06.1-wm-mibm-s1-ep-04 12 eng - wydziaŁ course code: 06.1-wm-mibm-s1-ep-04_12...

III NNN FFF OOO RRR MMM AAA TTT III CCC SSS

Course code: 06.1-WM-MiBM-S1-EP-04_12

06.1-WM-MiBM-N1-EP-04_12

Type of course obligatory

Language of ins truc t ion: polish

Direc tor of studies: Dr inŜ. Mariusz Jenek

Name of lec turer : Dr inŜ. Mariusz Jenek; Mgr inŜ. K.Adamczuk Dr inŜ. R.Maruda, Dr inŜ. A Lewandowski;,

Form of ins t ruc t ion

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for a course

Number o f ECTS

cred i ts a l loca ted

Ful l - t ime s tud ies

Lecture

Class

Laboratory 30 2 grade

Seminar

Workshop

Pro jec t

I

Part - t ime s tudies

Lecture

Class


Seminar

Workshop

Pro jec t

I

2

СOURSE AIMS:

The aim of the course is to introduction students with the fundamental issues related to the operation of the computer, and basic software.

PREREQUISITES No requirements

COURSE CONTENTS: Basic concepts. Construction a computer and a computer system, computer network basics. Elements of a typical PC configuration. Construction of the program and its execution by the computer. The concept of the algorithm and flowchart of the program. Computer software to enable word processing, spreadsheets, databases, presentation graphics. Rules of the Internet. Construction of Web sites.

TEACHING METHODS: Laboratory of audiovisual aids. Individual work of teaching materials containing exercises for self-execution.

LEARNING OUTCOMES: K_U07 The student can use information and communication technologies relevant to the tasks

related to the design, manufacturing and operating of machinery 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 CRITE RIA: The verification methods for learning outcomes are presented in the table below.

Odniesienie do efektów dla

kierunku studiów

Metoda sprawdzenia efektu kształcenia

K_U07 Prepared alone job

K_K01 Prepared alone job

Laboratory - provided credit is to get good ratings for the independent execution of exercises involving the thematic scope of the subject.

STUDENT WORKLOAD: The student workload of 50 (43) hours, including work in the auditorium 30 (18) hours, working alone 20 (25). Total hours of practical classes: 50 (43). Total hours of lessons with a teacher: 30 (18)

OPTIONAL READING:

1. Praca zbiorowa Podstawy informatyki – materiały dydaktyczne – Politechnika Zielonogórska 1998. Literatura uzupełniająca:

UWAGI:

Faculty of Mechanical Engineering

Subject area of studies: Mechanics and Mechanical Engineering

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

Course code: 06.1-WM-MiBM-S1-EP-10.2_09

06.1-WM-MiBM-N1-EP-10.2_09

Type of course: Optional

Language of ins truc t ion: Polish

Direc tor of studies: dr inŜ. Edward Tertel

Name of lec turer : dr inŜ. E.Tertel

dr inŜ. P. Kuryło

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 15 1 Grade

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 15 1

V

Grade


Lecture 18 2 Grade

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 18 2

V

Grade

2

COURSE AIMS: To familiarize students with the development history of technology and the impact of technology on society and civilizations. Understanding the role of technology creators in shaping the civilizational identity of societies and the necessity of responsible understanding the role of the modern engineer in the technical civilization. Presentation of the different, also non-technical aspects of engineering and a different approach to solving technical problems

PREREQUISITIES:

General history of technology.



COURSE CONTENTS: Lecture content.

Technique - understanding of technique, divisions, relationships technique-technology, the method-methodology. The creators of technology, technical education. Techniques features contemporary and historically. The objectives in the technique. Technology and scientific activities, technical knowledge, the relationship of science and technology. Technical civilization, combining the development of civilization with the development of technology. The impact of modern technology on society: a global network, e-commerce, widespread information. Approach to solving the technical problems: modeling, algorithms. Technical Creativity: the creative thinking, the creative action, the creative engineering. Technology and the environment.

Project content: Individual realization work back on the follow of technical development of the selected product/process changes observed in the context of social and civilization. Analysis of past, present and attempt to predict direction of development product/process in the future.

TEACHING METHODS: Lectures with audiovisual aids. Working with the journals. Individual work in project task. Presentation of works, discussion in groups.

LEARNING OUTCOMES: The

reference to the learning outcomes of the field of

study

Knowledge, skills, competence

K_W14 K_W17

Student can name and describe the historical stages of technology development Is able to define the historical and contemporary features of technology and goals of the technical activity.

K_W17 Is able explain the relationship of civilization with the development of technology. K_U08 Is able analyze the technical evaluation of the selected product/process in

civilizational and cultural aspects. K_U10 K_U15

Assesses the technical activities in a systemic manner, is able to assess the interaction of technology, society and the environment

K_K02 K_K04

Is able verify the usefulness of new technologies accepting appropriate (even non-technical) evaluation criteria.

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_W14 K_W17 K_K02 K_K04

Written test

K_U08 K_U10 K_U15 K_K02 K_K04

Assessment of the project. Assessment of the project is based on a project work and discussion of them

To get a credit the student has to receive all passing grades. The final grade received by the student is the arithmetic mean of the above grades.

STUDENT WORKLOAD: The student workload of 58 (58) hours, including work in the auditorium 30 (36) hours, and individual work 28 (22) hours, preparing a project 20 (16) hours, preparation for the written test 8 (6) hours.

Total hours of practical classes: 35 (34) which corresponds to 1 ECTS. Total hours of lessons with a teacher: 30 (36) which corresponds to 1 ECTS



RECOMMENDED READING:

1. Bańka J.: Filozofia techniki. Człowiek wobec odkrycia naukowego i technicznego.

2. Borkowski Robert: Cywilizacja – technika – ekologia: wybrane problemy rozwoju cywilizacyjnego u progu XXI wieku.

3. Cempel Cz.: Nowoczesne zagadnienia metodologii i filozofii badań.

KUBIŃSKI W.: WPROWADZENIE DO TECHNIKI.OPTIONAL READING:

1. Bańka Józef: Zarys filozofii techniki.

2. Losee J.: Wprowadzenie do filozofii nauki

1. Pogorzelski W.: O filozofii badań systemowych.

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

Department of Mechanics and Machine Design – Faculty of Mechanical Engineering


TTT EEE CCC HHH NNN III CCC AAA LLL MMM EEE CCC HHH AAA NNN III CCC SSS III


06.1-WM-MiBM-N1-EP-12_12

Type of course: compulsory


Direc tor of studies: Dr hab. inŜ. Anna Walicka, prof. UZ

Name of lec turer :

Prof. dr hab. inŜ. Edward Walicki;

Dr hab. inŜ. Anna Walicka, prof. UZ;

Dr inŜ. Dariusz Michalski;

Dr inŜ. Jarosław Falicki


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for a course

Number of ECTS



Lecture 30 2 Exam

Class 15 1 Grade

Laboratory 15 1 Grade

Seminar

Workshop

Project

II


Lecture 18 2 Exam

Class 9 1 Grade


Seminar

Workshop

Project

IV

6



COURSE AIM:

The aim of the course is to familiarize students problem-solving methodology based on the laws of mechanics and the knowledge and ability to solve complex problems of statics and kinematics.

ENTRY REQUIREMENTS: Knowledge of mathematics and physics

COURSE CONTENTS:

LECTURE

The basic notions and the principles of statics. Plane and spatial arrangement of convergent forces. Equilibrium plane and spatial arrangement of convergent forces. The basis of reduction of arrangement forces; moment of a force relative to point and axis, parallel forces, pair of forces and its moment, equilibrium reduction of pairs of forces. The plane arrangements of strengths without friction (reduction of plane arrangement of forces, equilibrium of any plane arrangement of forces equilibrium of an arrangement consisting of rigid bodies). Friction and friction laws. Arbitrary spatial arrangement of forces. Reduction of spatial arrangement of forces. Arrangement of parallel forces in space. Masses centres. Theorem of the Pappus - Guldin. Basic notions of kinematics. The kinematics of point: description of movement of a point, velocity and acceleration, average and instantaneous velocity, average and instantaneous acceleration, straight motion, curvilinear and circular, tangential and normal acceleration. The basic notions of movement of rigid body (methods for determining the velocities of points, progressive and rotational movement). The folded movement (the velocity and the acceleration in folded movement, the Coriolis acceleration on the surface of the Earth). The plane movement (method of determining the velocity and the accelerations in plane movement).

CLASS

Solving classes based on lectures and source materials

LABORATORY

Laboratory topics: • Determination of the static coefficient of friction, • Determination of the characteristics and spring stiffness, • Stroboscopic method of measuring the frequency of periodic motion, • Determination of the mass moment of inertia of a rigid body, • Measurement of the bearing friction torque of the electric motor rotor, • Determination of the kinetic coefficient of friction by means of self-excited vibration , • Determination of the characteristics and stability of springs, • Correction exercises, tests.

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

LEARNING OUTCOMES:

In the field of technical

sciences


K_W02 has knowledge of physics, including the fundamentals of mechanics, including the knowledge needed to understand and use the description of physical phenomena in the manufacturing design and operating of mechanical systems

K_W05 has ordered knowledge with strong theoretical underpinnings in the area of statics of rigid bodies systems, kinematics and dynamics of rigid bodies, as well as knowledge of the vibration area



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_U14 can use the measuring equipment used in problems of mechanics and mechanical engineering as well as methods for estimating measurement errors

K_K03 can interact and work in a group, adopting different roles

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


K_W02;

K_W05

Written exam, written test, the defense laboratory reports.

K_U14 Examination of laboratory reports

K_K01 Discussion in the classroom

K_K03 The division into teams and determine the different roles of team members, assign tasks to individuals, check and evaluate the results of the study, a discussion with the team about teamwork: the position, role, impact.

Lecture

positive evaluation of the test

Class


Laboratory

received positive ratings of reports carried out laboratory

Evaluation of the course is getting positive ratings from all forms: Lecture, Class, Laboratory

The final grade received by the student is the arithmetic mean of the above grades.

STUDENT WORKLOAD:

The student workload is 150 hours, including work in the auditorium 73 (51) hours, individual work 72 (99) hours, preparing for classes and study reports 39 (45) hours, revising for tests 25 (27) hours. Work with the literature 15 (18) Total hours of practical classes: 82 (78) which corresponds to 3 ECTS Total hours of lessons with a teacher: 73 (51) which corresponds to 3 ECTS

RECOMMENDED READING: 1. Misiak J., Mechanika ogólna – Statyka i kinematyka, 1993 WNT wydanie IV

2. Leyko J., Mechanika ogólna. t. I, 1980 PWN wydanie VII,

3. J. Nizioł, Metodyka rozwiązywania zadań z mechaniki, WNT, Warszawa 2002

4. Walicki E., Smak T., Falicki J., Mechanika. Wprowadzenie teoretyczne do laboratorium. 2005, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego,

5. Walicki E., Smak T., Falicki J., Mechanika. Materiały pomocnicze do ćwiczeń laboratoryjnych. 2005, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego

OPTIONAL READING: 1. Leyko J., Zbiór zadań z mechaniki ogólnej. t. I, 1978 PWN wydanie IV

2. Misiak J., Zadania z mechaniki ogólnej. Statyka, 1994 WNT wydanie V

3. Misiak J., Zadania z mechaniki ogólnej. Kinematyka, 1994 WNT wydanie V,



REMARKS:



SSS TTT RRR EEE NNN GGG TTT HHH OOO FFF MMM AAA TTT EEE RRR III AAA LLL SSS III


06.1-WM-MiBM-N1-EP-13_12




Name of lec turer :




Dr inŜ. Jarosław Falicki

Dr inŜ. Paweł Jurczak


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for a course

Number of ECTS



Lecture 30 2 Exam

Class 15 1 Grade


Seminar

Workshop

Project

III


Lecture 18 2 Exam

Class 9 1 Grade


Seminar

Workshop

Project

V

6



COURSE AIM: The aim of the course is to familiarize the students problem-solving methodology and analysis of the strength found in mechanical engineering.

ENTRY REQUIREMENTS: Technical Mechanics I, Mathematics

COURSE CONTENTS: LECTURE

Basic notions of strength of materials. Objectives and tasks of the strength of materials.The types of loads. Types of deformations. Internal forces, de Saint Venant principle. Tension and compression of materials. Hooke's law, Young's modulus, Poisson's ratio. Principle of superposition, allowable stress, the safety factor. Statically determinate and statically indeterminate systems tension or compression of rods systems. Analysis of stress and strain at the point, one-, two- and three-direction stresses and strains states. General components and main components of the stresses. Mohr’s circle. Generalized Hooke's law for two- and three- direction stresses. Shear, strain and shear stress. Hooke's law in shear. Static moments. Moments of inertia of plane areas. Steiner formulae. Principal axes and principal moments of inertia, Mohr's circle for the moments of inertia. Torsion of circular shafts. Analysis of stresses and strains in torsion. Calculation of springs. Internal forces in rods and beams. Bending of straight and curved rods. Bending with shear forces.

CLASS

Solving classes based on lectures and source materials LABORATORY

Laboratory topics: • Brinell hardness measurements, • Rockwell hardness measurements, • Vickers hardness measurements, • Static tensile metals, • Static compression test of metals • Static bending test, • Impact bending test, • Correction exercises, tests.


LEARNING OUTCOMES:


sciences


K_W06 has knowledge of the stress analysis of basic mechanical structures K_W09 has an elementary knowledge of the principles of workpiece design and

mechanical equipment constructions 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_K01 The student can understand the importance and the need of lifelong education and is able to organize the learning process of others







K_W06; K_W09 Written exam, written test, the defense laboratory reports.

K_U01 Discussion during the presentation developed laboratory reports.




Lecture


Class


Laboratory




STUDENT WORKLOAD:


RECOMMENDED READING: 1. Walicka A, Walicki E, Michalski D, Jurczak P, Falicki J., Wytrzymałość materiałów / T. 1:

Podręcznik akademicki. Teoria, wzory i tablice do ćwiczeń laboratoryjnych. - Zielona Góra : Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2008

2. Walicka A, Walicki E, Michalski D, Jurczak P, Falicki J., Wytrzymałość materiałów T. 2: Ćwiczenia laboratoryjne – Materiały pomocnicze.. - Zielona Góra : Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2008.

3. Niezgodziński M. E., Niezgodziński T., Wytrzymałość materiałów, 1979 PWN wyd. XI, 4. Gubrynowiczowa J., Wytrzymałość materiałów, 1968 PWN. 5. Banasiak M., Grossman K., Trombski M., Zbiór zadań z wytrzymałości materiałów, 1998, PWN.

OPTIONAL READING:

1. RŜysko J., Statyka i wytrzymałość materiałów , 1979 PWN,

2. Jakubowicz A., Orłoś Z., Wytrzymałość materiałów, 1984 WNT,

REMARKS:



FFF LLL UUU III DDD MMM EEE CCC HHH AAA NNN III CCC SSS III


06.1-WM-MiBM-N1-EP-14_12




Name of lec turer :




Dr inŜ. Paweł Jurczak.


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Number of ECTS



Lecture 30 2 Exam

Class 15 1 Grade


Seminar

Workshop

Project

IV


Lecture 18 2 Exam

Class 9 1 Grade


Seminar

Workshop

Project

IV

6



COURSE AIM:

The aim of the course is to familiarize students with the methodology of solving technical problems on the basis of the law of fluid mechanics and knowledge and ability to solve simple problems of flow occurring in mechanical engineering. Celem przedmiotu jest zapoznanie studentów z metodyką rozwiązywania problemów technicznych w oparciu o prawa mechaniki płynów oraz znajomość i umiejętność rozwiązywania prostych zagadnień przepływowych występujących w budowie maszyn.

ENTRY REQUIREMENTS:

Knowledge Mathematics I

COURSE CONTENTS:

Introduction. Division of fluids. Fundamental definitions for gases and liquids. Model of a fluid, fluid element definition. Physical properties of fluids. Fluid statics. Fluid pressure on a curved wall. Swimming and stability of floating bodies. Archimedes' principle. Stability of fully immersed body in a liquid. Stability of bodies floating on a free surface. Kinematics of fluids. Definition of fields, types of fields, operators of the field. Elements of tensor calculus. Differential equation of a fluid element thorium. Acceleration of a fluid element. Differential equation of a line current fluid element. Analytical methods for the study of fluid motion: method of Lagrange, Euler's method. Cauchy’s and Helmholtz’s theorem – deformation of the fluid element. Fluid dynamics. The principle of conservation of mass – continuity equation. The principle of conservation of momentum - momentum equation. The principle of conservation of moment of momentum – moment of momentum equation. The principle of conservation of energy – the energy equation. Constitutive equations. Closed system of equations describing the motion of viscous and heat conducting fluid. Navier and Stokes equation. General properties of inviscid fluid motion and non-conductive heat. Two general integrals of the Euler equation. Bernoulli's equation. Flat potential fluid motion. The function of current, velocity potential. Rotational motion of the fluid. Simplified forms of Navier and Stokes equation. Special integrals of Navier and Stokes equations. The theory of similarity of flow phenomena; criteria of similarity. Turbulent flows. The theory of a boundary layer. Fluid flow in closed channels. Bernoulli's equation for real flows. Coefficient of linear losses and coefficient of local losses. Fluid flow in open channels. Elements of the theory of rotating machinery. Elements of fluid dynamics. Elements of a perfect gas dynamics.

