AUTOMATION OF THE SYSTEM OF PROTECTION OF THE POWER TRANSFORMER

The article analyzes the main types of damage to power transformers, substantiates the requirements for modern multifunctional microprocessor protection, proposed the technical implementation of the automation of protection of a power transformer.

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A Solid-State On-Load Tap Changer for the Power Transformers of 10—0.4 kV Distribution Networks

Vestnik MEI ◽

10.24160/1993-6982-2020-3-82-90 ◽

2020 ◽

Vol 6 (6) ◽

pp. 82-90

Author(s):

Dmitriy I. Panfilov ◽

◽

Mikhail G. Astashev ◽

Aleksandr V. Gorchakov ◽

◽

...

Keyword(s):

Solid State ◽

Physical Model ◽

High Speed ◽

Power Transformer ◽

Voltage Control ◽

Power Transformers ◽

Control Algorithms ◽

Load Voltage ◽

Tap Changer ◽

Load Tap Changer

The specific features relating to voltage control of power transformers at distribution network transformer substations are considered. An approach to implementing high-speed on-load voltage control of serially produced 10/0.4 kV power transformers by using a solid-state on-load tap changer (SOLTC) is presented. An example of the SOLTC circuit solution on the basis of thyristor switches is given. On-load voltage control algorithms for power transformers equipped with SOLTC that ensure high reliability and high-speed operation are proposed. The SOLTC performance and the operability of the suggested voltage control algorithms were studied by simulation in the Matlab/Simulink environment and by experiments on the SOLTC physical model. The structure and peculiarities of the used simulation Matlab model are described. The SOLTC physical model design and its parameters are presented. The results obtained from the simulating the SOLTC operation on the Matlab model and from the experiments on the SOLTS physical model jointly with a power transformer under different loads and with using different control algorithms are given. An analysis of the experimental study results has shown the soundness of the adopted technical solutions. It has been demonstrated that the use of an SOLTC ensures high-speed voltage control, high efficiency and reliability of its operation, and arcless switching of the power transformer regulating taps without load voltage and current interruption. By using the SOLTC operation algorithms it is possible to perform individual phase voltage regulation in a three-phase 0.4 kV distribution network. The possibility of integrating SOLTC control and diagnostic facilities into the structure of modern digital substations based on the digital interface according to the IEC 61850 standard is noted.

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The Heating System of Agricultural Facilities Using Excess Heat Power Transformers

Elektrotekhnologii i elektrooborudovanie v APK ◽

10.22314/2658-4859-2020-67-1-42-47 ◽

2020 ◽

Vol 67 (1) ◽

pp. 42-47

Author(s):

Anatoliy I. Sopov ◽

Aleksandr V. Vinogradov

Keyword(s):

System Design ◽

Heat Supply ◽

Cooling System ◽

Power Transformer ◽

Electric Heating ◽

Heating System ◽

Power Transformers ◽

Large Power ◽

Excess Heat ◽

Power Centers

In power transformers, energy losses in the form of heat are about 2 percent of their rated power, and in transformers of large power centers reach hundreds of kilowatts. Heat is dissipated into the environment and heats the street air. Therefore, there is a need to consume this thermal energy as a source of heat supply to nearby facilities. (Research purpose) To develop methods and means of using excess heat of power transformers with improvement of their cooling system design. (Materials and methods) The authors applied following methods: analysis, synthesis, comparison, monographic, mathematical and others. They analyzed various methods for consuming excess heat from power transformers. They identified suitable heat supply sources among power transformers and potential heat consumers. The authors studied the reasons for the formation of excess heat in power transformers and found ways to conserve this heat to increase the efficiency of its selection. (Results and discussion) The authors developed an improved power transformer cooling system design to combine the functions of voltage transformation and electric heating. They conducted experiments to verify the effectiveness of decisions made. A feasibility study was carried out on the implementation of the developed system using the example of the TMG-1000/10/0.4 power transformer. (Conclusions) The authors got a new way to use the excess heat of power transformers to heat the AIC facilities. It was determined that the improved design of the power transformer and its cooling system using the developed solutions made it possible to maximize the amount of heat taken off without quality loss of voltage transformation.

