Showing total 35 results

1. Protection Against High-Energy Breakdowns in Neutral Beam Systems for Future Fusion Reactors.

Author

Ahmed, Kamal M., Esch, H. P. L. de, and Simonin, A.

Subjects

*FUSION reactors, *PLASMA beam injection heating, *BUSHINGS, *ELECTRIC potential, *ELECTRIC capacity

Abstract

In this paper, the capacitances of the two-stage bushing that is installed in the 1-MV test bed for neutral beam injectors in the future fusion reactors are calculated by modeling the bushing in a 3-D electrostatic code. One of the modeling results is the stored energy in the bushing, which corresponds to 1/2 CV2. After evaluating the bushing capacitance, a MATLAB/Simulink model is presented to model the possible breakdown in the bushing and between the electrodes in the 1-MV test bed. When a breakdown occurs between anode and cathode, an overcurrent is drawing that can cause damage in the electrode surfaces while an overvoltage takes place when the breakdown happens between the bushing stages. Such damage has been observed experimentally in the past. This paper also presents some of the possible protection against the breakdown in the 1-MV test bed to dissipate the stored energy in order to protect the electrode surfaces and the bushing. The suggested protections presented in this paper are damping resistors, surge arrester individually, and both of them. Also, a coil can be added to the DR either in series or in parallel. [ABSTRACT FROM AUTHOR]

Published

2019

2. Dual Resonant Voltage Droop Compensation for Bipolar Solid-State Marx Generator Topologies.

Author

Canacsinh, Hiren, Silva, J. Fernando, and Redondo, L. M.

Subjects

*SYNCHRONOUS capacitors, *ELECTRIC potential, *METHODOLOGY, *PULSE amplitude modulation, *ELECTRIC generators

Abstract

This paper discusses a novel methodology to increase the voltage droop compensation range in generalized solid-state bipolar high-voltage Marx modulators with one resonant stage. To maintain the modularity characteristic of bipolar Marx modulators, the imbedding of additional resonant stages is not straightforward. Nevertheless, this paper proposes to add a second resonant stage to the already existing resonant-type voltage droop compensation stage. This second stage increases the voltage droop compensation percentage of a generalized solid-state bipolar Marx generator. The compensation of the bipolar pulse voltage droop is now achieved by adding two auxiliary synchronous compensation resonant voltages, to the output capacitive decaying voltage. Simulation and experimental results are presented for six Marx plus two resonant stages, 16% voltage droop, with 3-kV pulse amplitude, 100- $\mu \text{s}$ pulsewidth, 40-ms relaxation time, and 10-Hz pulse repetition rate. [ABSTRACT FROM AUTHOR]

Published

2019

3. Modeling and Construction of Marx Impulse Generator Based on Boost Converter Pulse-Forming Network.

Author

Hosseini, Seyed Mohammad Hassan, Ghafourinam, Hamid Reza, and Oshtaghi, Mohammad Hossein

Subjects

*ELECTRIC generators, *ELECTRIC inductors, *IDEAL sources (Electric circuits), *CAPACITORS, *ELECTRIC potential, *ELECTRIC circuits

Abstract

This paper presents the design and construction of a sample of Marx pulsed generator based on boost converter (BC) pulse-forming networks (BCPFNs). BCPFN is used instead of the conventional Marx floors for constructing this pulsed generator. BCPFN is carried out by connecting inductors and capacitors in series and parallel modes, respectively, by using solid-state switches, and during this procedure the pulsed generator converts to BC temporarily and increases the voltage of capacitors uniformly to a considerable value. This technique causes an increase in the discharging voltage level to the load that is many times more than its dc voltage source by charging the capacitors to a greater level. In order to take advantage of the benefits of Marx generator and PFN, this paper suggests a new circuit with the minimum number of switches. It means, to compose BCPFN and Marx, we have tried to design the circuit with fewer switches and instead of it we have achieved our desired performance with changing the operating mode in the states of BC, PFN, BCPFN, and BCPFN Marx. The results are simulated with MATLAB software. At the end, the experimental results of the construction of the above-mentioned system at low-power levels are presented, and the topology’s accuracy is proved by comparing them to the results of simulation. [ABSTRACT FROM AUTHOR]

Published

2018

4. Modular Multilevel Converter Grid Interface for Klystron Modulators: An Augmented Modulation Scheme for Arm Balancing.

