Faculty of Mechanical Engineering Subject area of studies: Mechanics and Mechanical Engineering C C O O N N S S T T R R U U C C T T I I O O N N O O F F M M O O T T O O R R V V E E H H I I C C L L E E S S Course code: 06. 1-WM-MiBM-S1-KiEP-01_12 06. 1-WM-MiBM-N1-KiEP-01_12 Type of course: 1. Compulsory Language of instruction: 2. Polish, Director of studies: 3. Dr inŜ. Wladyslaw Papacz Name of lecturer: 4. Dr inŜ. Wladyslaw Papacz Form of instruction Number of teaching hours per semester Number of teaching hours per week Semester Form of receiving a credit for a course Number of ECTS credits allocated Full-time studies Lecture 45 3 Exam Class - - - Laboratory 30 2 Grade Seminar - - - Workshop - - - Project - - V - Part-time studies Lecture 16 2 Exam Class - - - Laboratory Grade Seminar - - - Workshop - - - Project - - V - 5 СOURSE AIMS: The aim of the course is to familiarize students with construction and operation of basic components of cars: personal, commercial vehicles and buses. Division of suspensions. PREREQUISITES: Basis of construction of machines
Transcript
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
The aim of the course is to familiarize students with construction and operation of basic components of cars: personal, commercial vehicles and buses. Division of suspensions.
PREREQUISITES: Basis of construction of machines
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE CONTENTS: Lecture content. Basic definitions, classification of cars. Masses and dimensions, exploational
coefficients. Building and destination of main aggregates of car. Basic connected notion with driving arrangement (drive, power, rotatory moment, total efficiency, driving strength). Burden of cars' vehicles. Building of driving system: clutches, gear box, driving ramparts, main gear and differential, driveshafts, examples of construction. The chassis and suspension. Division of suspensions. Technical profile. Conventional suspension and regulated. Assignment of suspensions and characters of resilience. Classification of suspensions. Dampers. Stabilisers. Axes of carriageable wheels. Wheels, tire and hoops. Analysis of solutions of suspensions of present vehicles, Braking, and brake sytems. Classification of brake systems. Legal requirement. Brake mechanisms. Efficiency of working of brakes - thermal load. Mechanisms starting brakes. Steerling scheme. Working and technical character of steerling system. Steer mechanism and linkage. Geometry of steer wheels. supporting mechanisms. Turn of multiaxial cars and group of vehicles. Frames vehicles: the method of calculation.
Laboratory content.
Practical analysis of the design and operation: the main clutch cars, classic gearboxes, shafts and driveshafts, driving axles, suspensions, brake systems run, mechanisms and brakes drum brakes, steering, clutch and hydrocinetics gears, automatic transmissions and engines.
Class project: Student performs the complete design clutch and brake system
TEACHING METHODS: Lectures with audiovisual aids. Working with the book. Group work in laboratory classes.
LEARNING OUTCOMES: In the field of
technical sciences
Knowledge, skills, competence
K_W16 The student knows the basic methods of techniques and required tools for dissolving of simple problems of buildings, technology of productions and exploitation of cars
K_U01 can obtain information from the literature, standards and other sources K_U07 can use information and communication technologies to produce laboratory results. K_U15 Can to execute critical analyses of way of functioning and to evaluate existing
technical solutions in range of buildings and exploitation of vehicles , in peculiarity devices, objects, systems, processes and services
K_K04 can interact with a group K_U03 can prepare a study in Polish and short scientific report in foreign language
considered mechanics and buildings of vehicles, can presenting the results of their own research
K_U07 The student can use information and communication technologies required to realize engineering tasks
K_U17 can identify and formulate the specification of complex engineering tasks characteristic of motor vehicles , including non-standard tasks, taking into account the non-technical aspects
K_U19 in line with predetermined specifications and taking into account the non-technical aspects, the student can design a complex device, object, system or process related to the scope of Mechanical Engineering, and implement the project - at least in part - by using appropriate methods, techniques and tools, including adapting the existing tools or developing new ones
K_K01 The student understands the need for lifelong learning; is able to inspire and organize the learning process of others
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification methods for learning outcomes are presented in the table below.
The reference to the learning outcomes of the field of study
The method of the learning outcomes assessment
K_W16
K_K01
Exam based on written test
K_U01
K_U03 K_U07
K_K04
grade based on performed projects
K_K04 K_U15
Exam and performed projects
K_U17 K_U19
the course of the laboratory classes
A passing grade in the lecture part of the course is determined by five written responses to questions about the theoretical aspects of the subject. A passing grade in laboratory part comprises positive evaluation of reports based on each laboratory class, attendance and initiative on the part of the student. To get a credit the student has to receive both passing grades. The final grade received by the student is the arithmetic mean of the above grades.
STUDENT WORKLOAD:
The student workload of 150 hours, including work in the auditorium 90 (16) hours, individual work 7 (32) hours, preparing for classes and study reports 40 (40) hours, revising for tests 25 (50) hours. Total hours of practical classes: 95 (0) which corresponds to 2 ECTS Total hours of lessons with a teacher: 92(16) which corresponds to 3 ECTS
RECOMMENDED READING: 1. H. Dajniak : Ciągniki, 2. K. Studziński : Samochód – teoria, konstrukcja i obliczanie. WKŁ Warszawa 1980, 3. J. Werner - Budowa samochodów, 4. J. Reimpell, Betzer J.: Podwozia samochodów – podstawy konstrukcji. WKŁ Warszawa 2004, 5. Z. Jaśkiewicz: Projektowanie układów napędowych pojazdów samochodowych, WKŁ, W-wa 1982 6. Z. Jaśkiewicz, A. Wąsiewski: – Układy napędowe pojazdów samochodowych. Obliczenia projektowe. PW. W-wa 2002, 7. Z. Jaśkiewicz – Poradnik inŜyniera samochodowego. Elementy i materiały. WKŁ W-wa 1990, 8. Z. Jaśkiewicz – Mechaniczne skrzynki przekładniowe. WKŁ Warszawa 1998. 9. Z. Jaśkiewicz: Mosty napędowe. WKŁ 1977. 10. E. Kamiński, J. Pomorski: Dynamika zawieszeń i układów napędowych pojazdów samochodowych. WKŁ W-wa 1983 11. T. Wrzesiński: Hamowanie pojazdów samochodowych. WKŁ W-wa 1973. 12. A. Reński: Budowa samochodów. Układy hamulcowe i kierownicze oraz zawieszenia. PW. W-wa 2004. 13. W. Miknass, R. Popiol, A. Sprenger: Sprzęgła, skrzynki biegów, wały i półosie napędowe. WKŁ. W-wa 2005
OPTIONAL READING: 1. Fr. Romanów - Wytrzymałość ram i nadwozi, 2. M. Mitschke - Dynamika samochodu, 3. J. Piechna - Podstawy aerodynamiki pojazdów, 4. Akopian R.: Budowa pojazdów samochodowych. Politechnika Rzeszowska, 1995.