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Study of power transformer loading in rural power supply systems

Safety and Reliability of Power Industry ◽

10.24223/1999-5555-2020-13-4-282-289 ◽

2021 ◽

Vol 13 (4) ◽

pp. 282-289

Author(s):

I. V. Naumov ◽

D. N. Karamov ◽

A. N. Tretyakov ◽

M. A. Yakupova ◽

E. S. Fedorinovа

Keyword(s):

Energy Efficiency ◽

Power Supply ◽

Rural Areas ◽

Power Transformer ◽

Electric Energy ◽

Power Transformers ◽

Electric Networks ◽

Load Factors ◽

Optimal Load ◽

Supply Systems

The purpose of this study is to study the effect of loading power transformers (PT) in their continuous use on their energy efficiency on a real-life example of existing rural electric networks. It is noted that the vast majority of PT in rural areas have a very low load factor, which leads to an increase in specific losses of electric energy when this is transmitted to various consumers. It is planned to optimize the existing synchronized power supply systems in rural areas by creating new power supply projects in such a way as to integrate existing power sources and ensure the most efficient loading of power transformers for the subsequent transfer of these systems to isolated ones that receive power from distributed generation facilities. As an example, we use data from an electric grid company on loading power transformers in one of the districts of the Irkutsk region. Issues related to the determination of electric energy losses in rural PT at different numerical values of their load factors are considered. A computing device was developed using modern programming tools in the MATLAB system, which has been used to calculate and plot the dependence of power losses in transformers of various capacities on the actual and recommended load factors, as well as the dependence of specific losses during the transit of 1 kVA of power through a power transformer at the actual, recommended and optimal load factors. The analysis of specific losses of electric energy at the actual, recommended and optimal load factors of PT is made. Based on the analysis, the intervals of optimal load factors for different rated power of PT of rural distribution electric networks are proposed. It is noted that to increase the energy efficiency of PT, it is necessary to reduce idling losses by increasing the load of these transformers, which can be achieved by reducing the number of transformers while changing the configuration of 0.38 kV distribution networks.

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A Novel Excitation Approach for Power Transformer Simulation Based on Finite Element Analysis

Applied Sciences ◽

10.3390/app112110334 ◽

2021 ◽

Vol 11 (21) ◽

pp. 10334

Author(s):

Wen-Ching Chang ◽

Cheng-Chien Kuo

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Magnetic Flux ◽

Flux Density ◽

Power Transformer ◽

Core Loss ◽

Power Transformers ◽

Magnetic Flux Density ◽

External Excitation ◽

Element Method

Power transformers play an indispensable component in AC transmission systems. If the operating condition of a power transformer can be accurately predicted before the equipment is operated, it will help transformer manufacturers to design optimized power transformers. In the optimal design of the power transformer, the design value of the magnetic flux density in the core is important, and it affects the efficiency, cost, and life cycle. Therefore, this paper uses the software of ANSYS Maxwell to solve the instantaneous magnetic flux density distribution, core loss distribution, and total iron loss of the iron core based on the finite element method in the time domain. . In addition, a new external excitation equation is proposed. The new external excitation equation can improve the accuracy of the simulation results and reduce the simulation time. Finally, the three-phase five-limb transformer is developed, and actually measures the local magnetic flux density and total core loss to verify the feasibility of the proposed finite element method of model and simulation parameters.

