ssttrruuccttuurree ......ssttrruuccttuurree,, pprrooggrraammmmiinngg aanndd ooppeerraattiioonn ooff...

SSS TTT RRR UUU CCC TTT UUU RRR EEE ,,, PPP RRR OOO GGG RRR AAA MMM MMM III NNN GGG AAA NNN DDD OOO PPP EEE RRR AAA TTT III OOO NNN OOO FFF CCC NNN CCC MMM AAA CCC HHH III NNN EEE TTT OOO OOO LLL SSS

Course code: 06.1-WM-MiBM-S1-EM-01_12

06.1-WM-MiBM-N1-EM-01_12

Type of course: obligatory

Language of ins truc t ion: Polish

Direc tor of studies: Dr inŜ. Alicja Laber

Name of lec turer : Dr inŜ. Alicja Laber

Form of instruct ion

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Form of rece iving a credit

for a course

Number of ECTS

credi ts a l loca ted

Ful l - t ime studies

Lecture 30 2 Exam

Class - -

Laboratory 30 2 grade

Seminar - -

Workshop - -

Pro jec t - -

VI

Part - t ime s tudies

Lecture 18 2 Exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI

5

СOURSE AIMS:

The aim of the course is to introduction students with the construction, and operation principle of contemporary programming of numerically controlled machines.

PREREQUISITES Manufacturing processes, Metrology, Fundamentals of Mechanical Engineering , CAM

COURSE CONTENTS: Substantive content. Axles modern machine controls. Geometric structure - physical. Determination of zero points of numerically controlled machine tools. The measurement systems. Servo. Engines and powertrains for infinitely variable speeds. Servo drives in carrying traffic. Trajectory specified

and implemented with linear and circular movement track. Types of controls. Determination of displacement tools. Transport items. Utility Warehouse. Bed, bodies and tables. Machining centers. Flexible machining systems. Trends in the construction of modern machine tools. Review by modern lathes, milling machines, drilling machines, Boring and milling machines, grinders, gear machines. The tasks of the working group at the start of a new production on CNC machines. The impact of the production process and the selection of machine calculation of production costs. Processes, implementation and operation of OSN. The operating and diagnostic machines. Acquainted with the principle of operation and construction of the milling EMCO F1 - CNC. Working machine for circular interpolation. Working machine with linear interpolation. Working machine curvilinear interpolation.

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, current standards, Magazines and catalogs of numerically controlled machine tool manufacturers, individual work student in developing the program for the CNC machine.

LEARNING OUTCOMES:

K_W04 knows the principles of engineering graphics and tools used in the preparation of the technical documentation

K_W09 has an elementary knowledge of the principles of workpiece design and mechanical equipment constructions

K_W14 has basic knowledge on developments in the design, manufacturing and operating of machines

K_W16 knows the basic methods, techniques and tools required to solve simple tasks in the field of construction engineering, technology, manufacturing and operating of machinery

K_U07 The student can use information and communication technologies relevant to the tasks related to the design, manufacturing and operating of machinery

K_U13 can use modern computer techniques in solving engineering tasks related to the design, manufacturing and operating of machines

K_K04 able to prioritize appropriately for implementation of tasks specified by yourself or others

K_K07 can the social role of an engineer and participates in communicating credible information and opinions about technological developments in the field of engineering, construction and machines operation

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


Knowledge of engineering graphics and tools used in the preparation of the technical documentation

K_W04 Written exam

Knowledge of the principles of design and construction of mechanical equipment

K_W09 Written exam

Knowledge on developments in the design, manufacture, construction and operation of machines

K_W14 Written exam

Knowledge of basic methods and tools required to perform simple tasks in the field of construction engineering, technology, manufacturing and maintenance of machinery

K_W16 Written exam

Ability to use information and communication technologies relevant to the tasks related to the design and operation of production machinery

K_U07 CNC program execution and reporting

Ability to use modern computer techniques in solving engineering tasks related to the design, manufacture and operation of

K_U13 CNC program execution and

machines reporting

The ability to determine priorities for the implementation of specific tasks to yourself or others

K_K04 CNC program execution and reporting

understand the social role of the engineer and is involved in the transmission of reliable information and views on technological developments in the field of engineering, construction and operation of machines

K_K07 CNC program execution and reporting

Lecture - long passing is the positive assessment of the three written answers to examination questions Laboratory - credit provided to perform all laboratory reports and credit alone program written for the CNC machine. In evaluating the questions of the lecture, the following guidelines:

For grade 2 For grade 3 For grade 4 For grade 5 The student did not understand the question, can not properly be answered

Replies contain only basic information without supporting diagrams, charts, etc.

Replies include information presented in the classroom, but not fully complete or with minor errors

Replies contain complete information presented in the classroom and their own perception of the problem

STUDENT WORKLOAD: THE STUDENT WORKLOAD OF 150 HOURS, INCLUDING WORK IN THE AUDITORIUM 60 (36) HOURS, WORKING ALONE 90 (114). TOTAL HOURS OF PRACTICAL CLASSES: 88 (110) TOTAL HOURS OF LESSONS WITH A TEACHER: 82 (36)

RECOMMENDED READING: 1. Boguś Z.: Numeryczne sterowanie obrabiarek. Skrypt Politechniki Gdańskiej.

Gdańsk 1987; 2. Bednarek M i inni: Obrabiarki sterowane numerycznie – podstawy eksploatacji

WNT Warszawa 1986; 3. Wrotny L. T.: Projektowanie obrabiarek – zagadnienia ogólne i przykłady obliczen.

WNT Warszawa 1986;

OPTIONAL READING: 1. Honczarenko J.: Elastyczna automatyzacja wytwarzania. Obrabiarki i systemy obróbkowe.

WNT Warszawa 2000; 2. Kosmol: Automatyzacja obrabiarek i obróbki skrawaniem. WNT 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.

MMM AAA CCC HHH III NNN EEE SSS DDD III AAA GGG NNN OOO SSS TTT III CCC SSS

Course code: 06.1-WM-MiBM-S1-EM-02.1_12

06.1-WM-MiBM-N1-EM-02.1_12

Type of course: eligible

Language of instruction: Polish

Director of studies: Dr hab. inŜ. Stanisław Laber, prof UZ

Name of lecturer: Dr hab. inŜ. Stanisław Laber, prof UZ


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Lecture 15 1 grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI


Lecture - -

Class - -

Laboratory - -

Seminar 16 2 grade

Workshop - -

Pro jec t - -

VII

2

СOURSE AIMS: The aim of the course is to introduction students with the methodology of diagnostic elements and components of equipment.

PREREQUISITES:

Fundamentals of Mechanical Engineering , Metrology

COURSE CONTENTS: Substantive content. The objectives and tasks of technical diagnostics. Machine as an object of diagnostic tests. Phases of the existence of the machine - in the construction of diagnosis, stage of production and operational diagnostics. The physical aspects of the diagnosis, the quality of machines: design, implementation and operation. The quality of machine parts. Damage to machine components - classification, measurement damage, preventing damage. United used in diagnostic tests, diagnostic parameters of the equipment and rules for their use. The diagnostic machines. Forms of diagnostic machines to diagnose, monitor. Diagnosis of selected

components of machines: bearings, plain bearings and bushings, gears, hydraulic systems, cutting nodes.

Diagnostics of machine parts. Diagnosis of machine performance by measuring: volume, spindle speed.

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, standards and individual work during the development issues.

LEARNING OUTCOMES: K_W03 has a basic knowledge of the chemistry needed to understand and describe the

phenomena occurring in the manufacturing and operating of machines K_W13 has knowledge of engineering materials, their investigation and shaping

technologies K_W14 has basic knowledge on developments in the design,

manufacturing and operating of machines K_W16 knows the basic methods, techniques and tools required to solve simple

tasks in the field of construction engineering, technology, manufacturing and operating of machinery


K_U14 can use the measuring equipment used in problems of mechanics and mechanical engineering as well as methods for estimating measurement errors

K_K02 can understand the non-technical aspects of the mechanical engineer actions, its validity and effects, including the impact on the environment and the responsibility for decisions accepted


LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: RULES FOR THE VERIFICATION OF LEARNING OUTCOMES ARE PRESENTED IN THE TABLE BELOW.



assessment


student has a basic knowledge of the chemistry needed to understand and describe the phenomena occurring in the manufacture and operation of machines

K_W03 grade

The student has knowledge of engineering materials, their research and technology development

K_W13 grade

The student has a basic knowledge on developments in the design, manufacture, construction and operation of machines

K_W14 grade

know the basic methods, techniques and tools required to solve simple tasks in the field of construction engineering, technology, manufacturing and maintenance of machinery

K_W16 grade

able to use information and communication technologies relevant to the tasks related to the design and operation of production machinery

K_U07 report of the exercises

can use the measuring apparatus used in problems of mechanics and mechanical engineering as well as methods for estimating measurement errors


understand the non-technical aspects of the mechanical engineer, the validity and effects, including the impact on the environment and consequently the responsibility for decisions

K_K02 report of the exercises



Lecture - subject to completion of the lecture is to provide a positive evaluation of the three written responses to questions regarding basic issues subject. Laboratory - Laboratory provided credit is a positive evaluation of the reports prepared for exercise. In evaluating the questions of the lecture, the following guidelines:





STUDENT WORKLOAD: The student workload of 60 hours, including work in the auditorium 30 (16) hours, working alone 30 (44) hours, including preparation for classes and study reports, 20 (44) hours, to prepare for the test first completion 10 Total hours of practical classes: 35 (41), which corresponds to 2 ECTS Total hours of lessons with a teacher: 30 (18) which corresponds to 1 ECTS

RECOMMENDED READING: 1. Cempel Cz., Tomaszewski F.: DIAGNOSTYKA MASZYN. Zasady ogólne. Przykłady

zastosowań. Wyd. MCNEMT. Radom 1992; 2. Cholewa W., Kazimierczak J.: Diagnostyka techniczna maszyn - przetwarzanie cech sygnałów. Wyd.