Author

Jankovic, Marija, Costabeber, Alessandro, Watson, Alan, Clare, Jon C., and Aguglia, Davide

Subjects

*KLYSTRONS, *ELECTRIC current converters, *ELECTRIC controllers, *ELECTRIC power distribution grids, *ELECTRIC potential

Abstract

This paper discusses the control of a modular multilevel converter (MMC) used as a grid interface for the klystron modulators in the compact linear collider (CLIC). The converter has a DC side load which takes short-duration power pulses, causing high DC side power fluctuations that are not tolerable if seen by the AC grid. The DC–AC power decoupling capability of the MMC enables mitigation of the power ripple on the AC side, guaranteeing compliance with power quality requirements. However, the pulse repetition rate of the CLIC modulators is synchronized the 50-Hz AC grid and this induces permanent power imbalance in the arms of the MMC, causing voltage deviation and overmodulation unless appropriate balancing strategies are implemented. Unlike existing arm balancing methods that control 50-Hz circulating currents to balance the arm powers, the method proposed in this paper introduces an augmented modulation strategy where modulation signals are redistributed among arms based on the demand from a balancing controller. The resulting controller has lower complexity and its simple structure enables an easier design of the balancing loop, which guarantees predictable dynamics in operation. The effectiveness of the method has been demonstrated in simulation for the full-scale CLIC converter ratings and experimentally on a 7-kW MMC prototype operating with a 3.3-kA pulsed DC load. [ABSTRACT FROM AUTHOR]

Published

2018

5. Design Validation of a Single Semiconductor-Based Marx-Generator Stage for Fast Step-Wise Arbitrary Output Waveforms.

Author

Hochberg, Martin, Sack, Martin, Herzog, Dennis, Weisenburger, Alfons, and Mueller, Georg

Subjects

*PULSED power systems, *MICROPROCESSORS, *ELECTROMAGNETIC interference, *SEMICONDUCTORS, *ELECTRIC potential

Abstract

A new modular pulsed-power source with fast rise time and step-wise arbitrary output waveform generation is currently under development to drive the Gepulste Elektronenstrahlanlage device investigated at the Institute for Pulsed Power and Microwave Technology (IHM). Acknowledging the complex design procedures necessary to set up a modular pulsed-power source for voltages of up to 120 kV, this paper focuses on the circuit design for a single stage and its validation prior to the generator assembly. Using a semiconductor-based Marx generator topology, the stages are designed to have an output voltage of 1 kV with a pulse current of up to 600 A. When connected to an ohmic load, the measured current rise times are in the order of 46 ns resulting in the current rise rates of up to 10 kA/ $\mu \text{s}$ using the commercial devices. The step-wise arbitrary output waveform is created by generating the switching commands on the stage using a microprocessor and a fast optical synchronization unit. Effective stage shielding is verified by operating the stage in a 100-kV, 2.5-kA electromagnetic interference test bed. This paper presents the design considerations and the corresponding measurements. [ABSTRACT FROM AUTHOR]

Published

2018

6. Discussion on Minimum Precharged Voltage and Energy of the Counter-Current Capacitor in ICCOS.

Author

Liu, Xukun, Yu, Xinjie, Ban, Rui, and Li, Zhen

Subjects

*SEMICONDUCTOR devices, *ELECTRIC potential, *CAPACITORS, *THYRISTORS, *POWER resources

Abstract

Because it possesses higher current turn-off capability, the inverse current commutation with semiconductor devices (ICCOS) is a better option for the opening switch of an inductive pulsed power supply than the integrated gate commutated thyristor. This paper investigates the counter-current capacitor, which is the key component that determines the turn-off result and the volume of the counter-current branch. The major contributions of this paper include the following: 1) deriving an analytical expression for the minimum precharged capacitor voltage that can reliably turn off the main switch; 2) verifying this expression through a series of experiments within a current range of 0 to 4000 A and an energy range of 0 to 50 kJ; 3) giving an approximate expression for the optimal capacitance that minimizes the precharged energy; and 4) investigating the variation trends of the optimal capacitance and the corresponding optimal precharged energy with varying inductor current. [ABSTRACT FROM PUBLISHER]

Published

2017

7. A High-Performance Drive Circuit for All Solid-State Marx Generator.

Author

Zhou, Ziwei, Li, Zi, Rao, Junfeng, Jiang, Song, and Sakugawa, Takashi

Subjects

*ELECTRIC circuits, *SYNCHRONOUS generators, *LINE drivers (Integrated circuits), *ELECTRIC potential, *ELECTRIC generators, *CAPACITORS, *OPTICAL fibers

Abstract

In recent years, all solid-state Marx generators have been found more and more extensive applications in industrial, environmental, and biological fields. All solid-state Marx generators have many requirements for their drive circuits, such as good synchrony for driving signals at different stages, fine isolation between control signals and the main circuits, adjustable pulsewidths and frequencies, and good driving abilities. This paper proposes a high-performance drive circuit for a 24-stage Marx generator based on IGBTs. A half-bridge circuit using IR2110 outputs a high-current turning-on drive signal (positive) and a turning-off drive signal (negative) with adjustable dead time. The control drivers are input to the common primary side of 24 nanocrystalline magnetic transformers, which isolate the control circuit and the main circuit. Through gate circuits at the second sides of the magnetic cores, the turning-on drive signal charges 24 gate–emitter capacitors to required voltages and consequently all IGBTs move into on state until the turning-off signal arrives. Similarly, the negative turning-off drive signal charges all gate–emitter capacitors to a negative voltage which ensures all IGBTs stay in the off state. Therefore, the pulsewidth is determined by the phase difference between the turning-on and turning-off drive signals. Equipped with this drive circuit, the 24-stage Marx generator is able to produce stable high voltage pulse with a peak value of −9.6 kV, PRF $0.05\sim 5$ kHz, and different pulsewidths. In this paper, the design details and experimental confirmation of the proposed drive circuit are illustrated. [ABSTRACT FROM AUTHOR]

Published

2016

8. Nonlinear Frequency Characteristic of Multiple Series Gaps With Voltage-Dividing Network and Its Application in HVDC Circuit Breaker.

