Relevant bibliographies by topics / Transformer substation

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  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers

Academic literature on the topic 'Transformer substation'

Author: Grafiati
Published: 4 June 2021
Last updated: 31 May 2022

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Journal articles on the topic "Transformer substation"

1

Survilo, Josifs, and Antons Kutjuns. "Operation Modes of HV/MV Substations." Scientific Journal of Riga Technical University. Power and Electrical Engineering 25, no. 25 (January 1, 2009): 81–86. http://dx.doi.org/10.2478/v10144-009-0018-y.

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Operation Modes of HV/MV SubstationsA distribution network consists of high voltage grid, medium voltage grid, and low voltage grid. Medium voltage grid is connected to high voltage grid via substations with HV/MV transformers. The substation may contain one, mostly two but sometimes even more transformers. Out of reliability and expenditure considerations the two transformer option prevail over others mentioned. For two transformer substation, there may be made choice out of several operation modes: 1) two (small) transformers, with rated power each over 0.7 of maximum substation load, permanently in operation; 2) one (big) transformer, with rated power over maximum substation load, permanently in operation and small transformer in constant cold reserve; 3) big transformer in operation in cold season, small transformer-in warm one. Considering transformer load losses and no load losses and observing transformer loading factor β it can be said that the mode 1) is less advantageous. The least power losses has the mode 3). There may be singled out yet three extra modes of two transformer substations: 4) two big transformers in permanent operation; 5) one big transformer permanently in operation and one such transformer in cold reserve; 6) two small transformers in operation in cold season of the year, in warm season-one small transformer on duty. At present mostly two transformers of equal power each are installed on substations and in operation is one of them, hence extra mode 5). When one transformer becomes faulty, it can be changed for smaller one and the third operation mode can be practiced. Extra mode 4) is unpractical in all aspects. The mode 6) has greater losses than the mode 3) and is not considered in detail. To prove the advantage of the third mode in sense of power losses, the notion of effective utilization time of power losses was introduced and it was proven that relative value of this quantity diminishes with loading factor β. The use of advantageous substation option would make it possible to save notable amount of electrical energy but smaller transformer lifetime of this option must be taken into account as well.
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2

Guo, Zheng Wei, Xiang Li Liu, Xin Ju Guo, Cun Kai Liu, Chuan Jing, Yong Li, and Min Tang. "Research on Pressure Relief Technology of Main Transformer in 220KV Indoor Substation." Applied Mechanics and Materials 873 (November 2017): 279–84. http://dx.doi.org/10.4028/www.scientific.net/amm.873.279.

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Most indoor substations adopt oil-immersed transformers as voltage transformation device. In multiple disadvantage conditions, the flammable gases formed form transformer oil may explode in transformer room. Typical 220kV main transformer room of indoor substation was researched in this paper. An correlation of pressure relief area of the 220kV mail transformer room of indoor substation were presented based on the CFD tool FLACS modeling of the general designing schemes of the State Grid Corporation of China. This research may be used as reference of the pressure relief technology for main transformer rooms of indoor substations.
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Xie, Lian Ke, Chuan Min Chen, Yang Gao, Song Tao Liu, and Li Xing Jiang. "Study on Noise Attenuation Laws and Control Methods of the Transformer." Advanced Materials Research 610-613 (December 2012): 2530–34. http://dx.doi.org/10.4028/www.scientific.net/amr.610-613.2530.

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The mechanism and characteristics of substation transformer noise are introduced in this paper. Based on the recent measured noise data of 220 kV, 500 kV and 750 kV substations, the noise source characteristics of transformer and the attenuation laws in noise transmission are analyzed. It is hoped that this paper can offer some measures and suggestions for controlling the noise of transformer substation. Lastly but not least it will provide some references for noise control during the new substation’s design and construction process.
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4

Oyeleye, Yinka, Dare Adeniran, and Emmanuel Itodo. "Design of Effective 33/11 kV Injection Substations Using International Standards." Journal of Applied Science & Process Engineering 8, no. 2 (October 31, 2021): 977–85. http://dx.doi.org/10.33736/jaspe.3625.2021.

