Course detail
Electromechanical Machine Systems
FSI-5ES Acad. year: 2025/2026 Winter semester
The subject provides students with an interpretation of electromechanical machine systems. The synergy of the machine (mechanical) and electrical parts is shown. The student will thus understand two systems that work together as a whole, and which are an essential part of all today's modern constructions of machine systems. Everything is demonstrated using examples, and the student thus learns the basic concepts of this system.
Language of instruction
Czech
Number of ECTS credits
6
Supervisor
Entry knowledge
• material sciences (choice of materials),
• construction (drawing documentation),
• technical mechanics.
Rules for evaluation and completion of the course
The subject is completed by taking an exam after the credit has been previously awarded. The credit confirms that the student actively participated in the work during the semester and obtained at least 50 points out of the maximum number of 100 points. The point assessment criterion is the degree of ability to correctly solve assigned tasks independently. Points from exercises do not transfer to the exam.
The exam determines the comprehensive mastery of the material defined in the subject card, especially the ability to apply the acquired knowledge independently and in a creative way. The degree of mastery of the issue is evaluated in the range of 0 to 100 points. The student must obtain at least 50 points out of a maximum of 100 points.
The exam has a written and an oral part. The written part of the exam is mandatory for all students. It consists of four tasks. The oral part of the exam is optional.
Lectures: participation is voluntary.
Exercise: participation is mandatory and controlled by the teacher. They allow a maximum of two absences. In case of long-term absence, compensation for missed lessons is the responsibility of the subject guarantor.
Aims
Graduates will be able to design electromechanical machine systems that work on the principle of linear, rotary and combined movements, including mechanical and electrical parts.
Furthermore, they will be able to apply these basic movements to more complex machinery. In addition to the mechanical part of these systems, they will be able to design the electrical part.
The study programmes with the given course
Programme B-STR-P: Engineering, Bachelor's
specialization KSB: Quality, Reliability and Safety, compulsory-optional
Programme B-STR-P: Engineering, Bachelor's
specialization SSZ: Machine and Equipment Construction, compulsory-optional
Type of course unit
Lecture
26 hours, optionally
Syllabus
1.Structure of electromechanical machine systems, examples of building elements, general principles.
2. Electromechanical systems for linear motion, morphology, design principles.
3. Electromechanical systems for rotary motion, morphology, design principles.
4. Electromechanical systems for combined motion, morphology, design principles.
5. CNC machine tool spindle, morphology, design principles.
6. Manipulation electromechanical systems of production machines and robots morphology, principles for design.
7. Electrical aspects of electromechanical actuators, a comprehensive approach between mechanical and electrical parts.
8. Definition of requirements for the electrical part, definition of input and output parameters, influence of the environment.
9. Power supply system of electrical elements, principles for choosing cabling, fuses.
10. Procedure for designing the electrical equipment of machine systems. 11. Integration of the control parts of the electromechanical machine system.
12. Functional safety of machine systems.
13. Case studies of complex electromechanical systems. Summary of the material discussed.
Exercise
39 hours, compulsory
Syllabus
1. Structure of electromechanical machine systems, decomposition, interconnection and principles for mechanical and electrical parts.
2. Electromechanical systems for linear motion, calculation.
3. Electromechanical systems for rotary motion, calculation.
4. Electromechanical systems for combined motion, calculation.
5. CNC machine tool spindle, calculation for milling and turning.
6. Manipulation electromechanical systems of production machines and robots, design of the size of the robot for handling the workpiece and the tool.
7. Electrical aspects of electromechanical actuators, design.
8. Definition of requirements for the electrical part, determination of the input power of the movement axes of the machine, robot and production system.
9. Power supply system of electrical elements, practical principles for selection.
10. Procedure for designing the electrical equipment of machine systems, application to specific units.
11. Integration of the control parts of the electromechanical machine system, practical principles.
12. Functional safety of machine systems, demonstration of calculation of not simple systems.
13. Case studies of complex electromechanical systems, commentary and demonstration of their creation.