Author

Li, Lee, Cheng, Yong, Peng, Mingyang, Yu, Bin, Liu, Yunlong, Yuan, Zhao, and Yuan, Pan

Subjects

*ELECTRIC potential, *ELECTRIC circuit breakers, *RESONANCE, *ELECTRIC capacity, *SIMULATION methods & models

Abstract

This paper proposes an active resonance circuit based on multiple series gaps (MSG) with voltage-dividing network and self-charging trigger device. The working principle of active resonance circuit, MSG, and triggering device is described in detail. To determine the optimal parameter setting of MSG, the effects of the voltage frequency, equalizing resistance, and voltage-dividing capacitance on the voltage distribution of MSG are analyzed by simulation. To realize the interrupting process of short fault current and determine the operation requirements of the main devices of precharge direct current (dc) circuit breaker, a simulation model of interrupting short fault current is performed. Furthermore, an experiment of four-series gaps is presented to verify the turn-on characteristic of the MSG and an experiment of artificial current zero is set up to testify the feasibility of the active resonance circuit. The simulation and experimental results show that the active resonance circuit proposed in this paper can generate an artificial zero current and is suitable for precharge dc circuit breaker. [ABSTRACT FROM AUTHOR]

Published

2016

9. Theoretical Analysis and Improvement on Pulse Generator Using BJTs as Switches.

Author

Li, Zi, Li, Pan, Rao, Junfeng, Jiang, Song, and Sakugawa, Takashi

Subjects

*JUNCTION transistors, *PULSE generators, *ELECTRIC switchgear, *ELECTRIC circuit analysis, *ELECTRIC resistors

Abstract

Bipolar junction transistors (BJTs) have been widely studied and used in nanosecond high-voltage pulse generators due to the advantages of fast switching speed and high repetitive frequency. Usually the Marx-type circuit is used to raise the peak value of output pulses. In this paper, a traditional BJT-Marx circuit using charging resistors is analyzed theoretically and experimentally. Based on the results, the structure of a circuit is changed to decrease the isolation voltage across the resistors, and diodes are used to replace charging resistors to block capacitors discharging to resistors. Experimental results showed that the three Marx generators proposed in this paper output pulses with higher voltage amplitude, and the last improved circuit outputs pulses with faster fall times at a higher efficiency. [ABSTRACT FROM AUTHOR]

Published

2016

10. Optimization of Self-Breakdown and Triggering Characteristics on Multigap Gas Switch by Mounting Resistors and Capacitors in Parallel With Switch Gaps.

Author

Jiang, Hongyu, Sun, Fengju, Cong, Peitian, Wang, Zhiguo, Jiang, Xiaofeng, Yin, Jiahui, Huang, Tao, Luo, Weixi, Zhang, Tianyang, and Zhai, Rongxiao

Subjects

*CAPACITOR switching, *ELECTRIC resistors, *ELECTRIC breakdown, *GASES, *STANDARD deviations, *RANDOM access memory, *SWITCHING circuits, *ELECTRIC potential

Abstract

The multigap gas switch has been widely used in liner transformer drivers (LTDs), but there is still room for improvement on its self-breakdown and triggering characteristics. In this paper, based on the circuit model of the six-gap gas switch, the gap voltage distribution during the charging and triggering process is analyzed, and the optimization on self-breakdown and triggering characteristics by mounting resistors and capacitors in parallel with switch gaps are theoretically and experimentally investigated. The results indicate that compared with the original switch, when the self-breakdown voltage is about ±90 kV, the standard deviation is reduced from 7.5 to less than 3 kV; for a charging voltage of ±80 kV and by operating at 60% working coefficient, when the negative trigger voltage is 75 kV, the jitter of the switch is reduced from 6.1 to 1.4 ns. [ABSTRACT FROM AUTHOR]

Published

2019

11. Analysis of the Conduction Process for Active Surge Protection Gap With Combination Wave Energy Injection.

Author

Yao, Xueling, Le, Yangjing, Xu, Wenjun, Han, Pei, Sun, Wei, and Chen, Jingliang

Subjects

*MAGNETIC coupling, *ELECTRIC circuits, *ELECTRIC potential, *STRUCTURAL optimization, *TOPOLOGICAL derivatives

Abstract

In this paper, we designed an active coupling trigger circuit and an active surge protection gap (ASPG). The surge protection level of the passive SPG is improved, and the operating time of the passive SPG is shortened. The equivalent circuits for the coupling trigger circuit were developed. Then, we analyzed the component transient voltage of the active coupling trigger circuit with the combination wave injected. We obtained the numerical relationship between the coupling trigger current and the current flowing through the ASPG. In addition, the timing relationship between the component voltage and the current was acquired. To verify the analysis results, we established the combination wave generator and conducted an experiment. In the experiment, we observed that the trigger circuit operating time and the ASPG impulse breakdown voltage changed with the capacitor charging voltage of the combination wave generator. Furthermore, we discovered the change laws. The results also show that the operating time and impulse breakdown voltage of the ASPG are both smaller than the passive SPG. These results provide an important theoretical and experimental basis for the further study and structural optimization of the ASPG. [ABSTRACT FROM AUTHOR]