CLASS

Solving classes based on lectures and source materials LABORATORY

Laboratory topics: • The test a liquid outflow from the tank. • Measurement of a coefficient of linear losses.. • Calibration of the Poncelet vessel. • Study of the characteristics of a pump. • Course of energy lines and pressure lines along the pipeline. • The free surface of a liquid in a vessel rotating about a vertical axis.. • Determination of the critical Reynolds number, • Correction exercises, tests.




LEARNING OUTCOMES:


sciences


K_W07 has knowledge of the stress analysis of basic mechanical structures K_U01 has an elementary knowledge of the principles of workpiece design and

mechanical equipment constructions K_U14 The student can obtain information from literature, databases and other sources, in


K_K01 can use the measuring equipment used in problems of mechanics and mechanical engineering as well as methods for estimating measurement errors



The reference

to the learning

outcomes of the field

of study


K_W07 Written exam, written test, the defense laboratory reports.





Lecture


Class


Laboratory




STUDENT WORKLOAD:




RECOMMENDED READING: 1. Walicki A., Walicki E., Ratajczak M., Mechanika Płynów. Wprowadzenie teoretyczne do

laboratorium. 2002, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2. Walicki A., Walicki E., Ratajczak M., Mechanika Płynów. Materiały pomocnicze do ćwiczeń

laboratoryjnych. 2003, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 3. Bukowski J., Kijkowski P., Kurs mechaniki płynów, PWN, Warszawa 1980, 4. Gryboś R., Podstawy mechaniki płynów PWN, Warszawa 1989, 5. Prosnak W.J., Mechanika płynów, PWN, Warszawa 1970, 6. Kazimierski Z., Orzechowski Z., Mechanika płynów, Politechnika Łódzka, Łódź 1993. 7. Rumianowski A., Zbiór zadań z mechaniki płynów nieściśliwych z rozwiązaniami, PWN,

Warszawa 1978, 8. Gołębiewski C., Łuczywek E., Walicki E., Zbiór zadań z mechaniki płynów, PWN, Warszawa

1980.

OPTIONAL READING:

REMARKS:



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


06.1-WM-MiBM-N1-EP-15_12

Type of course: optional



Name of lec turer :



Dr inŜ. Dariusz Michalski.


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Form of rece iving a c redi t

for a course

Number o f ECTS



Lecture 15 1 Exam

Class 15 1 Grade

Laboratory

Seminar

Workshop

Projec t

V


Lecture 9 1 Exam

Class 9 1 Grade

Laboratory

Seminar

Workshop

Projec t

VII

3



COURSE AIM:

The aim of the course is to familiarize students with the methodology of solving technical problems on the basis of the law of technical rheology and knowledge and ability to solve simple problems of flow occurring in mechanical engineering.

ENTRY REQUIREMENTS: Fluid mechanics, Mathematics

COURSE CONTENTS: WYKŁAD

Introduction to technical rheology. One-dimensional rheological and mechanical models of the substances. An introduction to tensor calculus. Constitutive equations of non-Newtonian fluids. Equations of motion of non-Newtonian fluids. Simplified systems of equations of motion. Simplified method to solve the equations of motion. Flows in flat channels: Poiseuille flow and Couette flow. Poiseuille flow in a circular channel. Rotational Couette flow between two concentric cylinders. Flows of fluids between non-rotating surfaces of revolution. The theory of non-Newtonian lubrication. Rheological models of lubricants. Reynolds equations. Rheology of the polymers. Rheological models of polymers. Rheological properties of biological fluids. Rheological models of biological fluids. Introduction to rheometry. Capillary viscometers. Viscometers with a moving measuring element. Capillary rheometers: basic equations, final effects and methods for their compensation. Rotational rheometers: advantages and disadvantages, sources of errors, methods of correction. Determining thixotropy and yield stress.

CLASS



LEARNING OUTCOMES:


sciences


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

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






The reference to the learning outcomes of the field

of study


K_W09,

K_W10

Written exam, written test.

K_U01 Discussion in the classroom


Lecture


Class




STUDENT WORKLOAD: The student workload is 75 hours, including work in the auditorium 41 (27) hours, individual work 34 (48) hours, preparing for classes and study reports 15 (20) hours, revising for tests 14 (18) hours. Work with the literature 5 (10)

Total hours of practical classes: 38 (35) which corresponds to 2 ECTS

Total hours of lessons with a teacher: 41 (27) which corresponds to 2 ECTS

RECOMMENDED READING: 1. Ferguson J., Kembłowski Z., Reologia stosowana płynów, Drukarnia Wydawnictw

Naukowych S.A., Łódź 1995.

2. Kisiel I., Reologia, Politechnika Wrocławska, Wrocław 1987,

3. Schramm G., Reologia Podstawy i zastosowania, Ośrodek Wydawnictw Naukowych, Poznań 1998,

4. Walicki E., Reodynamika smarowania łoŜysk ślizgowych, 2005, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego,

5. Wilczyński K., Reologia w przetwórstwie tworzyw sztucznych, Wydawnictwa Naukowo-Techniczne, Warszawa 2001,

OPTIONAL READING:

1. Gryboś R., Podstawy mechaniki płynów. PWN, Warszawa 1989,

2. Prosnak W.J., Mechanika płynów, PWN, Warszawa 1970,

3. Walicka A., Reodynamika przepływu płynów nienewtonowskich w kanałach prostych i zakrzywionych. Redakcja Wydaw. Naukowo-Technicznych UZ, Zielona Góra :2002

REMARKS:



FFF LLL UUU III DDD MMM EEE CCC HHH AAA NNN III CCC SSS III III


06.1-WM-MiBM-N1-EP-16_12




Name of lec turer :





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Number of ECTS



Lecture 15 1 Exam

Class 15 1 Grade

Laboratory

Seminar

Workshop

Project

V


Lecture 9 1 Exam

Class 9 1 Grade

Laboratory

Seminar

Workshop

Project

VII

3



COURSE AIM: The aim of the course is to familiarize students with the methodology of solving technical problems on the basis of the law of fluid mechanics and knowledge and ability to solve complex problems of flow occurring in mechanical engineering.

ENTRY REQUIREMENTS: Fluid Mechanics I, Mathematics

COURSE CONTENTS: Gas dynamics. Dynamics of inviscid and non-conducting heat gas. One-dimensional gas flows.

Bernoulli's equation for compressible flow. Wave phenomena in one-dimensional nonstationary flow. Flat flow of a gas. Inclined shock wave. The flow of the moved away shock wave. Transonic flow. Elements of a viscous gas dynamics and heat conduction. The equations of motion and some analytical solutions. Numerical methods for fluid dynamics: Numerical solutions for the flow of liquids; numerical solutions for the flow of gases.

CLASS


TEACHING METHODS: Lectures with audiovisual aids. Solving classes. Working with the book.

LEARNING OUTCOMES:


sciences



K_W10 has detailed knowledge of selected tasks related to the field of mechanical engineering





of study


K_W09,

K_W10


K_U01 Discussion in the classroom


Lecture


Class




Evaluation of the course is getting positive ratings from all forms: Lecture, Class.


STUDENT WORKLOAD:


RECOMMENDED READING: 1. Bukowski J., Kijkowski P., Kurs mechaniki płynów, PWN, Warszawa 1980, 2. Gryboś R., Podstawy mechaniki płynów PWN, Warszawa 1989, 3. Prosnak W.J., Mechanika płynów, PWN, Warszawa 1970, 4. Kazimierski Z., Orzechowski Z., Mechanika płynów, Politechnika Łódzka, Łódź 1993. 5. Rumianowski A., Zbiór zadań z mechaniki płynów nieściśliwych z rozwiązaniami, PWN,

Warszawa 1978, 6. Gołębiewski C., Łuczywek E., Walicki E., Zbiór zadań z mechaniki płynów, PWN, Warszawa

1980.

OPTIONAL READING:

REMARKS:



TTT EEE CCC HHH AAA NNN III CCC AAA LLL MMM EEE CCC HHH AAA NNN III CCC SSS III III


06.1-WM-MiBM-N1-EP-17_12




Name of lec turer :



Dr inŜ. Jarosław Falicki;



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Number of ECTS



Lecture 15 1 Exam

Class 15 1 Grade

Laboratory

Seminar

Workshop

Project

V


Lecture 9 1 Exam

Class 9 1 Grade

Laboratory

Seminar

Workshop

Project

VII

3



COURSE AIM: The aim of the course is to familiarize students the technical problem-solving methodology based on the principles of dynamics and the knowledge and solving folded problems occurring in mechanical engineering

ENTRY REQUIREMENTS: Technical Mechanics I, Mathematics

COURSE CONTENTS:

LECTURE Basic notions and definitions of dynamics. Dynamics of a point (tasks of dynamics, motion of a

point under the influence of specified forces). Principles of movement for a material point (principles: momentum and moment of momentum, conservation of mechanical energy, a equivalence of a kinetic energy and a work). Dynamics of arrangement of material points (principles: movement of mass centre, momentum and moment of momentum, d’Alembert, equivalence of a kinetic energy and a work, conservation of mechanical energy). The geometry of masses. Work, power, kinetic energy. Dynamics of movement of a rotatory motion of a rigid body (principles of momentum and moment of momentum in rotatory motion, static and dynamic reactions of fixed axis of rotation). The dynamics of a rigid body of plane movement (progressive movement of a rigid body, equations of motion, principle of equivalence of a kinetic energy and a work for rigid body)

CLASS


TEACHING METHODS: Lectures with audiovisual aids. Solving classes. Working with the book.

LEARNING OUTCOMES:


sciences



K_W10 has detailed knowledge of selected tasks related to the field of mechanical engineering






K_W09;

K_W10




Lecture




Class


Evaluation of the course is getting positive ratings from all forms: Lecture, Class


STUDENT WORKLOAD:

The student workload is 75 hours, including work in the auditorium 41 (27) hours, individual work 34 (48) hours, preparing for classes 15 (20) hours, revising for tests 14 (18) hours. Work with the literature 5 (10) Total hours of practical classes: 38 (35) which corresponds to 2 ECTS Total hours of lessons with a teacher: 41 (27) which corresponds to 2 ECTS


1. Leyko J., Mechanika ogólna. t. I, 1980 PWN wydanie VII,

2. Leyko J., Mechanika ogólna. t. II, 1980 PWN wydanie VII,.

3. Misiak J., Mechanika ogólna – Dynamika, 1993 WNT wydanie IV,

4. Walicki E., Smak T., Falicki J., Mechanika. Wprowadzenie teoretyczne do laboratorium. 2005, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego,

5. Walicki E., Smak T., Falicki J., Mechanika. Materiały pomocnicze do ćwiczeń laboratoryjnych. 2005, Oficyna Wydawnicza Uniwersytetu Zielonogórskiego

OPTIONAL READING:

1. Leyko J., Zbiór zadań z mechaniki ogólnej. t. I, 1978 PWN wydanie IV.

2. Leyko J., Zbiór zadań z mechaniki ogólnej. t. II, 1978 PWN wydanie IV.

3. Misiak J., Zadania z mechaniki ogólnej. Dynamika, 1994 WNT wydanie V,

REMARKS:



SSS TTT RRR EEE NNN GGG TTT HHH OOO FFF MMM AAA TTT EEE RRR III AAA LLL SSS III III


06.1-WM-MiBM-N1-EP-18_12




Name of lec turer :






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Number of ECTS



Lecture 30 2 Exam

Class


Seminar

Workshop

Project

IV


Lecture 9 1 Exam

Class


Seminar

Workshop

Project

VII

4



COURSE AIM: The aim of the course is to introduce students to problem-solving methodology and analysis of the strength found in mechanical engineering

ENTRY REQUIREMENTS: Strength of Materials I, Technical Mechanics I, Mathematics.

COURSE CONTENTS:

LECTURE Determination of beam bending deformations. Analytical method for determining of a bending line

of beams. The Clebsch method. The method of secondary loads. Stability of the compressed rods. Elastic buckling of straight bars. Euler's formula. Tetmajer and Johnson- Ostenfeld formulas. Slender rods compression and bending. Beams on elastic fundation. Strongly curved rods bending. Issues a static indeterminable bending. Single and multi-span beams. The equation of three moments. Statically indeterminable frame. Energy methods. Clapeyron system. Elastic energy in the tension, torsion or bending of the rods. Calculation of deformations using the Castigliano theorem. Menabrea’s theorem. Calculation of statically indeterminable beams and frames using the Menabrea’s theorem. Bending of plates. Cylindrical bending of plates. Two mutually perpendicular pure bending of plates. Differential equation of a circularly symmetric plate. Bending of rectangular plates. Spherical, cylindrical and conical tank. The stresses in thick-walled tanks. The Lamé task.

LABORATORY Laboratory topics:

• Measurement of the Young modulus by extensometric method, • Measurement of the Young modulus by method of retaining extensometry • Diagonal bending, • Examination of the compressed rod buckling • Examination of a circular ring strain • Correction exercises, tests.

TEACHING METHODS:

Lectures with audiovisual aids. Solving classes. Working with the book. Group work in laboratory classes

LEARNING OUTCOMES:


sciences


K_W06 has knowledge of the stress analysis of basic mechanical structures K_W09 has an elementary knowledge of the principles of workpiece design and

mechanical equipment constructions K_W10 has detailed knowledge of selected tasks related to the field of mechanical

engineering K_U01 The student can obtain information from literature, databases and other sources, in







The reference to the learning outcomes of the field of

study


K_W06,

K_W09

K_W10





Lecture


Laboratory


Evaluation of the course is getting positive ratings from all forms: Lecture, Laboratory

STUDENT WORKLOAD:


RECOMMENDED READING: 1. Walicka A, Walicki E, Michalski D, Jurczak P, Falicki J., Wytrzymałość materiałów / T. 1:

Podręcznik akademicki. Teoria, wzory i tablice do ćwiczeń laboratoryjnych. - Zielona Góra : Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2008

2. Walicka A, Walicki E, Michalski D, Jurczak P, Falicki J., Wytrzymałość materiałów T. 2: Ćwiczenia laboratoryjne – Materiały pomocnicze. - Zielona Góra : Oficyna Wydawnicza Uniwersytetu Zielonogórskiego, 2008.

3. Niezgodziński M. E., Niezgodziński T., Wytrzymałość materiałów, 1979 PWN wyd. XI, 4. Gubrynowiczowa J., Wytrzymałość materiałów, 1968 PWN. 5. Banasiak M., Grossman K., Trombski M., Zbiór zadań z wytrzymałości materiałów, 1998, PWN.

OPTIONAL READING:

1. RŜysko J., Statyka i wytrzymałość materiałów , 1979 PWN, 2. Jakubowicz A., Orłoś Z., Wytrzymałość materiałów, 1984 WNT,

REMARKS:



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


06.1-WM-MiBM-N1-EP-19_12




Name of lec turer :






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Number of ECTS



Lecture 30 2 Exam

Class


Seminar

Workshop

Project

IV


Lecture 9 1 Exam

Class


Seminar

Workshop

Project

VII

4



COURSE AIM: The aim of the course is to familiarize the students problem-solving methodology and complex analysis of the strength found in mechanical engineering.

ENTRY REQUIREMENTS: Strenght of Materials I, Mechanics I, Mathematics I

COURSE CONTENTS: LECTURE Extended scope of the news of item in addition to the strength of materials. Reminder issues

related to the types of supports flat and spatial systems. Calculation of the reactions of supports from the equilibrium equations (flat and spatial systems). Use the principle of virtual works to calculate the support reactions and internal forces in rigid systems. Graphs of internal forces. The characteristics of geometric cross-sections. Determination of beam deflection. Shear stresses distributions in cross-sections of beams subjected to irregular bending. Torsion of thin-walled beams with open and closed profiles. Application of hypotheses of strength to the sizing of beams and beam systems. loads complex. The use of hypotheses of strength to determine the material effort. Determination of displacement of beams and beam systems applying the principle of works correlation. Tasks statically determinable. Solving of the systems statically indeterminable. Use the continuity equations to solve statically indeterminable beam systems. Considerations for disks and plates. Thin-walled and thick-walled shell. Membrane stresses in thin and axisymmetric shells. Application of variational theorems of elasticity to approximate solving beams, discs and plates. Limit load beam and girder. Calculation of critical loads. Analysis of selected complex structures.

