14ZP103 - Technical physics 1
Course specification | ||||
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Course title | Technical physics 1 | |||
Acronym | 14ZP103 | |||
Study programme | Biochemical Engineering and Biotechnology,Chemical Engineering,Environmental Engineering,Material Engineering,Metallurgical Enginering | |||
Module | ||||
Lecturer (for classes) | ||||
Lecturer/Associate (for practice) | ||||
Lecturer/Associate (for OTC) | ||||
ESPB | 6.0 | Status | ||
Condition | Облик условљености | |||
The goal | The course is designed to provide fundamental knowledge of general physics that has a direct impact on engineering practice. Students get acquainted with basic physical quantities and units, material point and rigid body kinematics, dynamic quantities and laws, oscillatory and wave motion, phenomena in fluids, molecular-kinetic theory, and heat physics. | |||
The outcome | Introduction to students with basic natural physical laws and metrological evaluation of measurement results. Training students to apply physical laws in solving simpler versions of different engineering problems. | |||
Contents | ||||
Contents of lectures | Introduction. The place and role of physics as a fundamental science . The influence of physics on the development of technical disciplines with particular reference to the development of technology. Physical quantities and units. Dimensional analysis. Unit equations. Kinematics. Reference systems. Movement, types of movement. Parameters of movement. Kinematics of the material point. Kinematics of a rigid body. Kinematic relations and transformations. Dynamics. Dynamic size and legality. Frictional forces. Inertial forces. Dynamics of the material point. Newton's laws. Work, power, energy. Laws of conservation. Theory of collision processes. Dynamics of a rigid body. Non-Inertial Systems. Gravitation. Gravity field, potential energy, potential. Oscillatory and wavy motion. Harmonic oscillator. Oscillator energy. Furies’ harmonic analysis. Muffled oscillations. Compulsory oscillations. Resonance. Transfer of energy by wave motion. Superposition, reflection and transmission of waves. Doppler effect. Standing waves. Sound waves and physical sound characteristics. Fluids. Occurrences of fluid motion. Surface tension and capillary phenomena. Friction in the fluid. Hydrostatic and hydrodynamic pressure in the fluid. Equation of continuity. Toricelli's theorem. Molecular-kinetic theory. Speed, shape and energy of molecular motion. Maxwell's Law of Speed Distribution. Mean length of the free path. Transport phenomena in gases. Temperature and heat. Principles of temperature measurement. Thermometers. Thermal expansion of the body. Calorimetry. Thermal balance. Specific heat and heat capacity. Changes in aggregate state. Phase switches. The first principle of thermodynamics. | |||
Contents of exercises | Laboratory practicals: 1) Determination of the density of liquid and solid substances 2) Determining the acceleration of free fall by the mathematical pendulum 3) Determination of the Young's modulus of elasticity of metals 4) Determination of axial moment of inertia and torsion constants of the body 5) Determination of air velocity in air using Kundt’s tube 6) Determination of the surface tension constant of a liquid 7) Determination of body viscosity coefficient 8) Determination of the dependence of the boiling temperature of the water from the pressure 9) Determination of the specific thermal capacitance of the solid substance 10) Determination of adiabatic air constants | |||
Literature | ||||
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Number of hours per week during the semester/trimester/year | ||||
Lectures | Exercises | OTC | Study and Research | Other classes |
3 | 1.5 | 1.5 | ||
Methods of teaching | Theoretical lectures, practical lectures, laboratory practical | |||
Knowledge score (maximum points 100) | ||||
Pre obligations | Points | Final exam | Points | |
Activites during lectures | 10 | Test paper | 30 | |
Practical lessons | 10 | Oral examination | ||
Projects | ||||
Colloquia | 50 | |||
Seminars |