Published

2019

12. A Modular Topology of Marx Generator Using Buck–Boost Converter.

Author

Taherian, Mehdi, Allahbakhshi, Mehdi, Farjah, Ebrahim, and Givi, Hadi

Subjects

*ELECTROPORATION, *ELECTRIC potential, *ELECTRIC generators, *ELECTRIC inductors, *ELECTRIC switchgear

Abstract

In this paper, a high-voltage unipolar pulse power generator is introduced for electroporation applications. Operating principle of the proposed structure is based on the buck–boost (BB) converter. The generator is comprised of parallel modules connected to the converter through an SCR and is supplied by a low-voltage dc source. Each module consists of an insulated gate bipolar transistor (IGBT), two diodes, and a capacitor. In fact, the proposed topology is a combination of the Marx generator and BB (MG-BB) converter. In comparison with other modular MG-BB structures, the proposed topology achieves interesting advantages including simpler structure, reduction of IGBTs voltage rating, and reducing number of components (inductors and switches). In order to clarify the features of the proposed structure, it has been compared with other unipolar MGs considering different aspects including the number of circuit components, number of required input supplies, amplitude of the output pulse, and the maximum voltage across switches and diodes. To validate the effectiveness of the structure, simulation and experimental results are presented. The results confirm that the proposed topology is capable of generating unipolar pulses with desirable amplitude and repetition frequency using a low-voltage dc supply. [ABSTRACT FROM AUTHOR]

Published

2019

13. A Fast Modular Semiconductor-Based Marx Generator for Driving Dynamic Loads.

Author

Hochberg, Martin, Sack, Martin, Herzog, Dennis, Weisenburger, Alfons, An, Wladimir, Fetzer, Renate, and Mueller, Georg

Subjects

*ELECTRON beams, *SEMICONDUCTORS, *ELECTRIC potential, *ELECTRIC inductance, *ELECTRIC currents

Abstract

The challenging demands of pulsed electron beam devices (such as the GESA device) with respect to their pulsed power supply have led to the development of a new semiconductor-based Marx generator. At a maximum output voltage of 120 kV and 600-A pulse current for a duration of up to 100 $\mu \text{S}$ , stepwise arbitrary output waveforms are desired. A fast rise time of the generator is achieved by using fast switching circuitry, low inductance capacitors, and a low inductance stage arrangement. For low jitter triggering of all stages and efficient signal transmission, the generator uses an optical bus system for communication. Due to the inherent dynamic load characteristics of the GESA device, the generator features a fast overcurrent protection scheme. This paper presents selected design aspects of the generator and their validation in a small-scale assembly able of delivering up to 8 kV at 600-A load current. [ABSTRACT FROM AUTHOR]

Published

2019

14. Development of a High-Power Burst Pulse Generator Based on the Sequential Operation of Magnetic Switches.

Author

Sato, Hiromi, Yasu, Keita, Nukaga, Ken, and Minamitani, Yasushi

Subjects

*CANCER treatment, *ELECTROMAGNETIC waves, *MAGNETIC control, *ELECTRIC potential, *ELECTRIC lines

Abstract

Nanosecond and subnanosecond high-voltage pulses have used in new biological applications, such as cancer treatment using an ultrashort pulsed high electric field. For this treatment, the use of high-power pulsed electromagnetic wave has been proposed to obtain the required high electric field. This paper focuses on the design of a compact high-power pulsed electromagnetic wave generator using a nanosecond pulsed power generator for cancer treatment. We developed a pulsed power generator that continuously outputs multiple pulses via a nonlinear transmission line (NLTL) using magnetic switches. The NLTL comprises a ladder of capacitors and saturable inductors. The NLTL generates a pulse train by delaying the propagation of the pulse using the magnetic switch of each ladder. The frequency of repetition of the burst pulse is 13.8 MHz. The peak output voltage is 7 kV at the maximum input voltage of 28 kV. The number of pulses in the pulse train can be varied by the number of units of the magnetic switch. [ABSTRACT FROM AUTHOR]

Published

2019

15. Experimental Study of the Breakdown Characteristics of Polypropylene Films Under Nanosecond Voltage Pulses.

Author

Chen, Zhiqiang, Ji, Shengchang, Jia, Wei, Tang, Junping, Guo, Fan, Li, Junna, and Chen, Weiqing

Subjects

*POLYPROPYLENE films, *DIELECTRIC breakdown, *ELECTRIC potential, *ELECTRIC fields, *WEIBULL distribution