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This research focuses on the design of an effective 33/11 kV modelled injection substation that conforms to an appropriate standard for equipment protection, the safety of personnel and power quality compliance. This is to provide a solution to one of the major problems industries in Nigeria faces due to sudden voltage fluctuations in the power system which results in damages to equipment and thus outage of power supply and damages to substation equipment. The methodology involved designing an effective 33/11 kV injection substation and associated distributive substation elements using international codes and applicable algorithms. 60% loading of transformer and additional 1.25 factor of future expansion (F.E) were considered too. The results showed that a 7.5 MVA injection transformer was designed to operate at 60%. Also, the results revealed that the injection substation would feed 15 numbers of 500 kVA distributive transformers. Each distribution substation was sized in accordance with the 7.5MVA injection transformer philosophy in this work. This research concludes that the injection substation must be loaded at 60% with an additional 1.25 F.E. in order to increase the transformer life span, and the 7.5MVA injection substation can crater for 15nos of 500 kVA distribution transformers in this research. Each substation will reliably and effectively carry the expected load demand. This research recommends that injection substations should be designed for areas with high energy requirements for reliable power quality. It recommends that substations should conform to 60% loading at the initial years of usage and that the substation design should conform to appropriate standards used in this work.
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5

Oktaviani, Wiwin A., Rahmat Septiaji, and Barlian Taufik. "Variasi Nilai Tegangan Percik Arrester Akibat Pengaruh Kapasitas Trafo Daya dan Jarak Arrester." Electrician 16, no. 2 (May 27, 2022): 146–52. http://dx.doi.org/10.23960/elc.v16n2.2235.

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The ability of each substation to withstand lightning and overvoltage affects the power distribution of the power system. In order to make the best operation of the substations, it is necessary to install Arresters which are used to protect the transformers in each substation from overvoltage caused by lightning surges. In this study, the effect of capacity on the placement distance of the arrester is discussed with 30 MVA and 60 MVA transformers. The purpose of this study was to determine the effect of the power transformer capacity of the four substations on the value of the arrester spark voltage and to obtain the optimal arrester installation technique at each substation using the Lagrange optimization method. Lagrange optimization method is used to determine the optimal distance between the arrester and the power transformer. The calculation results show that in a transformer with a capacity of 60 MVA, the Arrester spark voltage occurs at t = 20 microseconds with a voltage drop of 390.49 kV. Meanwhile, in a transformer with a capacity of 30 MVA, the Arrester spark time is at t = 13.9 microseconds with a voltage drop of 266.3 kV. This shows the capacity of the transformer that affects the magnitude of the Arrester's spark voltage and the spark time. Thus, the smaller the transformer capacity, the smaller the arrester spark time with the large voltage drop
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Borodin, M. V., S. Yu Zakharov, R. P. Belikov, and V. I. Bobrovsky. "Improvement of the technology of installation of «pillows» under the foundation of CTS 10 / 0.4 kV kiosk type." Power engineering: research, equipment, technology 23, no. 3 (July 20, 2021): 169–82. http://dx.doi.org/10.30724/1998-9903-2021-23-3-169-182.

