Alternatywne i odnawialne źródła energii... 2 Base unit processes in chemical technology... 6 Calculation of technical chemistry...

Transcription

1 Alternatywne i odnawialne źródła energii... Base unit processes in chemical technology... 6 Calculation of technical chemistry... 1 Catalytic processes in oil industry Chemical and engineering thermodymics... 1 Chemical Engineering... 7 Chemical technology-raw materials and organic industry processes Chemical technology-raw materials and energy carriers Corrosion protection and industrial electrochemical processes Inorganic Technical Chemistry Investment and chemical plants maintenance principles Laboratory of surfactants technology II Materials science Measurements and Automatics Optimization of chemical processes and electrochemical production processes Physicochemistry of coal and carbon materials... 7 Physicochemistry of petroleum and derived materials Quality control of raw materials and products Quality Management Small volume chemical production Strategies of sustainable development Systems of management of the technological process and quality Technical organic chemistry Technical safety Technological project Technology of Coal and Carbon Materials Technology of Fine Chemicals Technology of disperse systems The industrial laboratory of crude oil and coal technology I The industrial laboratory of crude oil and coal technology II

2 Wroclaw University of Technology Faculty of Chemistry SUBJECT CARD Name in Polish Alternatywne i odnawialne źródła energii Name in English Alternative and renewable energy sources Main field of study (if applicable): Chemical Technology Specialization (if applicable):.. Level and form of studies: 1st level, full-time* Kind of subject: optional* Subject code TCC Group of courses NO* Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Lecture crediting with grade* For group of courses mark (X) final course Number of ECTS points including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) 1.0 classes *delete as applicable Zał. nr 4 do ZW 64/01 Classes Laboratory Project Seminar PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 1. \ SUBJECT OBJECTIVES C1 Getting knowledge of the possibility of obtaining energy from alternative sources C Getting knowledge about impact of alternative and renewable energy production on environment SUBJECT EDUCATIONAL EFFECTS relating to knowledge: PEK_W01 able to define alternative and renewable energy sources and determine their importance in modern energy systems PEK_W0 able to critically evaluate renewable energy sources PEK_W03 know the future possibilities of renewable energy production PEK_W04 is capable to evaluate essentially the renewable sources of energy from an economic point of view PEK_W05 has the basic knowledge about an environmental risks, associated with alternative PROGRAMME CONTENT Form of classes - lecture Number of hours Lec 1 Alternative energy sources. Introduction and basic concepts. The 1

3 importance of alternative energy for the economy. Classification of conventional and alternative methods of energy production Lec Fuel cells. Basic concepts, principle of operations. Classification of fuel cells in view of: fuel, electrolyte, the work temperature. Fuel cell applications Lec 3 Hydrogen as fuel in future. Production of hydrogen. Hydrogen storage. Hydrogen safety. Lec 4 Magnetohydrodynamic power plants. Conventional fossil fuels power 1 plants, thermodynamic limits. Energy efficiency improvements. Lec 5 Solar energy. Conversion of solar radiation into useful energy using various technologies. Solar thermal energy. Lec 6 Solar photovoltaics (PV). Basic principles and a brief history of PV. Efficiency of photovoltaics. Innovative PV technologies. The application of photovoltaic cells Lec 7 Geothermal energy. The source of heat and its availability. Technologies for geothermal resource exploitation. Resources of high-enthalpy stem fields, dry steam power plant, resources for direct use of geothermal energy. Environmental impact and safety of geothermal energy. Geothermal energy in Poland. Lec 8 Wind energy. Wind energy sources Wind energy potential. A brief history of wind energy. Environmental impact. Lec 9 Non-conventional hydroelectricity. Small-scale hydroelectricity as elements in a power system. Hydrological effect. Types of hydroturbines. Tidal power. Wave energy resources. The energy of ocean currents. Ocean thermal energy conversion. Lec 10 Biomass as a fuel. Main bioenergy conversion routes. Combustion of solid biomass: wood and crop residues, municipal solid wastes. Environmental benefits and impact. Lec 11 Gaseous and liquid fuels from biomass. Anaerobic digestion. Large scale anaerobic digestion plants. Fermentation to produce ethanol. From wood to liquid fuel. Lec 1 History and development of nuclear energy. Natural radioactivity. The interaction of neutrons with matter. Nuclear fission. Fissile isotopes. Lec 13 Nuclear weapons. The discovery and proliferation of nuclear weapons. Development of nuclear weapons. Nuclear weapons, a threat to humanity Lec 14 Non-conventional nuclear energy. Safety of nuclear techniques. Natural nuclear reactors. Radionuclides as an energy source. Lec 15 Nuclear fusion. Physical fundamentals of fusion. Attempts to peaceful use of nuclear fusion. Nuclear fusion in stars. Lec 16 Energy storage problems. 1 Lec 17 Summary and conclusion. Test. 1 Total hours 30 TEACHING TOOLS USED N1. Lecture with multimedia presentation EVALUATION OF SUBJECT EDUCATIONAL EFFECTS ACHIEVEMENT 3

4 Evaluation (F forming (during semester), P concluding (at semester end) Educational effect number Way of evaluating educational effect achievement P (Lecture) PEK_W01-PEK_W05 Test PRIMARY AND SECONDARY LITERATURE PRIMARY LITERATURE: [1] W. M. Lewandowski. Proekologiczne źródła energii odnawialnej. WNT, Warszawa 001. [] Red. J. Szlachta. Niekonwencjonalne źródła energii. WAR, Wrocław [3] A. J. Rotter. Bomba atomowa, Świat wobec zagrożenia. PWN, Warszawa 011. [4] J. Kubowski. Broń jądrowa. WNT, Warszawa 005. [5] H. Drulis, J. Hanuza, D. Hreniak, M. Miller, G. Paściak, W. Stręk. Ogniwa paliwowe, nowe kierunki rozwoju. Wiadomości chemiczne, biblioteka. Wrocław, 005. SECONDARY LITERATURE: [1] G. Charpak, R. L. Garwin. Błędne ogniki i grzyby atomowe. WNT, Warszawa [] J. Taubman. Węgiel i alternatywne źródła energii. Prognozy na przyszłość. PWN, Warszawa 011. [3] G. Jastrzębska. Ogniwa słoneczne. WKŁ, Warszawa 013. [4] K. Hoffmann. Wina i odpowiedzialność, Otto Hahn, Konflikty uczonego. WNT, Warszawa, [5] B. Burczyk. Biomasa. Oficyna Wyd. Politechniki Wr. Wrocław 011. SUBJECT SUPERVISOR (NAME AND SURNAME, ADDRESS) Dr hab. inż. Stanisław Gryglewicz, stanisław.gryglewicz@pwr.edu.pl 4