Politechnika Śląska. Gliwice 1995; 3. Garbacki A., Szewczyk K.: Pomiary i diagnostyka maszyn roboczych cięŜkich. Wyd. Politechnika

Krakowska, Kraków 1974; 4. Nizimski S., Pelc H.: Diagnostyka urządzeń mechnicznych. WMT Warszawa 1980; 5. Nizimski S.: Elemety eksploatacji obiektów technicznych. Wyd. Uniwersytet Warmińsko – Mazurski,

Olsztyn 2000;

OPTIONAL READING: 1. Praca zbiorowa: Diagnostyka urzadzeń mechanicznych. Wyd. PAN 1977; 2. śółtowski B.: Podstawy diagnostyki maszyn. Wyd. ATR, Bydgoszcz 1996; 3. śółtowski B, Ćwik Z.: Leksykon diagnostyki technicznej Wyd. ATR, Bydgoszcz 1996;


MMM AAA CCC HHH III NNN EEE CCC OOO NNN TTT RRR OOO LLL SSS YYY SSS TTT EEE MMM SSS DDD III AAA GGG NNN OOO SSS TTT III CCC SSS


06.1-WM-MiBM-N1-EM-02.2_12






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Lecture 15 1 grade

Class - -


Seminar - -

Workshop - -

Pro jec t

VI


Lecture 9 1 grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI

2

СOURSE AIMS: The aim of the course is to introduction students with the diagnostic elements and technical facilities during construction, technology, construction and operation. PREREQUISITES: Metrology, Fundamentals of Machine Design and Operation, Construction Record COURSE CONTENTS:

Substantive content. Sources of technical diagnostics. Signs and symptoms of technical diagnostics. Thermal vibroacoustic diagnostics. Diagnostic models of objects. Diagnostic experiments. Computer aided diagnosis. Diagnosing anthropotechnical systems. Organizational and economic aspects of technical diagnostics. Diagnostics components, sub-assemblies and machines selected industries.

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, standards and individual work in the development of design issues.



technologies K_W14 has basic knowledge on developments in the design, manufacturing and operating

of machines K_W16 knows the basic methods, techniques and tools required to solve simple tasks in

the field of construction engineering, technology, manufacturing and operating of machinery








assessment



K_W03 grade


K_W13 grade


K_W14 grade


K_W16 grade









Lecture - subject to completion of the lecture is to provide a positive evaluation of the three written responses to questions regarding basic issues subject. Laboratory - Laboratory provided credit is a credit report from each class In evaluating the questions of the lecture, the following guidelines:





STUDENT WORKLOAD:

The student workload of 60 hours, including work in the auditorium 30 (16) hours, working alone 30 (44) hours, including preparation for classes and study reports, 20 (44) hours, to prepare for the test 10 Total hours of practical classes: 35 (41), which corresponds to 2 ECTS Total hours of lessons with a teacher: 30 (18) which corresponds to 1 ECTS

RECOMMENDED READING: 1. Laber S. Diagnostyka elementów maszyn. Praca przygotowana do druku.

Uniwersytet Zielonogórski 2008; 2. Cempel Cz., Tomaszewski F.: Diagnostyka maszyn. Przykłady zastosowań.

Wyd. MCNEMT. Radom 1992;

OPTIONAL READING: 1. Cholewa W., Kazimierczak J.: Diagnostyka techniczna maszyn - przetwarzanie cech

sygnałów. Wyd. Politechnika Śląska. Gliwice 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

SSS EEE LLL EEE CCC TTT EEE DDD AAA SSS PPP EEE CCC TTT SSS OOO FFF MMM AAA CCC HHH III NNN III NNN GGG


06.1-WM-MiBM-N1-EM-03_12

Type of course: compulsory

Language of ins truc t ion: Polish, Russian

Direc tor of studies: Prof. dr hab. inŜ. Eugene FELDSHTEIN

Name of lec turer : Prof. dr hab. inŜ. E. FELDSHTEIN, dr inŜ. A.LEWANDOWSKI, dr inŜ. A.LABER


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Lecture 30 2 Grade

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 30 2

VI

Grade


Lecture 18 2 Grade

Class - -

Laboratory - -

Seminar - -

Workshop - -

Project 18 2

VI

Grade

3

COURSE AIM: The aim of the course is to familiarize students with some of the issues of mechanical engineering to be used in their further education and future careers.

ENTRY REQUIREMENTS: Manufacturing Engineering, Computer aided manufacturing, Fundamentals of machining process design, Fundamentals of mechanical engineering technology, Technological devices.



COURSE CONTENTS: Lecture content. Courses of action of technologist in the machines production. The input dates to planning technological process. Means of production. Technology card and processing instruction. Types of semi-finished products and their selection. Preparation of blanks for machining. Heat and thermo-chemical operations. Basic processing errors. Stocks and factors affecting their size. Conventional and non-conventional machining technologies. Additional operations - cleaning, marking, etc. Processing of typical machine parts: shaft, sleeve, plate, frame, gear and others. Classification of the machine parts in terms of technology similarities. Framework processes of typical machine parts. Automation of transport and exchange of workpieces and tools. Organizational methods of assembly. Assembly processes. Cost of production.

Project. Machining technology for selected machine part or assembly technology.

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_W10, K_W16

The student knows the action of technologist in the plant, lists the necessary data for the planning of technological processes, knows semi-finished production methods, knows the characteristics of typical technological machines, knows the use assembly methods and methods of technological processes automation

K_U01 can obtain information from the literature, standards and other sources of the area of mechanical engineering

K_U03 can prepare a project in the field of machining technology K_U07 can use information and communication technologies to prepare a project K_U15 can evaluate the capabilities of various technologies used in mechanical

engineering, can choose the typical machines, tools and propose methods for machining of typical machine parts

K_U18 can work a machining technology for typical machine parts and technical documentation

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_W10 K_W16

Written grade

K_U01 K_U07 K_U15 K_U18

Project

A passing grade in the lecture part of the course is determined by three written responses to questions about the basic aspects of the subject. A passing grade in the project part comprises a positive assessment of the project prepared according the assigned task. 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 75 hours, including work in the auditorium 62 (38) hours, individual work (7) hours, preparing for classes 3 (8) hours, preparing a project 8 (16) hours, revising for tests 2 (6) hours. Total hours of practical classes: 38 (34) which corresponds to 2 ECTS. Total hours of lessons with a teacher: 62 which corresponds to 2 ECTS

RECOMMENDED READING:



1. Feld M. Technologia budowy maszyn. Wyd. 3. Warszawa, PWN 2000; 2. Tymowski J. Technologia budowy maszyn. Warszawa, WNT, 1989; 3. Feld M. Podstawy projektowania procesów technologicznych typowych części maszyn. Wyd. 2

zm. Warszawa, PWN, 2003.

OPTIONAL READING:

1. Puff T. Technologia budowy maszyn. Wyd. 3 popraw. Warszawa, PWN, 1985;Poradnik inŜyniera. Obróbka skrawaniem. Tom 1 – 3. Warszawa, WNT, 1991;

3. Honczarenko J. Elastyczna automatyzacja wytwarzania. Obrabiarki i systemy obróbkowe. Warszawa, WNT, 2000.REMARKS:

Workloads in parentheses are the numbers for part time studies.

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Kod przedmiotu: 06.1-WM-MiBM-S1-EM-04.1_12

06.1-WM-MiBM-N1-EM-04.1_12






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Lecture 30 2 Exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI


Lecture 18 1 Exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI

5

СOURSE AIMS:

The aim of the course is to introduction students with the selected technologies and operational development of technology in the context of the surface layer to increase the performance of machines and operating technical equipment.

PREREQUISITES: Metrology, Fundamentals of Machine Design and Operation, Construction Record

COURSE CONTENTS:

Substantive content. The concept of surface engineering. Solid surface. The top layer (SL) of machines - the concept WW WW technological development, construction and characterization WW, WW models. System approach to tribological phenomena occurring in friction node. WW in the process of formation of friction. State of the surface layer and the properties of machine elements. Shaping the properties of the surface layer in the process of improving the treatment of treatment (mechanical, chemical, thermal, thermo - chemical, electrochemical, physical, laser, etc.). Development of WW properties in the finishing (grinding, superfinishing

oscillating, honing, lapping, etc.). Shaping properties of the surface layer in the process of burnishing process - burnishing static, dynamic, oscillating and others. State of the surface layer of the treated burnishing - tribological properties, resistance to seizure, contact resistance - Surface fatigue, and more. Optimization of machining parameters: cutting, burnishing. Assess the impact of types of machining, heat treatment, coating effects, operating parameters and roughness on the tribological properties.