LABORATORY

Laboratory topics:

• Measurement of Young's modulus by extensometric method, • Measurement of Young's modulus by method of retaining extensometry • Diagonal bending, • Examination of the compression of rod buckling • Examination of a circular ring strain • Correction exercises, tests.

TEACHING METHODS:

Lectures with audiovisual aids. Solving classes. Working with the book. Group work in laboratory classes

LEARNING OUTCOMES:


sciences


K_W06 has knowledge of the stress analysis of basic mechanical structures K_W09 has an elementary knowledge of the principles of workpiece design and mechanical

equipment constructions K_W10 has detailed knowledge of selected tasks related to the field of mechanical engineering 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






The reference to the learning outcomes of the field of

study


K_W06,

K_W09

K_W10





Lecture


Laboratory


Evaluation of the course is getting positive ratings from all forms: Lecture, Laboratory


STUDENT WORKLOAD:


RECOMMENDED READING: 1. Niezgodziński M. E., Niezgodziński T., Wytrzymałość materiałów, 1979 PWN wyd. XI, 2. RŜysko J., Statyka i wytrzymałość materiałów , 1979 PWN, 3. Jakubowicz A., Orłoś Z., Wytrzymałość materiałów, 1984 WNT,

OPTIONAL READING:

1. Gubrynowiczowa J., Wytrzymałość materiałów, 1968 PWN. 2. Banasiak M., Grossman K., Trombski M., Zbiór zadań z wytrzymałości materiałów, 1998, PWN.

REMARKS:



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


06.1-WM-MiBM-N1-EP-21_09

Type of course: COMPULSORY

Language of ins truc t ion: POLISH

Director of studies: DR INś. MAREK MALINOWSKI

Name of lec turer :

dr inŜ. Marek Malinowski, dr inŜ. Daniel Dębowski, dr inŜ. Tomasz Belica, dr inŜ. Izabela Gabryelewicz, dr inŜ. Roman Sobczak, dr inŜ. R. Falicki


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Number of ECTS



Lecture 30 2 Exam

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 30 2

I I

Grade


Lecture 24 3 Exam

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 24 3

I I I

Grade

3

COURSE AIMS:



To provide an opportunity to students to learn:,

Fundamentals of mechanical design, Design methodology, Design factor and factor of safety, allowable stresses, fatigue, Contact stresses, Failures resulting from static loading, Fatigue failure resulting from variable loading, Design of bolted, welded connections. Design of shafts and shaft components, Shaft resonance, Bearings, drive systems, Gears, fundamentals of engineering optimization, fundamentals of modeling and simulation, expert systems. CAD systems. Development and machine design projects and reports.

PREREQUISITIES: - Technical drawing, Materials Science I

COURSE CONTENTS:

Lecture contents

Fundamentals of mechanical design, Design methodology, Design factor and factor of safety, allowable stresses, fatigue, Contact stresses, Failures resulting from static loading, Fatigue failure resulting from variable loading, Design of bolted, welded connections. Design of shafts and shaft components, Shaft resonance, Bearings, drive systems, Gears, fundamentals of engineering optimization, fundamentals of modeling and simulation, expert systems. CAD systems. Development and machine design projects and reports.

Project contents

Project no.1 - Frame, Project no. 2 – lifting device with screw mechanism. Analytical engineering calculations, technical documentation.

Laboratory contents

Laboratory – see course: Computer Aided Design AutoCAD I

TEACHING METHODS: Audiovisual aids. Working with books. Individual work of each student in the development of a computational part of a task.

LEARNING OUTCOMES: In the field of

technical sciences



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

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_U16 can identify and formulate the specification of simple tasks of practical engineering in the design, technology and operation of machines





K_W09

K_W14 Exam

K_U15

K_U16

grade based on results of two projects arithmetic mean of all grades



STUDENT WORKLOAD:

The student workload of 60 hours, including work in the auditorium 60(24+24) hours, individual work and read the literature 45 (45) hours, projects preparation 10 (10) hours, analysis and solution of task problem - project 37 (46) hours. Total hours of practical classes: 110 (110) which corresponds to 4 ECTS Total hours of lessons with a teacher: 63 (44) which corresponds to 2 ECTS.

Total hours of practical classes: 66 (72) which corresponds to 3 ECTS Total hours of lessons with a teacher: 61 (40) which corresponds to 2 ECTS.

RECOMMENDED READING: 1. Pr. zbiorowa pod red. M. Dietrycha, Podstawy Konstrukcji Maszyn, T. 1,2,3,

Warszawa WNT, 1995. 2. Osiński Z., Bajon W., Szucki T., Podstawy konstrukcji maszyn, PWN, 1986. 3. Seria PKM: Podstawy konstrukcji maszyn (ponad 20 tomów), PWN.

OPTIONAL READING: 1. Kurmaz L. i inni. Podstawy konstrukcji maszyn. Projektowanie, PWN, Warszawa 1999. 2. Rutkowski A., Części maszyn, WSiP, 2007. 3. M. Malinowski, W. Babirecki, T. Belica, Materiały pomocnicze z podstaw systemu CAD

AutoCAD 2000 GB/PL, Uniwersytet Zielonogórski, Zielona Góra 2002 (preskrypt). 4. Mirosław Babiuch, AutoCAD 2000PL, Ćwiczenia praktyczne, Helion, 2000.

OOO PPP EEE RRR AAA TTT III OOO NNN OOO FFF MMM AAA CCC HHH III NNN EEE SSS


06.1-WM-MiBM-N1-EP-22_12

Type of course: obligatory


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

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


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Lecture 15 1 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

III


Lecture 9 1 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

III

6

СOURSE AIMS:

The aim of the course is to introduction students with the basic elements of the operation of machinery and the phenomena occurring in industrial processes and performance of machines operating processes.

PREREQUISITES: Manufacturing processes, Metrology, Fundamentals of Mechanical Engineering

COURSE CONTENTS: Problems of maintenance of machines and equipment in terms of the system. Outline of the science of machine operation. The operation of machinery and equipment. The use of technical equipment, renewal

of equipment. The lubricants and fuel handling facilities. Friction, wear and lubrication. Damage to machine components. The reliability of technical systems. Selected aspects of technical diagnostics.

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, standards and individual work during the development of laboratory 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_U07 The student can use information and communication technologies relevant to the tasks related to the design, manufacturing and operating of machinery


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

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: Rules for the verification of learning outcomes are presented in the table below.


The method of the learning outcomes

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 written exam

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

K_W13 written exam

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

K_W14 written exam

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 written exam

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

K_U07 Reports of exercise

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

K_U14 Reports of exercise

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 Reports of exercise

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 Reports of exercise

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 developed reports. 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 180 hours, including work in the auditorium 45 (32) stand-alone 90 (148) hours, preparation for classes 40 (98) hours, to prepare for the first completion of the colloquium lecture 50 (50) hours

Total hours of practical classes: 115 (120), which is equivalent to 4 ECTS Total hours of lessons with a teacher: 90 (27), which corresponds to 3 ECTS

RECOMMENDED READING: 1. Laber. S. Wybrane problemy eksploatacji maszyn. Wydawnictwo: Bibloiteka Problemów

Eksploatacji Instytut Technologii Eksploatacji Maszyn, Radom 2011;

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

3. Badania własności eksploatacyjnych i smarnych uszlachetniacza oleju Motor Life. Uniwersytet Zielonogórski 2004.

4. Lawrowski Z.: Tribologia – tarcie, zuŜycie i smarowanie. PWN, Warszawa 1993;

OPTIONAL READING: 1. Burakowski T., Wierzchoń T.: InŜynieria powierzchni metali. WNT, Warszawa 1995; 2. Legutko S.: Podstawy eksploatacji Maszyn. Wyd. Politechniki Poznańskiej, Poznań 1999;

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

Wydział Mechaniczny

Kierunek: Mechanika i Budowa Maszyn

EEE RRR GGG OOO NNN OOO MMM III CCC SSS

Course code:: 06.1-WM-MiBM-S1-EP-24_12

06.1-WM-MiBM-N1-EP-24_12

Type of course: Compulsory


Direc tor of studies: dr inŜ. Izabela Gabryelewicz

Name of lec turer : dr inŜ. Izabela Gabryelewicz


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Number of ECTS



Lecture 15 1 grade

Class

Laboratory

Seminar

Workshop

Project

IV


Lecture 8 1 grade

Class

Laboratory

Seminar

Workshop

Project

VII

1

COURSE AIMS: The course aims to provide students with interdisciplinary knowledge of the man at work, familiar with the stages of the work process, the transmission of messages about physical and mental burden of human work and basic information about the working environment of human material.

PREREQUISITIES: -

COURSE CONTENTS: Lecture content: The basic layout ergonomic. Characteristics and stages of labor. Physical and psychological burden of human work. Anthropometric characteristics of human beings.



The man and the technical object. The information system, control, human sensory. Material factors of the working environment of man.

TEACHING METHODS: Lectures with audiovisual aids.


technical sciences


K_W17 has a basic knowledge necessary to understand the social, economic, legal, environmental and other non-technical considerations of engineering activities

K_U01 The student can obtain information from literature, databases and other sources, in English or another foreign language;

K_U05 has self-education abilities




The reference to the learning outcomes of

the field of study


K_W17

K_U01

K_U05

K_U15

K_K01

grade based on written test

STUDENT WORKLOAD: The student workload of 30 hours, including work in the auditorium 15 (8) hours, individual work 5(10) hours, preparing for test 10 (12) hours.

RECOMMENDED READING: 1. Wykowska M.: Ergonomia. Wyd. AGH Kraków 1994

OPTIONAL READING: 1. Pacholski red.: Ergonomia. Wyd. Politechnika Poznańska


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 CCC AAA TTT III AAA III


06.1-WM-MiBM-N1-EP-24_12


Language of instruction: Polish

Director of studies: dr inŜ. Jerzy Sobich

Name of lecturer: dr inŜ. Jerzy Sobich, dr inŜ. Robert Barski


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Number of ECTS



Lecture

Class


Seminar

Workshop

Pro jec t

IV


Lecture

Class


Seminar

Workshop

Pro jec t

VII

3

COURSE AIMS: The aim of the course is the ability to design parts and components, machinery and equipment using the CATIA system.

PREREQUISITIES: Engineering graphics, fundamentals of engineering design, fundamentals of informatics.

COURSE CONTENTS: User interface. Design files. Main tools for objects create. Attributes of graphic elements. Coordinate systems. The manipulation of objects. The use of layers. Tools for modify of drawing elements. Dimensioning and descriptions. Sections. Parameterising of objects. Precision drawing tools.


TEACHING METHODS: Design exercises at the computer. Working with books and instructions. Individual work while preparing a project.


technical sciences


K_W04 The student has detailed knowledge of computer-aided design of machinery and equipment.

K_U08 Has the ability to design the structural components of machinery and equipment in the CATIA system.




K_W04 K_U08

The evaluation of laboratory exercises and 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 82 (82) hours, including work in the auditorium 30 (18) hours, consultations 2 (2), preparing for classes 20 (23) hours, preparing a projects 30 (39) hours. Total hours of practical classes: 77 (77) which corresponds to 3 ECTS (3 ECTS). Total hours of lessons with a teacher: 32 (20) which corresponds to 1 ECTS (1 ECTS).

RECOMMENDED READING: 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.

OPTIONAL READING: 1. WyleŜoł M., Modelowanie powierzchniowe i hybrydowe w systemie CATIA v.5. Ed. Helion 2003.




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

Course code: 1. 06.1-WM-MiBM-S1-EP-25_12

2. 06.1-WM-MiBM-N1-EP-25_12

Type of course: 3. Optional

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 - - -


Seminar - - -

Workshop - - -

Pro jec t - -

IV

-


Lecture - - -

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

VI

-

3

СOURSE AIMS:

The aim of this course is to present the principles of creating design of machines and devices using 3D software..

PREREQUISITES: Production engineering. Record structure, the base machine design, mechanical technician, basic engineering design, principles of basing elements during construction.



COURSE CONTENTS: Lecture content. Definitions of design concept, terminology and running SolidWorks, SolidWorks window features: toolbars, menus and views, keyboard trees Feature Manager dialog box options. Working in two dimensions. Sketch and sketch tools. Sketch simple and complex, the sketch plane and method of indicating the plane, sketch editing tools. Principles of dimensioning. The rules for creating simple elements: base creation, adding boss (annealing), cut subtraction, modification - fillets and chamfers append, change dimensions, cross-sectional view of the display, the display of multiple views, view and change the display mode, change the view orientation , rotation and mixing parts of the store. Modeling Fundamentals: Creating a basic, team building, creating bonds of the team. Creating a Record of Equipment: open and edit drawing template sheet formats, inserting the model standard views, dimensioning and editing of dimensions, adding the next sheet drawing, printing drawings.

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 under the laboratory, and the execution of the project and write the structure in 3D recording.

STUDENT WORKLOAD:



Total hours of practical classes: 90 (102), which corresponds to 2 ECTS



1. Podstawy SolidWORKS, CNS Solutions 2. SolidWORKS rysunki, CNS Solutions 3. Zaawansowane modelowanie części, CNS Solutions

OPTIONAL READING: 1. Zaawansowane modelowanie złoŜeń, CNS Solutions 2. M. Babiuch – SolidWorks 2006 w praktyce – Wyd. Helion, Gliwice 2007 3. A. Lewandowski - Podstawy projektowania w SolidWorks – materiały pomocnicze do ćwiczeń.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 MMM PPP UUU TTT EEE RRR AAA III DDD EEE DDD DDD EEE SSS III GGG NNN CCC AAA TTT III AAA III III


06.1-WM-MiBM-N1-EP-27_12




Name of lecturer: dr inŜ. Jerzy Sobich, dr inŜ. Robert Barski


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Number of ECTS



Lecture

Class

Laboratory 30 2 zaliczenie na ocenę

Seminar

Workshop

Pro jec t

V


Lecture

Class

Laboratory 18 2 zaliczenie na ocenę

Seminar

Workshop

Pro jec t

VII

4

COURSE AIMS: The aim of the course is the ability to design sub-assemblies of machinery and equipment using the CATIA system.

PREREQUISITIES: Engineering graphics, fundamentals of engineering design, fundamentals of informatics, computer aided design CATIA I.

COURSE CONTENTS: Assemblies designing. Creating and using libraries. Autogenerating modeling.


TEACHING METHODS: Design exercises at the computer. Working with books and instructions. Individual work while preparing a project.


technical sciences


K_W04 The student has detailed knowledge of computer-aided design of sub-assemblies of machinery and equipment.

K_U08 Has the ability to design the sub-assemblies of machinery and equipment in the CATIA system.




K_W04 K_U08

The evaluation of laboratory exercises and 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 102 (102) hours, including work in the auditorium 30 (18) hours, consultations 2 (2), preparing for classes and preparing a projects 70 (82) hours. Total hours of practical classes: 97 (97) which corresponds to 4 ECTS (4 ECTS). Total hours of lessons with a teacher: 32 (20) which corresponds to 1 ECTS (1 ECTS).

RECOMMENDED READING: 1. WyleŜoł M., CATIA. Podstawy modelowania powierzchniowego i hybrydowego. Ed. Helion 2003.

2. Skarka W., Podstawy budowy modeli autogenerujących. Ed. Helion 2009.

OPTIONAL READING: 1. WyleŜoł M., CATIA v.5. Modelowanie i analiza układów kinematycznych. Ed. Helion 2007.




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


2.

Type of course: 3. Optional





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Number of ECTS



Lecture - - -

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

V

-


Lecture - - -

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

VI

-

4

СOURSE AIMS:

The aim of this course is to present the principles of creating design of machines and devices using 3D software.

PREREQUISITES: Production engineering. Record structure, the base machine design, mechanical technician, basic engineering design, principles of basing elements of the design. SolidWorks Fundamentals.



COURSE CONTENTS: Lecture content. The concept of the design of the application allows to create structures with sheet metal. The concept design of welded joints of the SolidWorks application. Create assemblies, animation assemblies, exploded views. Using PhotoWorks software: shading, the choice of material is defined, adding color, texture mapped material selection, adding decals to the surface, composing the background, creating an ambient setting. Basic knowledge of application Cosmosexpress.



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_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 under the laboratory, and the execution of the project and write the structure in 3D recording.

STUDENT WORKLOAD:






1. „Podstawy SolidWORKS, CNS Solutions. 2. SolidWORKS rysunki, CNS Solutions. 3. Zaawansowane modelowanie części, CNS Solutions. 4. Zaawansowane modelowanie złoŜeń, CNS Solutions.