5 MATRIX OF CORRELATION BETWEEN EDUCATIONAL EFFECTS FOR SUBJECT Alternative and renewable energy sources AND EDUCATIONAL EFFECTS FOR MAIN FIELD OF STUDY Chemical technology Subject educational effect Correlation between subject educational effect and educational effects defined for main field of study and specialization (if applicable)** Subject objectives*** Programme content*** Teaching tool number*** PEK_W01 (knowledge) C1, C Lec1 N1 PEK_W0 C Lec1, Lec17 N1 PEK_W03 C1 Lec-16 N1 PEK_W04 C Lec-16 N1 PEK_W05 C Lec-16 N1 5

6 Wrocław University of Technology FACULTY OF CHEMISTRY Zał. nr 4 do ZW 64/01 SUBJECT CARD Name in Polish Name in English Main field of study (if applicable) Specialization (if applicable) Level and form of studies: Kind of subject Subject code Group of courses *delete as applicable Podstawowe procesy jednostkowe w technologii chemicznej Base unit processes in chemical technology Chemical technology 1 st level obligatory TCC No Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Examination Examination / crediting with grade* Lecture Classes Laboratory Project Seminar Crediting with grade* For group of courses mark (X) final course Number of ECTS points 3 3 including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) classes *delete as applicable 1 1 Examination / crediting with grade* PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 1. Competence in the field of general and physical chemistry. Competence in the field of base mathematics 3. Examination / crediting with grade* C1 C C3 C4 SUBJECT OBJECTIVES Introduce students to conception of process and unit operations Understanding the basic principles of operation of apparatus and reactors for unit processes and operations in a variety of layouts phase Introduce students to conception of realization of chemical processes in the continuous systems Introduce students to principles of technological systems structure as combination of chemical unit processes and operations 6

7 C5 C6 C7 Acquainting students with the selected processes of chemical technology, noncatalytic and catalytic processes in a fluidized and stationary beds, Introduce students to the specific features of biotechnological processes Introduce students to the modern operations of chemical substances operations SUBJECT EDUCATIONAL EFFECTS Relating to knowledge: PEK_W01 student is able to make the correct characterization of the unit processes and operations applied in chemical technology, PEK_W0 student is able to work up the correct technological scheme of the plant and select the proper apparatuses and reactors, to indicate the suitable unit processes and operations, PEK_W03 student is able to characterize the flow of chemical substances in various phase systems PEK_W04 student knows the principles of operation of catalytic and non-catalytic processes and is able to describe and characterize, PEK_W05 student obtained the fundamental knowledge on separation technics, PEK_W06 student obtained the fundamental knowledge on the methods of biofuels production, PEK_W07 student obtained the fundamental knowledge on polymerization processes and physicochemical properties the obtained materials, PEK_W08 student understands the principles of biotechnological processes. Relating to skills: PEK_U01 student is able to practically work up technological scheme of the process and define the indispensable unit processes and operations PEK_U0 student is able to practically describe the base unit operations and processes for the selected chemical technologies from the various chemistry branches, PEK_U03 student is able to practically realize the simple chemical laboratory as unit processes and to make the base calculations connected with their realization, PEK_U04 student is able to plane and realize the simple separation operation with application of membrane technics, PEK_U05 student is able to determine process effectiveness, PEK_U06 student is able to determine physicochemical properties of the obtained reaction products, PEK_U07 student is able to plane and realize the process of chemical modification of raw materials. Relating to social competences: PEK_K01 PEK_K0 change PROGRAMME CONTENT Form of classes - lecture Number of hours Lec 1 The base concepts, unit process, unit operation, definition, characteristics, Lec Scheme of technological process, unit operations and unit processes as 7

8 components of chemical technology process. Raw materials, products and side products of unit operations and processes. Lec 3 Regime and parameters of unit processes and operations. Mixing and mass and energy exchange. Equilibrium in chemical processes. Yields and reagent conversions in unit chemical processes. Lec 4 Concept of driving reaction force in various flowing systems, methods of increasing of reaction rate in unit processes. Lec 5 Examples of apparatuses systems for unit processes and operations in gassolid, gas-liquids, liquid solids systems, catalytic and non-catalytic threephase systems, reactor concepts for various catalyst forms. Lec 6 Examples of chemical technology processes, fluidized bed catalytic processes, solid bed catalytic processes, Lec 7 Non-catalytic thermal processes, high temperature in heterogeneous systems, electrolysis processes. Lec 8 Enzymes. Kinetics. Enzymatic processes with native and immobilized enzyme. Lec 9 Microorganisms, microbiological processes. Kinetics. Products separation. Lec 10 Separation operations: extraction, distillation, chromatography, sedimentation, flocculation. Lec 11 Ordinary membrane operations, microfiltration, ultrafiltration, nanofiltration, reversed osmosis, electro-dialysis. Lec 1 Advanced membrane processes, pervaporation, membrane distillation, membrane pertractors, hybrid processes. Lec 13 Addition polymerization: reaction mechanisms, initiators, inhibitors, condensation polymerization. Lec 14 Molecular weight. Distribution of molecular weights. Polymer solutions. Condensed phases. Lec 15 Mixtures. Crystallinity. Phase transformation temperatures. Total hours 30 Cl 1 Cl Cl 3 Cl 4 Form of classes - class Total hours Number of hours Form of classes - laboratory Lab 1 Introductory classes. Lab Catalytic cracking. 4 Lab 3 Rape oil transesterification in flow system. 4 Lab 4 Photodegradation of organic compounds in water. 4 Lab 5 Block polymerization of methyl methacrylate. 4 Lab 6 Membrane separation isolation of products from reaction mixture. 4 Lab 7 Sulfonation reaction - obtaining of p-toluenesulphonic acid. 4 Lab 8 Alkylation reaction obtaining of quaternary ammonium salts. 4 Number of hours 8

