Teaching language: Swedish
Course module 

Credit distribution 

Examination dates 
Sp1 
Sp2 
Sp3 
Sp4 
Summer course 
No Sp 
0109 
Examination 
5,5 c 
Grading: TH 

5,5 c







26 Oct 2015 pm V, 
05 Jan 2016 am H, 
17 Aug 2016 pm M 
0209 
Laboratory 
2,0 c 
Grading: UG 

2,0 c








In programs
TKTEM ENGINEERING MATHEMATICS, Year 2 (compulsory)
TKKEF CHEMICAL ENGINEERING WITH ENGINEERING PHYSICS, Year 2 (compulsory)
TKKMT CHEMICAL ENGINEERING, Year 2 (compulsory)
Examiner:
Professor
Lennart Vamling
Replaces
KVM090
Thermodynamics
Go to Course Homepage
Eligibility:
In order to be eligible for a first cycle course the applicant needs to fulfil the general and specific entry requirements of the programme(s) that has the course included in the study programme.
Course specific prerequisites
Basic chemisty, analysis and linear algebra.
Aim
The aims with the course are to provide
 a theoretical basis for and experience in using thermodynamic tools and models, based on the first years s chemistry course.
 the thermodynamic basis for analysis and description of chemical and energy engineering processes.
Learning outcomes (after completion of the course the student should be able to)
Describe the ideal gas model and be able to use the
thermal velocity and
speed distributions in order to
calculate different averages.
Have a
molecular (microscopic) understanding of the concept
of entropy, be able to
explain why thermodynamic processes
are spontaneous and to calculate the
entropy of a substance
from heat capacity data and phase transition
enthalpies.
Derive general relations for closed systems starting from
the
laws of thermodynamics and use these in order to calculate
changes in
state functions for condensed phases, ideal
and real gases and simple phase
transitions.
Be able to use thermodynamic relations, tables and diagrams
as well as the laws of thermodynamics for analysis of and calculations for both
open and closed systems.
Be familiar with and be able to carry out
calculations for standard cycles for conversion from work and heat and vice
versa.
Be able to use the concept efficiency for cycles as well as for
some cycle components.
Be familiar with the concept equationofstate and
be able to use it for calculating changes of state.
Master the concept
phase equilibrium for pure substances as well as for mixtures and be able to
apply it in simpler cases.
Be able to calculate activity coefficients for
components in
binary mixtures from experimental data, to calculate
changes
in state functions when mixing two components, and be able to use simple
activity factor models.
Calculate the equilibrium constant for a chemical
reaction from
data in thermodynamic tables and be able to use the
information
to draw conclusions about the extent of reaction and
the
composition at equilibrium.
Content
The laws of thermodynamics, energy balances, entropy and entropy balances, the
Carnot cycle, thermodynamics for important energy conversion processes (the
Rankine cycle, the refrigeration cycle, and combustion engines including gas
turbines), equations of state and their use, gasliquid equilibrium for pure
fluids as well as for mixtures, activity factor models and thermodynamics for
reacting systems.
Organisation
The course consists of lectures, tutorials, a project and laboratory work.
Computer calculations are an important part of the project. They are mainly
carried out under supervision. The course is given in collaboration between
Physical Chemistry at the Department for Chemistry and Chemical Engineering and
Industrial Energy Systems and Technologies at the Department for Energy and Environment.
Literature
Elliott, J.R.; Lira C.T., Introductory Chemical Engineering Thermodynamics ,
Prentice Hall, 2nd ed.
P. Atkins, L. Jones, Chemical Principles,
Freeman&Co.
Dedicated texts.
Examination
Written examination. Completed and approved project and laboratory work.