OPTIONAL READING: 1. Zaawansowane modelowanie złoŜeń, CNS Solutions 2. M. Babiuch – SolidWorks 2006 w praktyce – Wyd. Helion, Gliwice 2007 3. A. Lewandowski - Podstawy projektowania w SolidWorks – materiały pomocnicze do ćwiczeń

4. K.Ferenc, J.Ferenc – Konstrukcje spawane – WNT, Warszawa 2008




MMM AAA TTT EEE RRR III AAA LLL SSS SSS CCC III EEE NNN CCC EEE III


06.1-WM-MiBM-N1-EP-29_12



Direc tor of studies: Prof. dr hab. inŜ. Ferdynand Romankiewicz

Name of lec turer :

Prof. dr hab. inŜ. Ferdynand Romankiewicz, dr inŜ. Ryszard Gorockiewicz, dr inŜ. Mariusz Michalski, dr inŜ. Remigiusz Romankiewicz, mgr inŜ. Paweł Schlafka


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al located


Lecture 30 2 Grade

Class

Laboratory

Seminar

Workshop

Project

I


Lecture 18 2 Grade

Class

Laboratory

Seminar

Workshop

Project

I

3

СOURSE AIMS: The aim of the course is to familiarize the student the basic groups of engineering materials and the interactions between the atomic structure and the structural and physico-chemical properties, mechanical and technological materials, including the influence of phase transitions.

PREREQUISITES: There are no prerequisites.



COURSE CONTENTS: Lecture content. Structure of matter and mates. Natural and technical engineering materials - structure, properties and application. Transitions and phase equilibrium systems. Shape the structure and properties of engineering materials with technology methods. The strengthening of metals and alloys. Methods of research materials. Wear mechanisms of engineering materials including operating conditions. Phase transformations during heat treatment.

TEACHING METHODS: Conventional lectures with audiovisual aids. Working with professional literature.


technical sciences


K_W13 The student is able to characterize main groups of technical materials and material technologies. Can describe the corelations between structure and properties of materials forming technology.

K_W16 Is able to characterize the methods of metallographic and phase transformations in metal alloys.





K_W13

K_W16

Warunkiem zaliczenia części wykładowej jest uzyskanie pozytywnej oceny z kolokwium końcowego dotyczącego teoretycznych zagadnień przedmiotu.

Prerequisite for passing is pass, of all its forms.

STUDENT WORKLOAD: The student workload of 75 (75) hours, including work in the auditorium 43 (18) hours, part in the consultation 13 hours, individual work 32 (57) hours, sources familiar with the literature 17 (22) hours, preparation for the test 15 (35) hours.



RECOMMENDED READING: 1. Dobrzański L.A.: Metaloznawstwo z podstawami nauki o materiałach, WNT, Warszawa 2001.

2. Rudnik S.: Metaloznawstwo, PWN, Warszawa 1994.

3. Przybyłowicz K.: Metaloznawstwo, WNT, Warszawa 2001.

4. Blicharski M.: Wstęp do inŜynierii materiałowej, WNT, Warszawa 2001.

5. WoŜnica A: Podstawy nauki o materiałach, Wyd. politechniki Śląskiej, Gliwice 1996.

6. Wojtkun F., Sołncev P.: Materiały specjalnego przeznaczenia, Wyd. Politechniki Radomskiej, Monografia nr 36, Radom 1999.

7. Ashby M.F., Jones D.R.A.: Materiały InŜynierskie I i II, WNT, Warszawa 1996.

OPTIONAL READING:




MMM AAA TTT EEE RRR III AAA LLL SSS SSS CCC III EEE NNN CCC EEE III III


06.1-WM-MiBM-N1-EP-30_12




Name of lec turer :

Prof. dr hab. inŜ. Ferdynand Romankiewicz, dr inŜ. Ryszard Gorockiewicz, dr inŜ. Mariusz Michalski, dr inŜ.. Remigiusz Romankiewicz, mgr inŜ. Paweł Schlafka


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Lecture 30 2 Exam

Class


Seminar

Workshop

Project

II


Lecture 18 2 Exam

Class


Seminar

Workshop

Project

II

4

СOURSE AIMS: The aim of the course is to familiarize the student with basic technical groups ferrous and non-ferrous metals in the aspects of their importance in the construction and operation of machines and the design and selection of engineering materials.

PREREQUISITES: There are no prerequisites.



COURSE CONTENTS: Lecture content. Steels and casting alloys of iron (steel and cast iron). Heat treatment and thermo-chemical treatment. Non-ferrous metals and their alloys. Rules for selection of engineering materials and their role in the construction and operation of machines. Selection of materials of construction. Sources of information on engineering materials, their properties and applications. Elements of computing materials science and computer-aided design and material selection.

Laboratory content (Full-time studies).

1. Metallographic examination of macroscopic

2. Optical microscopy

3. Quantitative metallography

4. The analysis of the binary alloys

5. The cast iron structure and the crude-iron

6. Structure of the carbon steels

7. Influence of annealing temperature and cooling rate on the structure of carbon steel

8. Term correction

9. The structure of heat-treated steel and thermo - chemical

10. Tool Steel Structures

11. Special steel structure

12. Structures of aluminum alloys

13. Structure of copper alloys

14. Selection engineering materials

15. Term correction. CREDIT

Laboratory content (Part-time studies).

1. Metallographic examination of macroscopic

2. Optical microscopy

3. Quantitative metallography

4. Influence of annealing temperature and cooling rate on the structure of carbon steel

5. The structure of heat-treated steel and thermo - chemical

6. Structure of tool steels and special

7. Structure of aluminum and copper alloys

8. Selection engineering materials


TEACHING METHODS: Lectures with audiovisual aids. Working with professional literature. Individual and team execution of laboratory exercises.

LEARNING OUTCOMES: In the field

of technical sciences


K_W13 The student has knowledge of modern methods of shaping the structure and properties of materials and assess the suitability of an extended range of materials in mechanical engineering.

K_W16 He knows the rules for the selection of engineering materials and their role in the construction and operation of machines.

K_U01 Can interpret the data collected material and draw conclusions. K_U09 Student can use the experimental methods in the selection of engineering

materials. K_K03 Able to work in a group and perform a variety of functions in it.





of study


K_W13

K_W16

K_U01

Written exam

The pass of the lecture is to get a positive assessment of the 5 written responses to questions regarding the subject of theoretical issues.

K_U09

K_K03

K_W13

K_W16

K_U01

Grade based on laboratory classes

Assessment of the laboratory is determined on the basis of preparing the student to practice and their implementation, and reports / reports resulting from the execution of all exercises to be implemented.

Prerequisite for passing is pass, of all its forms. Final evaluation of the course is to include the arithmetic mean of the ratings for the various forms of activities.

STUDENT WORKLOAD: The student workload of 100 (100) hours, including work in the auditorium 64 (40) hours, part in the consultation and the egxam 4 (4) hours, individual work 36 (60) hours, preparing for classes and reports 18 (30) hours, preparing for an exam 12 (20) hours, sources familiar with the literature 6 (10) hours.


Total hours of lessons with a teacher: 64(40) which corresponds to 2 ECTS

RECOMMENDED READING: 1. Dobrzański L.A.: Metaloznawstwo z podstawami nauki o materiałach, WNT, Warszawa 2001. 2. Rudnik S.: Metaloznawstwo, PWN, Warszawa 1994. 3. Przybyłowicz K.: Metaloznawstwo, WNT, Warszawa 2001. 4. Blicharski M.: Wstęp do inŜynierii materiałowej, WNT, Warszawa 2001. 5. WoŜnica A: Podstawy nauki o materiałach, Wyd. politechniki Śląskiej, Gliwice 1996. 6. Wojtkun F.,Sołncev P.: Materiały specjalnego przeznaczenia, Wyd. Politechniki

Radomskiej, Monografia nr 36, Radom 1999. 7. Ashby M.F., Jones D.R.A.: Materiały InŜynierskie I i II, WNT, Warszawa 1996.

OPTIONAL READING: -

REMARKS: List of laboratories for part time students is selected from the list above.



UUU NNN CCC OOO NNN VVV EEE NNN TTT III OOO NNN AAA LLL CCC OOO NNN SSS TTT RRR UUU CCC TTT III OOO NNN MMM AAA TTT EEE RRR III AAA LLL SSS


06.1-WM-MiBM-N1-EP-31_12




Name of lec turer :

Prof. dr hab. inŜ. Ferdynand Romankiewicz, dr inŜ. Ryszard Gorockiewicz, dr inŜ. Mariusz Michalski, dr inŜ. Remigiusz Romankiewicz


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Lecture 15 1 Exam

Class


Seminar

Workshop

Project

III


Lecture 9 1 Exam

Class


Seminar

Workshop

Project

III

3

СOURSE AIMS: The aim of the course is to familiarize the student with structure and properties, and the use of modern technical possibilities of engineering materials with unconventional structure, properties and manufacturing technology.

PREREQUISITES: Materials Science.



COURSE CONTENTS: Lecture content. Sintered materials. Intelligent materials. Composite materials. Structural and functional ceramics. Superhard materials. Glass and glass ceramics. Other non-conventional construction materials.

Laboratory content (Full-time studies).

1. Structure of the materials used for bearings

2. Aluminum alloy structure after modification

3. Copper alloy structure after modification

4. Powder metallurgy products

5. Composite materials

6. Structural ceramics

7. Glassy metals


Laboratory content (Part-time studies).

1. Structure of the materials used for bearings

2. The structures of aluminum alloys and copper alloys after modification

3. Powder metallurgy products

4. Structural ceramics


TEACHING METHODS: Lectures with audiovisual aids. Working with professional literature. Individual and team execution of laboratory exercises.

LEARNING OUTCOMES: In the field

of technical sciences


K_W13 The student has knowledge of unconventional materials. He can describe the structure, properties and application of materials.

K_W16 Knows the basic technologies of unconventional materials. K_U15 It can make a critical analysis of the structure and properties of unconventional

materials for their selection. K_U19 Able to select appropriate materials unconventional.



of study


K_W13

K_W16

K_U15

Written exam


K_W13

K_W16

K_U15

K_U19



Prerequisite for passing is pass, of all its forms. Final evaluation of the course is to include the arithmetic mean of the ratings for the various forms of activities.



STUDENT WORKLOAD: The student workload of 75 (75) hours, including work in the auditorium 35 (23) hours, part in the consultation 5 (5) hours, part in the exam 3 (3) hours, individual work 37 (49) hours, preparing for classes and reports 18 (20) hours, preparing for an exam 15 (20) hours, sources familiar with the literature 4 (9) hours.



RECOMMENDED READING: 1. Dobrzański L.A.: Metaloznawstwo z podstawami nauki o materiałach, WNT, Warszawa 2001. 2. Przybyłowicz K.: Metaloznawstwo, WNT, Warszawa 2001. 3. Blicharski M.: Wstęp do inŜynierii materiałowej, WNT, Warszawa 2001. 4. Hetmańczyk M.: Podstawy nauki o materiałach, Wyd. Politechniki Śląskiej, Gliwice 1996 5. WoŜnica A: Podstawy nauki o materiałach, Wyd. politechniki Śląskiej, Gliwice 1996. 6. Romankiewicz F.,Skocovsky P., Gorockiewicz R.: Niekonwencjonalne materiały

konstrukcyjne, Wyd. PZ. Zielona Góra 1996 7. Ciszewski B., Przetakiewicz W.: Nowoczesne materiały w technice, Wyd. Bellona,

warszawa 1994 8. Wojtkun F.,Sołncev P.: Materiały specjalnego przeznaczenia, Wyd. Politechniki

Radomskiej, Monografia nr 36, Radom 1999. 9. Ashby M.F., Jones D.R.A.: Materiały InŜynierskie I i II, WNT, Warszawa 1996.

OPTIONAL READING: 1. Ciszewski B., Przetakiewicz W. : Nowoczesne materiały w technice, Wyd. Bellona, Warszawa

1993. 2. Pampuch R. : Współczesne materiały ceramiczne. Wyd. Nauk. Dyd. AGH, Kraków 2005.




MMM AAA NNN UUU FFF AAA CCC UUU RRR III NNN GGG EEE NNN GGG III NNN EEE EEE RRR III NNN GGG ––– MMM AAA CCC HHH III NNN III NNN GGG


2. 06.1-WM-MiBM-N1-EP-32_12

Type of course: 3. Compulsory

Language of ins truc t ion: 4. Polish, Russian

Direc tor of studies: 5. Prof. dr hab. inŜ. Eugene

Feldshtein

Name of lec turer :

6. Prof. dr hab. inŜ. E.Feldshtein, dr inŜ. A.Laber, dr inŜ. M.Jenek, dr inŜ. A.Lewandowski, dr inŜ. R.Maruda,

7. mgr inŜ. K.Adamczuk


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Number of ECTS



Lecture 30 2 Grade

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

II

-


Lecture 18 1 Grade

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

II

-

4

СOURSE AIMS:

The aim of the course is to familiarize students with structures and operation of conventional machine tools, conventional and unconventional methods of workpiece processing, methods



of machine assembly and general concepts of manufacturing processes design to be used in their further education and future careers.

PREREQUISITES: Manufacturing engineering – chipless machining.

COURSE CONTENTS: Lecture content. Components of the system Machine-Fixture-Workpiece-Tool. Materials for cutting tools. Basic concepts of the cutting process. Coordinate systems. Cutting edge, its surface and angles. Cutting parameters. Cutting process. Turning, drilling, reaming, milling. Machining with tools with rectilinear motion. Cutting teeth and threads. Grinding and free abrasive machining. Modern methods of machining – electrical, plasma, laser technologies, etc. Basic concepts of mechanical engineering and organization of production.

Laboratory content. 1. Turning of external rotating surfaces. 2. Turning of internal rotating surfaces. 3. Turning of complex shape rotating surfaces. 4. Milling of flat and shaped surfaces. 5. Milling of helical grooves. 6. Manufacturing parts on automatic lathes. 7. Processing technologies for holes. 8. Slotting. 9. Cutting gear teeth by hobbing. 10. Cutting gear teeth by shaping 11. Grinding of external rotating surfaces. 12. Grinding of flat surfaces. 13. Cutting tool sharpening. 14. Correction laboratory and tests.



technical sciences


K_W10, K_W16

The student knows the basic units of conventional technological machines; can determine the ability of these machines, characterize types and purposes of tool materials, describe the construction and use of conventional cutting tools and fixtures;

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_U08 can interpret the results of laboratory exercises and draw conclusions. K_U15 can select typical machinery and tools and propose methods for machining of

standard workpieces. K_K04 can interact with a group



the field of study


K_W10 K_W16 K_U15


K_U01 K_U07 K_U08

grade based on laboratory classes



K_K04 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 100 hours, including work in the auditorium 63 (39) hours, individual work 7 (32) hours, preparing for classes and study reports 15 (15) hours, revising for tests 15 (15) hours. Total hours of practical classes: 33 +15 = 48 (18 +33 = 51) which corresponds to 2 ECTS Total hours of lessons with a teacher: 63 which corresponds to 3 ECTS

RECOMMENDED READING: 1. Wybrane zagadnienia z inŜynierii wytwarzania: obróbka ubytkowa/ red. A. Laber.- Zielona

Góra Oficyna Wydaw. Uniwersytetu Zielonogórskiego, 2008;

2. Filipowski R., Marciniak M. Techniki, obróbki-mechanicznej i erozyjnej. Warszawa Oficyna Wydawnicza Politechniki Warszawskiej 2000;

3. Praca zbiorowa. Obróbka skrawaniem, ścierna i erozyjna. Pod red. L. Dąbrowskiego i in. Warszawa Oficyna Wydawnicza Politechniki Warszawskiej 1997.

OPTIONAL READING: 4. Praca zbiorowa. Encyklopedia technik wytwarzania stosowanych w przemyśle maszynowym. Pod red.

J.Erbla. T. II. Obróbka skrawaniem. MontaŜ. Warszawa Oficyna Wydawnicza Politechniki Warszawskiej, 2001;

5. Laboratorium technik wytwarzania. Obróbka skrawaniem i obrabiarki/ red. Z. Wójcik. Warszawa Wydawnictwo Politechniki Warszawskiej 1980.




MMM AAA NNN UUU FFF AAA CCC TTT UUU RRR III NNN GGG EEE NNN GGG III NNN EEE EEE RRR III NNN GGG ––– CCC HHH III PPP LLL EEE SSS SSS MMM AAA CCC HHH III NNN III NNN GGG


06.1-WM-MiBM-N1-EP-33_12



Direc tor of studies: Dr inŜ. Tadeusz Szmigielski

Name of lec turer :

Dr inŜ. Tadeusz Szmigielski

Dr inŜ. Ryszard Gorockiewicz

Dr inŜ. Janusz Walkowiak

Mgr inŜ. Paweł Schlafka


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Form of rece iving a c redi t

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Number of ECTS credi ts

a l located


Lecture 30 2 Exam

Class


Seminar

Workshop

Project

I


Lecture 18 2 Exam

Class


Seminar

Workshop

Project

I

5

СOURSE AIMS: The aim of the course is to acquaint students with the most important methods of performing the various forms of semi-finished products, development of methods of casting machines and metal forming, familiar with the methods of cutting, joining and welding parts, methods of heat and thermo-chemical, plastics processing, measurement techniques, and selected provision of information on used in the production of machinery and equipment.