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THE PURPOSE. To determine the number of reconstructed, newly installed and replaced 10 / 0.4 kV transformer substations, consider an improved technology for installing a "pillow" under the foundation of a kiosk-type 10 / 0.4 kV transformer substation and determine the time spent on its installation. METHODS. The article presents an analysis of data on the number of reconstructed, newly installed and replaced 10 / 0.4 kV transformer substations, an algorithm for installing an improved "pillow" under the foundation of a 10 / 0.4 kV kiosk-type transformer substation. RESULTS. In the course of the experiment on the installation of an improved "pillow" under the foundation of the CTS, the time of work was determined. The total time spent on the construction of an improved "pillow" under the foundation of a kiosk-type CTS was 580 minutes, which is just over 9.5 hours. Also the standardized time of work during the installation of an improved "pillow" under the foundation of a kiosk-type CTS Also, the standardized time for performing work during the installation of an improved "pillow" under the foundation of a kiosk- type package transformer substation has been proposed. CONCLUSIONS. The use of the data presented in the article on the number of reconstructed, newly installed and replaced 10 / 0.4 kV transformer substations will allow scientists and specialists to develop and propose new methods of reconstruction and construction technologies for various transformer substations, as well as determine the economic efficiency of new foundations for transformer substations. The technology of kiosk-type CTS foundation installation described in the article will allow not only to increase the operational characteristics of the CTS, but also ensure the fire safety of the installed equipment. The technical solution specified in the article can be used during the reconstruction and construction of a 10 / 0.4 kV kiosk-type package transformer substation. The proposed algorithm for mounting an improved "pillow" under the foundation of a kiosk-type package transformer substation is universal, since it can be used at a package transformer substation of various capacities.
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Borodin, M. V., S. Yu Zakharov, R. P. Belikov, and V. I. Bobrovsky. "Improvement of the technology of installation of «pillows» under the foundation of CTS 10 / 0.4 kV kiosk type." Power engineering: research, equipment, technology 23, no. 3 (July 20, 2021): 154–67. http://dx.doi.org/10.30724/1998-9903-2021-23-3-154-167.

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THE PURPOSE. To determine the number of reconstructed, newly installed and replaced 10 / 0.4 kV transformer substations, consider an improved technology for installing a "pillow" under the foundation of a kiosk-type 10 / 0.4 kV transformer substation and determine the time spent on its installation. METHODS. The article presents an analysis of data on the number of reconstructed, newly installed and replaced 10 / 0.4 kV transformer substations, an algorithm for installing an improved "pillow" under the foundation of a 10 / 0.4 kV kiosk-type transformer substation. RESULTS. In the course of the experiment on the installation of an improved "pillow" under the foundation of the CTS, the time of work was determined. The total time spent on the construction of an improved "pillow" under the foundation of a kiosk-type CTS was 580 minutes, which is just over 9.5 hours. Also the standardized time of work during the installation of an improved "pillow" under the foundation of a kiosk-type CTS Also, the standardized time for performing work during the installation of an improved "pillow" under the foundation of a kiosk- type package transformer substation has been proposed. CONCLUSIONS. The use of the data presented in the article on the number of reconstructed, newly installed and replaced 10 / 0.4 kV transformer substations will allow scientists and specialists to develop and propose new methods of reconstruction and construction technologies for various transformer substations, as well as determine the economic efficiency of new foundations for transformer substations. The technology of kiosk-type CTS foundation installation described in the article will allow not only to increase the operational characteristics of the CTS, but also ensure the fire safety of the installed equipment. The technical solution specified in the article can be used during the reconstruction and construction of a 10 / 0.4 kV kiosk-type package transformer substation. The proposed algorithm for mounting an improved "pillow" under the foundation of a kiosk-type package transformer substation is universal, since it can be used at a package transformer substation of various capacities.
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Abdikulova, Z. K., and E. O. Zhaparov. "СALCULATION AND CHOICE OF ELECTRIC CHART OF SUBSTATION OF THE КENTAU TRANSFORMER PLANT." BULLETIN Series of Physics & Mathematical Sciences 70, no. 2 (June 30, 2020): 141–48. http://dx.doi.org/10.51889/2020-2.1728-7901.21.