REMARKS: List of laboratories for part time students is selected from the list above. Workloads in parentheses are the numbers for part time studies.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
The aim of the subject is to familiarize students with the construction and operation of modern automation and control systems used in modern motor vehicles.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
PREREQUISITIES:
Construction vehicles. The theory of the movement of vehicles. The basics of electronics and electrical engineering. The basics of computer science.
COURSE CONTENTS: Lecture content.: Basic concepts of automation and control-static and dynamic properties of linear and nonlinear. The object of regulation and selection of parameters of regulators. Signal processing, drivers, control algorithms. Signal transducers-sensors, actuators, motors, actuators. Automation systems, control systems, active safety of vehicles: systems ABS, EBS, BASS, ASR, ESP. spark-ignition engines Control. Control of compression ignition engines. Algorithms work diagnostic devices. Control of automatic transmissions. Modern steering. On-board diagnostic devices in automotive vehicles.
TEACHING METHODS: Lectures with audiovisual aids. Working with the book.
EFEKTY KSZTAŁCENIA: In the field of technical sciences
Knowledge, skills, competence
K_W03 Is an ordered, theoretical background knowledge covering key issues from the scope of automation and control systems of motor vehicles
K_W05 Has knowledge of the development trends and the most important new achievements from the automation and control systems in vehicles
K_U01 Can obtain information from the literature, databases and other properly selected sources, also in English or other foreign language recognised as a language of international communication and control systems in vehicles, can integrate the information obtained, to their interpretation and critical evaluation, and also draw conclusions and formulate and fully justify the reviews
K_U09 Can use to formulate and solve engineering tasks and simple problems and experimental research analytical methods, simulation
K_U12 Can evaluate the usefulness and the opportunity to use new achievements (techniques and technologies) in the field of automation and control systems in vehicles
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITE RIA: The verification methods for learning outcomes are presented in the table below:
The reference to the learning outcomes of the field of study
The method of the learning outcomes assessment
K_W03
K_W05 Colloquium
K_U01 K_U09 K_U12
grade Semester
Lecture-condition assessment of the lecture is to obtain a positive evaluation of the Colloquium and of the semester work
STUDENT WORKLOAD: The student workload of 50 hours, including work in the auditorium 30(8) hours, individual work 20(42) hours. Total hours of individual work: 20(42) which corresponds to 1 ECTS. Total hours of lessons with a teacher: 30(8) which corresponds to 1 ECTS.
RECOMMENDED READING: 1. Kaczorek T., Dzieliński A., Dąbrowski W., Łopatka R.: Podstawy teorii sterowania. WKŁ, Warszawa
2005. 2. Greblicki W., Podstawy automatyki. Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław 2006. 3. Z. Kneba, S. Markowski: Zasilanie i sterowanie silników. WKŁ, W-wa 2004. 4. A. Herner, H. Riehl: Elektrotechnika i elektronika w pojazdach samochodowych. WKŁ. W-wa 2009. 5. M. Wendeker: Sterowanie zapłonem w silnikach benzynowych. LTN. Lublin, 1999.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
6. Mazurek St., Merkisz J.: Pokładowe systemy diagnostyczne pojazdów samochodowych, WKŁ, Warszawa 2007.
7. Trzeciak K.: Diagnostyka samochodów osobowych. WKŁ, Warszawa 2008. 8. Kuranowski A., Mirska-Świętek M.: Mechanizmy wspomagające w pojazdach samochodowych. Politechnika
Krakowska, Kraków 2002. 9. Zeszyt techniczne firmy BOSCH – Elektroniczne sterowanie skrzynią biegów EGS. 10. Zeszyty techniczne firmy BOSCH – Sterowanie EDC 11. Sieci wymiany danych w pojazdach samochodowych, informator techniczny firmy BOSCH, WKŁ,2008. 12. Czujniki w pojazdach samochodowych, informator techniczny firmy BOSCH, WKŁ, W-wa 2002 13. Układy stabilizacji toru jazdy. informator techniczny firmy BOSCH, WKŁ, W-wa 2002 14. Konwencjonalne i elektroniczne układy hamulcowe. Informator techniczny Bosch. WKŁ, Warszawa 2006.
OPTIONAL READING: 1. Heimann B., Gerth W., Popp K.: Mechatronika. Komponenty, metody, przykłady. PWN, Warszawa 2001. 2. Misala J., Missala T.: Elektryczne pomiary wielkości mechanicznych. PWN, Warszawa 1981. 3. Kasedorf J.: Układy wtryskowe i katalizatory. WKŁ, Warszawa 1996. 4. M. Konopiński - Elektronika w technice motoryzacyjnej. WkiŁ, W-wa, 1987. 5. Układy wtryskowe Common Rail. Informator techniczny Bosch. WKŁ, Warszawa 2000.
REMARKS: Workloads in parentheses are the numbers for part time studies.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE AIM: The aim of the subject is to familiarize students with methods of repair of cars.
ENTRY REQUIREMENTS: Manufacturing engineering
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE CONTENTS: Lecture: Characteristics of the repair work of cars. Methods of repairing of car components. Checking and repairing of individual parts of cars like the engine, the transmission, mechanisms of steering, the suspension, the braking system, etc. Selected issues of repairing cars.
Laboratory:
Technology of repair of the hull, the crankshaft and pistons of the engine. Technology of repair of head and the valves of the engine. Technology of repair of the braking system of the car. Technology of repair of mechanisms of steering the car. Technology of repair of elements of the drivetrain car. Correction laboratory.
TEACHING METHODS: Lectures - with using audiovisual means Laboratory - work in groups
LEARNING OUTCOMES: In the field of
technical sciences Knowledge, skills, competence
K_W10 the student chooses verification method and repair of assemblies of cars
K_U15 the student evaluates the functioning of existing sub-assemblies and parts of vehicles
K_U17 the student evaluates the suitability of methods and tools to solve simple tasks in the field of repair vehicles and uses the appropriate method and tools
K_K03 the student knowingly works in the group to obtain a particular effect
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification policy outcomes are shown in the following table.
The reference to the learning
outcomes of the field of study
The method of the learning outcomes assessment
K_W10 K_U15 K_U17
Lecture - grade
Evaluation is based on the final test, which refers to the teaching material (lecture and of the laboratory exercises).