PREREQUISITES: Fundamentals of chemistry at the high school.

COURSE CONTENTS:

Lecture content: The processes of production of pig iron and steel. Processes for non-ferrous metals. Processes shaping the structure and properties of engineering alloys. Techniques for casting in sand molds, metal molds in special forms. Thermal cutting. Bonded connection technologies-physical basis of welding processes. Electric arc-welding, TIG, MIG / MAG, plasma, electron beam, laser. Electric resistance welding. Plastic working of metals and alloys, heat treatment and thermo - chemical. Processing of plastics. Coating techniques. Elements of surface engineering. Processes in electrical engineering, electronics and optoelectronics. The structure of the production process and equipment design. Technological capabilities of machines. Computer-aided process planning. Assembly and organization of the course.

Laboratory content: Hand-sand molds, sand casting molds and metal castings qualitative assessment, evaluation of liquid alloys by ATD, MIG / MAG welding, electrical resistance welding, brazing solders based on tin plates and determination of cupping in the spring angle bending, injection thermoplastics and identification of plastics used in the construction of machines. The choice of a suitable technique depending on the shaping of the material properties.

TEACHING METHODS: Lectures with audiovisual aids. Working with professional literature.

Team execution of laboratory exercises. Some classes are taught in the form of production exercises.

LEARNING OUTCOMES:


sciences


K_W14 The student has basic knowledge of manufacturing techniques used in the production of semi-finished products, machinery parts, and assess their suitability for the construction and operation of machines.

K_W16 He knows the rules for the selection of the proper technique of shaping machines, depending on the technological properties of materials.

K_U17 It can make a proper selection of suitable manufacturing techniques in conjunction with the properties of the material, terms of use and volume of production.

K_K03 Able to work in a group and perform a variety of functions in it. K_K01 It is open to the use of Microsoft Office tools.


The reference to the

learning outcomes of the field of

study


K_W14 K_W16

Written exam




K_U17 K_K03 K_K01



Prerequisite for passing is pass, of all its forms.

Final evaluation of the course is to include the arithmetic mean of the ratings for the various forms of activities.

STUDENT WORKLOAD: The student workload of 125 (125) hours, including work in the auditorium 65 (48) hours, part in the consultation and the exam 7 (14) hours, individual work 58 (75) hours, preparing for classes and reports 38 (50) hours, sources familiar with the literature 8 (10) hours, preparing for an exam 15 (15) hours.




1. Perzyk M. i inni: Odlewnictwo, WNT, Warszawa 2001

2. Piwowar S.: Techniki wytwarzania. Spawalnictwo, PWN, Warszawa 1978

3. Mizerski J.: Spawanie-Wiadomości podstawowe, Wyd. REA s.j, Warszawa 2005

4. Erbel S., Kuczyński K., Marciniak Z.: Obróbka plastyczna, PWN, Warszawa 1986

5. Ciszewski B., Przetakiewicz W.: Nowoczesne materiały w technice, Wyd. Bellona, Warszawa 1994

6. Dobrzański L., A.: Podstawy nauki o materiałach i metaloznawstwo. WNT, Warszawa 2002

7. Karpiński T.: InŜynieria produkcji, WNT, Warszawa 2004

8. Feld M.: Podstawy projektowania procesów technologicznych typowych części maszyn, WNT, Warszawa 2003

9. Sikora R.: Przetwórstwo tworzyw wielkocząsteczkowych, Wyd. Edukacyjne Zofii Dobkowskiej, Kraków 1993

OPTIONAL READING:

1. Plichta J., Plichta St.: Komputerowo zintegrowane wytwarzanie, Wyd. Politechniki Koszalińskiej, Koszalin 1999

2. Ruszaj A.: Niekonwencjonalne metody wytwarzania elementów maszyn i narzędzi, IOS, Kraków 1999

3. Ashby M., F., Jones D.R.H.: Materiały inŜynierskie. Kształtowanie struktury i właściwości, dobór materiałów, T. 2, WNT, Warszawa 1998

4. Burakowski T., Wierzchoń T.: InŜynieria powierzchni metali, WNT, Warszawa 1995.




III NNN śśś YYY NNN III EEE RRR III AAA WWW YYY TTT WWW AAA RRR ZZZ AAA NNN III AAA --- OOO BBB RRR ÓÓÓ BBB KKK AAA BBB EEE ZZZ UUU BBB YYY TTT KKK OOO WWW AAA

Kod przedmiotu: 06.1-WM-MiBM-S1-EP-33_09

06.1-WM-MiBM-N1-EP-32_09

Typ przedmiotu: obowiązkowy

W ymagania wstępne: Podstawy chemii na poziomie LO

Język nauczania: polski

Odpowiedzia lny za przedmiot : Dr inŜ. Tadeusz Szmigielski

Prowadzący:

Dr inŜ. Tadeusz Szmigielski

Dr inŜ. Ryszard Gorockiewicz

Dr inŜ. Janusz Walkowiak

Mgr inŜ. Paweł Schlafka

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Lic

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Forma za l iczenia

Punkty ECTS

Studia s tac jonarne

W ykład 30 2 Egzamin

Ćwiczenia

Laborator ium 30 2 Zaliczenie na ocenę

Seminar ium

Warsztaty

Pro jek t

I

Studia n iestac jonarne

W ykład 32 4 Egzamin

Ćwiczenia

Laborator ium 24 3 Zaliczenie na ocenę

Seminar ium

Warsztaty

Pro jek t

I

6

10

ZAKRES TEMATYCZNY PRZEDMIOTU:

Procesy wytwarzania surówki i stali. Procesy otrzymywania metali nieŜelaznych. Procesy technologiczne kształtowania struktury i własności inŜynierskich stopów metali. Techniki otrzymywania odlewów w formach piaskowych, formach metalowych, w formach specjalnych. Cięcie termiczne. Techniki połączeń spajanych-podstawy fizyczne procesów spawania. Spawanie elektryczne łukowe -TIG, MIG/MAG, plazmowe, wiązką elektronów,



laserowe. Zgrzewanie elektryczne oporowe. Obróbka plastyczna metali i stopów, obróbka cieplna i cieplno – chemiczna. Przetwórstwo tworzyw sztucznych. Techniki nakładania powłok. Elementy inŜynierii powierzchni. Procesy technologiczne w elektrotechnice, elektronice i optoelektronice. Struktura procesu technologicznego wytwarzania maszyn i jego projektowanie. Technologiczne moŜliwości maszyn. Komputerowe wspomaganie projektowania procesów technologicznych. Przebieg i organizacja montaŜu.

EFEKTY KSZTAŁCENIA :

Umiejętność rozwiązywania podstawowych problemów technologicznych występujących w procesach wytwarzania w zaleŜności od wielkości produkcji. Umiejętność stosowania technologii wytwarzania w celu kształtowania postaci, struktury i właściwości produktów.

WARUNKI ZALICZENIA:

Wykład – warunkiem zaliczenia wykładu jest uzyskanie pozytywnej oceny z egzaminu. Laboratorium – warunkiem zaliczenia jest uzyskanie pozytywnych ocen ze wszystkich ćwiczeń laboratoryjnych, przewidzianych do realizacji w ramach programu laboratorium.

LITERATURA PODSTAWOWA:

10. Perzyk M. i inni: Odlewnictwo, WNT, Warszawa 2001

11. Piwowar S.: Techniki wytwarzania. Spawalnictwo, PWN, Warszawa 1978

12. Mizerski J.: Spawanie-Wiadomości podstawowe, Wyd. REA s.j, Warszawa 2005

13. Erbel S., Kuczyński K., Marciniak Z.: Obróbka plastyczna, PWN, Warszawa 1986

14. Ciszewski B., Przetakiewicz W.: Nowoczesne materiały w technice, Wyd. Bellona, Warszawa 1994

15. Dobrzański L., A.: Podstawy nauki o materiałach i metaloznawstwo. WNT, Warszawa 2002

16. Karpiński T.: InŜynieria produkcji, WNT, Warszawa 2004

17. Feld M.: Podstawy projektowania procesów technologicznych typowych części maszyn, WNT, Warszawa 2003

18. Sikora R.: Przetwórstwo tworzyw wielkocząsteczkowych, Wyd. Edukacyjne Zofii Dobkowskiej, Kraków 1993

LITERATURA UZUPEŁNIAJ ĄCA: 5. Plichta J., Plichta St.: Komputerowo zintegrowane wytwarzanie, Wyd. Politechniki

Koszalińskiej, Koszalin 1999

6. Ruszaj A.: Niekonwencjonalne metody wytwarzania elementów maszyn i narzędzi, IOS, Kraków 1999

7. Ashby M., F., Jones D.R.H.: Materiały inŜynierskie. Kształtowanie struktury i właściwości, dobór materiałów, T. 2, WNT, Warszawa 1998

8. Burakowski T., Wierzchoń T.: InŜynieria powierzchni metali, WNT, Warszawa 1995

UWAGI: brak

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

Course code:

06.1-WM-MiBM-S1-EP-34_12 Alpha CAM

06.1-WM-MiBM-N1-EP-33_12

06.1-WM-MiBM-S1-EP-35_12 Sprut CAM

06.1-WM-MiBM-N1-EP-34_12

06.1-WM-MiBM-S1-EP-36_12 Catia

06.1-WM-MiBM-N1-EP-35_12


Language of ins truc t ion: Polish, Russian

Direc tor of studies: Dr inŜ. Mariusz Jenek

Name of lec turer : Dr inŜ. Mariusz Jenek, Dr inŜ. Albert Lewandowski


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Number of ECTS



Lecture - - -

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

V

-


Lecture - - -

Class - - -

Laboratory 27 3 Grade -

Seminar - - -

Workshop - - -

Pro jec t - -

V

-

4

СOURSE AIMS: The purpose of this course is to present the principles of software development for numerically controlled machines.

PREREQUISITES

Manufacturing engineering - machining

COURSE CONTENTS: The rules for creating software for numerically controlled machines. Machining methods, and numerical control machine tools. Correction tools, machine reference points. Introduction to the program. The development of processes using a computer program selected.


LEARNING OUTCOMES: K_W11 has knowledge of computer-aided design, manufacturing and operating of machinery and

mechanical equipment 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_U01 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






assessment

K_W11 K_W14 K_W16 K_U01 K_U12 K_U18 K_K02

prepared project

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.

STUDENT WORKLOAD:

The student workload of 100 hours, including work in the auditorium 55 (37) hours, individual work 45 (60) hours. Total hours of practical classes: 45 +10+10+20 = 85 (27 +10+20+30 = 87) which corresponds to 4 ECTS Total hours of lessons with a teacher: 55 which corresponds to 4 ECTS


[1] AlphaCAM – podręcznik uŜytkownika [2] AlphaCAM – materiały dydaktyczne do ćwiczeń

OPTIONAL READING: [3] M.Feld – Podstawy projektowania procesów technologicznych typowych części maszyn. WNT. Warszawa 2000.

REMARKS:



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06.1-WM-MiBM-N1-EP-37_12




Name of lec turer :




Dr inŜ. Paweł Jurczak.


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Number of ECTS



Lecture 30 2 Exam

Class 15 1 Grade


Seminar

Workshop

Project

IV


Lecture 18 2 Exam

Class 9 1 Grade


Seminar

Workshop

Project

V

4



COURSE AIM: The aim of the course is to familiarize students with the methodology of solving technical problems on the basis of the law of thermodynamics and knowledge and ability to solve problems of heating problems occurring in mechanical engineering.

ENTRY REQUIREMENTS: Knowledge of mathematics and physics at level of education in high school

COURSE CONTENTS: Basic notions of thermodynamics. Principle of mass conservation, principle of substance quantity conservation. The first law of thermodynamics. Equation of state for ideal and semi-ideal gases. Characteristic changes of ideal and semi-ideal gases. The second law of thermodynamics. Steams and their transformation. Moist gases. Real gases. Gas mixtures. Combustion. Heat transfer. General information about engines and thermal devices. Reciprocating compressors and centrifugal. Reciprocating internal combustion engines. Thermodynamic cycles. Steam engines. Steam and gas turbines. Jet engines. Refrigerators and heat pumps. Non-conventional sources of energy, energy conversion. Devices for processing direct heat into electricity. The phase transformations. Basics chemical thermodynamics modeling of nonequilibrium and non-stationary processes. Elements of the theory of heat transfer.

CLASS


LABORATORY

Laboratory topics:

• Thermometers, scales thermometric. Temperature measurement - scaling thermocouple. • Measurements of pressure. • Measurements of viscosity of selected substances. Study of the effect of temperature on the

rheological properties of the liquid. • Measurement of humidity. • Determination of the heat of combustion of solid fuels. Determination of calorific value of liquid

fuels. • Examination of the composition of the gas - definition of excess air ratio. • Study the efficiency of reciprocating compressor - indicator diagram, • Correction exercises, tests.

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

LEARNING OUTCOMES:


sciences


K_W02 has knowledge of thermodynamics, including the knowledge needed to understand and use the description of physical phenomena in the manufacturing design and operating of mechanical systems

K_W07 has an elementary knowledge of technical thermodynamics necessary to understand the construction and operating of mechanical equipment










K_W02, K_W07 Written exam, written test, the defense laboratory reports.




Lecture


Class


Laboratory




STUDENT WORKLOAD:


RECOMMENDED READING: 1. Gumiński K.: Termodynamika, PWN, Warszawa, 1986,

2. Ochęduszko S., Szargut J., Górniak H., Guzik A., Wilk S.: Zbiór zadań z termodynamiki technicznej, PWN, Warszawa 1975

3. Staniszewski B.: Termodynamika, PWN, Warszawa 1986.

4. Szargut J. : Termodynamika, PWN, Warszawa 2000.

5. Tuliszka E. : Termodynamika techniczna, PWN, Warszawa 1978.

OPTIONAL READING: 1. Fodemski T. i inni : Pomiary cielne, cz. I, Podstawowe pomiary cieplne, WNT,

Warszawa 2001.

2. Wiśniewski S.: Termodynamika techniczna, WNT, Warszawa 2004.

3. Mały poradnik mechanika. Tomy 1-2, WNT, Warszawa 2005.

4. Madejski J.: Termodynamika techniczna, Wyd. Politechniki Rzeszowskiej, Rzeszów 2000.

5. Ochęduszko T.: Termodynamika stosowana, WNT, Warszawa 1993.

REMARKS:


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

Course code: 06.1-WM-MiBM-S1-EP-38_12 06.1-WM-MiBM-N1-EP-38_12

Type of course: Obligatory



Name of lecturer: dr inŜ. Jerzy Sobich, dr inŜ. Mirosław śygadło


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Lecture 30 2 Exam

Class


Seminar

Workshop

Pro jec t

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Lecture 32 4 Exam

Class


Seminar

Workshop

Pro jec t

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5

COURSE AIMS: The aim of the course is to familiarize students with the principles of electrotechnics and electronics.

PREREQUISITIES: Basic on physics.

COURSE CONTENTS:

Lecture content. Electrostatic field. DC circuits: current and voltage sources, resistive components, Ohm's law, Kirchoff’s laws, the method of solving DC circuits, energy, power, Joule's law. Magnetism and electromagnetism: magnetic field, magnetic circuits, electromagnetic induction. AC circuits: R, L and C


elements, energy and power. Three-phase current. DC and AC motors and dynamos, transformers. Electrically measuring instruments. Basics of electronics: diodes, transistors, logic circuits, computers.

Laboratory. Analysis of DC and AC circuits, measurement of electrical parameters (resistance, voltage, current, active and reactive power, phase offset, resonance frequency), the analysis of the measurement error, characteristics of the diode and the transistor.

TEACHING METHODS: Lectures with audiovisual aids. Accounting and laboratory exercises.


technical sciences


K_W04 The student has basic knowledge of electrical engineering and electronics.

K_U08 Has the ability to measuring and estimating the error of basic electrical parameters and to analysing the simple DC and AC circuits.

K_U12 Can evaluate the usefulness and the possibility of the use of new developments in the field of electrical engineering and electronics in machinery and equipment (drive systems, measuring systems and registration).

K_U18 The student can integrate knowledge from the fields of electrical engineering, electronics and mechanics.




K_W04 Written exam

K_U15 K_U17 K_U18

The evaluation of reports on the laboratory exercises.

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 laboratory part comprises a positive assessment of the laboratory exercises. To get a credit the student has to receive both passing grades.

STUDENT WORKLOAD: The student workload of 150 hours, including work in the auditorium 60 (56) hours, preparing for classes and preparing a reports 60 (64) hours, revising for the exam and tests 30 (30) hours.