Abstract

Due to its low-loss and high dielectric strength, polypropylene is widely used as electrical insulation material in pulse capacitors. In order to study its breakdown characteristics for nanosecond voltage pulses, an experimental setup was designed to generate voltage pulses with a 10%–90% rise time of 38 ns and a full width at half maximum of about 90 ns. Tests of the three polypropylene films with thicknesses of 12, 15, and $18~\mu \text{m}$ were performed. In addition, hundreds of nanoseconds pulse and dc voltage were also applied for comparison. The experimental results reveal that most of the breakdown occurs during the front edge of the pulse for tens of nanoseconds pulse, and the breakdown strengths of the three kinds of polypropylene films are almost identical for different applied voltages, which show a weak correlation between the thickness of the dielectric and the breakdown field. The expected breakdown strength of tens of nanoseconds pulse defined in this paper is not significantly higher than the mean value of the hundreds of nanoseconds pulse and the dc condition, suggesting that the breakdown of a thin polypropylene film is mainly determined by the electrical field but not the voltage-time cumulative effect. All these observations strengthen the conclusion that the breakdown of a thin polypropylene film is an intrinsic phenomenon. [ABSTRACT FROM AUTHOR]

Published

2018

16. Development and Test of a 400-kV PFN Marx With Compactness and Rise Time Optimization.

Author

Lassalle, Francis, Morell, Alain, Loyen, Arnaud, Chanconie, Thierry, Roques, Bernard, Toury, Martial, and Vezinet, Rene

Subjects

*ELECTRON beams, *MICROWAVES, *PULSE circuits, *CERAMIC capacitors, *ELECTRIC potential

Abstract

Repetitive high-voltage square pulses are of great importance for producing long-pulse electron beams and high-power microwaves. One of possible technologies for the generation of such pulses is a Marx generator using pulse forming network (PFN) stages, often combined with a pulse sharpening technique to reduce the rise time to a few nanoseconds (peaking stage). This paper presents an innovative design, named the “zigzag design,” for the optimization of the compactness and of the rise time of 400-kV–85-ns PFN-Marx. Thanks to this design, the 16 stages of this generator, which delivers an open circuit output voltage of 720 kV, fit in a 650-mm length. For a slightly overmatched load ($Z_{\mathrm {load}} = 100 ~\Omega$), the output voltage reaches 400 kV with a rise time as less as 5 ns. The inductance reduction associated with the innovative zigzag design, which allows this sharp rise time with no need for a peaking stage, is described. The 85-ns plateau duration of the pulse is given by the PFN construction of each stage, which is based on six ceramic capacitors (2.1 nF–45 kV) connected within a strip line. The 16 PFN stages are housed in a 360-mm diameter gas pressurized vessel. Burst mode operation for a duration of 10 s at a pulse repetition frequency of 100 Hz is reported, for a resistive load and for the electron beam diode of a X-band relativistic backward-wave oscillator (BWO). To reach further compactness, the BWO system is integrated on side of the generator vessel and a U-shaped gas pressurized line connects both systems through a compact conical vacuum insulator. [ABSTRACT FROM AUTHOR]

Published

2018

17. Study on Static and Dynamic Voltage Distribution Characteristics and Voltage Sharing Design of a 126-kV Modular Triple-Break Vacuum Circuit Breaker.

Author

Huang, Daochun, Wu, Gaobo, and Ruan, Jiangjun

Subjects

*ELECTRIC potential, *VACUUM circuit breakers, *FINITE element method, *ELECTRIC capacity, *RESIDUAL charges

Abstract

The static and dynamic voltage distribution characteristics and voltage sharing design of a 126-kV modular triple-break vacuum circuit breaker (VCB) was discussed in this paper. The finite-element method and power frequency tests were used to calculate and verify the static voltage distribution ratios and distributed capacitance parameters of multi-break VCBs, respectively. A model combining the post arc current model and equivalent capacitance model was proposed for simulations of dynamic transient recovery voltage (TRV) distribution characteristics of the triple-break VCB. The simulation results indicated that besides the stray capacitances, the TRV sharing design should take the influence of residual charge (RC) into account, and the influence of RC on the TRV distribution is relevant to the differences of RC parameters among the series interrupters. Therefore, the appropriate value of grading capacitors should meet the requirement of the worst case. Based on the investigation of this paper, a 126 kV U-shaped triple-break VCB prototype with 1000 pF grading capacitors has been produced, and the successful large current breaking tests indicate the good breaking capacity and suitable voltage sharing design of the triple-break VCB. [ABSTRACT FROM PUBLISHER]

Published

2015

18. Compact Pulse Topology for Adjustable High-Voltage Pulse Generation Using an SOS Diode.

Author

Driessen, A. B. J. M., van Heesch, E. J. M., Huiskamp, T., Beckers, F. J. C. M., and Pemen, A. J. M.