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Recycling Heat Losses of an Oil-Immersed Transformer: Feasibility Study

Bulletin of the South Ural State University series Power Engineering ◽

10.14529/power210105 ◽

2021 ◽

Vol 21 (1) ◽

pp. 48-54

Keyword(s):

High Efficiency ◽

Power Transformer ◽

Heat Losses ◽

Power Transformers ◽

Passive Mode ◽

Active Mode ◽

Short Circuits ◽

Definition Of ◽

The Relationship ◽

Novel Design

The paper investigates the feasibility of adding a liquid heater to an oil-immersed transformer. It proves that design the high efficiency of power transformers, losses due to idling and short circuits are substantial and are scattered in the environment as heat. The paper proposes a novel design that implements a liquid (coolant) heater to enable the unit not only to convert electricity, but also to generate heat. In order to analyze the feasibility of such heat recycling, the authors have developed an equivalent thermal circuit and a mathematical model thereof. Said heater can operate in two modes. In the passive mode, the coolant it contains only absorbs the heat emitted (lost) by the power transformer. In the active mode, it also receives the heat emitted due to the passage of electric current through the pipes of the heater. The paper further introduces the definition of heater efficiency. Studies have shown that up to 50 % of transformer heat losses can be recycled by heating the coolant in the heater. The paper presents the relationship between utilized heat and transformer losses, as well as heater efficiency as a function of coolant flow rate. The heater efficiency exceeds 90 % in the active mode.

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A Fuzzy Logic Model for Power Transformer Faults’ Severity Determination Based on Gas Level, Gas Rate, and Dissolved Gas Analysis Interpretation

Energies ◽

10.3390/en13041009 ◽

2020 ◽

Vol 13 (4) ◽

pp. 1009 ◽

Cited By ~ 4

Author(s):

Rahman Azis Prasojo ◽

Harry Gumilang ◽

Suwarno ◽

Nur Ulfa Maulidevi ◽

Bambang Anggoro Soedjarno

Keyword(s):

Fuzzy Logic ◽

Power Transformer ◽

Local Population ◽

Gas Analysis ◽

Power Transformers ◽

Support Vector ◽

Dissolved Gas ◽

New Approach ◽

Dissolved Gas Analysis ◽

Novel Approach

In determining the severity of power transformer faults, several approaches have been previously proposed; however, most published studies do not accommodate gas level, gas rate, and Dissolved Gas Analysis (DGA) interpretation in a single approach. To increase the reliability of the faults’ severity assessment of power transformers, a novel approach in the form of fuzzy logic has been proposed as a new solution to determine faults’ severity using the combination of gas level, gas rate, and DGA interpretation from the Duval Pentagon Method (DPM). A four-level typical concentration and rate were established based on the local population. To simplify the assessment of hundreds of power transformer data, a Support Vector Machine (SVM)-based DPM with high agreements to the graphical DPM has been developed. The proposed approach has been implemented to 448 power transformers and further implementation was done to evaluate faults’ severity of power transformers from historical DGA data. This new approach yields in high agreement with the previous methods, but with better sensitivity due to the incorporation of gas level, gas rate, and DGA interpretation results in one approach.

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On Simplified Calculations of Leakage Inductances of Power Transformers

Energies ◽

10.3390/en13184952 ◽

2020 ◽

Vol 13 (18) ◽

pp. 4952 ◽

Cited By ~ 1

Author(s):

Tadeusz Sobczyk ◽

Marcin Jaraczewski

Keyword(s):

Power Transformer ◽

Short Circuit ◽

Power Transformers ◽

Stray Field ◽

Good Representation ◽

The Finite Element Method ◽

Leakage Inductance ◽

Leakage Flux ◽

Calculation Results ◽

Discrete Differential Operator

This paper deals with the problem of the leakage inductance calculations in power transformers. Commonly, the leakage flux in the air zone is represented by short-circuit inductance, which determines the short-circuit voltage, which is a very important factor for power transformers. That inductance is a good representation of the typical power transformer windings, but it is insufficient for multi-winding ones. This paper presents simple formulae for self- and mutual leakage inductance calculations for an arbitrary pair of windings. It follows from a simple 1D approach to analyzing the stray field using a discrete differential operator, and it was verified by the finite element method (FEM) calculation results.