K_U15 K_U17 K_K03
Laboratory classes - grade
Evaluation is determined on the basis of the reports of the lab exercises and student activity.
Final evaluation of the subject is the arithmetic average of the ratings for the both forms of instruction.
STUDENT WORKLOAD: The student workload of 60 (50) hours, including work in the auditorium 30 (8) hours, individual work 30 (42) hours, preparing for classes and study reports 22 (22) hours, praca kontrolna 0 (10+10=20) godzin, preparing for colloquium 8 (0) hours.
Total hours of practical classes: 37 (40) which corresponds to 1 ECTS.
Total hours of lessons with a teacher: 30 (8) which corresponds to 1 ECTS.
RECOMMENDED READING:
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
1. Adamiec P. i inni – Technologia napraw pojazdów samochodowych. Wyd. Politechniki Śląskiej, Gliwice 2002.
2. Uzdowski M. i inni – Eksploatacja techniczna i naprawa samochodów. WKiŁ, Warszawa 2003.
3. Trzeciak K. – Diagnostyka samochodów osobowych. WKiŁ, Warszawa 2008.
OPTIONAL READING: -
REMARKS: Workloads in parentheses are the numbers for part time studies.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
Name of lec turer : dr inŜ. Jerzy Sobich, dr inŜ. Mirosław śygadło
Form of instruct ion
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Lecture 15 1 Grade
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Lecture 16 2 Grade
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COURSE AIMS: Getting to know bases of vehicle electrotechnology will be a main effect of the education.
PREREQUISITIES: Electrical engineering and electronics..
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE CONTENTS: Lecture content:
Batteries. Dynamos and motors. Voltage regulators. Starters. Ignition system. The vehicle lighting system. Electricity consumers in the vehicle.
The content of the lab exercises: Examination of the sources of electricity. The study of the boot. Examination of the ignition system. The study of the lighting of the vehicle.
TEACHING METHODS: Lectures with audiovisual aids. Working with books and standards. The laboratory exercises.
LEARNING OUTCOMES: In the field of
technical sciences
Knowledge, skills, competence
K_W04 It has a basic knowledge of electrical systems and equipment in the vehicle
K_U08 It has the ability to verify the basic operation of electrical equipment in a motor vehicle
K_U18 Can integrate knowledge of electrical engineering and electronics and automotive technology
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification methods for learning outcomes are presented in the table below:
The reference to the learning outcomes of the field of
study
The method of the learning outcomes assessment
K_W04 Colloquium
K_U08 K_U18
The assessment of the laboratory on the basis of tests and reports.
Lecture-condition assessment of the lecture is to obtain a positive evaluation of the Colloquium.
Laboratory-condition assessment is carried out on the basis of the grading lab exercises drawn up the report.
STUDENT WORKLOAD: The student workload of 60 hours, including participation in lectures and laboratory exercises 30 (16) hours, preparing for classes and study reports 30 (44) hours. Total hours of individual work: 30(44) which corresponds to 1 ECTS. Total hours of lessons with a teacher: 30(16) which corresponds to 1 ECTS.
OPTIONAL READING: 1. Herner A., Riehl H. J.: Elektrotechnika i elektronika w pojazdach samochodowych. WKiŁ Warszawa 2009 2. Ocioszyński J.: Elektrotechnika i elektronika pojazdów samochodowych. Wydawnictwa Szkolne i
Pedagogiczne,Warszawa 2008 3. Z. Kneba, S. Markowski: Zasilanie i sterowanie silników. WKŁ, W-wa 2004. 4. A. Herner, H. Riehl: Elektrotechnika i elektronika w pojazdach samochodowych. WKŁ. W-wa 2009. 5. M. Wendeker: Sterowanie zapłonem w silnikach benzynowych. LTN. Lublin, 1999. 6. Mazurek St., Merkisz J.: Pokładowe systemy diagnostyczne pojazdów samochodowych, WKŁ, Warszawa
2007. 7. Trzeciak K.: Diagnostyka samochodów osobowych. WKŁ, Warszawa 2008. 8. Zeszyty techniczne firmy BOSCH – Sterowanie EDC 9. Czerwiński A.: „Akumulatory, baterie, ogniwa”, WKiŁ, W-wa, 2005
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
10. Czujniki w pojazdach samochodowych, informator techniczny firmy BOSCH, WKŁ, W-wa 2002
OPTIONAL READING:
1. Kasedorf J.: Układy wtryskowe i katalizatory. WKŁ, Warszawa 1996. 2. M. Konopiński - Elektronika w technice motoryzacyjnej. WkiŁ, W-wa, 1987. 3. Układy wtryskowe Common Rail. Informator techniczny Bosch. WKŁ, Warszawa 2000.
REMARKS: Workloads in parentheses are the numbers for part time studies.
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
CCC OOO MMM BBB UUU SSS TTT III OOO NNN SSS EEE NNN GGG III NNN EEE SSS
Course code: 06.1-WM-MiBM-S1-KiEP-06_12
06.1-WM-MiBM-N1-KiEP-06_12
Type of course: compulsory
Language of ins truc t ion: polish
Direc tor of studies: Dr. Eng. Robert Barski
Name of lec turer : Dr. Eng. Robert Barski
Form of ins t ruc t ion
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Number o f ECTS
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Ful l - t ime s tud ies
Lecture 45 3 Exam
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Lecture 8 0,5 Exam
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COURSE AIM:
The aim of the course is to familiarize students with issues related to the design of internal combustion processes, motor fuels, the impact of combustions engines on the environment. In addition, students become familiar with the construction of modern internal combustion engines.
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
ENTRY REQUIREMENTS: Thermodynamics, Metrology and Measurement Systems, Chemistry, Principles of machine construction.
COURSE CONTENTS: Content of the lecture. The course covers familiarize students with the basic concepts of thermal machines, motor fuels, internal combustion engines, reciprocating compressors, gas properties ideal and real, thermodynamics quasi-static phenomena, heat transfer in thermal machines, reciprocating steam engine, steam turbine, engine flow, the theory of combustion in the Diesel engine and Semiconductor engine cycle theory, Otto cycle, Diesel cycle. Kinematics of crank-piston mechanism, the theory of turbocharging.
Laboratory: The laboratory classes students learn the practical side of engine measurements. These measurements include the performance characteristics of the engine velocity, load characteristics, regulatory, plotting the universal characteristics of the engine based on a set of characteristics of the load, Research injection pumps, testing pumps and diesel engines and semiconductor engines, performance measurements..
TEACHING METHODS: Lectures with audiovisual aids. Working with books and individual work during the development of laboratory issues.