Subjects

*ELECTRIC network topology, *PULSED power systems, *ELECTRIC switchgear, *ELECTRIC circuits, *ELECTRIC transformers, *ELECTRIC potential

Abstract

In this paper, a compact circuit topology is presented for pulsed power generation with a semiconductor opening switch (SOS). Such circuits require the generation of a fast forward current through the diode, followed by a reverse current that activates the recovery process. In general, magnetic switches are used to switch the diode current from forward to reverse. Therefore, adjustment of the output voltage of an SOS pulser is difficult. This paper introduces a circuit that allows an adjustable output voltage of the pulser. A solution is realized with a premagnetizing circuit on the primary winding of a pulse transformer (PT), so that a third winding is not needed. The primary capacitor voltage can now be varied while maintaining proper saturation of the PT. [ABSTRACT FROM PUBLISHER]

Published

2014

19. The Meat Grinder With CPFU: A Novel Circuit for Inductive Pulsed Power Supplies.

Author

Liu, Xukun and Yu, Xinjie

Subjects

*MEAT grinders, *PULSE circuits, *ELECTRIC power, *ELECTROMAGNETIC devices, *ELECTRIC potential, *ELECTRIC inductors

Abstract

A novel circuit with the better performance for the inductive pulsed power supplies in the electromagnetic launch system is proposed in this paper, namely, the meat grinder with capacitive pulse forming unit (CPFU). Its working process is qualitatively analyzed stage by stage. Its practical feasibility is verified through a 7.5-kJ experiment. From the perspectives of circuit structure and working principle, this circuit can be regarded as the combination of a meat grinder and a CPFU. Compared with its preceding circuits, this circuit possesses following advantages: 1) the self-recovery of the capacitor precharged voltage can easily be achieved, which is conducive to continuous operations of the whole circuit and 2) the waveforms of the inductor currents contain no capacitive components, which can promote the energy storage density of the inductors. [ABSTRACT FROM PUBLISHER]

Published

2017

20. Influence of External Factors on Self-healing Capacitor Temperature Field Distribution and Its Validation.

Author

Wang, Zijian, Yan, Fei, Xu, Menglei, Wang, Zhaomeng, Wang, Xun, and Xu, Zhiniu

Subjects

*SELF-healing materials, *CAPACITORS, *TEMPERATURE distribution, *ELECTRIC potential, *COMPUTER simulation

Abstract

Temperature field simulation for self-healing power capacitor makes sense to the capacitor optimization and improvement of capacitor’s rated voltage and capacity. On the basis of reasonable simplifications and assumptions for capacitor structure, a 3-D temperature field numerical simulation model for a self-healing power capacitor is formulated in Fluent 15.0. The ambient temperature is set to 55 °C, and the applied voltage is ac 400 V. The temperature distributions of the shell and core of the self-healing capacitor are obtained. The results reveal that the temperature of the core is 2 °C–3 °C higher than that of the shell. The highest temperature of the shell locates on the large side surface, and the temperature of the large side surface is higher than that of the small side surface. To validate the above simulation, a self-healing capacitor is manufactured and thermal resistance sensors are used to measure the temperature in the thermal stability test. The simulation is validated by the experiment. Finally, the influences of the ambient temperature and applied voltage on the temperature rise are investigated. This paper can be taken a reference to the self-healing capacitor operation, maintenance, and even the optimization of its internal structure and material. [ABSTRACT FROM PUBLISHER]

Published

2017

21. Research of Linear Charging for Repetition-Frequency Pulse Power Supply.

Author

Fu, Rongyao, Zhang, Dongdong, Sun, Yaohong, and Yan, Ping

Subjects

*POWER resources, *CLOSED loop systems, *ELECTRIC potential, *ELECTRONIC modulators, *SIMULATION methods & models

Abstract

Electrical parameter such as charging voltage and time series of discharge in repetition-frequency pulse power supply (RFPPS) can be adjusted. In order to obtain the accuracy of launch time and enough muzzle energy, constant current charging technology is taken, which can make RFPPS charge linear and the discharge time same in each discharge cycle. In this paper, the influence factors of accuracy are analyzed. It is proposed to control the accuracy of the charging time by means of the closed-loop feedback of the average charging current. A simulation and experiment of RFPPS test system are established. The results of simulation and experiment show that the charging time is proportional to the charging voltage after pulse-frequency modulation. The launch time can be determined by the charging voltage. Through this way, incoming target will be intercepted if the interception distance and the launching velocity are measured and calculated accurately. [ABSTRACT FROM PUBLISHER]

Published

2017

22. The Meat Grinder With SECT Circuit.

Author

Yu, Xinjie, Ban, Rui, Liu, Xukun, and Li, Zhen

Subjects

*MEAT grinders, *ELECTRIC power, *ENERGY transfer, *THYRISTORS, *ELECTRIC potential, *ELECTRIC circuits

Abstract

The meat grinder is a basic circuit for inductive pulsed-power supply (IPPS). Based on meat grinder, the Institute of Advanced Technology proposed a circuit called the slow transfer of energy through capacitive hybrid (STRETCH) meat grinder, in which an Integrated Gate Commutated Thyristors (IGCT) is selected as the main switch. Tsinghua University proposed the STRETCH meat grinder with inverse current commutation with semiconductor devices (ICCOS) in which the main switch is replaced by a thyristor and the ICCOS subcircuit is introduced to turn off the main switch. To reduce the opening switch voltage and increase the current turning-off capacity for IPPS, this paper presents a novel circuit topology named the meat grinder with self-charged capacitor and thyristors (SECTs). The key idea of the SECT topology is to turn off the primary current by the energy transfer capacitor, which is precharged. The meat grinder with SECT has larger capacity than the STRETCH meat grinder because it replaces the IGCT with a thyristor and is simpler than the STRETCH meat grinder with ICCOS because it only needs one capacitor. The suggested circuit is more suitable for IPPS module with high energy density. Simulation and experiment have been carried out to validate the circuit. [ABSTRACT FROM PUBLISHER]

Published

2017

23. PWM Voltage Droop Compensation for Bipolar Solid-State Marx Generator Topologies.

Author

Canacsinh, Hiren, Silva, J. Fernando, and Redondo, L. M.

