Letzte Änderung : 17.01.2025 09:59:02   


Output

Code: 216750
Module title: High Voltage Engineering
Version: 1.0 (06/2016)
Last update: 10.03.2022 08:07:12
Person responsible for content: Prof. Dr. techn. Kornhuber, Stefan
S.Kornhuber@hszg.de


Semester according to timetable: SoSe+WiSe (summer and winter semester)
Module level:Bachelor/Diplom
Duration:1 semester
Language of Instruction:English
Place where the module will be offered:Zittau

ECTS Credits: 5
Student workload (in hours): 150

Number of hours of teaching:
total
subdivided into
5
3.5
Lecture
0
Seminar/Exercise
1.5
Laboratory work
0
Other
Self study time (in hours):
sum

94


Learning and teaching methods:Communication of knowledge/Expertise takes the form of lectures and laboratory work.


Exam(s)
Assessments Major oral exam 20 min 60.0%
Major exam (laboratory work)
 - 
40.0%



Syllabus plan/Content: • High Voltage Technology in Power System and Industry
• High Voltage Test and Measurement Techniques
• Electrical Field Theory in Single and Multiple Insulation Materials (without Space Charges)
• Discharge Theory in Gases
• Lightning Theory
• Flashover Theory at Solid and Gaseous Interfaces
• Discharge Theory in Fluids and Solids
• Basics of Partial Discharges and Measurement

Laboratory (each 4 h):
• Discharges in Gases at AC/DC
• Discharges in Gases at Surge Voltage
• Flashover at Insulators
• Partial Discharge Measurement

Learning Goals
Subject-specific skills and competences: • Usage of Field Theory combined with the Basics of High Voltage Discharge Behaviour for Design of Components
• Usage of Test Systems and Measurement Systems for Test and Diagnostic
• Group work in the High Voltage Laboratory
• Preparation of Laboratory Protocols with a first Scientific Discussion and Evaluation
Generic competences (Personal and key skills): nachreichen

Prerequisites: • Fundamentals of Electrical Engineering (including (Quasi) Stationary Electrical Field Theory)
• Physics (Atomic Model, Kinetic, ...)
• Mathematics (Integration, Differentiation, Partial Different Equation)

Literature: - Philippow, E.: Taschenbuch Elektrotechnik, Bd. 6: Systeme der Elektroenergietechnik
- Küchler, A.: Hochspannungstechnik. Springer Verlag
- Kind, D.; Feser, K.: Hochspannungsversuchstechnik, Verlag Vieweg Braunschweig-Wiesbaden
- Beyer, M. u.a.: Hochspannungstechnik, Springer Verlag Berlin-Heidelberg