LEARNING OUTCOMES: K_W02 Detailed knowledge of the fields of study related to the direction of
Mechanical Engineering K_W05 Knowledge of the development trends and the most important new
developments in the field of sciences and scientific disciplines relevant to the direction of Mechanics and Mechanical Engineering and related disciplines associated with thermal machines
K_K03 Ability to cooperate and work in a group in the different roles K_K02 Awareness and understanding of the effects of non-technical aspects and
engineering activities, including its impact on the environment and consequently the responsibility for decisions
K_U01 Ability to obtain information from the literature and other sources, interpreting and integrating the information.
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITE RIA: K_W02
K_W05
K_U01 K_K02 K_K03 K_U01
Written or oral exam (written test)
Lecture - subject to completion of the lecture is to get a positive assessment of the three written or oral answers to exam questions (written test)
Revised report on the implementation of laboratory subjects and the degree of commitment to the issues
Implementation issues
Laboratory - Laboratory provided credit is a positive evaluation of all
STUDENT WORKLOAD: The student workload of 150 hours, including work in the auditorium 45 (8) hours, work in laboratory 30 (8), working alone 30 (60) hours, to prepare to laboratory 15 (30) hours, to prepare for the exam (test) of the lecture 30 (44) hours.
RECOMMENDED READING: 1. Luft, Sławomir, Podstawy budowy silników, Warszawa : Wydawnictwa Komunikacji i
Łączności, 2011
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
2. Mysłowski, Janusz Doładowanie silników , Warszawa : Wydawnictwa Komunikacji i Łączności, 2006
3. Mysłowski, Jaromir. Zanieczyszczenie powietrza przez pojazdy samochodowe, Warszawa: Wydawnictwa Komunikacji i Łączności, 2011
4. Dowkontt Jerzy Teoria silników cieplnych, Wydawnictwa Komunikacji i Łączności, Warszawa 1973.
5. JeŜ, Marian Silniki spalinowe : zasady działania i zastosowania, Warszawa : Wydawnictwo Naukowe Instytutu Lotnictwa, 2008.
6. Rychter, Tadeusz Teoria silników tłokowych , Warszawa : Wydawnictwa Komunikacji i Łączności, 2006.
7. BrzeŜański, Marek, Emisja toksycznych składników spalin w fazie nagrze wania si ę silnika o zapłonie iskrowym z zastosowaniem akumulatora ciepł a, Kraków : Wydawnictwo PK, 2006
8. Wajand, Jan Aleksander Tłokowe silniki spalinowe średnio- i szybkoobrotowe, Warszawa : Wydawnictwa Naukowo-Techniczne, 2005
9. Świątek, Antoni. Studium pracy reaktora katalitycznego w aspekcie poprawy jakości jego parametrów ekologicznych, Poznań : Wydaw. Politechniki Poznańskiej, 2005
10. Kowalewicz, Andrzej Wybrane zagadnienia samochodowych silników spalinowych, Radom : Politechnika Radomska. Wydaw., cop. 2002
11. Merkisz, Jerzy Ekologiczne problemy silników spalinowych., Poznań Wydawnictwo Politechniki Poznańskiej, 1999.
12. Kowalewicz, Andrzej, Podstawy procesów spalania, WNT, Warszawa, 2000
13. Kowalewicz, Andrzej, Doładowanie silników spalinowych, Radom : Politechnika Radomska im. K. Pułaskiego, 1998
14. Merkisz, Jerzy, Emisja cz ąstek stałych przez silniki spalinowe o zapłonie sam oczynnym : wybrane zagadnienia , Poznań Wydawnictwo Politechniki Poznańskiej, 1997
15. Merkisz, Jerzy Ekologiczne aspekty stosowania silników spalinowych , Poznań Wydawnictwo Politechniki Poznańskiej, 1996
OPTIONAL READING: 1. Technical Journals
2. Ubysz, Aleksander.Ćwiczenia laboratoryjne z silników spalinowych i ochrony środowiska, Gliwice, Wydaw. Politechniki Śląskiej, 2002
3. pod red. Wojciecha Serdeckiego Badania silników spalinowych : laboratorium, Poznań, Wydawnictwo Politechniki Poznańskiej, 2000
4. Ubysz, Aleksander. Materiały do ćwiczeń laboratoryjnych z silników spalinowych, Gliwice : Wydaw. Politechniki Śląskiej, 2001
5. Drozd Czesław, Sroka Zbigniew Silniki spalinowe : laboratorium, Wrocław : Oficyna Wydawnicza Politechniki Wrocławskiej, 1998
6. Pod red. Niewczasa Andrzeja: Laboratorium silników spalinowych Lublin : Politechnika Lubelska, 1996
REMARKS: The numbers in the list of student load in parentheses indicate the load of work for part-time studies.
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
VVV EEE HHH III CCC LLL EEE DDD III AAA GGG NNN OOO SSS TTT III CCC SSS
Course code: 06.1-WM-MiBM-S1-KiEP-000_09-07-01
06.1-WM-MiBM-N1-KiEP-000_09-07-01
Type of course: optional
Language of ins truc t ion: polish
Direc tor of studies: Dr. Eng. Robert Barski
Name of lec turer : Dr. Eng. Robert Barski
Form of ins t ruc t ion
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COURSE AIM:
The aim of the course is to familiarize students with the research on the stands and the principles of automotive development and optimization of diagnostic tests for use in the further process of education and future careers
ENTRY REQUIREMENTS:
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
Thermodynamics, Metrology and Measurement Systems, Chemistry, Fundamentals of Machine Design, Vehicle Design.
COURSE CONTENTS:
Basic concepts, test, measurement, test track, Stages of the object in terms of diagnosis, the diagnostic signals, ergodicity signal measurement circuit, transmitter, sensor, signal estimation technique of filtering, techniques of discretization, digital signal DFT and FFT analysis, the diagnostic classification of the technical parameters machinery, process diagnostics, diagnostic models of objects, diagnostic experiments, building diagnostics optimization of diagnostic tests, thermal and vibroacoustic diagnostics, Visual inspection of the vehicle, engine diagnostics, diagnostics and testing of brake systems, suspension automotive diagnostics, lines diagnostics. On Board Diagnostics OBD I and OBD II (EOBD)
Laboratory: Inspection and maintenance lighting system and car alarm. Chassis control. Study suspension and shock absorbers. Evaluating the effectiveness of the braking system in the research the stand. Research of the propulsion system, diesel engine diagnostics, semiconductor engines diagnostics, opacity measurement, measurement of toxic gases, cylinder leakage measurement, pressure measurement, compression damping performance measurement. OBD
TEACHING METHODS: Lectures with audiovisual aids. Working with books and individual work during the development of laboratory issues.
