1. komponenta

Lecture type	Total
Lectures	30
Laboratory exercises	15
Seminar	15

* Load is given in academic hour (1 academic hour = 45 minutes)

PURPOSE FOR THE COURSE
Study of transport phenomena (momentum, heat and mass transfer).
Considering the fundamentals of unit operations by using the principle of unique approach to transport processes that are fundamental to chemical engineering disciplines and applied sciences.

CONTENTS FOR THE COURSE
The 1st week Opening lecture, Students will be introduced to teaching and knowledge testing for this course, Introduction to fundamental terms - chemical engineering, transport phenomena, unit operations, The key properties of mechanical macroprocesses, thermal and equlibrium separation processes (their differences), General law of conservation, Stationary and non-stationary processes, Flux, Mechanisms of transport phenomena, Viscosity, Rheology (rheological characterization of fluids), Conservation laws for hydrodynamic systems (mass, momentum and energy)

The 2nd week Flow types, Analysis of laminar and turbulent flow in pipe (velocity and momentum distribution, and estimation of energy loss), Moody diagram, Flow through pipeline, Pump power estimation

The 3rd week Flow around obstacle, Flow through bed of particles (porous medium)

The 4th week Characterization of coarse disperse systems

The 5th week Fundamentals of mechanical separation for solid-liquid systems, Gravitational and centrifugal sedimentation, Filtration, Macrofiltration types

The 6th week Fluid flow in mixing unit, Mixing of liquids and suspensions, Design and scaling of process unit for mixing

The 7th week The 1st partial exam

The 8th week Heat transfer by conduction through single- and multi-layered wall. Heat transfer by convection in laminar and turbulent flow. Overall heat transfer. Heat transfer by radiation.

The 9th week Heat exchangers.

The 10th week Mass transfer by diffusion and convection.

The 11th week 2nd partial exam

The 12th week Extraction.

The 13th week Distillation.

The 14th week Drying.

The 15th week 3rd partial exam

Lectures are consecutively followed by seminars and lab tutorials.

GENERAL AND SPECIFIC COMPETENCE
Adoption of knowledges on transport phenomena and fundamentals of unit operations needed for gaining subsequent knowledges on the study programme.

RESPONSIBILITIES FOR THE STUDENTS AND METHODS TO DO SO
Regularly attending classes (lectures, seminars and lab tutorials), writting the lab reports and homeworks.

CRITERION TO ACCESS THE TEST
Regularly attending lecturs and seminars (75%), and successfully finished lab tutorials.

TEACHING MODI
Lectures, seminars and lab tutorials.

KNOWLEDGE TESTING AND EVALUATION
3 partial exams.
The 1st partial exam (momentum transfer and fundamentals of mechanical operations).
The 2nd partial exam (heat and mass transfer, heat exchangers).
The 3rd partial exam (extraction, distillation, drying)

MONITORING OF THE COURSE QUALITY AND SUCCESSFULNESS
By student questionnaire.

LEARNING OUTCOMES FOR THE COURSE
1. To analyse laminar and turbulent flow in pipe from the aspect of velocity and flux distribution, and energy loss.
2. To predict the conditions for successfull process runing on the basis of mathematical descriptions of phenomena.
3. To scan the dispersity state of coarse disperse systems.
4. To predict the progress of separation process, needed separator area, time and driving force for the process by using mathematical descriptions of underlying phenomena.
5. To design and scale of units for successful mixing and separation for real and set conditions.
6. To distinguish different thermal separation processes
7. To identify the need for energy and or mass separating agent for a particular separation process.
8. To differentiate mechanisms for mass and heat transfer and the corresponding resistances in a particular separation process.
9. To evaluate the feasibility of separation process.


LEARNING OUTCOMES FOR THE STUDY PROGRAMME
1. To solve qualitative and quantitative problems using the appropriate chemical principles and theories.
2. To apply knowledge in practice, in particular in problem-solving, relating to both qualitative and quantitative information.
3. To interpret data derived from laboratory observations and measurements in terms of their significance and relation to appropriate theory.

LITERATURE
1 M. Rhodes: Introduction to Particle Technology, John Wiley, London 1998. - optional literature
2 K. Satler, H. J. Feindt, Thermal Separation Processes-Principl and design, VCH Verlagsgesellschaft mbH, Weinheim, 1995. - optional literature
3 Richard G. Griskey, Transport Phenomena and Unit Operations, John Wiley & Sons, Inc., 2006. - optional literature
4 R.W. Fahrien, Fundamentals of Transport Phenomena, Mc Graw-Hill, New York, 1983. - optional literature
5 J.D. Seader, E.J. Henley, Separation Process Principles, John Wiley & Sons, Inc. 2006. - optional literature
6 Internal script: Antun Glasnović, PhD, Prijenos tvari i energije (available on web site of the Faculty of Chemical Engineering and technology). - mandatory literature
7 Course materials: Aleksandra Sander, PhD and Krunoslav Žižek, PhD Predavanja Procesi prijenosa i separacija (available on the web site of the Faculty of Chemical Engineering and technology). - mandatory literature
8 Internal script: Krunoslav Žižek, PhD Fenomen prijenosa količine gibanja, Mehanički makroprocesi. (available on the web sites of the Faculty of Chemical Engineering and technology and Merlin system for e-learning) - optional literature

1. Nastavni materijali, Predavanja Procesi prijenosa i separacija: Red. prof. dr. sc. Aleksandra Sander, Izv. prof. dr. sc. Krunoslav Žižek, (dostupno na mrežnim stranicama Fakulteta kemijskog inženjerstva i tehnologije)., Prof. dr. sc. Aleksandra Sander, Izv. prof. dr. sc. Krunoslav Žižek,
2. Interna skripta - Fenomen prijenosa količine gibanja, Mehanički makroprocesi, Dostupno na mrežnim stranicama Fakulteta i Merlin sustava za e-učenje,, Izv. prof. dr. sc. Krunoslav Žižek,
3. Mehaničko procesno inženjerstvo, M. Hraste, Hinus, 2003.
4. Transport Phenomena and Unit Operations, Richard G. Griskey, John Wiley and Sons, Inc., 2006.
5. Transport Phenomena, Revised 2nd Edition, R. Byron Bird, John Wiley and Sons, Inc., 2006.
6. Fundamentals of Transport Phenomena, R.W. Fahrien, Mc Graw-Hill, New York, 1983.
7. Separation Process Principles, J.D.Seader, E.J. Henley, 2006.
8. Introduction to Particle Technology, M. Rhodes, John Wiley, London, 1998.

Mandatory course - Regular studij - Applied Chemistry