Process thermodynamics
Some basic information about the module
Cycle of education: 2022/2023
The name of the faculty organization unit: The faculty Chemistry
The name of the field of study: Biotechnology
The area of study: technical sciences
The profile of studing:
The level of study: second degree study
Type of study: full time
discipline specialities : Laboratory diagnostics in biotechnology, Pharmaceutical biotechnology, Process and bioprocess engineering, Purification and analysis of biotechnological products
The degree after graduating from university: Master of Science (MSc)
The name of the module department : Department of Chemical Engineering and Process Control
The code of the module: 7701
The module status: mandatory for the speciality Process and bioprocess engineering
The position in the studies teaching programme: sem: 2 / W15 C15 L15 / 3 ECTS / Z
The language of the lecture: Polish
The name of the coordinator: Prof. Dorota Antos, DSc, PhD, Eng.
The aim of studying and bibliography
The main aim of study: The goal of eductaion is trnasfer the knowledge to students on fundamentals of chemical and technical termodynamics
The general information about the module: Module conists of 15h lecture and 15h seminar, 15 computer laboratory
Bibliography required to complete the module
| 1 | E Kuciel | Termodynamika Procesowa, Wydawnictwo Politechniki Wrocławskiej, | Wrocław . | 1987 |
| 2 | S. Michałowski, K. Wańkowicz | Termodynamika Procesowa | WNT, Warszawa . | 1993 |
| 1 | S. Wroński, R. Pohorecki, J. Siwiński | Przykłady obliczeń z termodynamiki i kinetyki inżynierii chemicznej | WNT, Warszawa. | 1979 |
| 1 | J. Gmehling, B. Kolbe, M. Kleuber, J. Rarey | Chemical Thermodynamics | Wiley-VCH. | 2012 |
Basic requirements in category knowledge/skills/social competences
Formal requirements: Registration for 2nd semester
Basic requirements in category knowledge: Knowledge in the scope of thermodynemics of ideal fluids - basic thermodynamic functions
Basic requirements in category skills: Student is able to determine parameters for ideal fluids
Basic requirements in category social competences: Student is able to work in a team
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 | Equations of state for gases and liquids. Selected thermodynamic functions for pure substances and mixtures. Calculation of mechanical work in selected processes. Fundamentals of thermodynamics cycles. Fundamentals of equilibrium in multi-phase systems. Methods of calculation of fugacity and activity coefficients. Liquid-liquid equilibrium (extraction). Liquid-vapor equilibrium (distillation, evap | lecture | test |
K_W02+ K_W04+ |
P7S_WG |
| 02 | Student is able to determine parameters of real fluids and perameters of phase equilibria | seminar, computer laboratory | test, perfoming computer calculations |
K_U09+ K_U15+ |
P7S_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 |
|---|---|---|---|---|
| 2 | TK01 | wykład, ćwiczenia | MEK01 MEK02 |
The student's effort
| The type of classes | The work before classes | The participation in classes | The work after classes |
|---|---|---|---|
| Lecture (sem. 2) | The preparation for a test:
2.00 hours/sem. |
contact hours:
15.00 hours/sem. |
complementing/reading through notes:
2.00 hours/sem. Studying the recommended bibliography: 10.00 hours/sem. |
| Class (sem. 2) | The preparation for a Class:
2.00 hours/sem. The preparation for a test: 10.00 hours/sem. |
contact hours:
15.00 hours/sem. |
Finishing/Studying tasks:
5.00 hours/sem. |
| Laboratory (sem. 2) | The preparation for a test:
2.00 hours/sem. |
contact hours:
15.00 hours/sem. |
|
| Advice (sem. 2) | The participation in Advice:
2.00 hours/sem. |
||
| Credit (sem. 2) | The preparation for a Credit:
10.00 hours/sem. |
The written credit:
2.00 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 | Lecture: on the basis of merk achieved from the colloquium |
| Class | Classes: on the basis of merk achieved for the colloquium |
| Laboratory | on the basis of excecuted tasks using computer software |
| The final grade | 50% mark from the lecture 30% mark form theclasses 20% from the laboratory |
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 | D. Antos; M. Korbetskyy; P. Mruc; M. Olbrycht | Altering the mobile phase composition to enhance self-disproportionation of enantiomers in achiral chromatography | 2024 |
| 2 | D. Antos; W. Piątkowski | Equilibria and kinetics of ion-exchange | 2024 |