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, standards and individual work during the development of laboratory issues.



technologies K_W14 has basic knowledge on developments in the design, manufacturing

and operating of machines K_W16 knows the basic methods, techniques and tools required to solve simple









assessment



K_W03 grade


K_W13 grade


K_W14 grade


K_W16 grade


K_U07 report on the exercise


K_U14 report on the exercise


K_K02 report on the exercise


K_K07 report on the exercise

Lecture - subject to completion of the lecture is to provide a positive evaluation of the three written responses to questions regarding basic issues of the subject. Laboratory - Laboratory provided credit is a positive evaluation of the developed reports. In evaluating the questions of the lecture, the following guidelines:





The student workload of 150 hours, including work in the auditorium 60 (16) hours, working alone 68 (132) hours, including preparation for classes and study reports, 48 (82) hours, to prepare for the exam 20 (50) hours. Total hours of practical classes: 88 (100), which corresponds to 3 ECTS Total hours of lessons with a teacher: 82 (38), which corresponds to 3 ECTS

RECOMMENDED READING: 1. Burakowski T., Wierzchoń T.: InŜynieria powierzchni metali, WNT Warszawa 1995; 2. Laber S.: Analiza współzaleŜności pomiędzy stanem warstwy wierzchniej

a właściwościami uŜytkowymi Ŝel;iwnych elementów maszyn obrabianych nagniataniem. Monografia 32,Wyd. WSInŜ. Zielona Góra 1985;

3. LABER. S. Wybrane problemy eksploatacji maszyn. Wydawnictwo:Bibloiteka Problemóww Eksploatacji. Instytut Technologii Eksploatacji Maszyn, Radom 2011;

4. Laber S.: Preparaty eksploatacyjne o działaniu chemicznym. Wyd. Uniwersytet Zielonogórski 2001.

OPTIONAL READING:

1. Stefko A.: Tribologiczne i technologiczne problemy warstwy wierzchniej części maszyn. Wybrane problemy tribologii. PWN. Warszawa 1990;

2. Marczak R., Burakowski T.: Eksploatacyjna warstwa wierzchnia i jej badania. Zagadnienia eksploatacji maszyn. Z.3 (103) 1995.


PPP HHH YYY SSS III CCC AAA LLL PPP RRR OOO CCC EEE SSS SSS EEE SSS AAA NNN DDD MMM EEE CCC HHH AAA NNN III CCC AAA LLL WWW EEE AAA RRR


06.1-WM-MiBM-N1-EM-04.2_12






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Lecture 30 2 exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI


Lecture 18 1 exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI

5

COURSE AIMS:

The aim of the course is to introduction students with the phenomena occurring in the operation of machinery affecting their durability and reliability.

PREREQUISITES:

Fundamentals of Machine Design and Operation, Construction Record

COURSE CONTENTS:

Substantive content. The concept of the surface layer of the machines. Fundamental processes in the surface layer during the aging (and structural phase transitions, diffusion, adhesion, adsorption, chemisorption, destruction, etc..). Aging tribological machine elements. Mechanisms of abrasive wear, adhesion, diffusion,

oxidation. Effect of tribological properties of the system components and operating conditions on the intensity of tribological processes involved. Aging processes of machining substances (oils, lubricants, cutting fluids). The impact of chemical, physical, bacteriological. Regeneration cutting substance. Effect of oil on the life of the lubricating properties. Influence of time and conditions of machines on the tribological properties. Impact of oil on the life of the friction .

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, standards and individual work during the development issues.



technologies K_W14 has basic knowledge on developments in the design, manufacturing

and operating of machines K_W16 knows the basic methods, techniques and tools required to solve simple







K_W03 student has a basic knowledge of the chemistry needed to understand and describe the phenomena occurring in the manufacture and operation of machines

K_W13 The student has knowledge of engineering materials, their research and technology development

K_W14 The student has a basic knowledge on developments in the design, manufacture, construction and operation of machines

K_W16 know the basic methods, techniques and tools required to solve simple tasks in the field of construction engineering, technology, manufacturing and maintenance of machinery

K_U07 able to use information and communication technologies relevant to the tasks related to the design and operation of production machinery

K_U14 can use the measuring apparatus used in problems of mechanics and mechanical engineering as well as methods for estimating measurement errors

K_K02 understand the non-technical aspects of the mechanical engineer, the validity and effects, including the impact on the environment and consequently the responsibility for decisions

K_K07 understand the social role of the engineer and is involved in the transmission of reliable information and views on technological developments in the field of engineering, construction and operation of machines

Lecture - subject to completion of the lecture is to provide a positive evaluation of the three responses to questions regarding basic issues of the subject. Laboratory-provided credit is to develop laboratory exercises reports

In evaluating the questions of the lecture, the following guidelines:





STUDENT WORKLOAD:

The student workload of 150 hours, including work in the auditorium 60 (36) hours, working alone 68 (132) hours, including preparation for classes and study reports, 48 (82) hours, to prepare for the exam 20 (50) hours. Total hours of practical classes: 88 (100), which corresponds to 3 ECTS Total hours of lessons with a teacher: 82 (38), which corresponds to 3 ECTS

RECOMMENDED READING: 1. Łuczak A., Mazur T.: Fizyczne starzenie elementów maszyn, WNT Warszawa 1981; 2. Burakowski T., Wierzchoń T.: InŜynieria powierzchni metali, WNT Warszawa 1995; 3. Hebda M., Wachal A.: Trybologia, WNT Warszawa 1980; 4. LABER. S. Wybrane problemy eksploatacji maszyn. Wydawnictwo:Bibloiteka Problemóww

Eksploatacji. Instytut Technologii Eksploatacji Maszyn, Radom 2011; 5. Laber S.: Preparaty eksploatacyjne o działaniu chemicznym. Wyd. Uniwersytet Zielonogórski

2001.

OPTIONAL READING: 1. Moliński M i inni: Ochrona przed korozją, WKŁ Warszawa 1986; 2. Gierek A.: ZuŜycie ścierne metalowych elementów roboczych, Politechnika Śląska 1993.




TTT HHH EEE UUU SSS EEE OOO FFF III NNN FFF OOO RRR MMM AAA TTT III OOO NNN TTT EEE CCC HHH NNN OOO LLL OOO GGG YYY III NNN EEE XXX PPP LLL OOO III TTT AAA TTT III OOO NNN

Course code: 1. 06.1-WM-MiBM-S1-EM-05_12

2. 06.1-WM-MiBM-N1-EM-05_12

Type of course: 3. Compulsory

Language of ins truc t ion: 4. Polish,

Direc tor of studies: 5. dr. inŜ. Albert Lewandowski

Name of lec turer : 6. dr inŜ. Albert Lewandowski,


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Number of ECTS



Lecture - - -

Class - - -

Laboratory 45 3 Grade

Seminar - - -

Workshop - - -

Pro jec t - -

VI

-


Lecture 1 1 -

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

VI

-

5

СOURSE AIMS:

The aim of the course is to develop students' knowledge about basic use of computer technology in the operation of machinery. The use of computers in the process of repair and operating policies of machinery and equipment.

PREREQUISITES: Base machine construction, engineering design basis, informatics, exploitation machines.



COURSE CONTENTS: Lecture content. General introduction to Microsoft Access. To familiarize students

Control problems of machine operation. Discussion of the conditions necessary for the implementation of a computerized control system operation of machines: the records of the process of operation of machines, data processing operating system, some models probabilistic data processing. Generate database "repairs of machinery and equipment as well as maintenance of the pits" using the Microsoft Access, based on the model chosen technical department.

TEACHING METHODS: Lectures with audiovisual aids. Working with the book. Group work in laboratory classes.


technical sciences


K_W11 has knowledge of computer-aided design, manufacturing and operating of machinery and mechanical equipment


K_W16 knows the basic methods, techniques and tools required to solve simple tasks in the field of construction engineering, technology, manufacturing and operating of machinery.

K_U01 The student can obtain information from literature, databases and other sources, in English or another foreign language; able to integrate the information, make their interpretation, as well as draw conclusions and formulate and justify opinions.

K_U12 can make a preliminary economic analysis of engineering activities undertaken in the design, manufacturing and operating of machines.

K_U18 can – according to the specifications – design and implement a simple device, object, system or process, typical for the process of design, technology and operation of machines, using appropriate methods, techniques and tools





K_W11 designed project K_W14 designed project

K_W16 designed project K_U01 designed project K_U12 designed project K_U18 designed project K_K02 designed project

Laboratory - provided credit is to get positive ratings from all the laboratory, to be implemented in the class. The evaluation shall assess the degree of self-reliance in solving engineering problems using Access and presentation of project results.



STUDENT WORKLOAD:

Total hours of practical classes: 90 (140) which corresponds to 3 ECTS

Total hours of lessons with a teacher: 60 (42), which corresponds to 2 ECTS

RECOMMENDED

READING: 1. „Access 2000 PL – ćwiczenia praktyczne”/ J. Graf. Gliwice: Helion, 2000 r. 2. „Access 2000 PL: programowanie według Petera Nortona”/ Peter Norton, Wirginia Andersen.

Warszawa: Mikom, 2000 r. 3. „Podstawy eksploatacji maszyn I urządzeń”/ T. śuk. Warszawa: Politechnika Warszawska,

1984 r. 4. „Podstawy teorii eksploatacji i niezawodności”/ J. Lewicki. Szczecin:Politechnika Szczecińska,

1984 r.

