D. A. Matveev

Bio: D. A. Matveev is an academic researcher from Moscow Power Engineering Institute. The author has contributed to research in topics: Electromagnetic coil & Transformer. The author has an hindex of 3, co-authored 13 publications receiving 24 citations.

Resonance Overvoltages in Primary Winding of a Station Service Voltage Transformer

Abstract: The design of new types of transformer equipment, in particular, station service voltage transformers (SSVTs), requires a detailed consideration of all technical aspects and conditions of their application and their design features. One problem is to provide their resistance to effects associated with their interaction with the grid. During transient events in the network caused by the operation of switching equipment or short circuits, the transformers are affected by the oscillating voltage, which, under certain conditions, can cause resonance overvoltages inside their windings. The design of SSVTs differs from that of common power transformers, mostly because different types of windings are used, which determines the essential difference in the natural oscillation frequencies and the theoretical possibility of the development of resonance overvoltages under changed combinations of network parameters and switching conditions. In this paper, the problems of estimating the natural and dominating oscillation frequencies in SSVT windings and the voltages on the longitudinal insulation of SSVT windings under the resonance conditions are considered. The proposed approach is applicable not only to SSVTs, but also to other types of transformer equipment.

Studying the Impulse Overloads in the Windings of a Station Service Voltage Transformer

Abstract: One of the key factors determining the performance of a 110–500-kV station service voltage transformer (SSVT) is a compact insulation design that provides minimum winding sizes. Since SSVTs are new equipment that combine the operational features of a power transformer and the design features of a measuring voltage transformer, it is necessary to study the characteristic transient processes occurring under the impact of lightning-impulse test voltages and lightning and switching overloads in operation in order to ensure proper insulation design. The article presents the results of an experimental investigation of impulse transients in the windings of a full-scale mockup model of an active part of a 20-kV A SSVT with a rated voltage of 110 kV. The influence of grounding the low-voltage winding terminals on the maximum values and duration of impulse stresses on the longitudinal insulation of the high-voltage winding is revealed. It is shown that, unlike in the case of power transformers with disc windings, more significant effects on the insulation are produced when no load is applied on the low-voltage windings.

A Study of Transferred Overvoltages on the Secondary Windings of Station Service Voltage Transformers

Abstract: Station service voltage transformers (SSVTs) are finding increasingly wide application in world practice. One of the key issues of ensuring the reliable operation of the SSVTs is the coordination of their insulation and the protection against high-frequency overvoltage including that induced on the secondary windings. The paper presents the results of measuring the transfer functions and the oscillographic recording of the voltages on the SSVT secondary windings. The transferred overvoltage ratios of unloaded and loaded transformer secondary windings are estimated. Estimated rates of output-voltage increase at resonant frequencies are presented. The transferred overvoltage ratios on the SSVT primary windings under the impact of the damped oscillatory voltage are assessed.

Using Dual Circuits to Simulate Electromagnetic Processes in Cascade Station Service Voltage Transformers

Abstract: —The scientific and methodological principles of development of the design models of a new device—station service voltage transformers intended for use in design study—are considered. The proposed models relate to the “white box” model class, which provide the maximum accuracy when solving such problems. The models are based on equivalent circuits of active parts, which are obtained using the principle of duality of magnetic and electric circuits. It is revealed that the determination of parameters and verification of models are possible only at the manufacturing plant of transformers. Special attention is paid to reproduction in the models of magnetizing process of transformer. The experimental oscillograms are given of magnetizing currents of magnetic conductors of the active parts and of the transformers as an assembly, which show the capacitances of high-voltage winding have a great effect on the open-circuit current. The algorithm for determination of the parameters of transformer model for calculation of steady state conditions is presented, which provides a good coincidence with experimental values for integral parameters, such as the power loss and the root-mean-square value of magnetizing current.

Calculation and Experimental Assessment of the Voltages on the Longitudinal Insulation of the Windings of Station Service Voltage Transformers under Resonant Overvoltages

Abstract: —Under high-frequency oscillations of grid voltage, resonant overvoltages may develop inside transformer windings if the frequencies of the grid voltage oscillations are close to the resonant frequencies of the transformer windings. For transformer equipment—in particular, station service voltage transformers, which, in virtue of the specifics of their operation, may be subjected to the action of high-frequency oscillatory voltages—to withstand internal resonance, it is necessary to assess potential impacts on the internal insulation of their windings under resonance as early as the design stage. The transformer models applied in practice for numerical simulation of high-frequency transients in the transformer windings do not allow accurate reproduction of resonant voltage rises, as they do not provide for rigorous consideration of the frequency dependence of the losses. Direct measurements of the winding voltages under resonance are an alternative to the calculations; however, in practice, such measurements are difficult to make and it is not always possible to measure voltages that affect the insulation in the parts of the windings of interest. In the article, the possibility of determining the impacts on the longitudinal insulation of the windings under resonance by supplementing the measured results with analytical solutions of equations of transients in the windings is studied. The approaches considered in this paper are applicable not only to the station service voltage transformers, but also to other types of the transformer equipment.