RECOMMENDED READING: 1. Paca zbiorowa: Elektrotechnika i elekktryków, Ed. WNT, Warszawa 1995.

2. Rusek A., Podstawy elektroniki – cz. 2, Ed. WNT, Warszawa, 1979.

3. Latek W. Zarys maszyn elektrycznych. Ed. WNT, Warszawa,1987.

OPTIONAL READING: 1. Filipowski A., Układy elektroniczne analogowe i cyfrowe, Ed. WNT, Warszawa, 1995.Przeździecki

F: Elektrotechnika i elektronika, Ed. PWN, Warszawa 1974.REMARKS: Workloads in parentheses are the numbers for part time studies.

Faculty of mechanical engineering


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06.1-WM-MiBM-N1-EP-39_12



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

Name of lec turer :

Prof. dr hab. inŜ. Eugene FELDSHTEIN,

dr inŜ. M. Jenek, dr inŜ. A.Lewandowski,

mgr inŜ. K.Adamczuk


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Lecture 30 2 Exam

Class - - -


Seminar - - -

Workshop - - -

Project

III

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Lecture 18 1 Exam

Class - - -


Seminar - - -

Workshop - - -

Project

III

-

5

COURSE AIM:

Provide basic knowledge in the field of metrology, the theory of measurement errors and measurement uncertainty calculation, design, operation and characteristics of measuring instruments and methods of



measurement of basic geometry parameters to be used in the further process of education and in their future careers.

ENTRY REQUIREMENTS: Technical drawing, Manufacturing Engineering

COURSE CONTENTS: The lecture content. Metrology procedures. Units of measurement. Probability distributions. Basics of measurement theory. Measurement errors. Uncertainty of the measurements. Types and basic characteristics of instruments and measurement systems. Transmitters. Signal processing and registration. Sensors to measure magnitudes of kinematic and dynamic factors, magnitudes of force, temperature, noise, humidity, dust and more. Methods and measurement tools to assess the accuracy of linear and angular dimensions. Measurements of geometric deviation. Geometric parameters of the surface texture, methods of its assessment. Measurements of threads and gears. The use of coordinate measuring machines. Laboratory content 1. Length measurement by slide gages and micrometer screw gage, 2. Measurement of internal and external angles. 3. Measurements of cones. 4. Measuring by sensor instruments. 5. Measure the diameters and spacing of hole axis. 6. Interference measurements. 7. Threads measurement. 8. Control of universal measurement tools. 9. Measurements of cylindrical gears with involutes’ straight teeth. 10. Measurement of the cams. 11. Straightness measurement methods based on the measurement of the angles. 12. Measurement of roughness parameters. 13. Universal Microscope Design. 14. Constructions of computerized measuring instruments.

TEACHING METHODS: Lectures with audiovisual aids. Brainstorming (in some lecture topics). Working with books and standards. Group work in laboratory classes.


technical sciences


K_W12 Student has a basic knowledge in the field of metrology, knows and understands the basic measurement methods for characterizing the sizes of mechanical engineering, knows calculation methods and computational tools needed to analyze the measurement results

K_U01 can obtain information from the literature, standards and other sources K_U07 can use information and communication technologies to prepare laboratory results. K_U08 can interpret the results of laboratory and draw conclusions. K_U15 can assess the usefulness of measuring tools, select typical measuring tools and

propose methods of measurement of typical machine parts. K_K04 can interact in a group




K_W12 K_U01

Exam based on written test, discussions while the credit reports of the laboratory

K_U07 K_U08




K_U15 K_K04 The course of the laboratory

A passing exam 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 passing exam and grade. The final grade received by the student is the arithmetic mean of the above grades.

STUDENT WORKLOAD: The student workload of 125 hours, including work in the auditorium 65 (35) hours, individual work 30 (60) hours, preparing for classes and study reports 15 (15) hours, revising for tests 15 (15) hours. Total hours of practical classes: 33 +30 = 65 (21+30=41) which corresponds to 3(2) ECTS. Total hours of lessons with a teacher: 65 which corresponds to 3 ECTS

RECOMMENDED READING: 1. Jakubec W., Malinowski J. Metrologia wielkości geometrycznych. Wyd. IV. Warszawa, WNT,

2004; 2. Jenek M. Metrologia długości i kąta Zielona Góra : Oficyna Wydaw. Uniwersytetu

Zielonogórskiego, 2012. 3. Barzykowski J. [et al.]. Współczesna metrologia: zagadnienia wybrane. Warszawa WNT, 2004; 4. Miłek M. Metrologia elektryczna wielkości nieelektrycznych. Zielona Góra Oficyna Wydawnicza

Uniwersytetu Zielonogórskiego, 2006. 5. Miłek M. Pomiary wielkości nieelektrycznych metodami elektrycznymi. Zielona Góra Politechnika

Zielonogórska, 1998.

OPTIONAL READING: 1. Piotrowski J. Teoria pomiarów: pomiary w fizyce i technice. -Warszawa PWN, 1986; 2. Szklarski J. Metrologia długości i kąta. Zielona Góra Politechnika Zielonogórska, 1997.




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06.1-WM-MiBM-N1-EP-41_12



Direc tor of studies: Dr.Sc. K. Bielefeldt, Associate Professor

Name of lec turer : Prof. K. Bielefeldt, Dr. Janusz Walkowiak


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Semester


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Number of ECTS



Lecture 15 1 Grade

Class

Laboratory

Seminar

Workshop

Project 15 1

V

Grade


Lecture 16 2 Grade

Class

Laboratory

Seminar

Workshop

Project 16 2

IV

Grade

4

COURSE AIM: The transfer of knowledge in the field of environmental management into practical use in engineering work. Students have to understand the causes of environmental degradation and possess the knowledge to protect and acquire the skills to take account of environmental aspects and environmental protection in the technical and technological solutions.



ENTRY REQUIREMENTS: -

COURSE CONTENTS: Lecture: Basic definitions and important legislation. The organization of environmental protection in Poland and the EU. Environmental management. An environmental mana-gement system (ISO 14 001); tasks of the public administration. Economic instruments in environmental protection. Climate and its changes. The greenhouse effect and discontinuity ozonosphere (ozone depletion).

Energy sources and their impact on the environment. Environmental pollution: air and water pollution, noise, vibration, and radiation - electromagnetic and radiation. Waste and waste minimization and recycling. Recycling, in particular recycling vehicles.

Project: Development of technology for waste disposal or other environmental projects.

TEACHING METHODS: Lecture: with multimedia presentation.

Project: working with books, standards and individual work.


technical sciences


K_W17

students get acquainted with basic knowledge in the field of environmental organizations and environmental management methods based on national law and EU

K_K02 K_U10

Knowledge of anthropogenic sources of risk and the ability and to prevent it by using engineering skills

K_K04 The ability to set priorities based on economical and ecological analysis K_K07 the skills to characterize environmental resources and knowing how these are to be

managed, scrupulous informing the public about the state of the environment

LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The reference to

the learning outcomes of the

field of study


K_W17 K_K02 K_U10

Lecture: Evaluation is based on the final test, which refers to the teaching material (lecture and the students own work) Thresholds: Grade: 60% mastery for thematic material object (60% of the possible points of the test). Score Good: the master is 75 to 90% of the material in the thematic subject (75 - 90% of the possible points test). Very good: More than 90% of the material in the thematic subject (more than 90% of the possible points of test execution).

K_K04 K_K07

Project: Grade: acceptance of the project technology of environmental protection

STUDENT WORKLOAD: 100 hours - including contact hours with teachers 40 (32) h, of which 10 hours of consultation, working alone - 60 (68) h


1. Poskrobko, B.: (red.): Zarządzanie środowiskiem, PWE, W-a 2007 2. Lipiński A.: Prawne podstawy ochrony środowiska, Wolters Kluwer Polska Sp. z o.o., Wa-wa

2007 3. śylicz, T.: Ekonomia środowiska i zasobów naturalnych, PWE 2007



OPTIONAL READING: 1. Actual prints and media publications

REMARKS:



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06.1-WM-MiBM-N1-EP-43_12

Type of course: eligible


Director of studies: Dr inŜ. Alicja Laber

Name of lecturer: Dr inŜ. Alicja Laber


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Number of ECTS



Lecture 15E 1 exam

Class - -

Laboratory 15 1

Seminar - -

Workshop - -

Pro jec t - -

V


Lecture 9 1 Grade

Class - -

Laboratory 9 1

Seminar - -

Workshop - -

Pro jec t - -

V

3

СOURSE AIMS:

The aim of the course is to introduction students with the means and methods for programming CNC machine tools.

PREREQUISITES:

MANUFACTURING PROCESSES, METROLOGY, FUNDAMENTALS OF MECHANICAL ENGINEERING



COURSE CONTENTS: Substantive content. Ways program (incremental and absolute) axis controls. Codes used in programming. Circular interpolation and linear .Examples programming for linear interpolation, circular and part of the arc.

TEACHING METHODS:

Lectures with audiovisual aids. Working with books, current standards, Magazines and catalogs of lubricants; individual student work in the development of laboratory reports.

LEARNING OUTCOMES:

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



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_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


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



assessment


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

K_W04 Written exam

grade

Knowledge of the principles of design and construction of mechanical equipment

K_W09 Written exam

grade

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

K_W14 Written exam

grade

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

grade

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

K_U07 performance report

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

K_U13 performance report



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

K_K04 performance report


K_K07 performance report

Lecture - long passing is the positive assessment of the three written responses to the examination questions, provided credit of the lecture is to provide a positive evaluation of the three written responses to questions about the fundamental issues of the subject. Laboratory - credit provided to perform all lab reports 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




STUDENT WORKLOAD:

THE STUDENT WORKLOAD OF 90 HOURS, INCLUDING WORK IN THE AUDITORIUM 30 (8) HOURS, WORKING ALONE 43 (82) HOURS, INCLUDING PREPARATION FOR CLASSES AND STUDY REPORTS, 33 (40) HOURS, TO PREPARE FOR THE EXAM / COMPLETION 10 (42) HOURS. TOTAL HOURS OF PRACTICAL CLASSES: 63 (49), WHICH CORRESPONDS TO 2 ECTS TOTAL HOURS OF LESSONS WITH A TEACHER: 47 (18), WHICH CORRESPONDS TO 2 ECTS

RECOMMENDED READING: 1. Boguś Z.: Numeryczne sterowanie obrabiarek. Skrypt Politechniki Gdańskiej. Gdańsk 1987; 2. Laber A., Adamczuk K. Podstawowe wiadomości z programowania numerycznego na frezarkę

EMCO F1 – CNC - skrypt; 3. Pritschow G. Technika sterowania obrabiarkami i robotami przemysłowymi. Oficyna Wyd.

Politechniki Wrocławskiej. Wrocław 1987; 4. Plichta J., Plichta S.: Podstawy programowania obrabiarek sterowanych numerycznie cz I i II.

Wydawnictwo uczelniane Politechniki Koszalińskiej. Koszalin 2002

OPTIONAL READING: 1. Poziomski T. Podstawy technologii na obrabiarki sterowane numerycznie; 2. Marciniak K. i in. Obróbka powierzchni krzywoliniowych na frezarkach sterowanych numerycznie; 3. Podstawy obrabiarek CNC. Wydawnictwo REA MAT; 4. ISO 6983 – 2:1982 Numerical control of machines – Program format and definition of adress words –

part 1 and 2: Coding of miscellaneous functions M

REMARKS:

LIST OF LABORATORIES FOR PART TIME STUDENTS IS SELECTED FROM THE LIST ABOVE.

WORKLOADS IN PARENTHESES ARE THE NUMBERS FOR PART TIME STUDIES.

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06.1-WM-MiBM-N1-EP-45_12

Type of course: eligible


Director of studies: Dr inŜ. Alicja Laber

Name of lecturer: Dr inŜ. Alicja Laber


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Number of ECTS



Lecture 15 1 Exam

Class - -


Seminar - -

Workshop - -

Pro jec t - -

V


Lecture 9 1 grade

Class - -

Laboratory 9 1

Seminar - -

Workshop - -

Pro jec t - -

V

5

COURSE AIMS:

The aim of the course is to introduction students with the basic messages of mechanical engineering.

PREREQUISITES: Metrology, Production Techniques, base machine design

COURSE CONTENTS: Types of semi-finished products, their selection and preparation for treatment. Types of allowances, and factors affecting their size. Basic size for oversizes. The calculation of the number of necessary machining operations. Normative for the treatment of excess material cut. Appointment conditions and machining parameters. Standardization of time. Machining base. Machining accuracy of machine parts. Factors affecting the machining accuracy. Technological documentation. Division of machinery for processing rational conduct. The technological process of typical machine parts.

TEACHING METHODS:

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

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_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


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



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 reports

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

K_U13 reports

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

K_K04 reports


K_K07 reports

Lecture - long passing is the positive assessment of the three written responses to the examination questions, provided credit of the lecture is to provide a positive evaluation of the three written responses to questions about the fundamental issues of the subject. Laboratory - credit provided to perform all lab reports 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




STUDENT WORKLOAD:

The student workload of 150 hours, including work in the auditorium 30 (8) hours, working alone 75 (142) hours, including preparation for classes and study reports 55 hours, to prepare for the exam / test 20 (142) hours. Total hours of practical classes: 113 (116), which corresponds to 4 points ETS Total hours of lessons with a teacher: 75 (48), which corresponds to 3 ECTS

RECOMMENDED READING: 1. Feld M. „Projektowanie i automatyzacja procesów technologicznych części maszyn.” WNT Warszawa

1994 2. Puff T. „Technologia budowy maszyn.” PWN 1977 3. Tymowski J. „ Technologia budowy maszyn.” WNT 1989

OPTIONAL READING:

1. Przybylski W. , Barylski A., Radlak A. „ Ćwiczenia laboratoryjne z technologii maszyn.” Gdańsk, Wydawnictwo Politechniki Gdańskiej 1980

2. Przybylski W. „ Technologia obróbki nagniataniem.” Warszawa, WNT 1987 REMARKS: LIST OF LABORATORIES FOR PART TIME STUDENTS IS SELECTED FROM THE LIST ABOVE. WORKLOADS IN PARENTHESES ARE THE NUMBERS FOR PART TIME STUDIES



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


2. 06.1-WM-MiBM-N1-EP-45_12






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Number of ECTS



Lecture 15 1 Exam

Class - - -

Laboratory - - -

Seminar - - -

Workshop - - -

Pro jec t 15 1

V

Grade


Lecture 9 1 Exam

Class - - -

Laboratory - - -

Seminar - - -

Workshop - - -

Pro jec t 9 1

V

Grade

3

СOURSE AIMS:

The aim of the course is to present basic concepts and technology for the repair of machinery and equipment repairs. To familiarize students with the processes of assembly and disassembly of the machine.

PREREQUISITES: Engineering manufacturing, base construction machinery, mechanical engineering base, the operation of machinery, metrology and measurement systems.



COURSE CONTENTS: Lecture content. Types of repairs and renovations. The order of corrective action. Removing machines. Preparatory operations (washing, drying, consumption verification, etc.). Evaluation of the possibility dismantling of machines. Regenerative technologies: mechanical, welding, laser, plasma, electrochemical, electrical discharge. Removing the selected non-metallic components (tires, belts etc.). Repair technologies selected components or machines. Measurement and control elements of the repair. Assembly of parts, assemblies and equipment after repair. Tools and equipment for removal and installation. Organization repair and overhaul processes. Use of policy management software machine repairer.



technical sciences


T1A_W06, T1A_W07, T1P_W05, T1P_W06

has knowledge of the stress analysis of basic mechanical structures; has an elementary knowledge of fluid mechanics and technical thermodynamics necessary to understand the construction and operating of mechanical equipment

T1A_U01, T1A_U03, T1A_U05, T1P_U15, T1P_U16

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, can prepare a study in Polish and a foreign language about problems related to basic tasks of mechanics and mechanical engineering, has self-education abilities

T1A_K04, T1P_K01, T1K_05

able to prioritize appropriately for implementation of tasks specified by yourself or others. The student can understand the importance and the need of lifelong education and is able to organize the learning process of others




T1A_W06, T1A_W07, T1P_W05, T1P_W06


T1A_U01, T1A_U03, T1A_U05, T1P_U15, T1P_U16

designed project

T1A_K04, T1P_K01, T1K_05

designed project

Lecture - subject to completion of the lecture is to get a positive assessment of the exam. Exercise - provided credit is to get positive ratings from all classes to be implemented in the class. Project evaluation process is subject to repair some of the machines - removal and installation.

STUDENT WORKLOAD:


Total hours of lessons with a teacher: 32 (20) which corresponds to 1 ECTS.


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;

5. 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. Adamiec P., Dziubiński J., Filipczyk J. Technologia napraw pojazdów samochodowych. Gliwice

Wydawnictwo Politechniki Śląskiej, 2002. 2. Cempel Cz., Tomaszewski F.: Diagnostyka Maszyn. Wyd. MCNEMT, Radom 1992.