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Electric supply system in enterprises must provide with electrical supply continuity and reliability as in normal and accidental regimes, quality electro energetic, production efficiency, so in connection with these in the article there have been analyzed work regimes of substations, studied electrical net scheme for Kentau Transformer Plant’s substation, calculated plant’s loads and short circuit currents and on the base of the calculated results curried out inspection for the chosen equipment. The number of connections, reliability of power supply and prospects for development are the determining factors for choosing the electrical scheme of high-voltage switchgears. You also need to take into account the need to conduct audits and tests of switches without interruption. In our case, we have four connections: two communication lines with electrical systems and two transformers. The distribution devices of the substation of the Kentau transformer plant are connected to the transformers according to a block scheme. Electrical installations are connected to the network transformer unit or receive backup power from another substation, since in case of failure of one network, both transformers can not work with the rest of the network. Based on this, measures are proposed for the reconstruction of the substation, with the replacement of the block diagram of the switchgear with the circuit for connecting the power transformer to the switchgear by a bus bridge. Offered measurements on reconstruction of the substation by replacing block scheme of switchgears to scheme of power transformer connection with DD bus bridge. Worked out main modernization problems of the substation switchgear, done calculation and selection of distributing bus bars for arranging switchgear.
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Ying, Liming, Donghui Wang, Guodong Wang, and Wenyi Wang. "Acoustic characteristic analysis of power transformers in urban communities based on a combined finite and boundary element method." Indoor and Built Environment 29, no. 2 (June 19, 2019): 208–20. http://dx.doi.org/10.1177/1420326x19857452.

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Power transformers in substations are common sources of noise in residential areas of neighbourhoods. A quantified and visualized analysis of the power transformer acoustic characteristics is a prerequisite for the suppression of audible noise from the corresponding substation. In this study, based on a combined finite and boundary element method, a full-sized 3D power transformer multiphysics coupling model, which is aimed at realizing high accuracy and improving the computational efficiency, was developed. After validation of the numerical method using comparative tests, profile analyses in the near-field and far-field in the extended planes and three-dimensional areas of a power transformer were conducted to characterize the external acoustic field. The calculation results included the distribution of the spatial sound pressure levels of the power transformer at multiple levels in the frequency domain. These spatial sound pressure levels can be used to guide the efficient measurement of the external acoustic field of a power transformer and the soundscape planning around a substation, and the differentiated design of the sound absorption structure inside a substation.
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Tao, Xiao. "Design and Research of Optical Fiber Signal Analyzer in Embedded System Based on Big Data." Journal of Physics: Conference Series 2066, no. 1 (November 1, 2021): 012055. http://dx.doi.org/10.1088/1742-6596/2066/1/012055.

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Abstract With the advent of the era of big data, substation automation technology has reached a certain level after more than ten years of application development. In recent years, in the transformation and construction of the transmission and distribution network, a large number of substations have adopted modern technology, which has greatly improved the technological modernization of transmission and distribution and transformer construction, enhanced the reliability of transmission and distribution and transformer scheduling, and reduced the substation. The total cost of construction and the application of electronic transformers have effectively promoted the research on digital substations. In order to complete the real-time monitoring and testing of the substation system, so as to more quickly grasp the working status of the substation equipment, this paper proposes a research and design of an optical fiber signal analyzer for substation system testing. By analyzing the IEC 61850 protocol, the characteristics of the embedded system and the embedded operating system, the software modular design of the sampling value module of the signal analyzer is carried out, and the analysis of the substation configuration file SCD is designed and realized. The research results show that in practical applications, it is necessary to parse the CID files one by one, which will cause cumbersome work and easy omissions. Based on the above considerations, the SCD configuration file containing the entire site information was finally selected.
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Dissertations / Theses on the topic "Transformer substation"

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Конденко, Віктор Анатолійович. "Електропостачання станційного виробничо-побутового приміщення залізничої станції." Bachelor's thesis, КПІ ім. Ігоря Сікорського, 2021. https://ela.kpi.ua/handle/123456789/43036.