LEARNING OUTCOMES: K_W02 Detailed knowledge of the fields of study related to the direction of
Mechanical Engineering K_W05 Knowledge of the development trends and the most important new
developments in the field of sciences and scientific disciplines relevant to the direction of Mechanics and Mechanical Engineering and related disciplines associated with thermal machines
K_K03 Ability to cooperate and work in a group in the different roles K_U11 Formulation and testing of hypotheses related to engineering problems and
simple research problems K_W06 Knowledge of the life cycle of equipment, facilities, and technical systems K_K02 Awareness and understanding of the effects of non-technical aspects and
engineering activities, including its impact on the environment and consequently the responsibility for decisions
K_K04 Understanding the importance of learning throughout life. K_U01 Ability to obtain information from the literature and other sources, interpreting and
integrating the information. K_U09 Formulating and solving engineering and scientific problems of simple analytical
methods, simulation and experimental
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITE RIA: K_W02
K_W05
K_U01 K_K02 K_U09
Written or oral exam (write test)
Lecture - subject to completion of the lecture is to get a positive assessment of the written or oral exam (written tests)
Revised report on the implementation of laboratory subjects and the degree of commitment to the issues
Laboratory - Laboratory provided credit is a positive assessment of the ongoing laboratory tests and controls.
STUDENT WORKLOAD:
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
The student workload of 90 hours, including work in the auditorium 30 (8) hours, working alone 10 (8) hours, work in laboratory 30 (8) hours, to prepare for the test of the lecture 10 (24) hours.
RECOMMENDED READING: 1. Merkisz Jerzy, Pokładowe systemy diagnostyczne pojazdów samochodowych,
Warszawa, Wydawnictwa Komunikacji i Łączności, 2007 2. Madej, Henryk Diagnozowanie uszkodzeń mechanicznych w silnikach, spalinowych
maskowanych przez elektroniczne urządzenia sterujące, Katowice; Radom, Wydawnictwo Naukowe Instytutu Technologii Eksploatacji - PIB, 2009
3. Kolanek, Czesław. Red. Diagnostyka współczesnych silników spalinowych., Wrocław, Oficyna Wydawnicza Politechniki Wrocławskiej, 1996
4. Cempel Czesław. Diagnostyka maszyn. Wydawnictwa Komunikacji i Łączności, 2005 5. Hebda M., Niziński S., Pelc H, Podstawy diagnostyki pojazdów. Wydawnictwa Komunikacji i
Łączności, Warszawa 1984 6. Orzełowski Seweryn, Badania pojazdów. Wydawnictwa Komunikacji i Łączności, 2005 7. Bocheński Czesław, Badania kontrolne pojazdów. Wydawnictwa Komunikacji i Łączności, 2000 8. Kierdorf Bruno, Diagnostyka silników o zapłonie iskrowym. Wydawnictwa Komunikacji i
Łączności, 1989 9. Bocheński Czesław, Diagnostyka silników wysokopręŜnych., Wydawnictwa Komunikacji i
Łączności, 1986 10. J. Merkisz, ST. Mazurek Pokładowe systemy diagnostyczne pojazdów samochodowych,.
Wydawnictwa Komunikacji i Łączności, 2005 11. Wrzecionarz Badania techniczne pojazdów, Wrocław : Oficyna Wydawnicza Politechniki
Wrocławskiej, 2004, 12. Trzeciak, Krzysztof Diagnostyka samochodów osobowych Warszawa, Wydawnictwa Komunikacji
i Łączności, 2008 13. Gołębiowski, Sławomir BADANIA KONTROLNE SAMOCHODOW, WARSZAWA : WKL, 1982 14. Kozłowski, Andrzej Pomiary diagnostyczne zespołów układu zasilania paliwem silników o
zapłonie samoczynnym, Warszawa : Wydawnictwa Komunikacji i Łączności, 2005 15. Leszek A. Stricker Diagnostyka samochodowa - bezpieczeństwo. Wrocław : Oficyna Wydawnicza
Politechniki Wrocławskiej, 1996
16. Jurczyk Grzegorz Badania techniczne pojazdów . Kraków : Centrum Szkolenia i Organizacji Systemów Jakości Politechniki Krakowskiej im. Tadeusza Kościuszki Ośrodek Kształcenia Kadr Kierowców "Auto-Transbud", 2004
The aim of the course is to familiarize students with the research on the stands and the principles of automotive development and optimization of diagnostic tests for use in the further process of education and future careers
ENTRY REQUIREMENTS:
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
Thermodynamics, Metrology and Measurement Systems, Chemistry, Fundamentals of Machine Design, Vehicle Design.
COURSE CONTENTS:
Basic concepts, test, measurement, test track, Stages of the object in terms of diagnosis, the diagnostic signals, ergodicity signal measurement circuit, transmitter, sensor, signal estimation technique of filtering, techniques of discretization, the diagnostic classification of the technical parameters machinery, process diagnostics, diagnostic models of objects, diagnostic experiments, building diagnostics optimization of diagnostic tests, thermal and vibroacoustic diagnostics, Visual inspection of the vehicle, engine diagnostics, engine power bench measurements, diagnostics and testing of brake systems, suspension automotive diagnostics, lines diagnostics.
Laboratory: Inspection and maintenance lighting system and car alarm. Chassis control. Study suspension and shock absorbers. Evaluating the effectiveness of the braking system in the research the stand. Research teams of the propulsion system, diesel engine diagnostics, engine diagnostics semiconductor engines, opacity measurement, measurement of toxic gases, cylinder leakage measurement, pressure measurement compression damping performance measurement.
TEACHING METHODS: Lectures with audiovisual aids. Working with books and individual work during the development of laboratory issues.
LEARNING OUTCOMES: K_W02 Detailed knowledge of the fields of study related to the direction of
Mechanical Engineering K_W05 Knowledge of the development trends and the most important new
developments in the field of sciences and scientific disciplines relevant to the direction of Mechanics and Mechanical Engineering and related disciplines associated with thermal machines
K_K03 Ability to cooperate and work in a group in the different roles K_U11 Formulation and testing of hypotheses related to engineering problems and
simple research problems K_W06 Knowledge of the life cycle of equipment, facilities, and technical systems K_K02 Awareness and understanding of the effects of non-technical aspects and
engineering activities, including its impact on the environment and consequently the responsibility for decisions
K_K04 Understanding the importance of learning throughout life. K_U01 Ability to obtain information from the literature and other sources, interpreting and
integrating the information. K_U09 Formulating and solving engineering and scientific problems of simple analytical
methods, simulation and experimental
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITE RIA: K_W02
K_W05
K_U01 K_K02 K_U09
Written or oral exam (write test)
Lecture - subject to completion of the lecture is to get a positive assessment of the written or oral exam (written tests)
Revised report on the implementation of laboratory subjects and the degree of commitment to the issues
Laboratory - Laboratory provided credit is a positive assessment of the ongoing laboratory tests and controls.