9 Lab 9 or Ions exchange in basic technological processes 4 Total hours 30 N1 N N3 N4 TEACHING TOOLS USED Lecture with multimedia presentation Realization of experimental tasks Reports from the realized exercises Consultation EVALUATION OF SUBJECT EDUCATIONAL EFFECTS ACHIEVEMENT Educational effect Way of evaluating educational effect number achievement Evaluation F forming (during semester), C concluding (at semester end) C (lecture) PEK_W01- PEK_W08 Final exam Mark.0: 0-50 % Mark 3.0: % Mark 3.5: % Mark 4.0: % Mark 4.5: % Mark 5.0: % Mark 5.5: >98 % F1 Laboratory exercises, preliminary test F Laboratory exercises, report PEK_U0 PEK_U08 PEK_U0 PEK_U07 Partial oral preliminary test (max. 30 points) Evaluation of report level (max. 30 points) C (laboratory exercises) = 3.0 if (F1 + F)/= pkt. 3.5 if (F1 + F)/ = 0 pkt. 4.0 if (F1 + F)/ = 4pkt. 4.5 if (F1 + F)/ = 4 6 pkt. 5.0 if (F1 + F)/ = 6 8 pkt. 5.5 if (F1 + F)/ > 8 pkt. 9

10 PRIMARY AND SECONDARY LITERATURE PRIMARY LITERATURE: [1] I. Mukhlyonov et al. The Theoretical Foundations of Chemical Technology, Part 1 and Part. Mir Publishers, Moscow [] M. Bodzek, J. Bohodziewicz, K. Konieczny, Techniki membranowe w ochronie środowiska, Wydawnictwo Politechniki Śląskiej, Gliwice 1997 [3] Praca zbiorowa pod red. Z. Florjańczyka, S. Penczka, Chemia polimerów t. III, Oficyna Wydawnicza Politechniki Warszawskiej, Warszawa 1998 [4] Szlachta Z., Zasilanie silników wysokoprężnych paliwami rzepakowymi, WKŁ Warszawa 00. [5] Baczewski K., Kałdoński T. Paliwa do silników o zapłonie samoczynnym, WKŁ Warszawa 008 [6] Morrison R.T., Boyd R.N. Chemia organiczna T.1 Wydawnictwo Naukowe PWN, Warszawa 010 SECONDARY LITERATURE: [6] T. Winnicki, Polimery w ochronie środowiska, Arkady, Warszawa 1978 [7] [8] SUBJECT SUPERVISOR (Prof. dr hab. inż. Jerzy Walendziewski, jerzy.walendziewski@pwr.wroc.pl) MATRIX OF CORRELATION BETWEEN EDUCATIONAL EFFECTS FOR SUBJECT AND EDUCATIONAL EFFECTS FOR MAIN FIELD OF STUDY. Subject educational effect Correlation between subject educational effect and educational effects defined for main field of study and specialization (if applicable)** Subject objectives*** Programme content*** Teaching tool number*** (knowledge) PEK_W01 K1Atc_W17 C1 Wy1, Wy, W3 N1, N4 PEK_W0 K1Atc_W17 C4, C5 Wy3, Wy4, Wy5 N1, N4 PEK_W03 K1Atc_W17 C, C3, C4 Wy3 - Wy7 N1, N4 PEK_W04 K1Atc_W17 C4, C5 Wy3 - Wy7 N1, N4 PEK_W05 K1Atc_W17 C7 Wy10 Wy1 N1, N4 PEK_W06 K1Atc_W17 C6 Cw3 N1, N4 PEK_W07 K1Atc_W17 C4 Wy, Wy3 N1, N4 PEK_W08 K1Atc_W17 C6 Wy13, Wy14 N1, N4 (skills) PEK_U01 K1Atc_U5 C, C4 Wy1, Wy, N3, N4 PEK_U0 K1Atc_U5 C, C4 Wy6, Wy7 N3, N4 PEK_U03 K1Atc_U5 C7 Cw6 N3, N4 10

11 PEK_U04 K1Atc_U5 C1, C4 Cw, Cw3, Cw7 N3, N4 Cw4, Cw6, Cw8, PEK_U05 K1Atc_U5 C3, C5, C7 Cw9 N3, N4 Cw3, Cw6, Cw7, PEK_U06 K1Atc_U5 C5, C6, C7 Cw8, Cw9 N3, N4 (competences) PEK_K01 PEK_K0 PEK_K03 ** - enter symbols for main-field-of-study/specialization educational effects *** - from table above 11

12 Wrocław University of Technology FACULTY OF CHEMISTRY Zał. nr 4 do ZW 64/01 SUBJECT CARD Name in Polish Name in English Main field of study (if applicable) Specialization (if applicable) Level and form of studies: Kind of subject Subject code Group of courses *delete as applicable Obliczenia w chemii technicznej Calculation of technical chemistry Chemical Technology 1st/full-time obligatory CHC01004 NO Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Lecture Classes Laboratory Project Seminar Examination / crediting with grade* crediting with grade For group of courses mark (X) final course Number of ECTS points including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) classes *delete as applicable 1 Examination / crediting with grade* Examination / crediting with grade* PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 1. Knowledge of chemistry at the high school level.. Knowledge of physics at the high school level. 3. Knowledge of elementary mathematics. Examination / crediting with grade* C1 C C3 C4 SUBJECT OBJECTIVES Can a practical use chemical calculations in the following technological processes: combustion processes, water softening, fluid dynamics, diffusion processes, processes catalytic and non-catalytic, technical analysis of gases and water, electrochemistry. 1

13 Relating to knowledge: PEK_W01... SUBJECT EDUCATIONAL EFFECTS Relating to skills: PEK_U01 Knows how to describe quantitatively the functions of state for basic change ideal and non-ideal gases. PEK_U0 Knows how to perform calculations for simply diffusion processes. PEK_U03 - Can a practical use chemical calculations in the combustion processes. PEK_U04 - Knows how to perform calculations of fluid dynamics. PEK_U05 - Can identify, formulate and solve simple tasks of the technical analysis of gases and water. PEK_U06 - Can a practical use chemical calculations in the catalytic and non-catalytic processes. PEK_U07 - Can a practical use chemical calculations in electrochemistry. Relating to social competences: PEK_K01 PEK_K0 PROGRAMME CONTENT Lec 1 Lec Lec 3 Lec 4 Form of classes - lecture Total hours Number of hours Form of classes - class Cl 1 How to conduct classes, conditions for obtaining credit. The accuracy of the calculations. Cl The dynamics of fluids. The equation of continuity, Bernoulli's equation, Stokes law, number of Reynolds'a, laminar flow and turbulent, Cl 3 Diffusion processes. Diffusion of gases. Ficke'a law. I law of thermodynamics, Cl 4 The properties of gases and vapours. Van der Waalls equation. Dalton's Law. The relative humidity. Clausius-Clapeyron equation. Cl5 The properties of gases and vapours. Van der Waalls equation. Dalton's Number of hours 13

