Automation and Control (FSI-IAR)

Academic year 2021/2022
Supervisor: Ing. Jiří Hejčík, Ph.D.  
Supervising institute: ÚAI all courses guaranted by this institute
Teaching language: Czech
Aims of the course unit:
Students will have an overall view of methods and devices for measurement, automation and regulation of basic parameters of environment in heating, ventilation and air-condition and their practical utilizing in practice.
Learning outcomes and competences:
General overview of methods, principles and devices for measurement, automation and regulation of heating, ventilation and air-condition of buildings and applying the acquired knowledge for solving a specific assignment.
Prerequisites:
Basic knowledge from physics and mathematics, introduction from theory automatic control, basic knowledge of problems of heating and ventilation in buildings
Course contents:
The course is concerned with problems of measurement, automation and regulation in branches of heating ventilation and air-condition. Attention is paid to individual parts of real control loop. The students are acquainted with sensors and measuring devices, regulators and actors in control systems used for regulation of temperature, humidity, heating, ventilation and air-condition of buildings. The course is also focused on the equipment starting from elementary regulators to modern systems of integrated automation of buildings.
Teaching methods and criteria:
The course is taught through lectures explaining the basic principles and theory of the discipline. Teaching is suplemented by practical laboratory work.
Assesment methods and criteria linked to learning outcomes:
Course - unit credit: participation in laboratory exercises and presentation of work results. Resulting evaluation up to 10 points is included in the result of the examination, provided credit is to obtain at least 6 points.
Exam: written test of all problems the subject (0 - 40 points). Total the student receives up to 50 points, condition passing of the exam at least 26 points. Classification: excellent (46-50 points), very good (41-45 points), good (36-40 points), satisfactory (31-35 points), sufficient (26-30 points), failed (0-25 points).
Controlled participation in lessons:
Attendance in laboratory exercises is monitored . An absence is compensated by solving individual assignments.
Type of course unit:
    Lecture  13 × 2 hrs. optionally                  
    Laboratory exercise  13 × 1 hrs. compulsory                  
Course curriculum:
    Lecture 1. Introduction, importance of automation, control loop
2. Feedback – measuring circuit, properties of measuring devices, new definitions of SI units 2019
3. Principles, methods and devices for measurement basic parameters of environment
4. Unified signals in control loop, amplifiers
5. Basics of automation, types of control modes and controllers
6. Continuous and discontinuous control in heating and ventilation control
7. Compact controllers and programmable logic controllers
8. Actuators in heating, ventilation and air-condition
9. Methods of solving simple control application in heating and ventilation technique
10.Using PC for measurement and control, devices for visualization and remote measurement and control by means of the Internet
11. Basics of integral systems of automation building – others monitored functions in a building
12. Modern systems – intelligent building, smart city, IoT.
13. Practical presentation of modern system of selected company
    Laboratory exercise 1. Static and dynamic characteristics of devices
2. Measurement of basic quantities in Environmental Engineering
3. Unified signals in control loop, converters
4. Elementary control loops
5. Measurement automation and using PC for control
6. Samples of software for measurement and control support; SMART systems
7. The final exercise, evaluation, credit
Literature - fundamental:
1. De Silva, C., Control, Sensors and Actuators : New Jersey : Prentice Hall 1989.
2. Levine, s., W. et al, The Control Handbook : Salem : CRC Press, Inc. 1996.
3. Toman, K., Kunc, J., Systémová technika budov : Praha : FCC Public, 1998.
4. Székyová,M.; Ferstl, K.; Nový, R. Větrání a klimatizace : Bratislava : Jaga group 2006. 360s. ISBN 80-8076-037-3.
5. Valeš,M.; Inteligentní dům : Brno : ERA group 2006. 123 s. ISBN 80-7366-062-8.
6. BAŠTA, J.; Regulace v technice prostředí staveb. :Praha: Česká technika – nakladatelství ČVUT v Praze, 2014 194 s. ISBN 978-80-01-05455-0.
Literature - recommended:
1. Jokl, M., Měření a automatická regulace systémů : Praha : Ediční středisko ČVUT v Praze 1990.
2. Bašta, J., Regulace vytápění : Praha : Vydavatelství ČVUT v Praze 2002.
3. Doubrava, J., a kol., Regulace vytápění : Praha : Společnost pro techniku prostředí 2000.
4. Székyová,M.; Ferstl, K.; Nový, R. Větrání a klimatizace : Bratislava : Jaga group 2006. 360s. ISBN 80-8076-037-3.
5. Valeš,M.; Inteligentní dům : Brno : ERA group 2006. 123 s. ISBN 80-7366-062-8.
6. VALTER, J.: Regulace v praxi aneb jak to dělám já. :Praha: BEN-technická literatura Praha, 2010. 176 s. ISBN 80-7366-062-8.
7. BAŠTA, J.; Regulace v technice prostředí staveb. :Praha: Česká technika – nakladatelství ČVUT v Praze, 2014 194 s. ISBN 978-80-01-05455-0.
The study programmes with the given course:
Programme Study form Branch Spec. Final classification   Course-unit credits     Obligation     Level     Year     Semester  
N-ETI-P full-time study TEP Environmental Engineering -- Cr,Ex 4 Compulsory 2 2 S