STUDENT WORKLOAD: The student workload of 90 hours, including work in the auditorium 30 (8) hours, working alone 10 (8) hours, work in laboratory 30 (8) hours, to prepare for the test of the lecture 10 (24) hours.
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
RECOMMENDED READING: 1. Merkisz Jerzy, Pokładowe systemy diagnostyczne pojazdów samochodowych,
Warszawa, Wydawnictwa Komunikacji i Łączności, 2007 2. Madej, Henryk Diagnozowanie uszkodzeń mechanicznych w silnikach, spalinowych
maskowanych przez elektroniczne urządzenia sterujące, Katowice; Radom, Wydawnictwo Naukowe Instytutu Technologii Eksploatacji - PIB, 2009
3. Kolanek, Czesław. Red. Diagnostyka współczesnych silników spalinowych., Wrocław, Oficyna Wydawnicza Politechniki Wrocławskiej, 1996
4. Cempel Czesław. Diagnostyka maszyn. Wydawnictwa Komunikacji i Łączności, 2005 5. Hebda M., Niziński S., Pelc H, Podstawy diagnostyki pojazdów. Wydawnictwa Komunikacji i
Łączności, Warszawa 1984 6. Orzełowski Seweryn, Badania pojazdów. Wydawnictwa Komunikacji i Łączności, 2005 7. Bocheński Czesław, Badania kontrolne pojazdów. Wydawnictwa Komunikacji i Łączności, 2000 8. Kierdorf Bruno, Diagnostyka silników o zapłonie iskrowym. Wydawnictwa Komunikacji i
Łączności, 1989 9. Bocheński Czesław, Diagnostyka silników wysokopręŜnych., Wydawnictwa Komunikacji i
Łączności, 1986 10. J. Merkisz, ST. Mazurek Pokładowe systemy diagnostyczne pojazdów samochodowych,.
Wydawnictwa Komunikacji i Łączności, 2005 11. Wrzecionarz Badania techniczne pojazdów, Wrocław : Oficyna Wydawnicza Politechniki
Wrocławskiej, 2004, 12. Trzeciak, Krzysztof Diagnostyka samochodów osobowych Warszawa, Wydawnictwa Komunikacji
i Łączności, 2008 13. Gołębiowski, Sławomir BADANIA KONTROLNE SAMOCHODOW, WARSZAWA : WKL, 1982 14. Kozłowski, Andrzej Pomiary diagnostyczne zespołów układu zasilania paliwem silników o
zapłonie samoczynnym, Warszawa : Wydawnictwa Komunikacji i Łączności, 2005 15. Leszek A. Stricker Diagnostyka samochodowa - bezpieczeństwo. Wrocław : Oficyna Wydawnicza
Politechniki Wrocławskiej, 1996
16. Jurczyk Grzegorz Badania techniczne pojazdów . Kraków : Centrum Szkolenia i Organizacji Systemów Jakości Politechniki Krakowskiej im. Tadeusza Kościuszki Ośrodek Kształcenia Kadr Kierowców "Auto-Transbud", 2004
The aim of the course is to familiarize students with the principles of operation of vehicles, systems, use of vehicles and supplies used in the automotive industry for use in their future careers.
ENTRY REQUIREMENTS:
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
Thermodynamics, Metrology and Measurement Systems, Chemistry, Fundamentals of Machine Design, Vehicle Design.
COURSE CONTENTS:
Content of the lecture. Vehicle operating systems: operation, maintenance, spare parts supply, management and operations. Models of vehicle operating process. Classification of condition of use. Quantitative characterization processes. Supported types of vehicles. Facilities operation, maintenance organization. The classification process handling. Quantitative characteristics of vehicle service. Physical aging (abrasion, adhesion, fatigue, pitting, wear oxidation, corrosion, cavitation). Technique for selected maintenance: basic mechanisms, regulation of motor systems and chassis mechanisms.
TEACHING METHODS: Lectures with audiovisual aids. Working with books and individual work during the development of laboratory issues.
LEARNING OUTCOMES: K_W02 Detailed knowledge of the fields of study related to the direction of
Mechanical Engineering K_W05 Knowledge of the development trends and the most important new
developments in the field of sciences and scientific disciplines relevant to the direction of Mechanics and Mechanical Engineering and related disciplines associated with thermal machines
K_K03 Ability to cooperate and work in a group in the different roles K_W06 Knowledge of the life cycle of equipment, facilities, and technical systems K_K02 Awareness and understanding of the effects of non-technical aspects and
engineering activities, including its impact on the environment and consequently the responsibility for decisions
K_K04 Understanding the importance of learning throughout life. K_U01 Ability to obtain information from the literature and other sources, interpreting and
integrating the information. K_U09 Formulating and solving engineering and scientific problems of simple analytical
methods, simulation and experimental
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: K_W02
K_W05
K_U01 K_K02 K_U09
Written test
Lecture - subject to completion of the lecture is to get a positive assessment of the two written tests
STUDENT WORKLOAD: The student workload of 90 hours, including work in the auditorium 30 (8) hours, working alone 30 (30) hours, to prepare for the test of the lecture 10 (22) hours.
RECOMMENDED READING: 1. Abramek F.K., Uzdowski M. Podstawy obsługiwania i napraw. Wydawnictwa Komunikacji i
Łączności. Warszawa 2009
2. Hebda M, Mazur T. Podstawy eksploatacji pojazdów samochodowych, WKiŁ. Warszawa, 1980,
3. Hebda M. Eksploatacja samochodów, Instytut Technologii Eksploatacji - PIB/ 2006
4. Niziński S. Eksploatacja obiektów technicznych, WKiŁ, Warszawa, 1996
5. S. Orzełowski Naprawa i obsługa pojazdów samochodowych, WSiP, Warszawa,
6. Uzdowski M., Abramek K.F., Garczyński K.: Eksploatacja techniczna i naprawa. WKiŁ Warszawa, 2003,
Mechanical Faculty
Subject area of studies: Mechanics and mechanical engineering
7. Merkisz J. Ekologiczne aspekty stosowania silników spalinowych. Wydawnictwo Politechniki Poznańskiej, Poznań 1994,
8. Niziński S.: Eksploatacja obiektów technicznych. Biblioteka problemów eksploatacji. ITE Wojskowy Instytut Techniki Pancernej i Samochodowej, Bydgoszcz – Sulejówek 2002
9. Niziński S. Eksploatacja techniczna i utrzymanie samochodów,. WKiŁ, Warszawa
10. Postrzednik, St., Termodynamiczne oraz ekologiczne uwarunkowania eksploatacji tłokowych silników spalinowych, Gliwice Wydawnictwo Politechniki Śląskiej, 2007
11. Tabor A., Franczyk J., Motoryzacyjne materiały eksploatacyjne, tachografy, badania techniczne pojazdów, odlewy i wyroby z proszków metali w motoryzacji, recykling zuŜytych pojazdów, korozja, medycyna pracy, Kraków, Centrum Szkolenia i Organizacji Systemów Jakości Politechniki Krakowskiej im. Tadeusza Kościuszki, 2006
OPTIONAL READING:
REMARKS: The numbers in the list of student load in parentheses indicate the load of work for part-time studies.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE AIM: The aim of the course is to familiarize students with logistics of supply, production and distribution, as well as types of the modern transport of goods.