Resonance Overvoltages in Primary Winding of a Station Service Voltage Transformer

Abstract: The design of new types of transformer equipment, in particular, station service voltage transformers (SSVTs), requires a detailed consideration of all technical aspects and conditions of their application and their design features. One problem is to provide their resistance to effects associated with their interaction with the grid. During transient events in the network caused by the operation of switching equipment or short circuits, the transformers are affected by the oscillating voltage, which, under certain conditions, can cause resonance overvoltages inside their windings. The design of SSVTs differs from that of common power transformers, mostly because different types of windings are used, which determines the essential difference in the natural oscillation frequencies and the theoretical possibility of the development of resonance overvoltages under changed combinations of network parameters and switching conditions. In this paper, the problems of estimating the natural and dominating oscillation frequencies in SSVT windings and the voltages on the longitudinal insulation of SSVT windings under the resonance conditions are considered. The proposed approach is applicable not only to SSVTs, but also to other types of transformer equipment.

Research On Ferromagnetic Resonance Overvoltage Based On Station Service Voltage Transformers

Abstract: Station Service Voltage Transformers (SSVT) combines the operating characteristics of power transformers and the design characteristics of measuring voltage transformers. Due to its lower initial cost and higher power supply reliability, its applications have been extended beyond that of auxiliary power. During transient events in the network caused by the operation of switching equipment or short circuits, the transformers are affected by the oscillating voltage, which, under certain conditions, can cause resonance overvoltage inside their windings. Based on the ATP-EMTP platform, the ferromagnetic resonance of SSVT is simulated and its simulation model, simulation algorithm, and waveform are analyzed. Based on the simulation analysis results, this paper puts forward the preventive measures of transformer ferromagnetic resonance from the perspective of voltage harmonics and insulation coordination.

A Study of Transferred Overvoltages on the Secondary Windings of Station Service Voltage Transformers

Abstract: Station service voltage transformers (SSVTs) are finding increasingly wide application in world practice. One of the key issues of ensuring the reliable operation of the SSVTs is the coordination of their insulation and the protection against high-frequency overvoltage including that induced on the secondary windings. The paper presents the results of measuring the transfer functions and the oscillographic recording of the voltages on the SSVT secondary windings. The transferred overvoltage ratios of unloaded and loaded transformer secondary windings are estimated. Estimated rates of output-voltage increase at resonant frequencies are presented. The transferred overvoltage ratios on the SSVT primary windings under the impact of the damped oscillatory voltage are assessed.

Using Dual Circuits to Simulate Electromagnetic Processes in Cascade Station Service Voltage Transformers

Abstract: —The scientific and methodological principles of development of the design models of a new device—station service voltage transformers intended for use in design study—are considered. The proposed models relate to the “white box” model class, which provide the maximum accuracy when solving such problems. The models are based on equivalent circuits of active parts, which are obtained using the principle of duality of magnetic and electric circuits. It is revealed that the determination of parameters and verification of models are possible only at the manufacturing plant of transformers. Special attention is paid to reproduction in the models of magnetizing process of transformer. The experimental oscillograms are given of magnetizing currents of magnetic conductors of the active parts and of the transformers as an assembly, which show the capacitances of high-voltage winding have a great effect on the open-circuit current. The algorithm for determination of the parameters of transformer model for calculation of steady state conditions is presented, which provides a good coincidence with experimental values for integral parameters, such as the power loss and the root-mean-square value of magnetizing current.

Overview of Voltage Transformers Suitable for High Voltage Levels

Abstract: With the development of the power grid, high voltage transmission lines and smart substations are put into use This requires higher-performance voltage transformers Potential transformer(PT) can no longer meet the measurement needs Analysis of the voltage measurement requirements in the power grid, pointing out the limitations of traditional PT such as poor insulation performance and ferromagnetic resonance The principles, characteristics and application of three new voltage transformers, that is, resistance voltage transformer, capacitor voltage transformer(CVT), and optical voltage transducer(OVT) are described, and the practical problems of new voltage transformers are summarized and put forward