14 Law. The relative humidity. Clausius-Clapeyron equation cd. Cl6 Technical analysis of gases and water. Cl7 Technical analysis of gases and water cd. Cl8 Repetition of the material and I Test. Cl9 Electrochemistry. Galvanic cells, electrode potential, electromotive force, Faraday law. Cl10 Electrochemistry. Galvanic cells, electrode potential, electromotive force, Faraday law, cd. Cl11 Thermochemistry. Heat and his unit. Dulonga and Petita rule. Termochemical equilibrium. Hess's Law. Heat phase transformations of substances and the heat of chemical reactions. Heat, combustion, neutralized, dissolving, hydration. Cl1 Thermochemistry. Heat and his unit. Dulonga and Petita rule. Termochemical equilibrium. Hess's Law. Heat phase transformations of substances and the heat of chemical reactions. Heat, combustion, neutralized, dissolving, hydration. Cd. Cl13 Fuel combustion processes. Cl14 Water softening. Cl15 Repetition of the material and II Test. Total hours 30 Lab 1 Lab Lab 3 Lab 4 Form of classes - laboratory Total hours Number of hours Proj 1 Proj Proj 3 Proj 4 Form of classes - project Total hours Number of hours Sem 1 Sem Sem 3 Sem 4 Form of classes - seminar Total hours Number of hours 14

15 N1 N Troubleshooting tasks TEACHING TOOLS USED EVALUATION OF SUBJECT EDUCATIONAL EFFECTS ACHIEVEMENT Evaluation F forming (during Educational effect number Way of evaluating educational effect achievement semester), C concluding (at semester end) F1(Class) PEK_U01 Test I (max. 0 points) PEK_U03 F(Class) PEK_U03 Test II (max. 0 points) PEK_U05 C (Class) = 3,0 (F1 + F) = 1,0 1,0 pkt. 3,5 (F1 + F) = 14,0 14,0 pkt. 4,0 (F1 + F) = 16,0 16,0 pkt. 4,5 (F1 + F) = 18,0 18,0 pkt. 5,0 (F1 + F) = 19,0 19,0 pkt. 5,5 (F1 + F) = 40,0 pkt. PRIMARY AND SECONDARY LITERATURE PRIMARY LITERATURE: [6] Ufnalski W., Podstawy obliczeń chemicznych z programami komputerowymi, WN-T, Warszawa, 1999 [7] Bielański A., Podstawy chemii nieorganicznej, PWN, Warszawa, 003 [8] Praca zbiorowa, Obliczenia w chemii nieorganicznej, Wyd. PWr., 00 [9] Walker J., Podstawy fizyki - zbiór zadań, PWN, Warszawa, 005 SECONDARY LITERATURE: [9] [10] [11] SUBJECT SUPERVISOR (NAME AND SURNAME, ADDRESS) Magdalena Klakočar-Ciepacz, magdalena.klakocar-ciepacz@pwr.wroc.pl 15

16 MATRIX OF CORRELATION BETWEEN EDUCATIONAL EFFECTS FOR SUBJECT. AND EDUCATIONAL EFFECTS FOR MAIN FIELD OF STUDY. Subject educational effect Correlation between subject educational effect and educational effects defined for main field of study and specialization (if applicable)** Subject objectives*** Programme content*** Teaching tool number*** (knowledge) PEK_W01 PEK_W0 PEK_W03 (skills) PEK_U01 K1Atc_U10 C1 Cl3, Cl4, Cl5 N PEK_U0 K1Atc_U10 C1 Cl N PEK_U03 K1Atc_U10 Cl6, Cl7,Cl11, C1 Cl1, Cl13 N PEK_U04 K1Atc_U10 C1 Cl4 N PEK_U05 K1Atc_U10 C1 Cl6, Cl7 N PEK_U06 K1Atc_U10 C1 Cl6, Cl7 N PEK_U07 K1Atc_U10 C1 Cl9, Cl10 N (competences) PEK_K01 PEK_K0 PEK_K03 ** - enter symbols for main-field-of-study/specialization educational effects *** - from table above 16

17 Wrocław University of Technology FACULTY OF CHEMISTRY Zał. nr 4 do ZW 64/01 SUBJECT CARD Name in Polish Name in English Main field of study (if applicable) Specialization (if applicable) Level and form of studies: Kind of subject Subject code Group of courses *delete as applicable Technologie przemysłu rafineryjnego Catalytic processes in oil industry Chemical Technology Processes and chemical products 1st level, full-time optional TCC NO Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Lecture Classes Laboratory Project Seminar crediting with grade For group of courses mark (X) final course Number of ECTS points including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) classes *delete as applicable 1 PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 4. Basic Organic Chemistry 5. Basic Chemical Engineering C1 C C3 C4 SUBJECT OBJECTIVES To provide students with the basic processes of oil processing To provide students with the directions of the development of liquid fuels technologies. To provide students with ways of reducing of the risks associated with the production and use of petroleum products 17

18 SUBJECT EDUCATIONAL EFFECTS Relating to knowledge: PEK_W01 knows the basic schemes of refinery PEK_W0 - knows methods of oil treatment PEK_W03 - knows methods of liquid fuels producing PEK_W04 - knows methods of hydrogen production PEK_W05 - knows methods of oxygenates production PEK_W06 - knows the ways to reduce the risks associated with the production and use of petroleum products... Relating to skills: PEK_U01 PEK_U0 Relating to social competences: PEK_K01 PEK_K0 PROGRAMME CONTENT Form of classes - lecture Lec 1 Flowsheets of oil refinery. Lec Fractionation Lec 3 Hydrotreating 4 Lec 4 Cracking and hydrocracking 8 Lec 5 Reforming of gasoline 4 Lec 6 Isomerization and alkylation 4 Lec 7 Production of oxygenates (ethers, FAME) Lec 8 Production of hydrogen Lec 9 Production of asphalt and refinery waste disposal Total hours 30 Number of hours N1 N TEACHING TOOLS USED 18