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06.1-WM-MiBM-N1-EP-47_12



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

Name of lec turer : Prof. dr hab. inŜ. Eugene FELDSHTEIN,

dr inŜ. Albert Lewandowski


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Number of ECTS



Lecture 15 1 Exam

Class - - -

Laboratory - - -

Seminar - - -

Workshop - - -

Project 15 1

V

Grade


Lecture 9 1 Exam

Class - - -

Laboratory - - -

Seminar - - -

Workshop - - -

Project 9 1

Grade

3

COURSE AIMS: The aim of the course is to familiarize students with the principles of designing processes for machine parts machining to be used in their further education and future careers.

PREREQUISITES: Manufacturing engineering – machining, metrology and measuring systems, materials science, fundamentals of machine design.



COURSE CONTENTS: Lecture content. Types of production and their characteristics. Manufacturability analysis of machine parts. The choice of workpiece basing. Selection of machining allowances. Typification of processes. Typical sequences of machine parts and surfaces machining. Rules for selection of machines. Rules for selection of cutting tools, measuring equipment and fixtures. Selection of machining parameters. Calculation of processing time.

Project. Machining technology for a machine part according to the assigned task

TEACHING METHODS: Lectures with audiovisual aids. Working with books and standards. Individual work while preparing a project.


technical sciences


K_W16 The student knows the use of conventional technological machines for cutting, machining technologies, design and use of cutting tools and fixtures.

K_U01 can obtain information from the literature and other sources, interpret and integrate the obtained information.

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 independently evaluate the abilities of different machining technologies, is able

to select a typical machinery, tools and propose methods for machining of typical machine components.

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



the field of study


K_W16

K_U15

written exam

K_U01

K_U03 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 33 (21) hours, individual work (11) hours, preparing for classes 7 (8) hours, preparing a project 20 (20) hours, revising for the exam and tests 15 (15) hours. Total hours of practical classes: 16+20=36 (10+20=39) which corresponds to 2 ECTS. Total hours of lessons with a teacher: 33 (9) which corresponds to 2 ECTS

RECOMMENDED READING: 1. Feld M. Technologia budowy maszyn. Warszawa, PWN, 2000; 2. Brodowicz W., Grzegórski Z. Technologia budowy maszyn. Warszawa, WSiP, 1998;



3. Poradnik inŜyniera. Obróbka skrawaniem. Tom 1 – 3. Warszawa, WNT, 1991; 4. 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;Honczarenko J.

Elastyczna automatyzacja wytwarzania. Obrabiarki i systemy obróbkowe. Warszawa, WNT, 2000. 3. Cichosz P. Narzędzia skrawające. Warszawa, WNT, 2009.




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06.1-WM-MiBM-N1-EP-48_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. R.Maruda


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Number of ECTS credi ts

a l loca ted


Lecture 15 1 Exam

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 15 1

V

Grade


Lecture 9 0,5 Exam

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t 9 0,5

V

Grade

3

COURSE AIM: The aim of the course is to familiarize students with the principles of device design for machining, controlling and assembly of machine parts to be used in their future careers.

ENTRY REQUIREMENTS: Manufacturing engineering – machining, metrology and measuring systems, materials science, fundamentals of machine design.



COURSE CONTENTS: Lecture content. Components and assemblies of machine equipment. Rules of determining and fixing of workpiece in the holder. The basic elements of fixtures. Forces to clamp workpiece and tool in holder. Positioning and mounting of device on the machine tool. Basic components and assemblies of cutting tools. Constructions of measuring instruments.

Project. Design of device, cutting tool or measuring instrument according to the task.

TEACHING METHODS: Lectures with audiovisual aids. Working with books and standards. Individual work while preparing a project.


technical sciences


K_W16 The student has a basic engineering knowledge of the use and selection of of cutting tools, measuring instruments and holders, their design and attachment to technological machines.

K_U01 can obtain information from the literature and other sources, interpret and integrate the obtained information.

K_U03 can prepare a project in the field of machine devices K_U07 can use information and communication technologies to prepare a project. K_U15 can independently evaluate the abilities of different machine devices, is able to

propose design solutions. K_U18 can develop design of technological devices for various purposes. K_K04 understands the need for learning throughout life, can justify the priority of chosen

decisions.



the field of study


K_W16

K_U15

written exam

K_U01

K_U03

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 33 (21) hours, individual work (11) hours, preparing for classes 7 (8) hours, preparing a project 20 (20) hours, revising for the exam and tests 15 (15) hours. Total hours of practical classes: 16+20=36 (10+20=39) which corresponds to 2 ECTS. Total hours of lessons with a teacher: 33 (9) which corresponds to 2 ECTS

RECOMMENDED READING: 1. Feld M. Uchwyty obróbkowe. Warszawa, WNT, 2002; 2. Feld M. Technologia budowy maszyn. Wyd. 3. Warszawa, PWN 2000.



OPTIONAL READING: 1. Poradnik inŜyniera. Obróbka skrawaniem. Tom 1 – 3. Warszawa, WNT, 1991; 2. Dobrzański T. Uchwyty obróbkowe. Poradnik konstruktora. Wyd. 7. Warszawa, WNT 1987. 3. Cichosz P. Narzędzia skrawające. Warszawa, WNT, 2009. 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: Mechanik; Obróbka metalu; Annals of

CIRP i inn.


Instytut Budowy i Eksploatacji Maszyn - Wydział Mechaniczny


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06.1-WM-MiBM-N1-EP-49_09



Direc tor of studies: : dr inŜ. Marek Malinowski

Name of lec turer : dr inŜ. Marek Malinowski


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Number of ECTS



Lecture 15 1 Grade

Class


Seminar

Workshop

Project

I


Lecture 9 1 Grade

Class


Seminar

Workshop

Project

I

2

COURSE AIMS: The aim of the course is to familiarize students with machinery dynamics problems and vibration isolation.

PREREQUISITIES: -



COURSE CONTENTS: General principles of dynamic loads occurring in the working processes of machines, selected mathematical models of assemblies, systems. Methodology of experiments, dynamic analysis, free vibration and forced vibration, force impulse, vibration of shafts, beams, vibration damping. vibration modeling.

TEACHING METHODS: Working with books. The individual work of the student during the execution of each laboratory.


technical sciences


K_W05 has ordered knowledge with strong theoretical underpinnings in the area of statics of rigid bodies systems, kinematics and dynamics of rigid bodies, as well as knowledge of the vibration area









field of study


K_W05

K_W16

K_U01

K_U05


K_U14

K_K01

K_K03

grade based on laboratory classes



STUDENT WORKLOAD:

The student workload of 60 hours, including work in the auditorium 30 (18) hours, consultations 1 (2), individual work and read the literature 29 (40) hours, preparing for classes 9 (10) hours, analysis and solution of task problem – raports 10 (15) hours. Total hours of practical classes: 35 (36) which corresponds to 1 ECTS Total hours of lessons with a teacher: 31 (22) which corresponds to 1 ECTS.

RECOMMENDED READING: 1. Borkowski W., Konopka S., Prochowski L., Dynamika maszyn roboczych, WNT,

1996.

2. Kucharski T., System pomiaru drgań mechanicznych, WNT, 2002.

OPTIONAL READING: 1. Misiak J., Mechanika techniczna, Kinematyka i dynamika, t.2, WNT, 1998.

2. KruszewskiJ., Wittbrodt E., Drgania układów mechanicznych w ujęciu komputerowym, t.1, Zagadnienia liniowe, WNT, Warszawa, 1992.

KruszewskiJ., Wittbrodt E., Walczyk Z., Drgania układów mechanicznych w ujęciu komputerowym, t.2 Zagadnienia wybrane, T, Warszawa, 1992.



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06.1-WM-MiBM-N1-EP-50_09



Direc tor of studies: dr inŜ. Izabela Gabryelewicz

Name of lec turer : dr inŜ. Izabela Gabryelewicz


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Number of ECTS



Lecture 15 1 Grade

Class


Seminar

Workshop

Pro jec t

I


Lecture 8 1 Grade

Class

Laboratory

Seminar

Workshop

Pro jec t

VII

2

СOURSE AIMS:

The aim of the course is to familiarize students with the influence of structural features on the properties of motion mechanisms, and analysis of the impact of the geometry and position of the kinematic parameters of the different mechanisms. Another effect of education is to provide students with the characteristics of the basic features of each type of mechanism (lever arch mechanisms, cam, circulation and manipulators), such as the kinematic and dynamic characteristics, efficiency, uneven running. The student will understand the operation of physical systems that will enable him to effectively use the different systems in practice.

PREREQUISITES: -



COURSE CONTENTS: Lecture content : Basic concepts related to the analysis of physical systems. Structure and classification mechanisms. Issues related to the study of mechanisms of movement - kinematics. The basic parameters of mechanisms: the location of members, the trajectories of points, velocity and angular and linear acceleration. Characteristics of the basic methods to characterize mechanisms: Graphics, analytical, numerical and combined. Analysis and review of selected groups of mechanisms. Lever mechanisms and mechanisms of the higher pairs. Analysis of the accuracy. Relationships between kinematic parameters and the masses of members operating at no forces - dynamics. Kinetostatics. Friction in kinematic pairs. The energy balance of the machine. The study of machines. Balancing. Dynamics of mechanisms.

Laboratory content:

1. Reminder that the school vector calculus and a reminder of basic physical quantities. 2. Identification of parameters of the structure and mechanisms. 3. Kinematic analysis of belt drive with brake 4. Analysis of the movement of the cam, setting speed and acceleration. 5. Kinematic analysis of helical gear units with straight teeth. 6. Kinematic analysis of the differential. 7. Kinematic analysis of the worm gear. 8. Experimental determination of the mass moments of inertia of planar mechanisms. 9. Block Diagram of mechanisms. 10. Correction exercises. Completion of the course.

The order and selection of laboratory exercises carried out depends on the teacher.



technical sciences


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










LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA:

The verification methods for learning outcomes are presented on the table below:




K_W10

K_W16

K_U01

K_U05

Grade based on written test

K_U14

K_U15

K_K01

K_K03


The pass mark for the course is to achieve positive evaluations of written tests carried out at least once a semester.

The pass mark for the lab is to get positive ratings from all the laboratory, to be implemented under the laboratory.

STUDENT WORKLOAD:

The student workload of 60 hours, including work in the auditorium 30 (8) hours, individual work 30 (52) hours, preparing for classes and study reports 10 (37) hours, preparing control work, reports etc. 15 (10) hours, revising for tests 15 (10) hours.

STUDENT WORKLOAD: 1. Miller S., Teoria maszyn i mechanizmów. Analiza układów kinematycznych, Politechnika

Wrocławska, Wrocław 1996

2. Gronowicz A., Miller S., Twaróg W., Teoria mechanizmów i maszyn. Zestaw problemów analizy i projektowania, Oficyna Wydawnicza Politechniki Wrocławskiej, Wrocław 1999.

OPTIONAL READING: 1. Morecki A., Knapczyk J., Kędzior K., Teoria mechanizmów i manipulatorów, WNT,

Warszawa 2002,

2. Olędzki A., Podstawy teorii maszyn i mechanizmów, WNT, Warszawa,

3. Morecki A., Oderfeld J., Teoria maszyn i mechanizmów, PWN, Warszawa,




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

Course code: 06. 1-WM-MiBM-S1-EP-52_12

06. 1-WM-MiBM-N1-EP-52_12



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 15 1 Exam

Class - - -


Seminar - - -

Workshop - - -

Pro jec t - -

-


Lecture 16 2 Exam

Class - - -

Laboratory

Seminar - - -

Workshop - - -

Pro jec t

5

СOURSE AIMS:

The aim of the course is to familiarize students with construction and operation of power transmission in machinery.

PREREQUISITES: Basis of construction of machines



COURSE CONTENTS: Lecture content Typical driving systems, basic components. Combustion drives, engines and theirs steering; Bases dynamics of driving arrangements; Choice of power of engine; electric drive: engines of direct current, engines of alternative current, starting, control rotatory speeds, braiking of engine; Hydrocinetyc drive: clutch, hydrocinetic gear: properties, exploational characters, building and service, basic classifications, selection clutches, selection of gears, analysis of buildings and properties powertrain. Hydrostatical driving systems, basic qualifications, graphic record of elements; Elements of hydraulic systems; Analysis workings of choose hydrostatical arrangements; Steering and control; energetic balance; pneumatic drive: elements and processing systems, energy of compressed air onto mechanical energy; steering elements flow and pressure of airs; choose questions from pneumatic steering. Laboratory content.

Analysis of buildings and rules workings of gearboxes, Research properties of kinematic ramparts of driving machines, Analysis buildings and workings of hydrostatical system, measurement of basic parameters, Analysis buildings and workings of choose components of hydrostatical machines, Preparing mechanical characters of combustion's engine, Analysis buildings and workings of pneumatic system, measurement of basic parameters, Analysis of building of frictions' clutches

Class project:

Student performs the complete design clutch and brake system



technical sciences


K_W16 knows the basic methods, techniques and tools required to solve simple tasks in the field of machinery propulsion and operating it

K_U02 can communicate using various techniques in the professional community as well as in other communities

K_K09 can use analytical simulation and experimental methods to formulate and solve engineering tasks K_U16 can identify and formulate the specification of simple tasks of practical engineering in the design,

drivin of machinery and it operation K_U18 can – according to the specifications – design and implement a simple device, object, system or

process, typical for the process of design, driving of machines, using appropriate methods, techniques and tools




K_W16

K_U02

Exam based on written test

K_K09 K_U16

grade based on laboratory

K_U18 Exam based on written test 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.




STUDENT WORKLOAD:

The student workload of 57 hours, including work in the auditorium 32 (18) hours, individual work 25 (39) hours, preparing for classes and study reports 8 (16) hours, revising for tests 15 (0) hours. Total hours of practical classes: 30 (0) which corresponds to 1 ECTS Total hours of lessons with a teacher: 32(18) which corresponds to 1 ECTS

RECOMMENDED READING: [1] A. Polański : Mechaniczne napędy maszyn, [2] Andrzej Osiecki: Hydrostatyczny Napęd Maszyn, WNT 1998, [3] Stefan Stryczek: Napęd hydrostatyczny, WNT 1992, [4] W. Szenajch: Napęd i sterowanie pneumatyczne, WNT 1997.

[5] Szydelski Z.: Sprzęgła, hamulce i przekładnie hydrokinetyczne, WKŁ, Warszawa, 1981.

OPTIONAL READING: [1] Z. Gogolewski, Z. Kuczewski : Napęd Elektryczny, WNT, W-wa 1972.




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


06.1-WM-MiBM-N1-EP-51_09




Name of lec turer :

dr inŜ. E.Tertel

dr inŜ. P. Kuryło

dr inŜ. J Cyganiuk


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Number of ECTS



Lecture 15 1 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

III


Lecture 8 1 Grade

Class - -

Laboratory - -

Seminar - -

Workshop - -

Pro jec t - -

VIII

2

COURSE AIMS: To familiarize students with the basic elements of transport and storage systems used in manufacturing processes. Discussion of the methods of storage and transport technology. Acquaint students with the principles of equipment selection and design of transport and storage systems.

PREREQUISITIES:

Automation and robotics, the ability to use basic computer tools.




Basic concepts for transport and storage activities in the context of manufacturing processes. Types of materials and loads occurring in the transport and storage processes. Susceptibility of selected materials for transport and storage. Technological transport - selection and design of elements. Material flow organizing in the production process. Technological transport devices. Selected storage technologies. Warehouses, storage buildings, warehouses in the supply, production and distribution, principles of design. Technical equipment of warehouses: tools to simple and complex manipulations. Mechanized and automated transport equipment.

Laboratory content: Selection of parameters and dimensions of loading units for selected types of cargo transport. Determination of the dimensions of the storage locations for transport and warehousing (STM). Selection and determination of the transport equipment parameters for the STM. Dimensioning of transport and storage systems. Creating the flow diagrams, setting the flow table for STM. Analysis of the accuracy of the STM, modify its parameters,.

TEACHING METHODS: Lectures with audiovisual aids. Working with the journals. Individual and group work in laboratory classes. Presentation of solutions, discussion of the obtained solutions.



study


K_W18, Can name the loads occurring in the process of handling and storage, and characterize them in terms of susceptibility to transport and storage.

K_W14 K_W18

He can name and describe the infrastructure elements used for technological transport and storage.

K_U17

Is able to characterize the basic technologies of storage and can choose the appropriate storage technologies for the type of load and production profile.

K_U09 K_U15

He can draw up a plan of material flows in a manufacturing company, is critical of the existing system of transport and storage by proposing the improving solutions.

K_K04 K_K06

Is able to properly set priorities for the transport and storage in the production processes, is looking for creative solutions to the given problem.

