Area of study: 13.04.02 Electric power and electrical engineering
Major: High Voltage Engineering and Electrophysics
Duration: 2 years
Start: September 1
Admission: open
Language : Russian
To minimise losses during the transportation of electrical energy, unified energy systems around the world use electrical equipment and power transmission lines running at voltages of hundreds of thousands of volts. As a result, professionals with a background in high voltage engineering and electrophysics are in high demand for positions in the electric power industry's design, construction, installation, and maintenance organizations.
This program's graduates can build and design new electrical installations, construct them competently for long-term usage, and ensure the operational reliability of high-voltage equipment and power transmission lines. The accident rate of electrical installations and power supply interruptions to electric energy consumers can be greatly decreased by strengthening the industry with expertly trained individuals who have thoroughly mastered the secrets and achievements of high-voltage technology and electrophysics.
Graduates are in demand by generating, electric grid, energy repair, energy sales, design and engineering enterprises all over the world
- Calculation of electromagnetic fields in the electric power industry
- Computer simulation in high-voltage power engineering
- Computer, network and information technologies
- Fundamentals of design in high-voltage electric power industry
- High voltage electrical equipment and its operation
- High voltage testing and electrophysical installations
- High-voltage electrical technologies
- High-voltage experiments and mathematical methods of processing their results
- Improving the reliability of high-voltage electrical equipment operation
- Innovative technologies in high-voltage electric power industry
- Insulation of electrical equipment and the basics of its design
- Lightning protection
- Modern issues of electrical and power engineering
- Over-voltage and isolation coordination
- Random processes in the electric power industry
- Regulation of electrical strength of high-voltage equipment
- Research methodology
- Special issues of high-voltage electric power industry
- Technical means of diagnostics of high voltage electrical equipment
- Vladimir Kachesov
- Alexander Ovsyannikov
- Andrey Trofimov
- Yury Tselebrovsky
- Nikolay Sheglov
- Investigation of internal overvoltages in high voltage and extra high voltage transformers with short-line fault
- Research and development of measures to improve the reliability of operation and efficiency of gas-insulated high voltage lines
- Investigation of the switching capacity of vacuum circuit breakers installed in various purposes networks
- Investigation of the properties of surface electromagnetic waves
- Investigation of the operating conditions of switching devices in networks with effective neutral grounding
- Investigation of the effectiveness of technical measures to prevent ferroresonance in 6-35 kV networks
- Simulation of higher harmonic components in networks with frequency converters
- Simulation of higher harmonic components in the supply chains of metallurgical enterprises
- Revision of the concept of protection of substation electrical equipment from atmospheric overvoltage
- Determination of the suspension location of a self-supporting optical cable on the supports of a double-chain power line
- Determination of the required electrical characteristics of switching and protective devices to ensure reliable operation of high-voltage electric motors
- Features of combined switches operation in various purposes networks
- Evaluation of changes in the characteristics of high voltage overhead lines by measuring the magnetic field
- Assessment of the technical condition of power transformer equipment
- Assessment of the technical condition of power transformer equipment
- Development of a hardware and software complex for monitoring lightning overvoltages on high-voltage overhead lines
- Development of a test procedure for 6-35 kV voltage transformers for resistance to ferroresonance
- Development of a lightning direction finding system in the Novosibirsk Oblast
- Development of technical measures to protect high-voltage cables from high-frequency overvoltages
- Development of technical requirements for the creation of ultra-compact overhead lines with a voltage of 110 and 220 kV
- Development of a technical proposal for dry end couplings for cables with cross-linked polyethylene insulation
- Development of a technological device for producing cold plasma based on a Tesla transformer
- Electrical safety systems for the auxiliaries of a high voltage substation network
- Formation of requirements for determining the suspension location of an optical self-supporting cable on a high-voltage overhead line
- Experimental and theoretical study of the antiresonance properties of voltage transformers
- Admission starts on June 20
- Admission stops on July 10
- The documents are sent to the university in electronic form through the NSTU Enrolee Personal Account. When submitting an application for admission in electronic form, the documents attached to it are submitted (sent) to the NSTU admission committee in the form of their electronic images (paper documents converted into electronic form by scanning or photographing with the provision of machine-readable recognition of its details)