Course Code: CHM_540
Credits: 4
ECTS Credits: 6
Teaching Type: Lectures (3h/W) Τutorial (2h/W)
Module Availability on Erasmus Students: Yes
Course URL: E-Class (CMNG2196)
Module Details

Apply principles and methods of General Chemistry, Physical Chemistry , Classical Thermodynamics and Calculus in solving Chemical Engineering Problems.

Ability to create models of any  process based on properly chosen control volumes and input/output  streams, and to subsequently solve them using the corresponding material, energy and entropy balances.

Mastering the use of key chemical engineering concepts, like model formulation and property-balances application  thereon,   in diverse technological areas.

Ability to appreciate the impact of engineering calculations (and the uncertainties thereof), when applied on problems involving critical economic, environmental and health/safety issues, via selected worked out  examples.

Students are expected to have basic knowledge from Mathematics, General and Inorganic Chemistry, Organic Chemistry, Thermodynamics I & II.

1. Brief summary of the concept of  Balances: Importance of Balances for Chemical Engineers  - Introduction to technical calculations.

2. Material Balances: Applications to simple and complex systems with and without chemical reactions. Industrial applications (Recycle – Bypass - Purge).

3. Calculations of thermodynamic property changes: Empirical equations of state. Multiparametric Corresponding States correlations (Lee- Kessler and Pitzer correlations - Nelson-Obert charts). Enthalpy and entropy change calculations from equations of state and  specific heat data. Thermodynamic charts, Steam Tables.  Calculating ΔΗ, ΔS using Corresponding States correlations to evaluate residual thermodynamic properties.

4. Material and Energy Balances:  Applications to systems with and without chemical reactions.

5. Entropy and an additional balance equation for closed and open systems. Calculation of entropy changes. Reversibility and irreversibility. Different forms of the 2nd thermodynamic law. Implications of the 2nd thermodynamic law for heat and work engines.

6. Some first applications of the entropy balance. Calculating if a process is possible or not. Availability and the maximum useful shaft work.

6. Combining material, energy and entropy balances. Thermodynamic analysis of processes. Power generation and refrigeration cycles: Carnot, Rankine, Stirling, Erickson, and Brayton cycles. Heat pumps. T-s and P-h diagrams. Thermodynamic efficiency. Isentropic coefficient. The Rankine cycle in the production of electric energy. The Linde process.

7. Explosions and their thermodynamics.

Teaching Organization

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