OPTIONAL READING: 1. Podstawy eksploatacji maszyn i urządzeń”/ T. śuk. Politechnika Warszawska, 1984 r. 2. „Wstęp do teorii eksploatacji urządzeń”/ J. Konieczny. Warszawa: WNT, 1981r. 3. Ken Bluttman, Wayne Freeze - Access - analiza danych - receptury, Wydawnictwo HELION,2000

r.

REMARKS: List of laboratories for part time students is selected from the list above. Workloads in parentheses are the numbers for part time studies.



CCC OOO NNN SSS TTT RRR UUU CCC TTT III VVV EEE AAA NNN DDD TTT EEE CCC HHH NNN OOO LLL OOO GGG III CCC AAA LLL MMM EEE TTT HHH OOO DDD SSS TTT OOO III NNN CCC RRR EEE AAA SSS EEE EEE FFF FFF III CCC III EEE NNN CCC YYY OOO FFF MMM AAA CCC HHH III NNN EEE SSS


06.1-WM-MiBM-N1-EM-06.1_12

Type of course: optional



Name of lec turer : Prof. dr hab. inŜ. Eugene FELDSHTEIN, dr inŜ. A.Lewandowski, dr inŜ. R.MARUDA


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Number of ECTS



Lecture 30 2 Exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VII


Lecture 18 1 Exam

Class - -

Laboratory 9 0 ,5 Grade

Seminar - -

Workshop - -

Pro jec t - -

VII

4

COURSE AIM: The aim of the course is to acquaint students with capabilities to increase work productivity through constructional, organizational technological actions to be used in their further education and future careers.



ENTRY REQUIREMENTS: Manufacturing Engineering, Computer aided manufacturing, Fundamentals of machining process design, Fundamentals of mechanical engineering technology, Technological devices.

COURSE CONTENTS: Lecture content. The concept of productivity. Factors affecting the performance of the machines. Possibility of reducing working time machine and manual work. Requirements and trends in the development of production machines. The main units of modern production machines providing increased performance. Technological capabilities of CNC machine tools, as well as DNC, ASO, etc. Controlling the technological processes of machine parts. Possibility of processes intensification. High-performance design of cutting tools and fixtures. Modern processing technologies: vibration assisted, heat assisted, high-speed cutting (HSC), etc. The rules modernization of machines and technological equipment to increase the efficiency, accuracy, stability of machining. Mechanization and automation of loading and unloading. Automated measurement of machined surfaces.

Laboratory. The use of electronic reference books of known companies (Sandvik Coromant, Prototype, Güring, Seko, Wintoms et al.) to choose high-performance tools and machining parameters.

TEACHING METHODS: Lectures with audiovisual aids. Working with the book. Group and individual work with computers in laboratory classes. Brainstorming (in some lecture topics).


technical sciences


K_W10, K_W16

The student knows the basic actions guaranted increase of production efficiency of machines and technological processes

K_U01 can obtain information from the literature and other sources in the field of subject studied

K_U07 can use information and communication technologies to produce laboratory results, to interpret this information and justify conclusions

K_U15 can analyze the performance of the machine, can select the machining parameters and tools for high-performance processing.

K_K04 can interact with a group



the field of study


K_W10 K_W16

written ezam, discussions when grade of laboratory parts

K_U01 K_U07 K_U15

grade based on laboratory classes

K_K04 laboratory classes

A passing grade in the lecture part of the course is determined by three written responses to questions about the basic 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 100 hours, including work in the auditorium 47 (31) hours, individual work 8 (46) hours, preparing for classes and study reports 30 (16) hours, revising for tests 15 (15) hours.



Total hours of practical classes: 30 (17) which corresponds to 2 ECTS Total hours of lessons with a teacher: 47 which corresponds to 2 ECTS

RECOMMENDED READING: 1. Feld M. Technologia budowy maszyn. Wyd. 3. Warszawa, PWN 2000; 2. Honczarenko J. Elastyczna automatyzacja wytwarzania. Obrabiarki i systemy obróbkowe.

Warszawa, WNT, 2000; 3. Cichosz P. Narzędzia skrawające. Warszawa, WNT, 2006; 4. Przybylski L. Strategia doboru warunków obróbki współczesnymi narzędziami. Politechnika

Krakowska, Kraków, 2000.

OPTIONAL READING: 1. Grzesik W. Podstawy skrawania materiałów metalowych. Warszawa, WNT, 1998; 2. Grzesik W. Podstawy skrawania materiałów konstrukcyjnych. Warszawa, WNT, 2010; 3. Poradnik inŜyniera. Obróbka skrawaniem. Tom 1 – 3. Warszawa, WNT, 1991; 4. Honczarenko J. Obrabiarki sterowane numerycznie. Warszawa WNT, 2008; 5. Czasopisma naukowe i naukowo-techniczne: Archiwum technologii maszyn i

automatyzacji; Mechanik; Obróbka metalu; Annals of CIRP i in.REMARKS: Workloads in parentheses are the numbers for part time studies.



SSS UUU RRR FFF AAA CCC EEE PPP RRR OOO CCC EEE SSS SSS III NNN GGG


06.1-WM-MiBM-N1-EM-06.2_12




Name of lec turer : Prof. dr hab. inŜ. E.FELDSHTEIN, dr inŜ. A.LEWANDOWSKI, dr inŜ. M.JENEK,

dr inŜ. R.MARUDA


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Number of ECTS credi ts

a l loca ted


Lecture 30 2 Exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VII


Lecture 18 1 Exam

Class - -

Laboratory 9 0 ,5 Grade

Seminar - -

Workshop - -

Pro jec t - -

VII

4

COURSE AIM: The aim of the course is to familiarize students with conventional and modern surface processing to be used in their further education and future careers.

ENTRY REQUIREMENTS: Manufacturing engineering, Materials Science, Fundamentals of mechanical engineering technology, Chemistry



COURSE CONTENTS: Lecture content. The concept of the surface. The surface layer, its structure and properties. Methods of surface layers manufacturing. Shaping the surface when machining. Influence of processing parameters and properties of machine tools on the surface roughness and strengthening. The role of the technological fluids. Surface machining with abrasive tools (grinding, honing, lapping, superfinish et al.). Burnishing technologies. Modern methods of surface processing (electrochemical, electro-mechanical, EDM, electropulse machining, etc.). Ultrasonic treatment. Treatment with concentration streams of energy (electron, plasma, laser treatment). Coating technologies. Thin-film and thick-film coatings. Methods for CVD and PVD surface treatment.

Laboratory. 1. Study of the effect of turning parameters on the state on the surface layer (stereometric and strengthening). 2. Study of the effect of plane and cylindrical grinding parameters on the state of the surface layer (stereometric and strengthening). 3. Study of the effect of the method and parameters of burnishing on the stereometric state of surface and its accuracy. 4. Study of the effect of face milling parameters on stereometric state of surface. 5. Study of the effect of drilling parameters on accuracy of machining holes. 6. Correction laboratory and tests.



technical sciences


K_W10, K_W16

The student knows the characteristics and capabilities of the basic methods of surface processing

K_U01 can obtain information from the literature and other sources in the field of subject studied

K_U07 can use information and communication technologies to produce laboratory results, to interpret this information and justify conclusions

K_U08 Can carry out experiments, interpreted the results and draw conclusions K_U15 can make a critical analysis of surface processing of typical machine parts K_K04 can interact with a group



the field of study


K_W10 K_W16

written exam, discussions when grade of laboratory parts

K_U01 K_U07 K_U15


K_K04 laboratory classes


STUDENT WORKLOAD:

The student workload of 100 hours, including work in the auditorium 47 (31) hours, individual work 8 (46) hours, preparing for classes and study reports 30 (16) hours, revising for tests 15 (15) hours.



Total hours of practical classes: 30 (17) which corresponds to 2 ECTS Total hours of lessons with a teacher: 47 which corresponds to 2 ECTS

RECOMMENDED READING: 1. Kaczmarek J. Podstawy obróbki wiórowej, ściernej i erozyjnej. Warszawa WNT 1970; 2. Burakowski T., Wierzchoń T. InŜynieria powierzchni metali. Warszawa WNT 1995; 3. Laber. S. Wybrane problemy eksploatacji maszyn. Radom Wydawnictwo Instytutu Technologii

Eksploatacji Maszyn 2011; 4. Szulc S., Stefko A. Obróbka powierzchniowa części maszyn. Warszawa, PWN, 2003.

OPTIONAL READING: 1. Oczoś K., Porzycki J. Szlifowanie. Warszawa WNT 1986; 2. Przybylski W. Technologia obróbki nagniataniem. Warszawa WNT 1987; 3. Grzesik W. Podstawy skrawania materiałów konstrukcyjnych. Warszawa, WNT, 2010; 4. Pszczołowski W., Rosienkiewicz P. Obróbka ścierna narzędziami nasypowymi. Warszawa WNT

1995; 5. Feld M., Szpunar A. Szlifowanie materiałów konstrukcyjnych taśmami ściernymi. Warszawa WNT

1977; 6. Laber S. Analiza współzaleŜności pomiędzy stanem warstwy wierzchniej a właściwościami

uŜytkowymi Ŝeliwnych elementów maszyn obrabianych nagniataniem. Monografia 32,Wyd. WSInŜ. Zielona Góra 1985;

7. Czasopisma naukowe i naukowo-techniczne: InŜynieria materiałowa, InŜynieria powierzchni, Tribologia: Teoria i praktyka; Archiwum technologii maszyn i automatyzacji; Annals of CIRP i in.REMARKS:

List of laboratories for part time students is selected from the list above. Workloads in parentheses are the numbers for part time studies.



