The aim of studying and bibliography

The main aim of study: Provide to students the knowledge essential to understand individual operations of the chemical engineering.

The general information about the module: The module is implemented in the forth semester. It includes 30 hours of lectures, 30 hours of classes.

Bibliography required to complete the module

Bibliography used during lectures

1	Tadeusz Hobler	Ruch ciepła i wymienniki	WNT.	1976
2	Tadeusz Hobler	Dyfuzyjny ruch masy i absorbery	WNT.	1979
3	Michałowski; Cz. Strumiłło; R. Zarzycki	Teoretyczne podstawy inżynierii chemicznej	WNT.	1985
4	Praca zbiorowa pod red. Zdzisława Ziółkowskiego	Podstawowe procesy inżynierii chemicznej. Przenoszenie pędu, ciepła i masy,	PWN.	1982
5	C.O.Bennet, J.E.Myers	Przenoszenie pędu, ciepła i masy	WNT.	1967
6	Dorota Antos, Krzysztof Kaczmarski, Wojciech Piątkowski	Wymiana ciepła - materiały pomocnicze	Pol. Rzeszowska.	2011
7	Krzysztof Kaczmarski i Wojciech Piątkowski	Przenoszenie masy - materiały pomocnicze	Politechnika Rzeszowska.	2011

Bibliography used during classes/laboratories/others

1	Roman Zarzycki	Zadania rachunkowe z inżynierii chemicznej	PWN.	1980
2	Zdzisław Kawala; Maksymilian Pająk; Jan Szust	Zbiór zadań z podstawowych procesów inżynierii, część I,II,III	Pol. Wrocławska., .	1980
3	praca zbiorowa pod redakcją T.Kudry	Zbiór zadań z podstaw teoretycznych inżynierii chemicznej i procesowej	WNT.	1985

Basic requirements in category knowledge/skills/social competences

Formal requirements: registration for the given semester

Basic requirements in category knowledge: Student has knowledge from the range of mathematics on the level of the basic courses of mathematics at the Universities.

Basic requirements in category skills: Student has a skill for self-education.

Basic requirements in category social competences: NONE

Module outcomes

MEK	The student who completed the module	Types of classes / teaching methods leading to achieving a given outcome of teaching	Methods of verifying every mentioned outcome of teaching	Relationships with KEK	Relationships with PRK
01	Student has an elementary knowledge about laws ruling the heat and mass transport within one phase as well as between not mixing phases. He knows basic equations for the energy and mass. balance. He has elementary knowledge of the method of designing periodic and continuous mass and heat exchangers.	lecture	exam	K_W03+ K_W04+ K_W05+	P6S_WG
02	Student is able to solve equations of the heat and mass balance for simple problems.	exercises for lectures	Colloquium	K_U04+ K_U05+ K_U06+ K_U18+ K_U19+ K_K01+	P6S_KK P6S_UO P6S_UU P6S_UW

Attention: Depending on the epidemic situation, verification of the achieved learning outcomes specified in the study program, in particular credits and examinations at the end of specific classes, can be implemented remotely (real-time meetings).

The syllabus of the module

Sem.	TK	The content	realized in	MEK
4	TK01	Energy transport. Steady and unsteady heat conduction. First Fourier low and its application. Differential energy balance, method of solution of energy balance equation. Heat convection, heat transfer, Newton equation, overall heat transfer. Energy transport by radiation. Energy transport by convection and radiation. Basics rules of heat exchanger designing. Mass transport. Steady and unsteady diffusion. First and second Fick law. Maxwell-Stefan equations for multicomponent diffusion. Differential mass balance. Exemplary analytical solution of mass balance equation. Estimation of diffusion coefficients. Mass convection, single-phase, two-phase mass transfer. Basics rules of mass exchanger designing. Theoretical one stage exchanger, multi stage exchanger, exchanger with continuous phase contact. Axial dispersion.	W30, C30	MEK01 MEK02

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 4)		contact hours: 30.00 hours/sem.	complementing/reading through notes: 10.00 hours/sem.
Class (sem. 4)	The preparation for a Class: 10.00 hours/sem. The preparation for a test: 15.00 hours/sem.	contact hours: 30.00 hours/sem.
Advice (sem. 4)		The participation in Advice: 5.00 hours/sem.
Exam (sem. 4)	The preparation for an Exam: 30.00 hours/sem.	The written exam: 1.00 hours/sem.

