Thyristor Voltage Research Articles

Influence of Different Peripheral Protections on the Breakover Voltage of a 4H-SiC GTO Thyristor

Influence of Different Peripheral Protections on the Breakover Voltage of a 4H-SiC GTO Thyristor

Distributed Mitigation of Voltage Sag by Optimal Placement of Series Compensation Devices Based on Stochastic Assessment

Central mitigation does not necessarily provide the most economical solution to voltage-sag problems. Distributed mitigation with strategically placed compensation devices should provide a better alternative. Placement studies of this nature usually involve extensive evaluations of candidate compensation schemes, which can become unmanageable for large systems with stochastic voltage-sag data. A probability-based technique known as the weighted sampling method is proposed to simplify the problem. The technique is applied to a distribution system to optimize the cost of placing series compensation. The cost has two components: device cost and cost reduction to consumers due to implementation of the device(s). Series compensation devices being optimized are the two distinctly different dynamic voltage restorer and thyristor voltage regulator. These devices are placed and optimized to best complement each other. To achieve reliable and fast convergence, a genetic algorithm with innovative coding is proposed. A 34-node distribution system is studied with a wide range of voltage-sag data and consumer tolerance characteristics.

High Speed TVR for Power Distribution Lines and its Test Results

The novel thyristor voltage regulator (TVR) for power distribution lines is discussed. It has faster response time, lighter weight, and higher maintainability compared with the existing TVR's. The newly developed “jumping-tap method” demonstrated high-speed response of 0.1 second. Thanks to this method, a big voltage disturbance caused by motor starting, for example, could be compensated. Reverse power flow cause judgement is discussed.

ダイオード・他励ハイブリッド順変換所と自励逆変換所の組合せによるHVDCシステムの提案と解析結果

ダイオード・他励ハイブリッド順変換所と自励逆変換所の組合せによるHVDCシステムの提案と解析結果

Discussion of thyristor characteristic optimization for HVDC valves

We have been developing thyristor valves for high-voltage dc transmission systems for more than 20 years. During this period, the size, power loss, and reliability have been dramatically improved and one of the technical advances which support the improvements is to increase the voltage and current rating of thyristors. However, when thyristor voltage rating exceeds 6 kV, increasing the voltage rating does not lead to size and power loss reduction of the valve because of turn-off characteristic deteriorations. This paper describes a method which can optimize the thyristor characteristics in such a way that the size and power loss of valves are minimized. Two different approaches for HVDC and back-to-back systems are presented. © 1999 Scripta Technica, Electr Eng Jpn, 128(3): 43–52, 1999

A high-voltage pulse generator for plasma immersion ion implantation applications

The design and construction of a high-voltage pulse generator for applications in the treatment of metal and polymer materials by plasma immersion ion implantation (PIII) are described. The generator was built in a circuit category of pulse forming network (PFN), consisting of ten LC sections with L =300 μH, C =2.5 nF and an air core high-voltage pulse transformer. The instrument was designed to produce an adjustable, several amperes, flat 70 kV pulse for over 15 μs with pulse repetition frequency from 50 to 500 Hz. The generator is fed with a high-voltage power supply (10 kV, 1.7 A) with a thyristor voltage regulator from 0 to maximal voltage value in the primary transformer winding. Voltage and current pulse shapes of a PIII reactor using this pulse source are presented.

Development of a Thyristor Valve for Next Generation 500 kV HVDC Transmission Systems

A high voltage thyristor valve is the basic component of an HVDC transmission system. Development of a 500 kV valve for next generation HVDC transmission systems is described. First, the power loss of the valve is analyzed to decide a reasonable wafer size for the light-triggered thyristor. From these results, a six inch diameter wafer size is selected. A light-triggered thyristor, with ratings of 8 kV and 3.5 kA, is developed using the six inch wafer. The design of the valve employing the thyristor and test results with a prototype valve prove that a 500 kV valve can be realized by this design method.