RRR EEE PPP AAA III RRR TTT EEE CCC HHH NNN OOO LLL OOO GGG III EEE SSS


06.1-WM-MiBM-N1-EM-07_12



Direc tor of studies: Prof. dr hab. inŜ. E.FELDSHTEIN

Name of lec turer : Prof. dr hab. inŜ. E.Feldshtein, dr inŜ. A.Lewandowski, dr inŜ. M.Jenek, dr inŜ. R.Maruda, mgr inŜ. K.Adamczuk


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Number of ECTS credi ts

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Lecture 30 2 Exam

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 15 1

VII

Grade


Lecture 18 1 Exam

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 9 0,5

VII

Grade

4

COURSE AIM: The aim of the course is to familiarize students with the issues of repair of machines realized during their lifetime to be used in their further education and future careers.

ENTRY REQUIREMENTS: Manufacturing Engineering, Materials Science, Computer aided manufacturing, Fundamentals of machining process design, Fundamentals of mechanical engineering technology, Technological devices.



COURSE CONTENTS: Lecture content. General information. Types of repairs and renovations. The order of repair actions. Disassembling of machines. Preparatory operations (washing, drying, wear verification, etc.). Evaluation of the possibility of machine parts regeneration. Regenerative technologies: mechanical, welding, laser, plasma, electrochemical, EDM, et al. Coatings used in the regeneration of the machine parts: galvanic, plasma, padded, vacuum and others. Regeneration technologies of non-metallic machine parts (tires, belts etc.). Repair technologies for some components and units of machines. Control elements after the repair. Assembly of equipment after repair. Tools and equipment for repair. Organization of repair and overhaul processes. Basic issues of quality control in the repair works.

Project. Repair process for selected parts of machines, assembly or disassembling

TEACHING METHODS: Lectures with audiovisual aids. Preparing of presentations within individual tasks. Working with books and standards. Individual work while preparing a project.


technical sciences


K_W10 The student knows the principles of repair actions, lists the order of execution of repair actions, describes the main methods of cleaning, checking, disassembling, etc.

K_W15 has a basic knowledge of the life cycle of machines and equipment K_W16 knows the regeneration method of machine parts, lists the methods of repair

actions organizing K_W18 has a basic knowledge of repairs management and quality control. K_U01 can obtain information from literature and other sources of the area machine repair K_U03 can prepare a project in the field of machine repair in polish language K_U07 can use information and communication technologies to prepare project K_U15 is able to assess the causes of wear and damage of machines, work a procedural

path during repair works K_U18 can plane technological issues of repair and regeneration of the machine


In the field of technical sciences


K_W10 K_W15 K_W16 K_W18

Written exam

K_U01 K_U03 K_U07 K_U15 K_U18

project, control work

A passing grade in the lecture part of the course is determined by a positive assessment of control work and three written responses to exam questions about the basic aspects of the subject. A passing grade in the project part comprises a positive assessment of the project prepared according the assigned task. 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 100 hours, including work in the auditorium 49 (31) hours, individual work 21 (39) hours, preparing for classes 6 (8) hours, preparing a project 15 (15) hours, revising for the exam and tests 15 (15) hours. Total hours of practical classes: 40 (34) which corresponds to 2 ECTS. Total hours of lessons with a teacher: 49 which corresponds to 2 ECTS



RECOMMENDED READING: 1. Adamiec P., Dziubiński J., Filipczyk J. Technologia napraw pojazdów samochodowych. Gliwice

Wydawnictwo Politechniki Śląskiej, 2002; 2. Cypko J., Cypko E. Podstawy technologii i organizacji naprawy pojazdów mechanicznych.

Wyd. 2 popr. i uzup. Warszawa: Wydawnictwa Komunikacji i Łączności, 1989

OPTIONAL READING: 1. Ratajczak A, Tomkowiak P, Wieczorowski K. Technologia remontów maszyn i urządzeń

technologicznych. Warszawa PWN, 1982; 2. Wronkowski J., Paszkowski B., Wojdak J. Remont maszyn: demontaŜ, naprawa elementów,

montaŜ. Warszawa WNT, 1987; 3. Kazarcew W. Remont maszyn. Warszawa PWRiL, 1966; 4. Niewczas A., Ludew R., Rosiński W. Technologia naprawy pojazdów. Radom WSI, 1984.

REMARKS: Workloads in parentheses are the numbers for part time studies.

MMM AAA III NNN TTT EEE NNN AAA NNN CCC EEE OOO FFF MMM AAA CCC HHH III NNN EEE SSS AAA NNN DDD EEE QQQ UUU III PPP MMM EEE NNN TTT III NNN TTT HHH EEE SSS TTT AAA TTT EEE OOO FFF AAA III RRR WWW OOO RRR TTT HHH III NNN EEE SSS SSS


06.1-WM-MiBM-N1-EM-08_12

Type of course: Compulsory


Direc tor of studies: Dr inŜ. Mariusz Jenek

Name of lec turer : Dr inŜ. Mariusz Jenek


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for a course

Number of ECTS



Lecture 30 2 Grade

Class 15 1 Grade

Laboratory - - -

Seminar - - -

Workshop - - -

Pro jec t - -

VII

-


Lecture 19 2 Grade

Class 9 1 Grade

Laboratory - - -

Seminar - - -

Workshop - - -

Pro jec t - -

VII

-

3

СOURSE AIMS:

The aim of the course is to present the basic concepts of terms related to the maintenance of machines and equipment in the state of airworthiness

PREREQUISITES

Fundamentals of machine operation

COURSE CONTENTS: Basic concepts and terms. Definitions of fitness and unfitness, maintainability, TBO, worked hard. Force - load - exposure. Overview of reliability indices for repairable objects. Basic models identify the type of loads. Maintainability and availability of machinery and equipment. Rules for selection of a strategy to maintain machines and equipment in the state of airworthiness.


LEARNING OUTCOMES: K_W10 has detailed knowledge of selected tasks related to the field of mechanical

engineering, maintenance, technical diagnosis, repair technologies and safe operations

K_W15 has a basic knowledge of the life cycle of machinery and mechanical systems K_U01 can obtain information from the literature, standards and other sources K_U03 can prepare a study in Polish and a foreign language about problems

related to basic tasks of mechanics and mechanical engineering K_U10 can – in formulating and solving engineering tasks – see their system and non-

technical aspects K_U15 can critically analyze and evaluate the functioning of the existing solutions

in terms of construction and operation of machinery, in particular equipment, objects, systems, processes and services





assessment

K_W10 K_W15

grade based on written test

K_U01 K_U03 K_U10 K_U15 K_K02

grade based on 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 class part comprises positive evaluation of reports based on each 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 95 hours, including work in the auditorium 50 (35) hours, individual work 30 (40) hours, revising for tests 15 (15) hours. Total hours of practical classes: 15 +10+5 = 30 (9 +8+20 = 37) which corresponds to 2 ECTS Total hours of lessons with a teacher: 50 which corresponds to 3 ECTS


1. J.Godziszewski – Badanie niezawodności maszyn i urządzeń. Skrypt WSI Zielona Góra 1993 2. M.Woropay – Podstawy niezawodnej eksploatacji maszyn. Wydawnictwo Akademii Techniczno Rolniczej.

Bydgoszcz 1996 3. L.Dwiliński – Wybrane zagadnienia jakości i niezawodności wyrobów. Politechnika Warszawska 1997. 4. J.śółtowski – Wybrane zagadnienia z podstaw konstrukcji i niezawodności maszyn. Politechnika Warszawska

2004.

OPTIONAL READING: 1. J.Jaźwinski – Poradnik niezawodności. Część II. Wydawnictwo WEMA 1987 2. J.Kaźmierczak – Eksploatacja systemów technicznych. Politechnika Śląska. Gliwice

REMARKS:



MMM AAA CCC HHH III NNN III NNN GGG PPP RRR OOO CCC EEE SSS SSS EEE SSS AAA NNN DDD DDD EEE VVV III CCC EEE SSS III NNN MMM AAA CCC HHH III NNN EEE MMM AAA NNN UUU FFF AAA CCC TTT UUU RRR III NNN GGG AAA NNN DDD OOO PPP EEE RRR AAA TTT III OOO NNN


06.1-WM-MiBM-N1-EM-09.1_12




Name of lec turer : Prof. dr hab. inŜ. E.FELDSHTEIN, dr inŜ. A.Lewandowski, dr inŜ. R.Maruda


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Number of ECTS



Lecture 30 2 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI


Lecture 18 1 Grade

Class - -

Laboratory 9 0,5 Grade

Seminar - -

Workshop - -

Pro jec t - -

VI

3

COURSE AIM: The aim of the course is to familiarize students with the processes occurring when cutting, cutting tools and devices for the processing of the machine parts to be used in their further education and future careers.