19 EVALUATION OF SUBJECT EDUCATIONAL EFFECTS ACHIEVEMENT Educational effect Way of evaluating educational effect number achievement Evaluation F forming (during semester), C concluding (at semester end) F1 F F3 C PEK_W01 PEK_W06 test PRIMARY AND SECONDARY LITERATURE PRIMARY LITERATURE: [10] J.G. Speight: The chemistry and technology of petroleum, M. Dekker. [11] E.W. Smidowicz: Przeróbka destrukcyjna ropy naftowej i gazu, WNT. [1] SECONDARY LITERATURE: [1] G.D. Hobson: Modern petroleum technology, J. Wiley & Sons [13] [14] SUBJECT SUPERVISOR (NAME AND SURNAME, ADDRESS) prof. dr hab. inż. Janusz Trawczyński; janusz.trawczynski@pwr.wroc.pl MATRIX OF CORRELATION BETWEEN EDUCATIONAL EFFECTS FOR SUBJECT Catalytic processes in oil industry AND EDUCATIONAL EFFECTS FOR MAIN FIELD OF STUDY Chemical Technology Subject educational effect Correlation between subject educational effect and educational effects defined for main field of study and specialization (if applicable)** Subject objectives*** Programme content*** Teaching tool number*** (knowledge) PEK_W01 PEK_W0 PEK_W03 Course selectable 19

20 (skills) PEK_U01 PEK_U0 PEK_U03 (competences) PEK_K01 PEK_K0 PEK_K03 ** - enter symbols for main-field-of-study/specialization educational effects *** - from table above 0

21 Wrocław University of Technology FACULTY OF CHEMISTRY Zał. nr 4 do ZW 64/01 SUBJECT CARD Name in Polish Name in English Main field of study (if applicable) Specialization (if applicable) Level and form of studies: Kind of subject Subject code Group of courses *delete as applicable Termodynamika chemiczna i techniczna Chemical and engineering thermodymics Chemical Technology 1st level, full-time obligatory TCC NO Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Lecture Classes Laboratory Project Seminar Crediting with grade Crediting with grade For group of courses mark (X) final course Number of ECTS points 1 including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) classes *delete as applicable 1 0,5 0,5 PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 6. Knowledge fundamentals of physical chemistry 7. Knowledge fundamentals of inorganic chemistry 8. Knowledge of algebra and mathematical analysis C1 C C3 C4 C5 C6 SUBJECT OBJECTIVES To familiarize students with the basic dependencies and status functions equations of thermodynamic. To get basic knowledge about the thermodynamic description of change; ideal, nonideal. Learn how to perform basic calculations for thermodynamic cycles, heat engine. To familiarize students with a description of the thermodynamic solutions ideal and non-ideal. To get basic knowledge about the thermodynamic equilibrium. Learn how to perform basic calculations for technological processes. 1

22 SUBJECT EDUCATIONAL EFFECTS Relating to knowledge: PEK_W01 Familiar with description of reversible and not reversible thermodynamic process. PEK_W0 Learns the criteria for chemical equilibrium thermodynamic PEK_W03 - Has basic knowledge to describe the thermodynamic real and non-real solutions PEK_W04 - Knows how to describe qualitatively and quantitatively balance in ideal and non-ideal solutions gas/liquid systems.... Relating to skills: PEK_U01 knows how to describe quantitatively the functions of state for basic change ideal and non-ideal gases PEK_U0 knows how to perform calculations for thermodynamic efficiency of refrigerators engine: cooling and warm, heat pumps PEK_U03 - Can make activity of substance and activity coefficients in gas and liquid solutions and the reaction heat PEK_U04 - Knows how to perform calculations of the equilibrium constants and equilibrium composition PEK_U05 - Can identify, formulate and solve simple tasks of practical engineering Relating to social competences: PEK_K01 PEK_K0 PROGRAMME CONTENT Form of classes - lecture Lec 1 Forms of energy, basic concepts of thermodynamics, the types of systems. Determination of thermodynamic system (parameter). The functions of the State; internal energy, enthalpy, free energy. Transformation processes with and without the effects of ideal gas interactions with the environment, reversible and irreversible. The principle of thermodynamics, open system, technical work. The status of reference in thermodynamics. Lec Thermodynamic cycles; Carnot, Diesel and others, Gas turbines; refrigeration, a heat pump. Devices using heat pumps; the furnace, drying, fractionating column. Throttling an ideal gas; adiabaticizoenergy, adiabatic-izoentalpy Lec 3 Real gases. The equation of State of real gases; Virial, compressibility factor, is capacity, van der Waals (reduced), Berthelot's (reduced). The principle of corresponding States. Calculation of thermodynamic function of pure real gases for the specified parameters; an approximate method of Watson-Hougena, using graphs of functions of the universal parameters reduced. Number of hours

23 Throttling of the actual effect Joula-Thomson. The temperature inversion, liquify gases. Lec 4 Thermodynamic description of the condensed phases. Calculate the molar volume, density using the coefficient of expansion. The molar heat capacity, enthalpy, entropy of solids and liquid. Solutions of partial molar volumes, equation Gibsa-Duhema. Thermodynamic potential, molal particle thermodynamic potential. Depending on the chemical potential of temperature, pressure and concentration of the component. Lec 5 Gas solutions, solutions. Amagata Rule. Thermodynamic description of solutions (the principle of corresponding States, parameters, pseudo-critical parameters, reduced parameters, Kaya s formula of universal reduced parameters. Activity, the activity pressure coefficient, Randall-Lewis rule. Calculation of pressure activity (volatility) using any equation of State. Lec 6 Description of the equilibrium state, the relative number of reaction progress, degree of change. Equilibrium state (pressure, activity pressure). Calculation of thermodynamic potential of standard for a chemical reaction with specific parameters (T, p). Depending on the pressure and temperature of equilibrium states. The influence of intertów on the State of equilibrium in the gas phase. Calculation of the equilibrium constant and the equilibrium composition. Lec 7 Phase equilibrium. Enthalpy and entropy changes. Phase transition of the first and second-order transition. Thermodynamics and kinetics of electrochemical processes. The termochemical calculations. Thermal balance of chemical process. Lec 8 Exam 1 Total hours 15 Cl 1 Cl Cl 3 Cl 4 Cl 5 Cl 6 Form of classes - class How to conduct classes, conditions for obtaining credit. Calculation of thermodynamic function changes and heat, work and work volume for ideal gas reversible transformations. Chemical calculations for the reverse transformation of politropic ideal gas. Engineering calculations for simple devices (theoretical power, stream water cooling for perfect izotermic compressors). Carnot cycle, thermodynamic factor value calculations in the cycle, heat and work volume for each changes, the efficiency of circulation. Calculation for heat pumps, refrigerators, freezers, power cooling. Thermodynamic description of the condensed phases. Calculate the molar volume, density using the coefficient of expansion. The molar heat capacity, enthalpy, entropy of solids and liquid. Application of the equation of State of ideal gas, universal reduced parameters. Perfect gases and their mixtures: calculation of activity and activity coefficients. Calculation of standard chemical reaction energy with specific characteristics and thermodynamic constants and composition of równowagowego. Calculation of activity coefficients for real gases activity and their mixtures. Calculation of standard chemical reaction energy with specific parameters, the equilibrium constant and the equilibrium Number of hours 3