Temperature dependence of the emitter switched thyristor characteristics

The effect of increasing the temperature on the characteristics of the EST is discussed in this paper. High temperature measurements were made on 600 V forward blocking multi-cell EST devices which were fabricated using an IGBT process sequence. An important feature of the EST is that the voltage drop across the lateral MOSFET, which is in series with the thyristor region, increases and compensates for the decrease in the thyristor voltage drop at higher temperatures, producing an emitter ballasting effect. Thus, the integration of this MOSFET in series with the thyristor results in a positive temperature coefficient for the forward voltage drop at current densities above 167 A cm −2 and a negative temperature coefficient below this current density. This behavior favors uniform current distribution and improved turn-off capability. Experimental results indicate a decrease in the latching current density of the main thyristor and the parasitic thyristor with an increase in the ambient temperature. Transient measurements show an increase in the turn-off time and a decrease in the maximum controllable current density. These experimental results are supported and quantified by two-dimensional physics based models.

Power semiconductors-a new method for predicting the on-state characteristic and temperature rise during multicycle fault currents

Solid-state switches are being designed for use on AC transmission lines for tighter control of power flow and increased use of transmission capacity in accordance with an advanced concept called "Flexible AC Transmission System" (FACTS). These necessitate using the largest available thyristors and GTOs that must perform under emergency fault conditions with assurance of long term reliability and life expectancy. This paper is concerned with reviewing concepts needed to predict on-state losses incurred at extreme variations of junction temperature and describing an empirical method being used for commercially available 100 mm thyristors.

Compact 50 kJ pulse forming unit, switched by semiconductors

Compact pulse forming units for the 10 MJ PEGASUS facility have been designed and constructed. Each unit consists of a 50 kJ capacitor, a thyristor stack as main switch, a semiconducting diode stack as crowbar switch and a compact pulse forming inductance. For the PEGASUS facility a pulse forming network of 200 basic units is required. The maximal operating voltage of each unit is 10 kV and the current pulse yielded has an amplitude of up to 52 kA with an increasing time of 230 /spl mu/s. To minimize the electrical power dissipation in the primary circuit, the pulse forming unit was built up very compactly and coaxially. The inductance in the primary circuit consisting of the capacitor, the main switch and the crowbar switch is less than 120 nH. Thus the reverse voltage measured at the capacitor is reduced to only 4% of the original voltage and the electrical power dissipation is negligible. The pulse forming units are connected to the railgun by flexible coaxial cables. Since the main switch consists of a high voltage thyristor, the operating voltage can be varied continuously between 0 kV and 10 kV. The parallel operation of several pulse forming units is feasible and the standard of security is very high, because the units are decoupled completely by a pulse forming inductance of 30 /spl mu/H. With a special trigger unit each 50 kJ capacitor can be switched independently, so an almost arbitrary current pulse can be formed by switching several units with temporal delays. Therefore, and due to the negligible electrical power dissipation in the pulse forming unit, the overall efficiency of the railgun can be enhanced.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

Loss measurement in high voltage thyristor valves

No measuring method is presently available for direct and sufficiently accurate evaluation of power losses in thyristor valves used in HVDC converter substations and static VAr controllers. This paper presents a measuring method to be be used during the valve type tests with the intention to verify the guaranteed loss characteristic. The method was validated under laboratory conditions by comparison to a sophisticated calorimetric technique. An uncertainty of 1% was achieved at conditions simulating full load operation. Voltage across and current through the valve are recorded in discrete steps and digitized. The loss is then calculated as their product. Special current and voltage sensors were developed to cover a very high dynamic range of the measured quantities. A high resolution, multichannel digital recorder was used for simultaneous registration of two voltage and two current signals. The method is of a general application, since the valve is treated as a two port circuit. Therefore, it can be used to measure loss in other nonlinear components and apparatus, where large dynamic changes of the measured quantities preclude application of conventional techniques. >

COMPUTER SIMULATION OF THREE-PHASE THYRISTOR VOLTAGE REGULATOR FED STATIC AND INDUCTION MOTOR LOADS-A GENERALIZED APPROACH

ABSTRACT A generalized simulation technique that can be used to study both dynamic and steady state performance of a phase-controlled thyristor voltage regulator with static RL and Induction motor loads is presented. The technique extends an approach developed earlier for application to a cycloconverter fed induction motor drive - where logic variables represent the thyristor switches in the voltage regulator model and the induction motor operation for various modes with the switchings in the stator is represented by a generalized set of equations in d-q reference frame. The equations so developed avoid any matrix inversion operation during computation. Digital computer programs developed for determination of the switching variables and the simulation of the systems are discussed and typical steady state and dynamic responses as predicted with thyristor firing angles as independent variables are shown.