ENTRY REQUIREMENTS: Manufacturing Engineering, Metrology and measuring systems, Fundamentals of machine design, Fundamentals of mechanical engineering technology, Technological devices



COURSE CONTENTS: Lecture content. Cutting parameters for different types of cutting. The process of the chip shaping. Contact phenomena and friction in the cutting zone. Forces and power of cutting. The temperature in the cutting zone. Wear and tool life of cutting tools. Machinability of construction materials. Classification and principles of cutting tools design. The materials used for the work part and shank end. Optimal wedge geometry. Calculation of tools strength. Tolerances of tools. Design of devices for fixing basic cutting tools (pilot pins, stocks, etc.).

Laboratory content. 1. Examining the possibility of LENZKES instrumentation system to use for fixing workpieces when machining. 2. Use SolidWORKS to design fixing systems for the processing of machine parts. 3. Use SolidWORKS to design tooling for cutting tools mounting (pilot pins, stocks, etc.) on the machine tools. 4. Use SolidWORKS to design special equipment to fix machine parts.

TEACHING METHODS: Lectures with audiovisual aids. Working with the books and standards. Group work in laboratory classes.


technical sciences


K_W10 The student knows the basic factors of cutting process, can determine the influence of cutting conditions on the cutting process

K_U01 can obtain information from the literature and other sources in the area of the cutting process, design of cutting tools and devices

K_U07 can use information and communication technologies to prepare results of laboratory exercises, interpret the laboratory results and work conclusions.

K_U08 can realize simple experimental studies and computer simulations, interpret their results

K_U18 can design a simple tool or device. K_K04 can interact with a group



the field of study


K_W10 grade based on written test K_U01 K_U07 K_U08 K_U18


K_K04 the course of the laboratory classes A passing grade in the lecture part of the course is determined by three 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 75 hours, including work in the auditorium 47 (29) hours, individual work 5 (25) hours, preparing for classes and study reports 18 (16) hours, revising for tests 5 (5) hours. Total hours of practical classes: 27 (19) which corresponds to 2 ECTS Total hours of lessons with a teacher: 47 which corresponds to 2 ECTS




1. Grzesik W. Podstawy skrawania materiałów metalowych. Warszawa WNT 1998; 2. Kaczmarek J. Podstawy obróbki wiórowej, ściernej i erozyjnej. Warszawa WNT 1970; 3. Jemielniak K. Obróbka skrawaniem. Warszawa Oficyna wydawnicza Politechniki Warszawskiej,

2004; 4. Cichosz P. Narzędzia skrawające. Warszawa, WNT, 2006; 5. Feld M. Uchwyty obróbkowe. Warszawa, WNT, 2006.

OPTIONAL READING: 1. Dobrzański T. Uchwyty obróbkowe. Poradnik konstruktora. Wyd. 7. Warszawa, WNT 1987; 2. Kunstetter S. Narzędzia skrawające do metali. Warszawa WNT 1986; 3. Porembski J. Przyrządy obróbkowe. Podstawy teoretyczne i zasady projektowania. Warszawa,

WNT 1982; 4. Feldshtein E. i in. Metallorežuscie instrumenty: spravočnik konstruktora. Minsk, Novoe Znanie,

2009; 5. Feldshtein E. i in. Režuscij instrument. Minsk, Novoe Znanie, 2007. 6. Czasopisma naukowe i naukowo-techniczne: Archiwum Technologii Maszyn i

Automatyzacji; Mechanik; Obróbka metalu; Annals of CIRP i in.

REMARKS: Workloads in parentheses are the numbers for part time studies.



SSS EEE LLL EEE CCC TTT EEE DDD AAA SSS PPP EEE CCC TTT SSS OOO FFF MMM AAA CCC HHH III NNN III NNN GGG


06.1-WM-MiBM-N1-EM-09.2_12




Name of lec turer : Prof. dr hab. inŜ. E.FELDSHTEIN, dr inŜ. A.Lewandowski, dr inŜ. R.Maruda


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Number of ECTS



Lecture 30 2 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

VI


Lecture 18 1 Grade

Class - -

Laboratory 9 0,5 Grade

Seminar - - Grade

Workshop - -

Pro jec t - -

VI

Grade

3

COURSE AIM: The aim of the course is to familiarize students with the basic factors of the cutting process, including chip formation parameters, the influence of cutting conditions on the forces and cutting temperature, wear and tool life of cutting tools to be used in their further education and future careers.

ENTRY REQUIREMENTS: Manufacturing engineering, Fundamentals of machine design, Fundamentals of mechanical engineering technology, Technological devices.



COURSE CONTENTS: Lecture content. Kinematic and geometric parameters of the cutting process. Cutting layer parameters for different types of cutting. Types of chips. The process of the chip shaping. Friction and contact phenomena in the cutting zone. Built-up-wedge formation. Forces and dynamic phenomena when cutting. Power of cutting. Heat balance and the temperature in the cutting zone. Wear of cutting tools. Tool life, strength and reliability of cutting tools. Machinability of construction materials. The process of cutting in a non-stationary conditions (the CNC cutting). Optimization of geometry and cutting parameters.

Laboratory content. 1. Effect of cutting parameters on chip shape and parameters of chip formation zone when turning. 2. Effect of cutting parameters on chip shape and parameters of chip formation zone when drilling. 3. Influence of cutting parameters on cutting power when turning. 4. Influence of cutting parameters on cutting power when drilling. 5. Influence of cutting parameters on cutting power when milling. 6. Influence of the workpiece material on the chip shaping. 7. Correction laboratory and tests.

TEACHING METHODS: Lectures with audiovisual aids. Working with the books. Group work in laboratory classes.


technical sciences


K_W10 The student knows the basic factors of citting process, can determine the influence of cutting conditions on the cutting process

K_U01 can obtain information from the literature and other sources in the area of the cutting process

K_U07 can use information and communication technologies to prepare results of laboratory exercises, interpret the laboratory results and work conclusions.

K_U08 can realize simple experimental studies and computer simulations, interpret their results

K_K04 can interact with a group



the field of study


K_W10 grade based on written test K_U01 K_U07 K_U08 K_U18


K_K04 the course of the laboratory classes A passing grade in the lecture part of the course is determined by three 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:





1. Grzesik W. Podstawy skrawania materiałów metalowych. Warszawa WNT 1998; 2. Grzesik W. Podstawy skrawania materiałów konstrukcyjnych. Warszawa WNT, 2010; 3. Jemielniak K. Obróbka skrawaniem. Warszawa Oficyna wydawnicza Politechniki Warszawskiej,

2004; 4. Bartoszewicz J. Obróbka skrawaniem i erozyjna. Cz. 1. Podstawy teoretyczne obróbki

skrawaniem. Gdynia WyŜsza Szkoła Morska 1997; 5. Olszak W. Obróbka skrawaniem. Warszawa WNT 2008.

OPTIONAL READING: 1. Kaczmarek J. Podstawy obróbki wiórowej, ściernej i erozyjnej. Warszawa WNT 1970; 2. Praca zbiorowa. Poradnik inŜyniera. Obróbka skrawaniem. Tom 1. Warszawa WNT 1991; 3. Feldshtein E., Kamiński W., Pijanowski M., Wieczorowski K. W. Podstawy teorii obróbki

skrawaniem: tworzenie wióra w obróbce metali skrawaniem. Poznań Komisja Budowy Maszyn PAN Oddział w Poznaniu, 2000

4. Feldshtein E. i inn. Teoriâ rezaniâ: uĉebnik. Izd. 2 .- Minsk Novoe Znanie, 2006. 5. Czasopisma naukowe i naukowo-techniczne: Archiwum technologii maszyn i

automatyzacji; Mechanik; Obróbka metalu; Annals of CIRP i in.REMARKS: Workloads in parentheses are the numbers for part time studies.



PNEUMATIC AND HYDRAULIC SYSTEMS FOR MACHINES CONTROL


06.1-WM-MiBM-N1-EM-11_12


Language of ins truc t ion: Polish


Name of lec turer : Dr inŜ. Albert Lewandowski


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Number of ECTS



Lecture 15 1 Grade

Class 15 1 Grade

Laboratory - -

Seminar - -

Workshop - -

Project - -

VII


Lecture 9 0,5 Grade

Class 9 0,5 Grade

Laboratory - -

Seminar - -

Workshop - -

Project - -

VII

COURSE AIM: The aim of the course is to familiarize students with the use of pneumatic and hydraulic equipment of machines to be used in their further education and future careers.

ENTRY REQUIREMENTS:



Manufacturing engineering, Metrology and measuring systems, Fundamentals of mechanical engineering technology.

COURSE CONTENTS: Lecture content. Basic characteristics of hydraulic fluids and air. Compressors and hydraulic pumps. Air preparing systems. Pneumatic and hydraulic actuators. Pneumo-hydraulic transducers. The valves controlled the flow of air and oil. Separating valves. Logic functions and their implementation using separating valves. Electro and electro-hydraulic systems. The order of design and calculation of hydraulic and pneumatic control systems.

Studies content. 1. The basic components of pneumatic and hydraulic systems, their designation schematic and connections. 2. Schemes of direct and indirect control for cylinders of single and double action. 3. The implementation of automatic end-to-end motion for single- and double-acting cylinders with mechanical limit switching valves. 4. Implementation of an automatic cycle of single cylinder with one and two keys. 5. Principles of modeling and simulation of pneumatic systems using software Festo. 6. Implementation of basic logic functions OR, AND, NOT using pneumatic components. 7. Construction of combinatorial control systems based on cyclogram of work. 8. Construction of combinatorial control systems based on verbal description of the action. 9. Reading of cyclogram chosen pneumatic system based on the basic scheme. 10. Construction of sequential control systems with the use of tact blocks. 11. Construction of special valves/pneumatic units - return throttle valves, quick exhaust valves, timers, time delay. 12. The use of electromagnetic sensors of actuator position in control systems.