The way of giving the component module grades and the final grade

The type of classes	The way of giving the final grade
Lecture	exam - final grade - arithmetic mean of the grades obtained for each question
Class	test
The final grade	((exam grade)*0.7+( exercises grade)*0.3)*w, but not less than 3 w - coefficient taking into account the term when positive final grade was obtained, w = 1,0 first term, w = 0,9 second term, w = 0,8 third term.

Sample problems

Required during the exam/when receiving the credit
(-)

Realized during classes/laboratories/projects
(-)

Others
(-)

Can a student use any teaching aids during the exam/when receiving the credit : no

The contents of the module are associated with the research profile: yes

1	E. Chmiel-Szukiewicz; A. Szałek; M. Szukiewicz	Graph Theory in Chemical Kinetics Practice Problems	2024
2	E. Chmiel-Szukiewicz; M. Szukiewicz	Generalized Linear Driving Force Formulas for Diffusion and Reaction in Porous Catalysts	2024
3	E. Chmiel-Szukiewicz; M. Szukiewicz; L. Zaręba	Application of the kinetic polynomial idea to describecatalytic hydrogenation of propene	2024
4	K. Kaczmarski; M. Szukiewicz	Analytical and numerical solutions of linear and nonlinear chromatography column models	2024
5	T. Fornstedt; K. Kaczmarski; M. Leśko; J. Samuelsson	Prediction of overloaded concentration profiles under ultra-high-pressure liquid chromatographic conditions	2024
6	W. Czechtizky; T. Fornstedt; M. Jora; K. Kaczmarski; T. Leek; M. Leśko; J. Samuelsson; K. Stavenhagen	Strategies for predictive modeling of overloaded oligonucleotide elution profiles in ion-pair chromatography	2023
7	K. Kaczmarski; E. Lorenc-Grabowska; M. Przywara	Advanced modelling of adsorption process on activated carbon	2022
8	T. Fornstedt; K. Kaczmarski; M. Leśko; J. Samuelsson	A closer study of overloaded elution bands and their perturbation peaks in ion-pair chromatography	2022
9	A. Szałek; M. Szukiewicz	Application of transfer function for quick estimation of gas flow parameters—A useful model‐based approach to enhancing measurements	2021
10	E. Chmiel-Szukiewicz; A. Szałek; M. Szukiewicz	Kinetic investigations of heterogeneous reactor processes – Optimization of experiments	2021
11	K. Kaczmarski; M. Szukiewicz	An efficient and robust method for numerical analysis of a dead zone in catalyst particle and packed bed reactor	2021
12	K. Kaczmarski; M. Szukiewicz	Modeling of a Real-Life Industrial Reactor for Hydrogenation of Benzene Process	2021
13	M. Chutkowski; K. Kaczmarski	Impact of changes in physicochemical parameters of the mobile phase along the column on the retention time in gradient liquid chromatography. Part A – temperature gradient	2021
14	T. Fornstedt; E. Glenne; K. Kaczmarski; M. Leśko; J. Samuelsson	Predictions of overloaded concentration profiles in supercritical fluid chromatography	2021
15	T. Fornstedt; K. Kaczmarski; M. Leśko; J. Samuelsson	Experimental and theoretical investigation of high- concentration elution bands in ion-pair chromatography	2021
16	D. Asberg; T. Fornstedt; K. Kaczmarski; M. Leśko; J. Samuelsson	Evaluating the advantages of higher heat conductivity in a recently developed type of core-shell diamond stationary phase particle in UHPLC	2020
17	M. Chutkowski; K. Kaczmarski	Note of solving Equilibrium Dispersive model with the Craig scheme for gradient chromatography case	2020
18	M. Szukiewicz	Differential quadrature method for some diffusion-reaction problems	2020
19	M. Szukiewicz	Study of reaction - diffusion problem: modeling, exact analytical solution, and experimental verification	2020
20	E. Chmiel-Szukiewicz; K. Kaczmarski; A. Szałek; M. Szukiewicz	Dead zone for hydrogenation of propylene reaction carried out on commercial catalyst pellets	2019
21	M. Chutkowski; G. Król; M. Szukiewicz	Formation of dead zone in catalytic particles in catalysis and biocatalysis - New alternative method of determination	2019
22	M. Szukiewicz; M. Wójcik	A simple method of determination of the degree of gas mixing by numerical Laplace inversion and Maple	2019