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Під час виконання дипломного проекту було проведено розрахунок навантажень цеху залізничної станції. Вибрано живлячі мережі напругою до 1 кВ та вище 1 кВ, силові трансформатори, апарати захисту та автоматики. Проведено розрахунок струмів короткого замикання. У якості спец питання було проаналізовано проблеми якості та надійності електропостачання цеху, вибрано найбільш доступне можливе технічне рішення та підібрано електричні установки з необхідними характеристиками.
During the implementation of the diploma project, the load calculations of the railway station shop were calculated. Supply networks up to 1 kV and above 1 kV, power transformers, protection devices and automation are selected. The calculation of short-circuit currents is carried out. As a special issue, the problems of quality and reliability of power supply of the shop were analyzed, the most accessible possible technical solution was selected and electrical installations with the necessary characteristics were selected.
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Pinches, Derek S. "Transient voltage distribution within the windings of a power transformer connected to a gas insulated substation." Thesis, Staffordshire University, 2004. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.412418.

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Лень, С. Ю. "Модернізація РП 10 кВ районної трансформаторної підстанції на базі мікропроцесорних засобів захисту." Master's thesis, Сумський державний університет, 2019. http://essuir.sumdu.edu.ua/handle/123456789/76685.

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В магістерській роботі розглядаються питання підвищення ефективності та надійності системи електропостачання споживачів в зоні підстанції 35/10 кВ за рахунок модернізації комплектних розподільних пристроїв 10 кВ. Проаналізована зона електропостачання, проведено розрахунок струмів короткого замикання, вибрано відповідні трансформатори струму та напруги, вимикачі, обмежувачі перенапруги. Приведено основні принципи виконання релейного захисту елементів, вимоги до пристроїв та їх будова. Обґрунтовано та вибрано елементи релейного захисту підстанції 35/10 кВ, релейний захист ліній, РЗ силового трансформатора. Проаналізовано вибір варіанту реконструкції підстанції 35/10 кВ на основі модернізації комплектних розподільних пристроїв який виконаний з урахуванням вимог до надійності електропостачання та якості електроенергії. Проведено техніко-економічне обґрунтування проекту на впровадження, обслуговування та амортизацію електрообладнання підстанції. Розглянуто питання охорони праці, визначені основні параметри при оцінці пожежної безпеки на об’єктах господарської діяльності при надзвичайних ситуаціях.
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Росюк, О. В. "Проект реконструкції КРУН-10 кВ підстанції "Промислова-4" с. Мала Дівиця Прилуцького району Чернігівської області." Master's thesis, Сумський державний університет, 2020. https://essuir.sumdu.edu.ua/handle/123456789/82368.

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Проаналізовано параметри і режими навантаження трансформаторної підстанції 35/10 кВ. Виконано модернізацію шаф відхідних ліній розподільного пристрою 10 кВ шляхом заміни масляних вимикачів на вакуумні. Вибрано інше електрообладнання цих шаф. Запропоновано захід забезпечення надійності електропостачання шляхом застосування автоматичного шунтування фази на підстанції. Обґрунтовано спосіб зниження втрат електричної енергії в мережах шляхом компенсації реактивної потужності на шинах 10 кВ районної трансформаторної підстанції.
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Зарва, В. Ю. "Розрахунок техніко-економічного обґрунтування переведення розподільчих мереж 35 кВ на 20 кВ." Master's thesis, Сумський державний університет, 2019. http://essuir.sumdu.edu.ua/handle/123456789/76099.

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Розроблено проект реконструкції підстанції на нижчий клас напруги 20 кВ, розраховані капітальні затрати на реконструкцію, проведений економічний аналіз доцільності правильного вибору перерізу провідників, обґрунтована доцільність переходу на клас напруги 20 кВ.
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Остапенко, А. С. "Модернізація системи електропостачання РТП 110/35/10 кВ «Бориспільського РП ЗАТ «Київобленерго»." Master's thesis, Сумський державний університет, 2019. http://essuir.sumdu.edu.ua/handle/123456789/76687.