TEACHING METHODS: Lectures with audiovisual aids. Working with the books and standards. Group work in studies classes.


technical sciences


K_W10 The student knows the principles of action of pneumatic and hydraulic systems, know the basic units, determine the overall order of evaluation when designing

K_W11 has knowledge in computer-assisted design of pneumatic and hydraulic systems K_W16 knows the basic design method of pneumatic and hydraulic systems K_U01 can obtain information from the literature and other sources in the area of

pneumatic and hydraulic systems K_U07 can use information and communication technologies to prepare results of studies K_U15 is able to design a basic pneumatic or hydraulic control system, make the

necessary calculations



the field of study


K_W10 K_W11 K_W16

grade based on written test

K_U01 K_U07 K_U15

grade based on studies classes




STUDENT WORKLOAD:


RECOMMENDED READING: 1. Hydraulika i pneumatyka: podstawy, ćwiczenia, laboratorium/ red. Ryszard Dindorf. Kielce:

Wydawnictwo Politechniki Świętokrzyskiej, 2003; 2. Osiecki A. Hydrostatyczny napęd maszyn. Warszawa WNT, 1998; 3. Stryczek S. Napęd hydrostatyczny. Wyd. 4 dodruk. Warszawa WNT, 2003; 4. Szenajch W. Napęd i sterowanie pneumatyczne. Wyd. 3 zm. dodr. Warszawa WNT, 2003; 5. Tomasiak E. Napędy i sterowania hydrauliczne i pneumatyczne. Gliwice Politechnika Śląska, 2001.

OPTIONAL READING: 1. Szydelski Z., Olechowicz J. Elementy napędu i sterowania hydraulicznego i pneumatycznego.

Warszawa PWN, 1986; 2. Garbacik A., Szewczyk K. Napęd i sterowanie hydrauliczne: podstawy projektowania układów.

Kraków Politechnika Krakowska, 1988


Wydział Mechaniczny

Kierunek: Mechanika i Budowa Maszyn

BBB ... SSS CCC ... SSS EEE MMM III NNN AAA RRR


06.1-WM-MiBM-N1-EM-11_12

Type of course: Obligatory


Director of studies: Dr hab. inŜ. S.Laber, prof. UZ

Name of lecturer: Prof. dr hab.inŜ. E.Feldshtein, dr. inŜ. A.Laber, dr inŜ. A.Lewandowski, dr. inŜ. M.Jenek, dr inŜ. R.Maruda


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Number of ECTS



Lecture

Class

Laboratory

Seminar 5 grade

Workshop

Pro jec t

VI


Lecture

Class

Laboratory

Seminar 5 grade

Workshop

Pro jec t

VI

7

COURSE AIM: The aim of the course is to develop a set of materials for thesis and an analysis of the literature.

PREREQUISITES: Knowledge of the areas of general engineering and specialty items. COURSE CONTENTS:

Types and characteristics of engineering. Rules for selecting the topic and define the research problem, design, construction, technology, operational. The main components of engineering. Literature. Bibliographic descriptions. General rules for writing dissertations. Marking drawings, formulas, tables, and symbols used. Units of measurement. Ethics in writing of engineering. Policy analysis of the literature. Preparations theoretical future thesis.



TEACHING METHODS:

Working with the book, the source data, directories, standard on the Internet. Discussions during the meetings with the supervisor.

LEARNING OUTCOMES: K_W10 has detailed knowledge of selected tasks related to the field of mechanical

engineering, maintenance, technical diagnosis, repair technologies and safe operations


K_W15 has a basic knowledge of the life cycle of machinery and mechanical systems


K_W19 knows and understands the basic concepts and principles of the protection of industrial property and copyright, can use the resources of patent information

K_W21 has an elementary knowledge of the protection of intellectual property and patent law

K_U01 The student can obtain information from literature, databases and other sources, in English or another foreign language; able to integrate the information, make their interpretation, as well as draw conclusions and formulate and justify opinions

K_U03 can prepare a study in Polish and a foreign language about problems related to basic tasks of mechanics and mechanical engineering

K_U05 has self-education abilities K_U15 The student can critically analyze and evaluate the functioning of the existing

solutions in terms of construction and operation of machinery, in particular equipment, objects, systems, processes and services

K_U17 can assess the usefulness of routine methods and tools to solve simple tasks of practical engineering in the design, technology and operation of machines and select and apply the right method and tools

K_K01 The student can understand the importance and the need of lifelong education and is able to organize the learning process of others


LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA:

Verification of learning outcomes is in the course of consultation with the supervisor and credit seminar presented studies. The pass is to present the collected materials and made their analysis.

STUDENT WORKLOAD:

The student workload of 210 hours (stand-alone and individual consultations with the promoter).

RECOMMENDED READING: 1. Literatura z obszarów przedmiotów ogólnotechnicznych i specjalistycznych. 2. Dobre obyczaje w nauce. Zbiór zasad i wytycznych (wyd. 3), Wyd. PAN Warszawa, 2001. 3. Fras J., Dziennikarski warsztat językowy, Wyd. UWr. Wrocław, 1999. 4. Kmita J., Szkice z teorii poznania naukowego, PWN Warszawa, 1976. 5. Linsay D., Dobre rady dla piszących teksty naukowe, Oficyna Wydawnicza PWr. Wrocław, 1995.

OPTIONAL READING: 1. Affeltowicz J., Ogólne podstawy pisania technicznych prac dyplomowych : pomocnicze materiały

dydaktyczne, Wyd. Politechnika Gdańska, Gdańsk, 1980. 2. Boć J., Jak pisać pracę magisterską, wyd. 4 popr., Wyd. Kolonia Wrocław, 2003. 3. Budzeń H., Przygotowanie pracy magisterskiej: przewodnik metodyczny, wyd. 2 popr. i uzup.,

Wyd. Politechnika Radomska, Radom, 2000. 4. Burek J., Poradnik dyplomanta, Wyd. Politechnika Rzeszowska, Rzeszów, 2001.



5. Godziszewski J., Ogólne zasady pisania, recenzowania i obrony prac dyplomowych, Politechnika Zielonogórska Zielona Góra, 2001.

6. Knecht Z., Metody uczenia się i zasady pisania prac dyplomowych: poradnik jak się uczyć, jak pisać pracę dyplomową, Wyd. . WyŜsza Szkoła Zarządzania EDUKACJA" Wrocław, 1999.

7. Koch M., Przewodnik do pisania pracy magisterskiej, Wyd. Prywatnej WyŜszej Szkoły Businessu i Administracji Warszawa, 1994.

8. Majchrzak J., Mendel T., Metodyka pisania prac magisterskich i dyplomowych : poradnik pisania prac promocyjnych oraz innych opracowań naukowych wraz z przygotowaniem ich do obrony lub publikacji, wyd. 2 popr., Wyd. Akademia Ekonomiczna w Poznaniu, Poznań, 1996.

9. Opoka E., Uwagi o pisaniu i redagowaniu prac dyplomowych na studiach technicznych, wyd. 2, Wyd. Politechnika Śląska Gliwice, 2001.

10. Pabian A., Gworys W., Pisanie i redagowanie prac dyplomowych: poradnik dla studentów, Wyd. Politechnika Częstochowska, Częstochowa, 1997.

11. Pioterek P., Zieleniecka B., Technika pisania prac dyplomowych, wyd. 2 zm. i uzup, Wyd. WyŜsza Szkoła Bankowa w Poznaniu, Poznań 2000.

12. Rawa T., Metodyka wykonywania inŜynierskich i magisterskich prac dyplomowych, Wyd. Akademia Rolniczo-Techniczna w Olsztynie, Olsztyn, 1999.

13. Urban S., Ładoński W., Jak napisać dobrą pracę magisterską, wyd. 4 uzup., Wyd. Akademia Ekonomiczna we Wrocławiu, Wrocław, 2001.

14. Węglińska M., Jak pisać pracę magisterską?, Oficyna wydawnicza "IMPULS" Kraków, 1997. 15. Wojciechowski T., Doktór G., Jak pisać prace dyplomowe - licencjackie i magisterskie: poradnik,

wyd. 2 uzup., Wyd. WyŜsza Szkoła Zarządzania i Marketingu w Warszawie, Warszawa, 1999. 16. Wojcik K., Piszę pracę magisterską: poradnik dla autorów akademickich prac promocyjnych

licencjackich, magisterskich, doktorskich, wyd. 5 zm., Wyd. Szkoła Główna Handlowa Warszawa, 2000.

17. Zaczyński W.P., Poradnik autora prac seminaryjnych, dyplomowych i magisterskich, Wyd. "śAK" Warszawa, 1995.

18. śółtowski B., Seminarium dyplomowe: zasady pisania prac dyplomowych, Wyd. Akademia Techniczno-Rolnicza w Bydgoszczy, Bydgoszcz, 1997.




