Course detail
Design of Robotic Workplaces
FSI-ENR Acad. year: 2023/2024 Winter semester
The main focus of the course is to introduce students to the basics of designing robotic cells for various applications or technologies. The main emphasis is placed on the use of simulation tools (e.g. Siemens Process Simulate, Abb RobotStudio) for verification of the technological process and determination of the line timing at the level of time-based simulation or event-based simulation. Furthermore, students will learn the basics of currently available industrial robot programming options.
Supervisor
Learning outcomes of the course unit
Students will gain a comprehensive overview of the possibilities and requirements for the design of robotic cells. Based on the experience gained, they will be able to work independently in the design of single robot workstations for typical applications in industry (handling, palletizing, welding, machining, etc.). They will also gain a comprehensive and practically oriented overview of the possibilities of programming industrial robots.
Prerequisites
Successful completion of Construction of Production Machines and Robots (6SR), Electrical and Electronic Engineering (6EE) and basic knowledge of programming.
Planned learning activities and teaching methods
The course is taught in the form of lectures focused on the requirements and solutions for the design of robotic cells for various applications and exercises focused on the practical applicability of the acquired knowledge. The acquired knowledge will be verified in the exercises on industrial robots KUKA, ABB. If possible, lectures by experts from practice and excursions to companies engaged in activities related to the subject content will be organized for students.
Assesment methods and criteria linked to learning outcomes
A condition for the award of credit is at least 80% participation in the exercises and the preparation of a semester project on a prescribed topic. Specifications for the preparation of individual projects will be specified at the beginning of the semester. The credit is worth 40 points. The examination is carried out in oral form and the student can obtain 60points.
The evaluation of the exam result is determined by the ECTS grading scale.
Language of instruction
Czech
Aims
The aim of the course is to familiarize students with the methodology of designing small robotic cells for typical applications and technologies used in industry. Another objective is to provide a practical introduction to the basics of programming industrial robots, including the use of simulation tools for off-line programming.
Specification of controlled education, way of implementation and compensation for absences
Exercises are compulsory. Justified absence may be made up by consultation. The student will present the semester project for credit.
The study programmes with the given course
Programme B-STR-P: Engineering, Bachelor's
branch KSB: Quality, Reliability and Safety, 5 credits, compulsory-optional
Type of course unit
Lecture
26 hours, optionally
Syllabus
1. Technological possibilities of industrial robot deployment
2. Peripheries of industrial robots
3. Automatic end effector exchange
4. End effectors
5. End effector collision protection
6. Handling operations – design of mechanical grippers
7. Handling operations – design of vacuum grippers
8. Welding operations
9. Additive technologies (painting, bonding, 3D printing)
10. Machining
11. Robotic workplace safety
12. Robotic workplace control systems for individual projects – consultation and verification of procedures
Computer-assisted exercise
26 hours, compulsory
Syllabus
1. Introduction to off-line programming ABB Robot Studio
2. Introduction to off-line programming ABB Robot Studio
3. Introduction to off-line programming ABB Robot Studio
4. Approaches to robotic workplace design I
5. Approaches to Robotic Workstation Design II
6. Off-line programming of ABB robots I
7. Off-line programming of ABB II robots
8. On-line programming of KUKA I robots
9. On-line programming of KUKA II robots
10. Individual project solutions – consultation and verification of procedures
11. Individual project solutions – consultation and verification of procedures
12. Individual project management – consultation and verification of procedures
13. Individual project management – consultation and verification of procedures