24 composition. Cl 7 The calculation of termo-chemical. Thermal balance of chemical processes. Repetition of the material. Cl 8 Test 1 Total hours 15 Lab 1 Lab Lab 3 Lab 4 Form of classes - laboratory Total hours Number of hours Proj 1 Proj Proj 3 Proj 4 Form of classes - project Total hours Number of hours Sem 1 Sem Sem 3 Sem 4 Form of classes - seminar Total hours Number of hours N1 N TEACHING TOOLS USED Lecture with mulimedial presentation Troubleshooting tasks EVALUATION OF SUBJECT EDUCATIONAL EFFECTS ACHIEVEMENT Educational effect Way of evaluating educational effect number achievement Evaluation F forming (during semester), C concluding (at semester end) P (lecture) PEK_W01 PEK_W04 Exam (max. 15 points) 4

25 P (classes) PEK_U01 PEK_U05 P (lecture, classes) = 3,0=7,5-9,0 3,5=9,5-11,0 4,0=11,5-1,5 4,5=13,0-13,5 5,0=14,0-14,5 5,5=15,0 Test (max. 15 points) PRIMARY AND SECONDARY LITERATURE PRIMARY LITERATURE: [13] J. Szarawara, Termodynamika chemiczna stosowana, WNT, Warszawa 1997 [14] S. Michałowski, K. Wańkowicz, Termodynamika procesowa, WNT, Warszawa 1999 SECONDARY LITERATURE: [15] W. Ufnalski, Wprowadzenie do termodynamiki chemicznej, Oficyna Wydawnicza Politechniki Warszawskiej, 004 [16] K. Annamalai, Advance Thermodynamics Engineering, CRC Press, 00 SUBJECT SUPERVISOR (NAME AND SURNAME, ADDRESS) Dr. hab. inż. Piotr Falewicz, piotr.falewicz@pwr.wroc.pl MATRIX OF CORRELATION BETWEEN EDUCATIONAL EFFECTS FOR SUBJECT. AND EDUCATIONAL EFFECTS FOR MAIN FIELD OF STUDY. Subject educational effect Correlation between subject educational effect and educational effects defined for main field of study and specialization (if applicable)** Subject objectives*** Programme content*** Teaching tool number*** (knowledge) PEK_W01 K1Atc_W16 C1 Lec1 N1 PEK_W0 KlAtc_W16 C Lec, Lec3 N1 PEK_W03 KlAtc_W16 C4 Lec4, Lec5 N1 KlAtc_W16 C5 Lec6, Lec7 N1,N 5

26 (skills) PEK_U01 KlAtc_U6 C3 Cl1 N1,N PEK_U0 KlAtc_U6 C3 Cl N PEK_U03 KlAtc_U6 C6 Cl3, Cl4 N PEK_U04 KlAtc_U6 C6 Cl5, Cl6 N PEK_U05 KlAtc_U6 C6 Cl7 N (competences) PEK_K01 PEK_K0 PEK_K03 ** - enter symbols for main-field-of-study/specialization educational effects *** - from table above 6

27 Wrocław University of Technology FACULTY OF CHEMISTRY Zał. nr 4 do ZW 64/01 SUBJECT CARD Name in Polish Name in English Main field of study (if applicable) Specialization (if applicable) Level and form of studies: Kind of subject Subject code Group of courses *delete as applicable Inżynieria Chemiczna Chemical Engineering Chemical Technology 1st level, full-time obligatory ICC NO Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Examination Crediting with grade Lecture Classes Laboratory Project Seminar Crediting with grade For group of courses mark (X) final course Number of ECTS points including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) classes *delete as applicable Examination / crediting with grade* PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 9. Completion physics 10. Completion mathematics Examination / crediting with grade* C1 C C3 C4 C5 C6 C7 SUBJECT OBJECTIVES Introduce with chemical and physical basis of basic chemical engineering processes Cognition of form rules of heat and mass balances in the steady state and unsteady state conditions. Cognition of mathematical modeling and design rules of processes and apparatus used in chemical engineering and processing Cognition of scale-up rules Usage of hydrostatics and hydrodynamics rules for description of apparatus occur in industrial installations Cognition of rules choice of pumps and other flow apparatus Cognition of rules of apparatus calculation with two phases flow 7

28 C8 C9 C10 C11 C1 C13 Cognition of mathematical methods of heat exchangers description and design Introduction to balancing and operation parameters calculation for selected mass transfer apparatus Carrying out of pressure drops measurements in order to determine flow velocity. Carrying out of stream volume measurement Experimental determining of heat and mass transfer coefficients Experimental determining of reflux ratio in rectification column and graphical interpretation of column operation SUBJECT EDUCATIONAL EFFECTS Relating to knowledge: PEK_W01 Know chemical and physical basis of selected processes and oparations occur in chemical engineering PEK_W0 Can define heat and mass balances in steady state and unsteady state conditions. PEK_W03 Can describe with the use of mathematical model and design selected processes and apparatus used in chemical engineering PEK_W04 Know rules of scale-up Relating to skills: PEK_U01 Can describe apparatus operation used in industrial plants using rules of hydrostatics and hydrodynamics PEK_U0 Can choice pumps and other apparatus cooperating with pipeline PEK_U03 Can calculate heat exchangers area and determine heat exchanger operation parameter PEK_U04 Can form mass balances and determine operation parameters of selected mass exchangers PEK_U05 Can use appropriate metering equipment for determination of pressure drop and can calculate fluid flow velocity PEK_U06 Can carry out of volume stream of gas or liquid PEK_U07 Can experimentally measure heat and mass transfer coefficients PEK_U08 Can experimentally determine reflux ratio and use to calculation of operating lines of rectification process PROGRAMME CONTENT Form of classes - lecture Lec 1 Field of interest of chemical engineering and rules of mass and energy balancing in chemical engineering processes Lec Fluid flow in apparatus, Bernoulli law, flow resistances in pipelines (Darcy Weisbach equation) and in selected apparatus for one- and two phase flows Lec 3 Pumps pump and pipeline characteristics. Rules of pumps and pipelines connecting. Calculation of pump operating pump in selected configurations pump pipeline. Lec 4 Flow single particle in fluids. Calculation of particle diameter, flow velocity, coefficient of flow resistance, swarm falling, fluidization, pneumatic transport, sedimentation Number of hours 8