ENTRY REQUIREMENTS:
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
-
COURSE CONTENTS: Lecture:
Logistics - tasks and activities. Elements of logistics of supply, production and distribution. Types of the modern transport of goods. The operational technologies in the loading and unloading of goods. Machines, vehicles and equipment of transport companies.
TEACHING METHODS: Lectures - with using audiovisual means
LEARNING OUTCOMES: In the field of
technical sciences Knowledge, skills, competence
K_W18 the student characterizes modern technologies of transport of goods
K_U15 the student evaluates existing technical solutions in terms of infrastructure, cargo handling and transport processes
K_K04 the student is able to determine priorities for implementation of specific tasks of transport logistics
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification policy outcomes are shown in the following table.
The reference to the learning
outcomes of the field of study
The method of the learning outcomes assessment
K_W18 K_U15 K_K04
Lecture-grade
Evaluation of the lecture is determined on the basis evaluation of the colloquium (weight = 0.5) and evaluation of control work (weight = 0.5).
STUDENT WORKLOAD: The student workload of 50 (50) hours, including work in the auditorium 25 (16) hours, including consultations 10 (8) hours, individual work 25 (34) hours, control work 17 (24) hours, preparing for the final colloquium 8 (10) hours.
Total hours of practical classes: 27 (32) which corresponds to 1 ECTS.
Total hours of lessons with a teacher: 25 (16) which corresponds to 1 ECTS.
RECOMMENDED READING: 1. Rydzkowski W. (red.) - Transport. PWN, Warszawa 2002.
2. Kwaśniowski S., Nowakowski T., Zając M. – Transport intermodalny w sieciach logistycznych. OW PW, Wrocław 2008.
3. Mindura L. (red.) – Technologie transportowe XXI w. Wyd. ITE, Warszawa – Radom 2008.
4. Markusik S. – Infrastruktura logistyczna w transporcie. T. 1. – Środki transportu. Wyd. Polit. Śląskiej, Gliwice 2009.
OPTIONAL READING: 1. Korzeń Z. (red.) – Logistyka w transporcie towarów. PW, Wrocław 1998.
2. Tarkowski J. – Transport – logistyka. ILiM, Poznań 1995.
REMARKS: Workloads in parentheses are the numbers for part time studies.
Faculty of Mechanical Engineering Subject area of studies: Mechanics and Mechanical Engineering
CCC OOO MMM PPP UUU TTT EEE RRR AAA III DDD EEE DDD DDD EEE SSS III GGG NNN AAA NNN DDD VVV EEE HHH III CCC LLL EEE TTT EEE SSS TTT III NNN GGG
Name of lecturer: dr inŜ. Jerzy Sobich, dr inŜ. Robert Barski
Form of ins t ruc t ion
Nu
mb
er
of
tea
ch
ing
ho
urs
p
er
se
me
ste
r
Nu
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er
of
tea
ch
ing
ho
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p
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Se
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Form of rece iving a c redi t
for a course
Number o f ECTS
cred i ts a l loca ted
Ful l - t ime s tud ies
Lecture
Class
Laboratory
Seminar
Workshop
Pro jec t 30 2
II
Grade
Part - t ime s tudies
Lecture
Class
Laboratory
Seminar
Workshop
Pro jec t 16 2
IV
Grade
4
COURSE AIMS: The aim of the course is the ability to design parts and components of motor-vehicles using the CATIA system.
PREREQUISITIES: Engineering graphics, fundamentals of engineering design, fundamentals of informatics.
COURSE CONTENTS: Project of the construction element of motor-vehicle in CATIA system.
Faculty of Mechanical Engineering Subject area of studies: Mechanics and Mechanical Engineering
TEACHING METHODS: Design exercises at the computer. Working with books and instructions. Individual work while preparing a project.
LEARNING OUTCOMES: In the field of
technical sciences
Knowledge, skills, competence
K_W04 The student has basic knowledge of computer-aided design of the construction elements and assemblies of motor-vehicles.
K_U08 Has the ability to design the simply construction elements and simply assemblies of motor-vehicles in the CATIA system.
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITE RIA: The verification methods for learning outcomes are presented in the table below:
The reference to the learning outcomes of the field of study
The method of the learning outcomes assessment
K_W04 K_U08
The evaluation of projects.
To get a credit the student has to receive a passing grade of the course comprises a positive assessment of the projects prepared according the assigned task.
STUDENT WORKLOAD: The student workload of 110 (110) hours, including work in the auditorium 30 (16) hours, preparing for classes and preparing a projects 80 (94) hours.
LITERATURA PODSTAWOWA 1. WyleŜoł M., Modelowanie bryłowe w systemie CATIA. Przykłady i ćwiczenia. Ed. Helion
2002.
2. Wełyczko A., CATIA v.5. Przykłady efektywnego zastosowania w projektowaniu mechanicznym. Ed. Helion 2005.
3. Skarka w., Mazurek A., Podstawy modelowania i zapisu konstrukcji. Ed. Helion 2005.
LITERATURA UZUPEŁNIAJ ĄCA 1. WyleŜoł M., Modelowanie powierzchniowe i hybrydowe w systemie CATIA v.5. Ed.
Helion 2003.
Faculty of Mecanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
Direc tor of studies: Dr.Sc. K. Bielefeldt, Associate Professor
Name of lec turer : Prof. K. Bielefeldt, Dr. Janusz Walkowiak
Form of instruct ion
Number of
teaching
hours per
semester
Number of
teaching
hours per
week
Semester
Form of rece iving a credit
for a course
Number of ECTS
credi ts a l loca ted
Ful l - t ime studies
Lecture
Class
Laboratory
Seminar 30 2 Grade
Workshop
Project
Part - t ime s tudies
Lecture
Class
Laboratory
Seminar 8 1 Grade
Workshop
Project
3
COURSE AIM: Transferring basic knowledge about development conditions and international cooperation in the automotive industry in a global world with focus on the outsourcing strategy.