Subjects

*PULSE width modulation transformers, *ELECTRIC potential, *SOLID-state lasers, *ELECTRIC generators, *HIGH voltages

Abstract

This paper presents a novel technique for the voltage droop compensation of long pulses in solid-state bipolar high-voltage Marx generators. Considering the modularity of Marx generators the compensation consists in adding one extra stage to perform as a pulsewidth modulation circuit. This stage voltage is added to the output positive or negative pulses, and an output LfCf filter is included to smooth the voltage pulse waveform. A five-stage laboratory prototype of this circuit has been assembled using 1200-V Insulated Gate Bipolar Transistors and diodes with 1000-V dc input voltage. The circuit was operated at 50-Hz bipolar pulse rate, giving 4-kV bipolar pulses, into a resistive load, with 100- \mu \texts pulsewidth and 9.5-ms relaxation time. The circuit was able to compensate 10% of bipolar pulse voltage droop. [ABSTRACT FROM PUBLISHER]

Published

2017

24. A High-Voltage Pulse Generator With Continuously Variable Pulsewidth Based on a Modified PFN.

Author

Mohsenzade, Sadegh, Zarghany, Mostafa, Aghaei, Morteza, and Kaboli, Shahriyar

Subjects

*PULSE generators, *ELECTRIC potential, *ELECTRIC impedance, *ELECTRICAL load, *SEMICONDUCTORS

Abstract

The amount of stored energy is an important issue in the low-droop and high-precision pulse generation. Pulse forming network (PFN) simulating an open-ended transmission line seems to be useful due to its minimum stored energy. The drawbacks of the PFN include low-output pulse quality and constant pulsewidth, which limit their applications. Another limitation of generating rectangular pulses using PFN is that half of the charged voltage appears in the output when delivering the entire stored energy to the matched load. This paper proposes a structure of PFN-based pulse generator that overcomes the above-mentioned limitations. For continuous pulsewidth adjustment, a lossless scheme is presented. By increasing the ratio of the load magnitude to the characteristic impedance, the amplitude of the output pulse voltage would be approximately equal to that of the charged voltage. Therefore, the semiconductor switches can be utilized in the PFN pulse generator easily. In addition, the pulse quality is enhanced and faster rising time is obtained in comparison with the conventional PFNs. In this proposal, the stored energy quantity is limited to three times the energy needed for the output pulse in the case of RL=10Z0 . To verify the proposed structure, a prototype is simulated using PSPICE software, and the experimental results are presented. [ABSTRACT FROM AUTHOR]

Published

2017

25. Energy Transfer Efficiency Optimization in an Electromagnetic Railgun.

Author

Meyer, Richard T., DeCarlo, Raymond A., and Dickerson, Julianne

Subjects

*ENERGY transfer, *ELECTROMAGNETIC rail guns, *PULSE circuits, *CAPACITORS, *KINETIC energy, *ELECTRIC potential

Abstract

Electromagnetic railguns (EMRs) launch projectiles by the systematic triggering of current pulse forming units (PFUs), which release stored capacitor energy. Past work has focused on maximizing projectile velocity at the muzzle for given PFU capacitor charge voltages, which maximizes efficiency. However, operators in naval applications need to be able to select the muzzle velocity for a projectile to achieve a desired ballistic path. Thus, there is a demand to maximize efficiency for a given muzzle velocity. As such, this paper investigates maximizing the efficiency of transferring the stored PFU capacitor electrical energy to projectile kinetic energy while minimizing the current value when the projectile exits the rails to reduce damage to them from arcing. This is accomplished by optimizing the choice of the initial capacitor voltage in each PFU and the trigger timing subject to an electrical-mechanical dynamic model of the EMR and projectile and any additional scenario constraints (described shortly). This optimization is solved using numerical programming in the context of a relaxation with the initial capacitor voltages and triggering times as the only explicit variables to the optimizer; additional needed values are obtained from a differential algebraic equation solver. The optimization is successfully demonstrated for three scenarios: operation for a projectile mass and muzzle velocity associated with published operating parameters, operation for several projectile mass-muzzle velocity pairs with both equal and distinct initial capacitor voltages, and operation for several projectile mass-muzzle velocity pairs with a load current bound and equal initial capacitor voltages. Results show improved efficiency in comparison to the use of the published parameters, the independence of efficiency from projectile mass when there is no current bound, virtually identical results for equal and distinct initial capacitor voltages, and decreased efficiency with a current bound. [ABSTRACT FROM PUBLISHER]

