English Original Reader for Technical Students. Power transformers: short-circuit testing, monitoring systems (Smart Grid). Александр Юрьевич Хренников
electrical network.
3. Algorithm of the operation of the information-measuring system for continuous monitoring of the state of the windings of power transformers.
4. Metrological parameters of the device for continuous monitoring of the state of windings of power transformers.
5. Quick-working protection during the operation of the device for continuous monitoring of the state of the windings of power transformers.
6. Registration of primary and secondary currents and voltages of a power transformer during operation of the device for continuous monitoring of the state of power transformer windings.
References
[1] Голубев А. П. Английский язык для технических специальностей. English for Technical Colleges: учебник для студ. Учреждений СПО/ А. П. Голубев, А. П. Коржавый, И. Б. Смирнова. – М.: Издательство «Академия», 2014. – 208 с.
[2] Khrennikov, A. Yu., Shlegel, O. A., Lurie, S. I., (1996). Control and protection device of transformer windings against deformation at short-circuits in service. Patent of Russian Federation, № 2063050. Bulletin № 18.
[3] Т. Н., Гращенкова Г. Н., Зудилова Е. Н., Смирнова Л. И., Английский язык. Менеджмент. Учебно-методическое пособие, – М.: ЛИТРЕС, 2018, с. 65.
[4]Khrennikov, A. Yu. Control and protection device of transformer windings against deformation at short circuits”, Patent of Russian Federation, № 2136099. 1999,Bulletin № 24.
[5] Т. Н., Зайцева С. Е., Смирнова Е. В., Тинигина Л. А., English reader for technical students Английский язык, Учебно-методическое пособие, – М.: ЛИТРЕС, 2018, с. 66.
[6] Khrennikov, A. Yu., (1998). Measuring device of the inductive transformer short-circuit impedance”, Patent of Russian Federation, № 96110718 А.
Луговая А. Л. Английский язык для студентов энергетических специальностей: Учебное пособие/А. Л. Луговая. – М.: Высш. шк., 2009. – 150 с.
[7] Fogelberg, T., Girgis, R. S., (1994). ABB power transformers – a result of merging different technologies with prospects for significant future advancements”, International Simposium "Electrotechnics – 2010", Moscow, vol. 1, 56–59.
[8] Balakrishnan, V. A study of short-circuits in large power transformers, Electrical India, 1989, Vol. XXIX, № 4, 87–91.
[9] Бухарова Г. П. Техническое чтение для энергетиков: Методическое пособие по английскому языку для студентов 1, 2 курсов энергетических специальностей дневной и заочной форм обучения / сост. Г. П. Бухарова. – Ульяновск: УлГТУ, 2004–112 с.
[10] Lech, W., Tyminski, L. Detecting transformer winding damage – the low voltage impulse method, Electrical Review, 1966, № 18, 23–27.
[11]Галиахметова А. Т., Лутфуллина Г. Ф. English for energy industry. Английский язык для энергетических специальностей: Учебное пособие /, А. Т. Галиахметова, Г. Ф. Лутфуллина. – Казан. гос. энерг. ун-т, 2014–152 с.
[12] Malewski, R., Khrennikov, A. Yu., Shlegel, O. A., Dolgopolov, A. G. (1995). Monitoring of Winding Displacements in HV Transformers in Service, Reports of CIGRE Working Group 33.03. Italy, Padua.
[13] Khrennikov, A. Yu., (1999). Short-circuit performance of power transformers. Test experience at Samaraenergo Co and at Power Testing Station in Togliatti, including fault diagnostics, Reports of CIGRE Study Commitee 12 Transformers. Hungary, Budapest.
[14] Трухан, Е. В. Английский язык для энергетиков: учеб. пособие /Е. В. Трухан, О. Н. Кобяк. Минск: Выш. шк., 2011–191 с.
[15] Khrennikov, A. Yu., (2000). Power transformer's fault diagnostics at Samaraenergo Co, including FRA/LVI method, Reports from School of Math. and System Engineering, Vaxjo University, Sweden, № 43, ISSN 1400–1942.
[16] Khrennikov, A. Yu., (2005). Short-circuit performance of power transformers. Transformer testing experience for reliability’s increase of electric power supply, Reports of CIGRE Colloquium, Comitee A2., Moscow.
[17] Khrennikov, A. Yu., Goldshtein, V. G., Skladchikov, A. A., (2010). The analysis of a condition of overhead lines of power transmission 6–500 кV, Power plants, № 5.
[18] Khrennikov, A. Yu. (2012). New «intellectual networks» (Smart Grid) for detecting electrical equipment faults, defects and weaknesses. Smart Grid and Renewable Energy, February, Volume 3, Issue 1, 159–164. http://www.scirp.org/journal/sgre/
[19] Khrennikov, A. Yu., (2013). Smart Grid technologies for Detecting Electrical Equipment Faults, Defects and Weaknesses. Workshop on Mathematical Modelling of Wave Phenomena with applications in the power industry, Linnaeus University, Växjö.
[20] Khrennikov, A.Yu., Mazhurin, R. V., Radin P. S., (2014). Infra-red and ultraviolet control, LVI-testing, partial discharges and another diagnostic methods for detection of electrical equipment’s faults, defects. Journal of Multidisciplinary Engineering Science and Technology (JMEST) (ISSN: 3159–0040), Volume 1, Issue 4, 184–189. http://www.jmest.org/vol-1-issue-4-november-2014/
Chapter 2. Diagnostics and Transformer Testing Experience by LVI/FRA Methods
Abstract
LVI-testing, FRA and short-circuit inductive reactance measurements are sensitive to detecting such typical transformers winding faults as buckling, axial shift and other. It is given an algorithm of the frequency spectral analysis. The examples of diagnostics by LVI-testing, frequency spectral analysis of capacity range from 20 to 400 MVA and voltage range from 35 to 220 kV transformers and autotransformers are showed in service and during short-circuit testing. The studies are carried out for dependency of LVI oscillograms and signal spectra of power transformer winding of one type manufacturing.
Keywords: Short-circuit, Testing Laboratory, Winding fault, Electrodynamic deformation, Low voltage impulse method
2.1.