1. SylabUZ
2. Faculty of Engineering and Technical Sciences
3. winter term 2018/2019
4. WM - oferta ERASMUS - Erasmus programme
5. Industrial Mechanics

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Industrial Mechanics - course description

Aim of the course

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.

Prerequisites

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Knowledge of mathematics and physics

Scope

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 and methods of theirs verification

Outcome description	Outcome symbols	Methods of verification	The class form

Assignment conditions

Lecture

positive evaluation of the test

Class

positive evaluation of the test

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.

Recommended reading

Misiak J., Mechanika ogólna – Statyka i kinematyka, 1993 WNT wydanie IV

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

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

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

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

Further reading

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

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

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

Notes

Modified by dr inż. Paweł Jurczak (last modification: 30-04-2018 07:11)