K_U12 K_K02

Is aware of the importance of a properly functioning transportation and storage system in a manufacturing company.





K_W14 K_W18, K_U12 K_K02 K_K04 K_K06

Written test

K_U09 K_U12 K_U15 K_U17 K_K02 K_K04 K_K06

Assessment of the laboratory is based on: the laboratory exercises and reports/programs resulting from the execution of all exercises to be exercised.




STUDENT WORKLOAD: The student workload of 60 (54) hours, including work in the auditorium 30 (8) hours, and individual work 30 (46) hours, including: preparation for classes and preparation of reports and audit work 20 (30) hours, preparation for the written test 10 (16) hours.


RECOMMENDED READING: 1. Korzeń Zb., „Logistyczne. systemy transportu bliskiego i magazynowania” ILiM 2003 2. Stanisław KrzyŜaniak, Piotr Cyplik Zapasy i magazynowanie, ILiM 2008 3. Marek Fertsch, Piotr Cypli, Logistyka produkcji. Teoria i praktyka ILiM 2010 4. P. Andrzejczyk, J. Zając, Zapasy i magazynowanie. ILiM 2011 5. Korzeń Zb., „Logistyka w transporcie towarów” Nawigator 1998

,

OPTIONAL READING: 1. Logistyka– dwumiesięcznik. 2. Logistyka a jakość – dwumiesięcznik 3. Nowoczesny magazyn - dwumiesięcznik 4. http://www.logistyka.net.pl/ 5. http://nm.pl/




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


06.1-WM-MiBM-N1-EP-52_09




Name of lec turer : dr inŜ. E.Tertel

dr inŜ. P. Kuryło


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Number of ECTS



Lecture 15 1 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

III


Lecture 9 1 Grade

Class - -

Laboratory 9 1

Seminar - -

Workshop - -

Pro jec t - -

III

2

COURSE AIMS: Acquainting students with the basic methods and tools of manufacturing processes automation. Learning the basic technical means used in automation. To familiarize students with the tools and methods of controlling the operation of the automated systems. Acquaint students with the various aspects of the implementation of automation.

PREREQUISITIES:

Automation and robotics, the ability to use basic computer tools.




The essence of automation, definitions: automation, control. The manufacturing process, automation in the production processes, the degree of automation, the areas of automation in the manufacturing systems. Methods of automation, the desirability and limitations in automation. Computerization in the manufacturing systems. Pneumatic and hydraulic means of automation. Actuators, control valves, logical elements, hydraulic and pneumatic equipment. Design methods of hydraulic and pneumatic control systems, hydraulic and pneumatic diagrams. Basics of robotics. Review of the structures and applications of robots, industrial robots, mobile robots. The robots degrees of freedom, the robot workspace, robots communication with the environment, sensors, effectors, actuators, control. Numerical control. PLCs. Basics of construction, phase of controller cycle, the main areas of application.

Laboratory content: Basic methods for the implementation of an automatic cycle of the actuator. Implementation of the basic logic functions: OR, AND, NOT using the basic elements of pneumatics. Control of automated working pneumatic/hydraulic actuators - combinational and sequential systems. PLC programming using the FBD (Function Block Diagram). ARM1 manipulator control..

TEACHING METHODS: Lectures with audiovisual aids. Working with the journals. Individual and group work in laboratory classes. Presentation of solutions, discussion of the obtained solutions.



study


K_W08, Is able to define the basic concepts of automation. Is able name the technical means used in automation and briefly describe them

K_W08 K_W16

Can describe the basic methods of automated control systems.

K_U17 K_U18

Can design and build a simple automatic control system for pneumatic and hydraulic actuators

K_U07 K_U08 K_U18

Is able design a PLC program control and test/simulate it. Is able to create and test the software that controls industrial robot manipulator model.

K_U10 K_K02

Is aware of the consequences of implementation of automation, sees both positive as well as negative aspects of automation.

K_K03 Is able interact in a group





K_W08, K_W16 K_U10 K_K02

Written test

K_U07 K_U08 K_U10 K_U17 K_U18 K_K02 K_K03

Assessment of the laboratory is based on: the laboratory exercises and reports/programs resulting from the execution of all exercises to be exercised.







1. Chorowski B., Werszko M. Mechaniczne Urządzenia Automatyki Wydawnictwo Naukowo-Techniczne, Warszawa 1990 i nowsze

2. Honczarenko J., Roboty przemysłowe budowa i zastosowanie, WNT, Warszawa 2004 3. Mikulczyński, Tadeusz.: Automatyzacja procesów produkcyjnych, Warszawa : Wydawnictwa

Naukowo-Techniczne, 2006. 4. Kowalowski H.: Automatyzacja dyskretnych procesów przemysłowych. WNT, Warszawa 1981

,

OPTIONAL READING: 1. Pomiary, Automatyka, Robotyka – miesięcznik. 2. http://www.automatyka.pl 1. http://automatykab2b.pl/




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


06.1-WM-MiBM-N1-EP-54_09



Direc tor of studies: Prof. dr hab. inŜ. Mirosław Galicki

Name of lec turer :

Prof. dr hab. inŜ. Mirosław Galicki

dr inŜ. P. Kuryło

dr inŜ. E.Tertel


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Number of ECTS



Lecture 15 1 Grade

Class - -


Seminar - -

Workshop - -

Pro jec t - -

IV


Lecture 9 1 Grade

Class - -

Laboratory 9 1

Seminar - -

Workshop - -

Pro jec t - -

IV

2

COURSE AIMS: The aim of the course is to familiarize students with the basic concepts and definitions of selected methods of mechanical control systems, the essence of control, the mathematical basis, the mechanical control systems. Identify methods and tools for solving problems of mechanical control systems with particular emphasis on applications in mechanics and mechanical engineering.

PREREQUISITIES:



Mathematical analysis with elements of probability theory and mathematical statistics, the ability to use IT tools, Matlab / Scilab.


The concepts of control systems. Examples of dynamic objects with the control systems. Stability - the basic definitions. Stability of linear and non-linear systems. Examples of stability testing. Frequency criteria of stability. The dynamics of object control. Classical controllers P, PD and PID. Control systems based on the inverse dynamics model of the object. Adaptive control systems. Resistant controls objects with uncertain dynamics.

Laboratory content: Matlab / Scilab - a tool for modeling of dynamic systems, the basic terms of use. Mathematical modeling of dynamic objects. Modeling of dynamic objects with control without feedback. Modeling of dynamic objects with control with feedback. The study of the stability of automatic control systems. Regulators - tuning.

TEACHING METHODS: Lectures with audiovisual aids. Working with the book and journals. Individual and group work in laboratory classes. Presentation of solutions, discussion of the obtained solutions.



study


K_W08 The student is able to define basic concepts of methods to control the mechanical systems

K_W08 K_U18

Student is able to design correctly the control system of the mechanical object Is able to analyze the stability of the control system of the mechanical object

K_W08 K_U17

Is able use the control methods in implementation of engineering tasks.

K_U09 K_U16

Is able to present a problem in the language of the control theory of mechanical systems and use the appropriate method to solve it

K_U01 K_U05

Is determined to find solutions in the field of methods to control the mechanical systems

K_K01 Is open to the use of various tools in the field of methods to control the mechanical objects





K_W08 K_U18 K_U17

Written test

K_W08 Assessment of the laboratory is based on: the laboratory exercises and reports/programs resulting from the execution of all exercises to be exercised.






RECOMMENDED READING: 1. M. Krstic, I. Kanellakopoulos and P. Kokotpvic, Nonlinear and Adaptive Control Design, Wiley,

New York, 1995. 2. T. Kaczorek, Teoria sterowania i systemów, WNT, Warszawa, 1999 3. H. Górecki, Algorytmy i programy sterowania, WNT, Warszawa, 1980 1. Z. Bubnicki, Teoria i algorytmy sterowania, Wydawnictwo Naukowe PWN, Warszawa,

2002,

OPTIONAL READING: 1. K. Ogata, Metody przestrzeni stanów w teorii sterowania, WNT, Warszawa 1974 2. M.W. Spong i M. Vidyasagar, Dynamika i sterowanie robotów, WNT, 1997.


Mechanical Faculty

Subject area of studies: Mechanics and mechanical engineering

HHH EEE AAA TTT EEE NNN GGG III NNN EEE SSS

Course code: 06.1-WM-MiBM-S1-EP-59_12 06.1-WM-MiBM-N1-EP-59_12



Direc tor of studies: Dr. Eng. Robert Barski

Name of lec turer : Dr. Eng. Robert Barski


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for a course

Number o f ECTS



Lecture 15 1 Exam

Class

Laboratory 15 1

Seminar

Workshop

Projec t

IV


Lecture 9 1 Grade

Class

Laboratory 9 1

Seminar

Workshop

Projec t

IV

1

3

COURSE AIM: The aim of the course is to familiarize students with thermal machines including internal combustion engines, combustion processes, steam engines and motor fuels.

ENTRY REQUIREMENTS:

Mechanical Faculty


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, 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.

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_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: Odniesienie do

efektów dla kierunku studiów

Metoda sprawdzenia efektu kształcenia

K_W02

K_W05

K_U01 K_K02 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)

STUDENT WORKLOAD: The student workload of 95 hours, including work in the auditorium 30 (18) hours, working alone 60 (60) hours, to prepare for the exam (test) of the lecture 15 (15) hours.

RECOMMENDED READING: 1. Luft, Sławomir, Podstawy budowy silników, Warszawa : Wydawnictwa Komunikacji i

Łączności, 2011 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.

Mechanical Faculty


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

REMARKS: The numbers in the list of student load in parentheses indicate the load of work for part-time studies.



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


06.1-WM-MiBM-N1-EP-60_12



Direc tor of studies: dr inŜ. Janusz Walkowiak

Name of lec turer : dr inŜ. Janusz Walkowiak


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Number of ECTS



Lecture 30 2 Grade

Class

Laboratory

Seminar

Workshop

Project

V


Lecture 8 1 Grade

Class

Laboratory

Seminar

Workshop

Project

VIII

2

COURSE AIM: The aim of the subject is to familiarize students with the design of small companies producing parts of machinery.

ENTRY REQUIREMENTS:



Manufacturing engineering

COURSE CONTENTS: Lecture: Analysis of demand for services and products. Selected issues of the investment process. Legal forms to the company organization. The structure of the production process, production volume, cooperation, etc. Manufacture parts of machines of different types. Selection of machinery and equipment, their location, etc. General rules for inventory management in the company. Organization of the internal transport, the choice of means of the transport and the flow of materials and products. Technical documentations. Facilities and additional equipment, technical support. Installations in the company. The employment of workers. The occupational safety and health, the fire protection, the environmental protection, etc. related to your business. The design of the manufacturing of chosen product.

TEACHING METHODS: Lectures - with using audiovisual means


technical sciences Knowledge, skills, competence

K_W17 The student proposes the organization of the plant to manufacture of some kind of products

K_W20 the student formulates framework for manufacture company with the design of the essential elements of the process line

K_U10 the student evaluates the non-technical aspects of the performance of the tasks of the engineering company

K_U17 the student evaluates usefulness of standard methods and instrumentation to achieve effects of technological process, and selects and uses to design the process line

K_K02 the student is aware of negative effects of production processes and includes them in the project

LEARNING OUTCOMES VERIFICATION AND ASSESSMENT CRITERIA: The verification policy outcomes are shown in the following table.




K_W17 K_W20 K_U10 K_U17 K_K02

Lecture - grade

Evaluation is based on the test, which refers to the teaching material (lecture and the students own work)

STUDENT WORKLOAD: The student workload of 60 (50) hours, including work in the auditorium 30 (8) hours, individual work 30 (42) hours, work (design) 22 (32) hours, preparing for classes 8 (10) hours.

Total hours of practical classes: 22 (32) which corresponds to 1 ECTS.

Total hours of lessons with a teacher: 30 (8) which corresponds to 1 ECTS.

RECOMMENDED READING: 1. Feld M.- Podstawy projektowania procesów technologicznych typowych części

maszyn. WNT, Warszawa 2007.



2. Karpiński T. - InŜynieria produkcji. WNT, Warszawa 2007.

3. Poradnik InŜyniera Mechanika. PWN, Warszawa 1996.

4. Bukowski A. – Projektowanie zakładów przemysłowych. PWN, Warszawa 1997.

5. Przepisy prawne dotyczące powstania i działalności firmy (Dzienniki Ustaw).

OPTIONAL READING: 1. Bukowski P. – Projektowanie wydziałów obróbki plastycznej w przemyśle

maszynowym. Skrypt PW, Warszawa 1980.

2. Pachelska H. - Projektowanie zakładów mechanicznej obróbki drewna. Wyd. SGGW, Warszawa 2006.




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


06.1-WM-MiBM-N1-EP-61_12



Direc tor of studies: Dr.Sc. K. Bielefeldt, Associate Professor

Name of lec turer : Prof. K. Bielefeldt, Dr. Janusz Walkowiak


Number of

teaching

hours per

semester

Number of

teaching

hours per

week

Semester


for a course

Number of ECTS



Lecture 15 1 Grade

Class


Seminar

Workshop

Project

V


Lecture 8 1 Grade

Class

Laboratory

Seminar

Workshop

Project

VIII

2

COURSE AIM: Cognitive aim is to provide a basic knowledge of polymeric materials, ranging from the creation of the structure in the polymerization reaction and the resulting properties, the classification of polymeric materials and ways to modify them, as well as processing methods. The main applications of plastics.



ENTRY REQUIREMENTS: Basic knowledge of chemistry and solid state physics and fluid mechanics and thermodynamics

COURSE CONTENTS: Lecture: Basic technical knowledge of plastics, polyreactions, molecular and supermolecular structure. Classification and major properties of polymeric materials. Polymers and plastics. Change of properties by modification.

Selected topics in thermodynamics and rheology of processing. Processability. The main methods of processing: primary processing (casting, laminating, plastic injection molding, extrusion and compression), secondary processing (molding in solid state and thermoforming).

Processing machines and tools at a glance. The quality of plastic products. Use of polymeric materials - possibilities and limitations.

Exercises in the laboratory:

1. Identification of plastics with instrumental methods.

2. Preparation processes of thermoforming - processing parameters.

3. Determination of the characteristics of the thermal curing reaction.

4. Production of surface layers in the laminating process on sheet materials

5. Gel time crosslinking systems.

6. Non-pressure molding - regeneration section.

7. Injection and Compression Tools - construction and analysis of their function

TEACHING METHODS: Lecture - with the presentation

Laboratory - working in groups


technical sciences


K_W13 Student acquires the knowledge of important plastics and knows the relationship between structure and properties and processability of these materials

K_U19 K_W10 K_K03

He is able to identify and classify plastics and knows the possibilities and the limits of their application

K_W16 K_W14

knows the most important polymer processing methods (principles and practice) and is familiar with plastics processing machinery and tools



field of study


K_W10 K_W13 K_W14 K_W16

Lecture: Evaluation is based on the final test, which refers to the teaching material (lecture and the students own work) Thresholds: Grade: 60% mastery for thematic material object (60% of the possible points of the test). Score Good: the master is 75 to 90% of the material in the thematic subject (75 - 90% of the possible points test). Very good: More than 90% of the material in the thematic subject (more than 90% of the possible points of test execution).

K_U19 K_K03

Exercises in the laboratory: Grade: based on of participation in laboratory work (activity, report and the like).



STUDENT WORKLOAD: Workload of 50 hours, including work in class 30 (8) hours, self study 20 (42) hours, including preparation for classes and practical exercises, preparing reports, 12 (30) hours, as well as to prepare for the written test.

RECOMMENDED READING: 1. H. Saechtling, Tworzywa sztuczne: poradnik; Warszawa, WNT, 2007. 2. Ozimina D., Madej M., Wdowin A.: Tworzywa sztuczne i materiały kompozytowe, Kielce,

Wydawnictwo Politechniki Świętokrzyskiej, 2006. 3. Hyla I.: Tworzywa sztuczne: własności, przetwórstwo, zastosowanie, Gliwice, Wydawnictwo

Politechniki Śląskiej, 2004. 4. Koszkul J., Bociąg E. Materiały polimerowe i ich przetwórstwo, praca zbiorowa Częstochowa,

Wydawnictwo Politechniki Częstochowskiej, 2004.

OPTIONAL READING: 1. Broniewski T. [i inni]: Metody badań i ocena właściwości tworzyw sztucznych Warszawa,

WNT, 2000.

2. Koszkul J.: Stosowanie i przetwórstwo materiałów polimerowych - praca zbiorowa pod red., Częstochowa, Wydawnictwo Politechniki Częstochowskiej, 1998.

REMARKS: -

06.1-wm-mibm-s1-ep-04 12 eng - wydziaŁ course code: 06.1-wm-mibm-s1-ep-04_12...

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