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В магістерській роботі розглядаються питання підвищення ефективності та надійності системи електропостачання споживачів в зоні підстанції 110/35/10 кВ за рахунок модернізації комплектних розподільних пристроїв 10 кВ. Проаналізована зона електропостачання, проведено розрахунок струмів короткого замикання, вибрано відповідні трансформатори струму та напруги, вимикачі, обмежувачі перенапруги. Приведено основні принципи виконання релейного захисту елементів, вимоги до пристроїв та їх будова. Обґрунтовано та вибрано елементи релейного захисту підстанції 110/35/10 кВ, релейний захист ліній, РЗ силового трансформатора. Проаналізовано вибір варіанту реконструкції підстанції 110/35/10 кВ на основі модернізації комплектних розподільних пристроїв який виконаний з урахуванням вимог до надійності електропостачання та якості електроенергії. Проведено техніко-економічне обґрунтування проекту на впровадження, обслуговування та амортизацію електрообладнання підстанції. Розглянуто питання охорони праці, визначені основні параметри при оцінці пожежної безпеки на об’єктах господарської діяльності при надзвичайних ситуаціях.
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Petrovskyi, Mykhailo Vasylovych, Михаил Васильевич Петровский, Михайло Васильович Петровський, В. В. Афанасьев, А. В. Панченко, and А. В. Титаренко. "Расчет напряжения в узловых точках подстанции методом бегущих волн с применением метода подкасательной." Thesis, Видавництво СумДУ, 2010. http://essuir.sumdu.edu.ua/handle/123456789/4056.

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Курченко, Я. В. "Система керування режимами енергопостачання районних підстанцій РТП-110/35/10 кВ." Master's thesis, Сумський державний університет, 2020. https://essuir.sumdu.edu.ua/handle/123456789/81484.

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Робота присвячена розробці системи керування режимами енергопостачання районних підстанцій РТП-110/35/10 кВ на базі SINAUT LSA фірми SIЕMENS. Розглянуто призначення, пристрій і роботу силової підстанції загальнопромислового призначення, системи обліку і контролю, інформаційне забезпечення підстанції. Проведено розрахунок мережі 10 кВ. Вибрано мікропроцесорну систему управління на основі SIEMENS.
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Коваленко, А. М. "Автоматизована система контролю та ліквідації пожежонебезпечних ситуацій на трансформаторній підстанції." Master's thesis, Сумський державний університет, 2020. https://essuir.sumdu.edu.ua/handle/123456789/81479.

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Робота присвячена розробці автоматизованої системи контролю та ліквідації пожежонебезпечних ситуацій на трансформаторній підстанції з використанням системи управління, що розробляється, для створення на її базі систем доступу, систем відеоспостереження і ін. Універсальність такого методу широко представлена в даній роботі. Простота в управлінні робить цю систему не тільки вигідною з боку економічної точки зору, але і достатньо простій в обслуговуванні і ремонті.
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Михайлик, Е. А. "Розрахунок параметрів та випробування низьковольтного обладнання двотрансформаторної підстанції." Master's thesis, Сумський державний університет, 2018. http://essuir.sumdu.edu.ua/handle/123456789/71305.

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Розроблено проект двотрансформаторної підстанції. Були вибрані кабелі, силові трансформатори, трансформатори струму, автоматичні вимикачі, роз’єднувачі. Для здійснення пуско-налагоджувальних робіт були вибрані методики виконання вимірювань та здійснено випробування електрообладнання із результатами вимірювання. Під час виконання робіт були дотримані правила техніки безпеки, правила технічної експлуатації, виконані вимоги з охорони праці. Визначено витрати на виконання монтажних та пуско-налагоджувальних робіт.
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Books on the topic "Transformer substation"

1

National Association of Corrosion Engineers. Maintenance painting of electrical substation apparatus includingflow coating of transformer radiators. Houston: NACE, 1997.

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National Association of Corrosion Engineers. Maintenance painting of electrical substation apparatus including flow coating of transformer radiators. Houston: NACE, 1995.

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Masleeva, Ol'ga, German Pachurin, Aleksandr Sevost'yanov, and Anatoliy Fitasov. Safe operation of power supply systems. ru: INFRA-M Academic Publishing LLC., 2022. http://dx.doi.org/10.12737/1029790.