29 Lec 5 Filtration. Filters construction, classification of filtration processes, filtration with constant pressure difference, filtration with constant filtrate stream two stage filtration, application of filtration in selected technologies Lec 6 Mixers, construction of stirrers and mixers, definition of Reynolds number, power consumption, scale-up Lec 7 Heat transfer processes, calculation of heat transfer through multilayer flat and cylindrical walls, dimensions analysis, rules of heat transfer exchangers design Lec 8 Classification of mass transfer apparatus, mass transfer and overall mass transfer coefficients, conception of process operation line, concurrent and countercurrent flow of streams, diffusional and thermo-diffusional apparatus Lec 9 Absorption processes. Absorption apparatus, methods of description of interphase mass transfer process, calculation of column diameter and column high. Methods of process realization. Lec 10 Distillation processes. Equilibrium distillation, batch distillation, distillation with steam, thin layer distillation, molecular distillation. Preparation of balance equations for continuous and periodic processes. Lec 11 Rectification of two components systems, construction of rectification column, heat and mass balance of the process, determination of minimal reflux ratio, determination of minimal number of theoretical stages (plates). Lec 1 Aparaty ekstrakcyjne o działaniu okresowym i ciągłym. Sposoby obliczania z wykorzystaniem trójkąta składu. Obliczanie stopnia zatrzymania fazy rozdrobnionej, średnicy kropel, średnicy kolumny, współczynników wnikania masy oraz wysokości kolumny ekstrakcyjnej. Lec 13 Procesy adsorpcyjne, właściwości adsorbentów stałych, adsorbery o działaniu okresowym, pojęcie frontu adsorpcji, metody obliczania czasu adsorpcji, łączenie adsorberów. Lec 14 Procesy suszarnicze. Obliczanie właściwości medium suszącego (powietrza) na podstawie wykresu Moliera. Pierwszy i drugi okres suszenia, bilansowanie procesów suszarniczych, obliczanie zużycia ciepła i czasu suszenia. Podział reaktorów i zasady bilansowania. Lec 15 Obszar zainteresowań inżynierii chemicznej oraz zasady bilansowania masy i energii w procesach inżynierii chemicznej Total hours 30 Form of classes - class Cl 1 Presentation of subject program. Discuss to meet the completion requirements. Basic concepts and parameters. Used units and conversions. Cl Hydrostatics. Calculation of pressure arrangement in the chemical plants. Cl 3 Hydrodynamics. Phenomena connected with fluids flow. Calculation Number of hours 9

30 of pressure drops. Cl 4 Bernoulli law and application. Cl 5 Pumps and calculation of pumps installations. Rules of pumps choice. Cl 6 Verification colloquium I. Cl 7 Sedimentation of particles. Forces act on the single particle. Fall of single particle. Stokes law. Fall of particle swarm. Cl 8 Calculation of sedimentation tank, dust chamber, cyclone. Cl 9 Filtration. Filtration equation and usage for filter design. Cl 10 Heat conduction in the flat and cylindrical wall. Calculation of temperature profile in the solid. Cl 11 Heat transfer in the natural convection, forced convection, liquid boiling and steam condensation. Calculations of heat transfer coefficients. Cl 1 Two phase heat transfer. Heat exchangers calculations. Cl 13 Basic mass transfer processes. Rectification, absorption, extraction. Calculation of mass balances. Cl 14 Calculation of rectification column for separation of two component solution. Cl 15 Verification colloquium II. Total hours 30 Form of classes - laboratory Lab 1 Organizational activities. Becoming acquainted with rules of health 3 and safety at work in research laboratory. Discuss to meet the completion requirements. Take knowledge of apparatus used in laboratory. Lab Determination of fluid flow profile in the pipeline with circular cross 3 section. Lab 3 Pump characteristics. 3 Lab 4 Determination of flow coefficient in flow narrow for liquids. 3 Lab 5 Heat exchanger pipe in pipe type. 3 Lab 6 Heat transfer during liquid boiling 3 Lab 7 Efficiency of mixing energy on the mass transfer coefficient in the 3 solid liquid system. Lab 8 Determination of HETP in packed bed rectification column. 3 Lab 9 Distillation with the steam. 3 Lab 10 Heat transfer in fluidized bed. 3 Total hours 30 Number of hours N1 N N3 N4 N5 N6 TEACHING TOOLS USED Informational lecture Multimedia presentation Solution of problems Application of Excel for specialist calculations. Realization of experiments. Report description. 30

31 EVALUATION OF SUBJECT EDUCATIONAL EFFECTS ACHIEVEMENT Evaluation F forming (during Educational effect number Way of evaluating educational effect achievement semester), C concluding (at semester end) C(lecture) PEK_W01 Exam PEK_W04 F1 PEK_U01 Verification colloquium I class PEK_U0 F PEK_U03 - Verification colloquium II class PEK_U04 Cl(ćwiczenia) = (F1+F)/ F3 PEK_U05 PEK_U08 C (laboratory) = mean of reports and colloquium marks Appraise a student's reports and colloquium after each laboratory exercise. PRIMARY AND SECONDARY LITERATURE PRIMARY LITERATURE: [15] J. Ciborowski, Podstawy inżynierii chemicznej, WNT, Warszawa198 [16] M. Serwiński, Zasady inżynierii chemicznej i procesowej, WNT, Warszawa 198 [17] Koch Roman, Noworyta Andrzej: Procesy mechaniczne w inżynierii chemicznej. Warszawa : WNT, 199. [18] Koch Roman, Kozioł Antoni: Dyfuzyjno-cieplny rozdział substancji. Warszawa : WNT, [19] Zadania rachunkowe z inżynierii chemicznej, (pr. zbiorowa pod red. R.Zarzyckiego), PWN W-wa [0] Z. Kawala, A. Kołek, M. Pająk, J. Szust, Zbiór zadań z podstawowych procesów inżynierii chemicznej cz. I III. Skrypty PWr. [1] Laboratorium Inżynierii Procesowej cz.i. Przenoszenie pędu i procesy mechaniczne oraz cz.ii. Przenoszenie ciepła i masy praca zbiorowa pod redakcją Danuty Beliny- Freundlich, Wrocław [] [] Instrukcje do ćwiczeń, dostępne na stronie Wydziału Chemicznego PWr. SECONDARY LITERATURE: [17] K.F.Pawłow, P.G.Romankow, A.A.Noskow. Przykłady i zadania z zakresu aparatury i inżynierii chemicznej, WNT W-wa 1988 [18] Selecki A., Gradoń L., Podstawowe procesy przemysłu chemicznego, WNT, Warszawa1985. [19] Kembłowski Z., Podstawy teoretyczne inżynierii chemicznej i procesowej, WNT, Warszawa 1985 [0] Hobler T., Ruch ciepła i wymienniki, WNT, Warszawa1986. SUBJECT SUPERVISOR (NAME AND SURNAME, ADDRESS) Dr inż. Wojciech Skrzypiński, wojciech.skrzypinski@pwr.wroc.pl 31