DDD III PPP LLL OOO MMM AAA TTT HHH EEE SSS III SSS


06.1-WM-MiBM-N1-EM-13_12

Type of course: Obligatory

Language of instruction: Polski

Director of studies: Dr hab. inŜ. S.Laber, prof. UZ

Name of lecturer: Prof. dr hab.inŜ. E.Feldshtein, dr. inŜ. A.Laber, dr inŜ. A.Lewandowski, dr. inŜ. M.Jenek, dr inŜ. R.Maruda


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Number of ECTS



Lecture

Class

Laboratory

Seminar

Workshop

Pro jec t 5

VII

acceptance of work by the promoter


Lecture

Class

Laboratory

Seminar

Workshop

Pro jec t 5

VII

acceptance of work by the promoter

15

COURSE AIMS: The aim of the course is the final preparation of students to work in the profession.

PREREQUISITES: B.SC. SEMINAR COURSE CONTENTS:

Development of engineering work according to your thesis. The work consists of theoretical (reviewed scientific and technical literature) and individual work (presentation of research methodology, research results, development of product design, production parts, technology, machine operation, etc.). The defense must be developed multimedia presentation.



TEACHING METHODS:

Working with the book, the source data, directories, standard on the Internet. Independent and team work in laboratories and computer labs. Discussions during the meetings with the supervisor.

LEARNING OUTCOMES:

K_W10 has detailed knowledge of selected tasks related to the field of mechanical engineering, maintenance, technical diagnosis, repair technologies and safe operations


K_W15 has a basic knowledge of the life cycle of machinery and mechanical systems


K_W19 knows and understands the basic concepts and principles of the protection of industrial property and copyright, can use the resources of patent information

K_W21 has an elementary knowledge of the protection of intellectual property and patent law

K_U01 The student can obtain information from literature, databases and other sources, in English or another foreign language; able to integrate the information, make their interpretation, as well as draw conclusions and formulate and justify opinions

K_U03 can prepare a study in Polish and a foreign language about problems related to basic tasks of mechanics and mechanical engineering

K_U05 has self-education abilities K_U08 can plan and carry out experiments, including measurements and

computer simulations, to interpret the results and draw conclusions K_U09 can use analytical simulation and experimental methods to formulate and

solve engineering tasks K_U14 can use the measuring equipment used in problems of mechanics and

mechanical engineering as well as methods for estimating measurement errors

K_U15 The student can critically analyze and evaluate the functioning of the existing solutions in terms of construction and operation of machinery, in particular equipment, objects, systems, processes and services

K_U17 can assess the usefulness of routine methods and tools to solve simple tasks of practical engineering in the design, technology and operation of machines and select and apply the right method and tools



VERIFICATION OF THE EFFECTS OF EDUCATION AND CONDITIONS OF ASSESSMENT:

Verification of learning outcomes is in the course of consultation with the supervisor and submitted credit thesis. The pass is to adopt a work by the promoter.

STUDENT WORKLOAD:

Student workload consists of 450 hours of individual consultation with the supervisor and work independently in laboratories, workshops, libraries.



RECOMMENDED READING: 1. Literatura z obszarów przedmiotów ogólnotechnicznych i specjalistycznych. 2. Dobre obyczaje w nauce. Zbiór zasad i wytycznych (wyd. 3), Wyd. PAN Warszawa, 2001. 3. Fras J., Dziennikarski warsztat językowy, Wyd. UWr. Wrocław, 1999. 4. Kmita J., Szkice z teorii poznania naukowego, PWN Warszawa, 1976. 5. Linsay D., Dobre rady dla piszących teksty naukowe, Oficyna Wydawnicza PWr. Wrocław, 1995.

OPTIONAL READING: 1. Affeltowicz J., Ogólne podstawy pisania technicznych prac dyplomowych : pomocnicze materiały

dydaktyczne, Wyd. Politechnika Gdańska, Gdańsk, 1980. 2. Boć J., Jak pisać pracę magisterską, wyd. 4 popr., Wyd. Kolonia Wrocław, 2003. 3. Budzeń H., Przygotowanie pracy magisterskiej: przewodnik metodyczny, wyd. 2 popr. i uzup.,

Wyd. Politechnika Radomska, Radom, 2000. 4. Burek J., Poradnik dyplomanta, Wyd. Politechnika Rzeszowska, Rzeszów, 2001. 5. Godziszewski J., Ogólne zasady pisania, recenzowania i obrony prac dyplomowych, Politechnika

Zielonogórska Zielona Góra, 2001. 6. Knecht Z., Metody uczenia się i zasady pisania prac dyplomowych: poradnik jak się uczyć, jak

pisać pracę dyplomową, Wyd. WyŜsza Szkoła Zarządzania EDUKACJA" Wrocław, 1999. 7. Koch M., Przewodnik do pisania pracy magisterskiej, Wyd. Prywatnej WyŜszej Szkoły Businessu i

Administracji Warszawa, 1994. 8. Majchrzak J., Mendel T., Metodyka pisania prac magisterskich i dyplomowych : poradnik pisania

prac promocyjnych oraz innych opracowań naukowych wraz z przygotowaniem ich do obrony lub publikacji, wyd. 2 popr., Wyd. Akademia Ekonomiczna w Poznaniu, Poznań, 1996.

9. Opoka E., Uwagi o pisaniu i redagowaniu prac dyplomowych na studiach technicznych, wyd. 2, Wyd. Politechnika Śląska Gliwice, 2001.

10. Pabian A., Gworys W., Pisanie i redagowanie prac dyplomowych: poradnik dla studentów, Wyd. Politechnika Częstochowska, Częstochowa, 1997.

11. Pioterek P., Zieleniecka B., Technika pisania prac dyplomowych, wyd. 2 zm. i uzup, Wyd. WyŜsza Szkoła Bankowa w Poznaniu, Poznań 2000.

12. Rawa T., Metodyka wykonywania inŜynierskich i magisterskich prac dyplomowych, Wyd. Akademia Rolniczo-Techniczna w Olsztynie, Olsztyn, 1999.

13. Urban S., Ładoński W., Jak napisać dobrą pracę magisterską, wyd. 4 uzup., Wyd. Akademia Ekonomiczna we Wrocławiu, Wrocław, 2001.

14. Węglińska M., Jak pisać pracę magisterską?, Oficyna wydawnicza "IMPULS" Kraków, 1997. 15. Wojciechowski T., Doktór G., Jak pisać prace dyplomowe - licencjackie i magisterskie: poradnik,

wyd. 2 uzup., Wyd. WyŜsza Szkoła Zarządzania i Marketingu w Warszawie, Warszawa, 1999. 16. Wojcik K., Piszę pracę magisterską: poradnik dla autorów akademickich prac promocyjnych

licencjackich, magisterskich, doktorskich, wyd. 5 zm., Wyd. Szkoła Główna Handlowa Warszawa, 2000.

17. Zaczyński W.P., Poradnik autora prac seminaryjnych, dyplomowych i magisterskich, Wyd. "śAK" Warszawa, 1995.

18. śółtowski B., Seminarium dyplomowe: zasady pisania prac dyplomowych, Wyd. Akademia Techniczno-Rolnicza w Bydgoszczy, Bydgoszcz, 1997.

REMARKS:



TTT RRR AAA III NNN III NNN GGG

Course code: 06. 1-WM-MiBM-S1-EM-15_12

06. 1-WM-MiBM-N1-EM-15_12

Type of course: 1. Compulsory

Language of ins truc t ion: 2. Polish,

Direc tor of studies: 3. Dr inŜ. Władysław Papacz

Name of lec turer : 4. Dr inŜ. Władysław Papacz


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Number of ECTS



Lecture - - -

Class - - -

Laboratory - - -

Seminar - - -

Workshop 160 - Grade

Pro jec t - -

II-VI

-


Lecture

Class - - -

Laboratory

Seminar - - -

Workshop 160 - Grade

Pro jec t

5

СOURSE AIMS:

The aim of the course is to familiarize students with work of industrial institutions, co-operation of individual departments of them organization as well as management human supplies in practical activity of enterprises.

PREREQUISITES:

Lack of preliminary requirements



COURSE CONTENTS: • establishment of theoretical capture knowledge on studies through use of them in professional practice; • acquaintance oneself with process of production and work of technical sections, meeting of methods of organization of work and technical progress; • acquaintance with basic regulations of discipline of work as well as conditions of safeties and hygienes of work; • arousing and strengthening of interests of students work in enterprise as well as introduction with placed of institution requirements workers; • creation of conditions to samooceny of own workings, recognition of one's predyspozycji and disclosing of own lacks; • meeting of observational material and experimental connected with qualifying work; • enlargement of possibility of employment after completion of studies. During practice students should get to know not only run of production, but also concurrent him factors of nature economic, sociological with which onto totality do not meet in time of science in higher school

TEACHING METHODS:

Connected experience from everyday presence and work in institution of work.


technical sciences



K_K03 can interact and work in a group, adopting different roles K_K05 can identify properly and resolve the dilemmas related to their profession K_K06 can demonstrate entrepreneurship and ingenuity in action related to the professional activities




K_K01

K_K03

K_K05 K_K06

Performance and grade of practice

Condition of credit practician is:

Performance of practice. Presentation of reporting from course of practice in form of Daily Practician. Daily practician has to be equipped stamp of institution of work and undersigned through representative of institution. In daily practician student notes down executed actions in time of duration of practice.

STUDENT WORKLOAD:

The student workload of 160 hours (WORK IN COMPANY). Total hours of practical classes: 160 (160) which corresponds to 7 ECTS Total hours of lessons with a teacher: 0 (0) which corresponds to 0 ECTS


OPTIONAL READING:


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