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The main purpose of the textbook is to identify dangerous and harmful production factors during the operation of electrical equipment of the main step-down substations and transformer substations. Specific measures are proposed to reduce their negative impact on service personnel. Meets the requirements of the federal state educational standards of higher education of the latest generation. For bachelors and masters of full-time and part-time education in the areas of training 13.03.02 and 13.04.02 "Electric power and electrical engineering". It can be used by teachers, engineers and specialists in the operation of industrial equipment and the safe organization of work in production, as well as by a wide range of readers interested in the problems of human life safety.
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National Seminar, Large Power Transformers - Modern Trends in Aplication, Testing, and Condition Monitoring (2002 New Delhi, India). National Seminar, Large Power Transformers - Modern Trends in Application, Testing, and Condition Monitoring, 14-15 November, 2002, New Delhi: Proceedings. Edited by Mathur G. N, Narasimhan S. L, Prasher V. K, and India. Central Board of Irrigation and Power. New Delhi: Central Board of Irrigation and Power, 2002.

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Marzecki, Jerzy. Metody badania rozwoju i wyznaczania optymalnego rozmieszczenia stacji transformatorowo-rozdzielczych 110 kV/SN w aglomeracji miejskiej. Warszawa: Oficyna Wydawnicza Politechniki Warszawskiej, 1995.

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[Protest of BIA solicitation for substation transformers]. Washington, D.C: [U.S. General Accounting Office, 1995.

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Large Power Transformers in the U. S. Electric Grid: Elements, Issues, and Substation Security. Nova Science Publishers, Incorporated, 2014.

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Parker, Philip M. The 2007-2012 World Outlook for Dry-Type Secondary Unit Substation Power Transformers. ICON Group International, Inc., 2006.

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Parker, Philip M. The 2007-2012 World Outlook for Liquid-Immersed Secondary Unit Substation Power Transformers. ICON Group International, Inc., 2006.

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The 2006-2011 World Outlook for Dry-Type Secondary Unit Substation Power Transformers. Icon Group International, Inc., 2005.

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Book chapters on the topic "Transformer substation"

1

Wu, Jia, Hong-zhen Yang, Hong-fei Xu, Si-ri Pang, Huan-yuan Li, and Wang Luo. "Attribute Segmentation for Transformer Substation Using Convolutional Network." In Advances in Intelligent Systems and Computing, 679–86. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-30874-6_63.

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de Melo, Cristiano G., Renata Maria Cardoso R. de Souza, and Liliane R. B. Salgado. "Assessing Reliability of Substation Spare Current Transformer System." In Neural Information Processing, 660–67. Berlin, Heidelberg: Springer Berlin Heidelberg, 2012. http://dx.doi.org/10.1007/978-3-642-34478-7_80.

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He, Guangceng, and Yushan Dong. "The Transformer Substation Scenario Modeling and Visual Perception Visualization System." In Data Processing Techniques and Applications for Cyber-Physical Systems (DPTA 2019), 1559–65. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-1468-5_185.

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Wu, Jia, Dan Su, Hong-fei Xu, Si-ri Pang, and Wang Luo. "Attribute Classification for Transformer Substation Based on Deep Convolutional Network." In Advances in Intelligent Systems and Computing, 669–77. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-30874-6_62.

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Huang, Lichao, and Jianchao Bi. "A New Embedded-Based Relay Protection System of Transformer Substation." In Lecture Notes in Electrical Engineering, 283–89. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-2386-6_37.

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Klimash, Vladimir S., and Bekhruz D. Tabarov. "Application of a Reactor-Thyristor Device at a Transformer Substation." In Current Problems and Ways of Industry Development: Equipment and Technologies, 614–21. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-69421-0_65.

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Zhang, Fang, Xin Dong, Minghui Liu, and Chengchang Liu. "Image Fusion Method for Transformer Substation Based on NSCT and Visual Saliency." In Human Centered Computing, 75–83. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-70626-5_8.

