Course detail

Railway Constructions II

FAST-CN004Acad. year: 2019/2020

Measuring technique and modelling. Introduction into transportation structures problems, hygiene standards and regulations. Aims and physical principles of measurements and devices. Types of measuring sensors, principles of electronic measurements of physical quantities. Multi-channel measurements, measuring software, principles of data recorded elaboration and proportional dependencies on various quantities. Measurements of mechanical and fatigue material properties within transportation structures, measurements, analyses and modelling of mechanical exertion, static and dynamic phenomena. Measuring, modelling and analysis of temperature and thermal fields.
Measurements and analyses of noise and trembling. Comparison of measuring and modelling techniques. Prediction of noise levels from road, rail transport and air transport. Modal analyses, comparison of measuring and modelling techniques. Analyses of measurements. Project and analyses of anti-noise and anti-vibration measurements.
Dynamical analysis of rail track constructions. Principles, simple dynamical model of interaction: vehicle and rail track. Dynamical exertion within the rail joints, sources of vibration in dependency on frequency. Dynamical models of rail track, critical train speed, dynamical response on vehicle, dynamical response on moving wheelset, vibration transmission between vehicle and rail track.
Application of advanced models by the method of final elements.
Stability of rail grid and alongside strength, diagonal and alongside resistance, modelling by the method of final elements.

Language of instruction

Czech

Number of ECTS credits

6

Mode of study

Not applicable.

Department

Institute of Railway Structures and Constructions (ZEL)

Learning outcomes of the course unit

A student acquires skills in dynamical analysis of rail track constructions, measuring technique and modelling and stability of rail track.

Prerequisites

Railway substructure, subdivision and construction of rail substructure and its construction layers, construction and shape of earth formation
Railway superstructure and modern railway structure design, interaction between railway vehicle and track, static track design, switches, crossings and turnouts.
Basic principles of numerical computations, basic elementary problems of numerical mathematics.
Physics, vibrations, proper vibrations, energy of a harmonics vibrations, damped vibrations, forced vibrations, addition of vibrations
Examination of the response of structures subjected to excitation, bases of the vibration theory, frequency domain analysis.

Co-requisites

Not applicable.

Planned learning activities and teaching methods

Not applicable.

Assesment methods and criteria linked to learning outcomes

Not applicable.

Course curriculum

1. Measuring technique and modelling. Introduction into transportation structures problems, hygiene standards and regulations. Aims and physical principles of measurements and devices.
2. Types of measuring sensors, principles of electronic measurements of physical quantities.
3. Multi-channel measurements, measuring software, principles of data recorded elaboration and proportional dependencies on various quantities.
4. Measurements of mechanical and fatigue material properties within transportation structures.
5. Measurements, analyses and modelling of mechanical exertion, static and dynamic phenomena. Measuring, modelling and analysis of temperature and thermal fields.
6. Measurements and analyses of noise and trembling. Comparison of measuring and modelling techniques. Prediction of noise levels from road, rail transport and air transport.
7. Modal analyses, comparison of measuring and modelling techniques. Analyses of measurements.
8. Design and analyses of anti-noise and anti-vibration measurements. Dynamical analysis of rail track constructions. Principles, simple dynamical model of interaction: vehicle and rail track.
9. Dynamical exertion within the rail joints, sources of vibration in dependency on frequency. Dynamical models of rail track, critical train speed. Dynamical response on vehicle, dynamical response on moving wheelset, vibration transmission between vehicle and rail track.
10. Application of advanced models by the method of final elements. Stability of rail grid and alongside strength, diagonal and alongside resistance, modelling by the method of final elements.

Work placements

Not applicable.

Aims

The objective of the subject is to introduce students to the problems of dynamical analysis of rail track constructions, measuring technique and modelling and stability of rail track and to practise acquires knowledge and skills.

Specification of controlled education, way of implementation and compensation for absences

Extent and forms are specified by guarantor’s regulation updated for every academic year.

Recommended optional programme components

Not applicable.

Prerequisites and corequisites

Not applicable.

Basic literature

Not applicable.

Recommended reading

Not applicable.

Classification of course in study plans

  • Programme N-P-E-SI (N) Master's

    branch K , 2. year of study, winter semester, compulsory

  • Programme N-K-C-SI (N) Master's

    branch K , 2. year of study, winter semester, compulsory

  • Programme N-P-C-SI (N) Master's

    branch K , 2. year of study, winter semester, compulsory

Type of course unit

 

Lecture

26 hours, optionally

Teacher / Lecturer

Syllabus

1. Measuring technique and modelling. Introduction into transportation structures problems, hygiene standards and regulations. Aims and physical principles of measurements and devices. 2. Types of measuring sensors, principles of electronic measurements of physical quantities. 3. Multi-channel measurements, measuring software, principles of data recorded elaboration and proportional dependencies on various quantities. 4. Measurements of mechanical and fatigue material properties within transportation structures. 5. Measurements, analyses and modelling of mechanical exertion, static and dynamic phenomena. Measuring, modelling and analysis of temperature and thermal fields. 6. Measurements and analyses of noise and trembling. Comparison of measuring and modelling techniques. Prediction of noise levels from road, rail transport and air transport. 7. Modal analyses, comparison of measuring and modelling techniques. Analyses of measurements. 8. Design and analyses of anti-noise and anti-vibration measurements. Dynamical analysis of rail track constructions. Principles, simple dynamical model of interaction: vehicle and rail track. 9. Dynamical exertion within the rail joints, sources of vibration in dependency on frequency. Dynamical models of rail track, critical train speed. Dynamical response on vehicle, dynamical response on moving wheelset, vibration transmission between vehicle and rail track. 10. Application of advanced models by the method of final elements. Stability of rail grid and alongside strength, diagonal and alongside resistance, modelling by the method of final elements.

Exercise

26 hours, compulsory

Teacher / Lecturer

Syllabus

The exercises are presented in the following learning tasks: 1. Practical analysis of the measured data analysis in time, frequency and time-frequency plane. 2. Measurements of mechanical and fatigue material properties within transportation structures. 3. Measurements and analyses of noise and trembling, prediction of noise levels from road, rail transport and air transport. 4. Modal analyses, comparison of measuring and modelling techniques. 5. Measurements, analyses and modelling of mechanical exertion. 6. Analyses of anti-noise and anti-vibration equipments. 7. Analyses of anti-vibration equipments. 8. Static and dynamic loading of the structures samples. 9. Measuring and analysis of temperature and thermal fields. 10. Dynamical analysis of rail track constructions. Teaching jobs are presented with the active participation of students.