32 MATRIX OF CORRELATION BETWEEN EDUCATIONAL EFFECTS FOR SUBJECT Chemical Engineering AND EDUCATIONAL EFFECTS FOR MAIN FIELD OF STUDY Chemical Technology Subject educational effect (knowledge) PEK_W01 (knowledge) PEK_W01 Correlation between subject educational effect and educational effects defined for main field of study and specialization (if applicable)** Subject objectives*** Programme content*** Teaching tool number*** K1Atc_W1 C1 Wy1 N1, N PEK_W0 K1Atc_W1 C, C3, C8,C9 Lec 1, Lec 5, Lec 7, Lec 8, Lec 15 N1, N PEK_W03 K1Atc_W1 C3, Lec Lec 15 N1, N PEK_W04 K1Atc_W1 C4 Lec Lec 15 N1, N (skills) Cl 1 Cl 4, K1Atc_U09 C5 PEK_U01 Cl 7 Cl 9 N3, N4 PEK_U0 K1Atc_U09 C6, C7 Cl 5, N3, N4 PEK_U03 K1Atc_U09 C8 Cl 10, Cl 11 N3, N4 PEK_U04 K1Atc_U09 C9 Cl 4, Cl 5, Cl 7 Cl 14 N3, N4 PEK_U05 K1Atc_U14 C10 Lab, Lab4 N5, N6 PEK_U06 K1Atc_U14 C11 Lab, - Lab5, Lab7, - Lab10 N5, N6 PEK_U07 K1Atc_U14 C1 Lab5, - Lab7, Lab10 N5, N6 PEK_U08 K1Atc_U14 C13 Lab8 N5, N6 ** - enter symbols for main-field-of-study/specialization educational effects *** - from table above 3

33 Wrocław University of Technology FACULTY OF CHEMISTRY Zał. nr 4 do ZW 64/01 SUBJECT CARD Name in Polish Name in English Main field of study (if applicable) Specialization (if applicable) Level and form of studies: Kind of subject Subject code Group of courses *delete as applicable Technologia chemiczna-surowce i procesy przemysłu organicznego Chemical technology-raw materials and organic industry processes Chemical Technology 1st level, full-time / part-time* obligatory TCC YES Lecture Classes Laboratory Project Seminar Number of hours of organized classes in University (ZZU) Number of hours of total student workload (CNPS) Form of crediting Examination crediting For group of courses mark (X) final course Number of ECTS points 4 including number of ECTS points for practical (P) classes including number of ECTS points for direct teacherstudent contact (BK) classes with grade crediting with grade 3 1,5 1 PREREQUISITES RELATING TO KNOWLEDGE, SKILLS AND OTHER COMPETENCES 11. Principles of organic chemistry C1 C C3 C4 C5 C6 SUBJECT OBJECTIVES Gaining of basic knowledge on technology of petroleum, coal and natural gas and the manufacture of chemicals from petroleum and natural gas hydrocarbons Gaining of basic knowledge on the large scale manufacture of organic chemicals Gaining of basic knowledge on polymeric materials: classification, structure, preparation, processing methods, properties and application Gaining of basic knowledge on fine chemicals manufacturing Gaining of knowledge on fabrication technologies of polymer materials Gaining of knowledge on classification and application of surfactants and pesticides including the green chemistry products 33

34 C7 Acquaintance with synthesis methods of selected chemical compounds and selected technological processes in laboratory- scale SUBJECT EDUCATIONAL EFFECTS Relating to knowledge: Student, who has completed the course: PEK_W01 has a knowledge on technology of petroleum PEK_W0 has a knowledge on processing of petroleum hydrocarbons for chemical industries PEK_W03 has a knowledge on coal conversion processes PEK_W04 has knowledge on the processing natural gas to pipeline dry gas quality levels PEK_ W05 has knowledge on production of chemicals from natural gas PEK_ W06 knowing basic unit processes (e.g., oxidation, alkylation, hydrogenation, halogenation) in chemical organic technology PEK_ W07 knowing basic isolation and fabrication methods of the most important reagents for syntheses in the large and small volume scale PEK_W08 has knowledge on the basic chemical and technological principles PEK_W09 has knowledge on the catalysts importance in chemical technology and green chemistry PEK_W0Y1 has knowledge on basic synthesis methods of polymers PEK_W0Y has knowledge on main polymers and their applications PEK_W0Y3 has knowledge on features of chemical and physical structure of polymeric materials with connection to their properties PEK_W0Y4 knows the basic preparation and molding methods of polymeric materials along with examples of typical products PEK_W0Y5 knows the main methods of property determination of polymeric materials PEK_W0Y6 knows the ways of disposal and management of polymer waste Relating to skills: Student, who has completed the course: PEK_U01 can discuss the fundamental aspects of technological process PEK_U0 can discuss the process course in industrial plant PEK_U03 can define the requirements with respect to raw materials for organic syntheses and their gaining methods PEK_U04 can evaluate the process with respect to by-products PEK_U05 can diversify integrated processes with respect to raw materials and products PEK_U06 can prepare the multimedia and oral presentations PEK_U07 can prepare the case study from the seminar subject area PEK_U08 is able to conduct synthesis of selected chemical compounds in laboratory-scale PEK_U09 is able to perform selected operations of technological process in laboratory conditions 34