Attention is directed to the production relations and the transfer of know-how (new materials, new techniques and modern methods of construction)
Faculty of Mecanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
ENTRY REQUIREMENTS: Main subjects of the study, as well as elements of the economy
COURSE CONTENTS: Selection criteria for parts and assemblies which are to be manufactured with the outsourcing strategy. The practice of outsourcing in the manufacturing of automotive components for Western manufacturers.
Modern materials and technology in the automotive industry, in use at the component parts and modules. Use of glass fiber reinforced plastic, nanomaterials, biopolymers and natural reinforcing materials. Engineering and technological problems. Recycling.
K_W17 features necessary to understand basic knowledge to the social, economic, legal, environmental and other non-technical factors of engineering activities,
K_U17 knowledge of evaluating the usefulness of routine methods and tools to solve simple tasks of practical engineering in the following areas: design, technology and operation of machines and select and use appropriate methods and tools,
K_K04 student knowingly compiles work station together with equipment, used to perform the tasks of design.
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The reference to the learning outcomes of
the field of study
The method of the learning outcomes assessment
K_W17 K_U17 K_K04
The full time studies: grade based on written test; The part-time studies cast on the basis of an average weight assessment written test of the test (weight = 0.6) and the evaluation of the semester work control (weight = 0.4).
STUDENT WORKLOAD: 90 hours - including 45 h (15) hours of contact with the teacher, 45 h (20) - working alone, including 20 hours to prepare for busy, 15 h familiar with the source material
Ekonomiczna Grupa Wolters Kluwer, Kraków 2002 , wyd.1
2. Bielefeldt, K.H.: Outsourcing w przemyśle maszynowym w praktyce, w: InŜynieria produkcji,red. J. Mutwil, J. Jakubowski.- Zielona Góra: Oficyna Wyd. UZ 2006
OPTIONAL READING: 1. Kunststoffe im Automobilbau, ed. VDI Düsseldorf and next ed. (2000 – 20..)
REMARKS: -
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE AIMS: The aim of the subject is to familiarize students with a safe way to get around in traffic. Cognition-enhancing factors and solutions and the safety of road users. PREREQUISITIES: Construction vehicles. The theory of the movement of vehicles.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE CONTENTS: Lecture kontent: Dangers and the threats associated with the participation in the road traffic. Analysis of findings of the safety state, general characteristics of road traffic accidents. Analysis of the influence of the state of the road infrastructure and for her surrounding, features of vehicles and behaviours of the driver on the safety state in the road traffic. Structural solutions in vehicles increasing safety of road users.
TEACHING METHODS: Lectures with audiovisual aids. Working with books and standards. Individual work while preparing a project.
LEARNING OUTCOMES: In the field of
technical sciences
Knowledge, skills, competence
K_W04 He has detailed knowledge of theoretical underpinnings related to selected topics of Mechanics and Mechanical Engineering
K_W08 He has the knowledge necessary to understand the social, economic, legal and other non-technical considerations engineering activities and their role in engineering practice
K_U01 Can obtain information from the literature, databases and other properly selected sources, also in English or other foreign language recognised as the language of international communication in the field of road safety, it can integrate the information obtained, to their interpretation and critical evaluation, and also draw conclusions and formulate and fully justify the reviews
K_K02 Is aware of and understands the non-technical aspects and effects of engineering activities, including its impact on the environment, and the associated responsibility for decisions
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification methods for learning outcomes are presented in the table below:
The reference to the learning outcomes of the field of study
The method of the learning outcomes assessment
K_W04
K_W08 Colloquium
K_U01 K_K02
grade Semester
Lecture-condition assessment of the lecture is to obtain a positive evaluation of the Colloquium and of the semester work
STUDENT WORKLOAD: The student workload of 30 hours, including work in the auditorium 15 (8) hours, individual work 15(22) hours. Total hours of individual work: 15(22) which corresponds to 1 ECTS. Total hours of lessons with a teacher: 15(8) which corresponds to 1 ECTS.
RECOMMENDED READING: 1. Wicher J. :Bezpieczeństwo samochodów i ruchu drogowego. WKiŁ, Warszawa 2002. 2. Wierciński J.:Wypadki drogowe – elementy analizy technicznej i opiniowania. WKiŁ,
Warszawa 1985. 3. Datka S., Suchorzewski W., Tracz M.: InŜynieria ruchu. WKiŁ Warszawa 1999. 4. Bachrach A.: Elementy ogólnej profilaktyki wypadków drogowych. Wydawnictwo Szkolne i
Pedagogiczne, Warszawa 1978. 5. Krystek R.: Zintegrowany system bezpieczeństwa transportu. WKŁ, Warszawa 2009.
OPTIONAL READING: 1. Ustawa „Prawo o ruchu drogowym”.
2. Gacek W.: Pierwsza pomoc. Warszawa, Centralny Instytut Ochrony Pracy, 1998.
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
The aim of the course is to familiarize students with construction and operation of motor vehicle powertrain.
PREREQUISITES: Basis of construction of machines
Faculty of Mechanical Engineering
Subject area of studies: Mechanics and Mechanical Engineering
COURSE CONTENTS: Hybrid powertrain, basic definitions, selection of components, electro - combustion powertrain of motor vehicles. Student performs the complete design chosen powertrain.
TEACHING METHODS: Working with the book. Group work in classes.
LEARNING OUTCOMES: In the field of
technical sciences
Knowledge, skills, competence
K_W16 The student knows the basic methods of techniques and required tools for dissolving of simple problems of buildings, technology of productions and exploitation of cars
K_U02 can communicate using a variety of techniques in the professional environment and other environments, also in English or any other foreign language considered as a language of international communication in the field of motor vehicle powertrain
K_U09 can use analytical, simulation and experimental methods to formulate and solve engineering tasks and simple research problems
LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification methods for learning outcomes are presented in the table below.
The reference to the learning outcomes of the field of study
The method of the learning outcomes assessment
K_W16
K_U02
K_U09
grade based on performed projects
STUDENT WORKLOAD:
The student workload of 30 hours, including work in the auditorium 15 (8) hours, individual work 15 (22) hours, preparing for classes 15 (20) hours. Total hours of practical classes: 30 (30) which corresponds to 1ECTS Total hours of lessons with a teacher: 15(8) which corresponds to 1 ECTS
RECOMMENDED READING: 1. Szumanowski A.: Akumulacja energii w pojazdach. Wydawnictwa Komunikacji i Łączności,