| 3 | D. Antos; M. Balawejder; J. Gumieniak; P. Mruc; M. Olbrycht; W. Piątkowski | Separation of non-racemic mixtures of enantiomers by achiral chromatography | 2023 |
| 4 | D. Antos; M. Kołodziej; W. Piątkowski; T. Rumanek | Preferential precipitation of acidic variants from monoclonal antibody pools | 2023 |
| 5 | D. Antos; M. Kołodziej; W. Piątkowski; T. Rumanek; P. Zimoch | Coupling of chromatography and precipitation for adjusting acidic variant content in a monoclonal antibody pool | 2023 |
| 6 | D. Antos; R. Bochenek; B. Filip; W. Marek | Flow behavior of protein solutions in a lab-scale chromatographic system | 2023 |
| 7 | D. Antos; R. Dürr; A. Kienle; E. Otto; M. Przywara | Modeling of particle formation in pan granulators with sieve-mill recycle | 2023 |
| 8 | D. Antos; R. Muca | Protein association on multimodal chromatography media | 2023 |
| 9 | D. Antos; W. Piątkowski | Kinetic and Thermodynamic Aspects of Hydrophobic Interaction Chromatography | 2023 |
| 10 | D. Antos; I. Poplewska; P. Zimoch | Dissociation events during processing of monoclonal antibodies on strong cation exchange resins | 2022 |
| 11 | D. Antos; A. Bajek-Bil; M. Balawejder; M. Olbrycht; W. Piątkowski | Sposób otrzymywania stereoizomeru szczawianu nafronylu o konfiguracji absolutnej (2S, 2\'R) | 2021 |
| 12 | D. Antos; A. Bajek-Bil; M. Balawejder; M. Olbrycht; W. Piątkowski; I. Poplewska | Development of a Route to the Most Active Nafronyl Stereoisomer by Coupling Asymmetric Synthesis and Chiral Chromatography Separation | 2021 |
| 13 | D. Antos; K. Baran; R. Bochenek; B. Filip; D. Strzałka | Influence of the geometry of extra column volumes on band broadening in a chromatographic system. Predictions by computational fluid dynamics | 2021 |
| 14 | D. Antos; K. Baran; W. Piątkowski; A. Stańczak; P. Zimoch | Separation of charge variants of a monoclonal antibody by overloaded ion exchange chromatography | 2021 |
| 15 | D. Antos; P. Antos; M. Balawejder; R. Bochenek; J. Gorzelany; K. Kania; M. Kołodziej; N. Matłok; M. Olbrycht; W. Piątkowski; M. Przywara; G. Witek | Sposób wytwarzania nawozu wieloskładnikowego o kontrolowanym uwalnianiu składników | 2021 |
| 16 | D. Antos; R. Dürr; A. Kienle; E. Otto; M. Przywara | Population Balance Modelling of Pan Granulation Processes | 2021 |
| 17 | D. Antos; R. Dürr; A. Kienle; E. Otto; M. Przywara | Process Behavior and Product Quality in Fertilizer Manufacturing Using Continuous Hopper Transfer Pan Granulation—Experimental Investigations | 2021 |
| 18 | D. Antos; W. Piątkowski; I. Poplewska | A case study of the mechanism of unfolding and aggregation of a monoclonal antibody in ion exchange chromatography | 2021 |
| 19 | D. Antos; A. Górak; M. Jaworska | Review on the application of chitin and chitosan in chromatography | 2020 |
| 20 | D. Antos; G. Carta; M. Kołodziej; R. Muca; W. Piątkowski | Effects of negative and positive cooperative adsorption of proteins on hydrophobic interaction chromatography media | 2020 |
| 21 | D. Antos; J. Beck; A. Durauer; R. Hahn; A. Jungbauer; M. Kołodziej; W. Marek; W. Piątkowski; D. Sauer | Scale up of a chromatographic capture step for a clarified bacterial homogenate - Influence of mass transport limitation and competitive adsorption of impurities | 2020 |
| 22 | D. Antos; K. Baran; A. Stańczak | A high-throughput method for fast detecting unfolding of monoclonal antibodies on cation exchange resins | 2020 |
| 23 | D. Antos; P. Antos; M. Balawejder; R. Bochenek; M. Kołodziej; N. Matłok; M. Olbrycht; W. Piątkowski; M. Przywara | Mechanism of nutrition activity of a microgranule fertilizer fortified with proteins | 2020 |
| 24 | D. Antos; K. Baran; W. Marek; W. Piątkowski | Effect of flow behavior in extra-column volumes on the retention pattern of proteins in a small column | 2019 |
| 25 | D. Antos; M. Balawejder; H. Lorenz; M. Olbrycht; W. Piątkowski; I. Poplewska; A. Seidel-Morgenstern | Cooperative Kinetic Model to Describe Crystallization in Solid Solution Forming Systems | 2019 |
| 26 | D. Antos; M. Kołodziej; A. Łyskowski; W. Piątkowski; I. Poplewska; P. Szałański | Determination of protein crystallization kinetics by a through-flow small-angle X-ray scattering method | 2019 |
| 27 | D. Antos; P. Antos; M. Balawejder; R. Bochenek; J. Gorzelany; K. Kania; M. Kołodziej; N. Matłok; M. Olbrycht; W. Piątkowski; M. Przywara; G. Witek | Sposób wytwarzania nawozu wieloskładnikowego o kontrolowanym uwalnianiu składników | 2019 |