Comparison of thyristor switched capacitor and voltage source GTO inverter type compensators for single phase feeders

The use of small static compensators for the control of voltage on single-phase distribution feeders is investigated. A candidate feeder system is examined to determine the size and type of reactive compensation required. A comparison is made of the single-phase design of a thyristor switched capacitor type compensator with an advanced gate turn-off thyristor voltage source inverter type of compensator. The advantages of the three-phase advanced compensator are not evident in the single-phase design.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

Analysis and performance characteristics of three-phase, thyrode AC voltage controllers

A generalized approach based on numerical evaluation of the Fourier coefficients is used to determine the performance of three-phase phase-controlled thyrode AC voltage controllers. Balanced resistive and inductive loads of different power factors are considered. Various electrical properties are computed and compared graphically for different circuit configurations. It is found that although the branch-controlled delta-connected load gives the highest distortion and power factors, it offers limited control of input power. The line-controlled star-connected circuit offers full range of power control, a simple control scheme over a wider range of firing angle retardation, and good distortion and power factors. For applications where even harmonics can be tolerated in the line currents, such a controller has superior performance characteristics compared to that of the conventional thyristor voltage controller of similar configuration.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

A THYRISTORIZED A.C. VOLTAGE CONTROLLER WITH SINUSOIDAL OUTPUT

ABSTRACT In this paper a thyristor voltage controller suitable for high power loads is presented. A load voltage higher than that of the supply can be obtained without difficulty. Thyrsitor switches are used in a secondary circuit such that voltage control is achieved via flux level variation of an output coil. The load voltage is varied in steps which can be made as narrow as desired but distortion and switching transients in the load circuit are avoided. Theoretical and experimental results of a prototype are presented and compared. If the load is an inductor, the proposed arrangement can be used as a variable reactive power compensator without harmonic current injection into the mains supply.

Harmonic Analysis of Three Phase AC Voltage Regulators Using Thyristor - Diode Switches

Based upon numerical evaluation of Fourier coefficients, complete harmonic analysis is carried out for various three phase, AC thyrode voltage regulators. Various quantities of interest are computed and presented in the form of normalized curves for balanced R-L loads of different power factors. It is shown that the line controlled circuits offer the best overall performance and are superior in performance than the conventionally used thyristor voltage controllers.

Gating systems for high voltage thyristor valves

The requirements on gating systems for thyristor valves used in high-voltage direct current and static VAr compensator systems are listed. Different techniques used to meet these requirements are discussed with a view on the specific service condition of the particular application and illustrated by service performance.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>

Increase in sustaining voltage of gate-turnoff thyristors by an innovative floating gate structure

The turnoff capability of a gate-turnoff thyristor is described by a sustaining voltage Vs which is the maximum reapplied voltage during current interruption. An innovative floating gate structure in which one of the two gate electrodes formed on both sides of the cathode emitter is connected to the external gate terminal provides a significant increase in Vs of more than 800 V from the 600 V of a conventional gate structure. This is attributed to the series gate conductance which is more than three times larger than that of the conventional gate structure during the tail period.

High Voltage Thyristor Pulser for Spark Gap Switches

A compact inexpensive high voltage thyristor pulser is developed. The output voltage of the pulser is stepped up to more than 10 kV with pulse transformer. The ramp rate of the secondary terminal voltage is 7 kV/µs. The pulser is used for triggering spark gap switches in fast discharge experiments. The total time jitter of the discharge system is less than 50 ns. Several techniques are employed to improve the noise margin.

Evaluation of Field Insulation of Turbine-Generators with Higher Thyristor Excitation

Application of a thyristor excitation system with high ceiling voltage to the turbine-generator field has required precise evaluation on field insulation, especially against spiky voltage. This paper reports on the investigation of breakdown through and over the surface of field insulating components for thyristor voltage. Particular emphasis is placed on the method for estimating voltage endurance characteristics for thyristor voltage in hydrogen. We established a simple evaluating method on the rotor slot armor by using the relation of voltage endurance characteristics between ac and thyristor voltages. Estimation tests have proved that hazardous points are (a) the surface flashover of the creepage block for initial-stage characteristics and (b) degradation of the slot armor due to partial discharge for long-term characteristics.