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Novel Remanence Determination for Power Transformers Based on Magnetizing Inductance Measurements

Energies ◽

10.3390/en12244616 ◽

2019 ◽

Vol 12 (24) ◽

pp. 4616

Author(s):

Chen Wei ◽

Xianqiang Li ◽

Ming Yang ◽

Zhiyuan Ma ◽

Hui Hou

Keyword(s):

Numerical Simulations ◽

Laboratory Experiments ◽

Power Transformer ◽

Power Transformers ◽

Inrush Current ◽

The Core ◽

Novel Method ◽

Simulation Results ◽

Electro Magnetic ◽

The Relationship

The remanence (residual flux) in the core of power transformers needs to be determined in advance to eliminate the inrush current during the process of re-energization. In this paper, a novel method is proposed to determine the residual flux based on the relationship between residual flux and the measured magnetizing inductance. The paper shows physical, numerical, and analytical explanations on the phenomenon that the magnetizing inductance decreases with the increase of residual flux under low excitation. Numerical simulations are performed by EMTP (Electro-Magnetic Transient Program) on a 1 kVA power transformer under different amounts of residual flux. The inductance–remanence curves are nearly the same when testing current changes. Laboratory experiments conducted on the same transformer are in line with the numerical simulations. Furthermore, numerical simulation results on a 240 MVA are reported to demonstrate the effectiveness of the proposed method.

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Monitoring of Winding Deformation of Power Transformer by Using Nanosecond Pulses

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.128-129.190 ◽

2011 ◽

Vol 128-129 ◽

pp. 190-195

Author(s):

Hua Lin Liu ◽

Yin Bo Zhan ◽

Xiao Lei ◽

You Yuan Wang ◽

Hua Rong Zeng ◽

...

Keyword(s):

Frequency Domain ◽

Frequency Band ◽

Low Voltage ◽

Power Transformer ◽

Test System ◽

Power Transformers ◽

Distribution Transformer ◽

Frequency Method ◽

Nanosecond Pulses ◽

Measurement Results

As we know, the TF method is more sensitive to changes in the power transformers at higher frequencies. Although measurement based on low voltage impulse (LVI) is definitely faster than that based on swept frequency method (SFM), the available frequency band is narrow because of the typical microsecond impulse. In this paper, the characteristics of the nanosecond impulse in the frequency domain were investigated. A test System based on Nanosecond low voltage impulse was developed. The proposed method was applied to a 10kV/100kVA distribution transformer in the laboratory. Measurement results with two different impulses were compared.

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A New Adaptive Differential Protection Scheme for Tap Changing Power Transformer

International Journal of Emerging Electric Power Systems ◽

10.1515/ijeeps-2015-0005 ◽

2015 ◽

Vol 16 (4) ◽

pp. 339-348 ◽

Cited By ~ 2

Author(s):

Ashesh Mukeshbhai Shah ◽

Bhavesh Bhalja

Keyword(s):

Power Transformer ◽

Detection Sensitivity ◽

Power Transformers ◽

Test Cases ◽

Differential Protection ◽

Protection Scheme ◽

Differential Characteristic ◽

Numerous Test ◽

Internal Faults ◽

Conventional Scheme

Abstract This paper presents a new adaptive differential protection scheme which efficiently adapts the change in tap position of a power transformer. The proposed scheme is based on analytical derivation of pick-up and slope of the differential relay characteristic. By acquiring information such as rating & connection of CTs and present tap position as input, the proposed scheme enhances sensitivity of differential relay during internal faults. This is accomplished either by decreasing pick-up and/or adjusting slope of the differential characteristic of the relay in case of change in tap position. Numerous test cases consisting of various types of internal and external faults have been simulated for an existing power transformer of Gujarat Energy Transmission Corporation Limited (GETCO), Gujarat, India using PSCAD/EMTDC software package. The proposed scheme increases percentage of winding to be protected during internal faults for power transformers having different ratings and connections compared to the conventional differential protection scheme. Furthermore, it has been observed that the detection sensitivity during special types of turn-to-turn and inter-winding faults with varying fault resistances is also enhanced compared to the conventional scheme. Moreover, it equally maintains stability during CT saturation condition. At the end, comparative evaluation of the proposed scheme with the existing schemes clearly indicates superiority of the proposed adaptive scheme.

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