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Lv, Ling, Linke Zhang, and Li Wang. "Study on the Effectiveness of Transformer Equivalent to Point Source in Substation." In Vibration Engineering for a Sustainable Future, 311–18. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-48153-7_40.

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Li, Hui, Hao Zhang, and Daogang Peng. "Research and Application of FlexRay High-Speed Bus on Transformer Substation Automation System." In Web Information Systems and Mining, 263–70. Berlin, Heidelberg: Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-16515-3_33.

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Chen, Hui-Ying, Zhi-Peng Wang, and Mu-Qin Tian. "Research to Prevent the Anti-charging Incident of the Voltage Transformer in the Substation." In Communications in Computer and Information Science, 135–40. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-24282-3_19.

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Conference papers on the topic "Transformer substation"

1

Villot, A. V., A. H. Zapata, and E. M. Gurumeta. "Environmental transformer substation." In 18th International Conference and Exhibition on Electricity Distribution (CIRED 2005). IEE, 2005. http://dx.doi.org/10.1049/cp:20050931.

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Zhang, Yingjie, Erkui Chen, Zhen Li, Pingjie Guo, and Xiaoping Liang. "Transformer Substation Life Cycle Prediction." In 2017 5th International Conference on Mechatronics, Materials, Chemistry and Computer Engineering (ICMMCCE 2017). Paris, France: Atlantis Press, 2017. http://dx.doi.org/10.2991/icmmcce-17.2017.66.

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Cochran, R. S. "Seismic Base Isolation of a High Voltage Transformer." In Electrical Transmission and Substation Structures 2015. Reston, VA: American Society of Civil Engineers, 2015. http://dx.doi.org/10.1061/9780784479414.033.

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Qiang Gao and Hongli Wang. "WSN design in high-voltage transformer substation." In 2008 7th World Congress on Intelligent Control and Automation. IEEE, 2008. http://dx.doi.org/10.1109/wcica.2008.4593947.

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Xinghui, Duan, Hou Chaojun, Tian Junjie, Zhao Yunfeng, Wang Jianwei, Kang Lisheng, and Yang Gengzhu. "Study on Transformer Fault for 220kV Substation." In 2019 IEEE 4th Advanced Information Technology, Electronic and Automation Control Conference (IAEAC). IEEE, 2019. http://dx.doi.org/10.1109/iaeac47372.2019.8997894.

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Zhang, Daming, Kazi Saiful Alam, and Faz Rahman. "Study on medium-frequency transformer isolated substation." In 2015 IEEE PES Asia-Pacific Power and Energy Engineering Conference (APPEEC). IEEE, 2015. http://dx.doi.org/10.1109/appeec.2015.7381055.

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Wu, Dong-xun, Miao Wang, and Ji-wu Liu. "Main Transformer Fault Analysis in 220kV Substation." In 2019 IEEE 3rd Information Technology, Networking, Electronic and Automation Control Conference (ITNEC). IEEE, 2019. http://dx.doi.org/10.1109/itnec.2019.8729215.

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Ravi, Nanthiine Nair, Sulfeeza Mohd Drus, Prajindra Sankar Krishnan, and Nur Laila Abdul Ghani. "Substation Transformer Failure Analysis Through Text Mining." In 2019 IEEE 9th Symposium on Computer Applications & Industrial Electronics (ISCAIE). IEEE, 2019. http://dx.doi.org/10.1109/iscaie.2019.8743719.

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Liu, Zhengdao, Xiyuan Li, and Qiqi Wang. "On the Automation System of Transformer Substation." In 2015 3rd International Conference on Mechanical Engineering and Intelligent Systems. Paris, France: Atlantis Press, 2015. http://dx.doi.org/10.2991/icmeis-15.2015.142.

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Emin, Z. "Voltage transformer ferroresonance in 275 kV substation." In 11th International Symposium on High-Voltage Engineering (ISH 99). IEE, 1999. http://dx.doi.org/10.1049/cp:19990562.

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