Published

2017

26. Influence of the AMF Arc Control on Voltage Distribution of Double-Break VCBs.

Author

Liao, Minfu, Ge, Guowei, Duan, Xiongying, Huang, Jinqiang, Huang, Zhihui, and Zou, Jiyan

Subjects

*VACUUM circuit breakers, *ELECTRIC potential, *VACUUM switches, *MAGNETIC fields, *SIMULATION methods & models

Abstract

This paper investigates the influence of the axial magnetic field (AMF) arc control on voltage distribution (VD) of double-break vacuum circuit breakers (VCBs) in order to gain balanced VD, and thus enhance the breaking capacity. The interaction of vacuum arc plasma, postarc current (PAC), and AMF is discussed. We conduct the breaking test of double-break VCBs with externally applied AMF of a different pulsewidth, magnitude, and a different moment. The PAC, postarc charge, and the VD are measured to analyze the relationship between the AMF arc control and the VD. The optimal AMF arc control and the relationship between the AMF magnitude and the unbalanced voltage ratio are gained when the grading capacitors were 400 pF. The experimental test showed that the proper AMF arc control can improve the unbalanced VD. The mechanism is that the proper AMF arc control can make the postarc charge small and stable, so the unbalanced postarc charge, which caused the unbalanced VD is limited. [ABSTRACT FROM AUTHOR]

Published

2016

27. A Fast and Series-Stacked IGBT Switch With Balanced Voltage Sharing for Pulsed Power Applications.

Author

Zarghani, Mostafa, Mohsenzade, Sadegh, and Kaboli, Shahriyar

Subjects

*PULSED power systems, *ELECTRIC power production, *SEMICONDUCTOR switches, *ELECTRIC potential, *ELECTRIC circuit analysis

Abstract

The series configuration of fast semiconductor switches seems to be the key component in the high-voltage and fast rising time pulse generation. In this approach, two important issues must be considered. The first is to provide a safe operating condition for the switches in transient intervals. The second is to design a gate drive system with the capability of driving a large number of discrete devices simultaneously. The aim of this paper is to obviate these two requirements. First, different factors affecting the unbalanced voltage sharing between the series switches are discussed. In this investigation, the switch-to-ground parasitic capacitance effect has been recognized as the major effect on the unbalanced voltage sharing in the transient interval. Two schemes for abating this effect are proposed. To solve the unbalanced voltage distribution, the structure with a snubber circuit in the clamp mode operation is suggested. This scheme can be used for any number of switches without destructively affecting their behavior. In addition, the output pulse with a fast rising time could be obtained by the proposed gate drive system. In order to evaluate the operation of the proposed structure, a stacked switch with the voltage capability of 36 kV is tested experimentally. The characteristics of the obtained pulse are the fast rising time (69.5 ns) with the dV/dt of 460 kv/ \mu \texts and the wide range of the pulsewidth adjusting to 0.5–15 \mu \texts . In addition, the voltage variance of the switches level in the series structure is about 10%. [ABSTRACT FROM AUTHOR]

Published

2016

28. Characterization of an n-Type 4-kV GTO for Pulsed Power Applications.

Author

Flack, Tyler, Hettler, Cameron, and Bayne, Stephen

Subjects

*PULSED power systems, *THYRISTORS, *ELECTRIC potential, *ELECTRIC resistance, *SIMULATION methods & models, *SILICON

Abstract

This paper details the experimental evaluation and simulation of a 4-kV n-type gate turn-OFF thyristor (GTO) designed for pulsed power applications. The primary criteria of evaluation are rate of current rise ( dI/dt ), turn-ON delay time ( T_{D}) , and resistance of the device during turn-ON transients [ R_{\mathrm{\scriptscriptstyle ON}}(t)$ ]. The device under test (DuT) is an n-type asymmetric-blocking GTO manufactured by Silicon Power (Part No. 14N40A10) with a rated dc blocking voltage of 4 kV. A test circuit was specifically designed to minimize stray inductance in order to capitalize on the dI/dt$ capabilities of the DuT. Experimental data collected from resistance measurements are used to develop a single-switch approximate model for use in simulation. The results of dI/dt$ experiments provide a profile of DuT dI/dt$ operation beyond rated values; specifically dI/dt were readily achieved. The turn-ON delay time of the DuT is also characterized and determined to be $\sim 225$ ns on average. [ABSTRACT FROM AUTHOR]

Published

2016

29. Studies on the ITER NBI Residual Ion Dump Power Supply System.

Author

Barp, Marco, Gaio, Elena, and Toigo, Vanni

Subjects

*NEUTRAL beams, *ELECTRIC potential, *ELECTRIC power, *POWER resources, *CAPACITORS

Abstract

This paper describes the studies performed to identify a suitable design solution for the power supply of the residual ion dump for neutral beam injectors (NBI) of International Thermonuclear Experimental Reactor (ITER). A novel approach has been proposed based on the series of two power supplies, one to produce the average output voltage and one devoted to the generation of the required ac component. The paper is focused in particular on the schematic circuit adopted to generate the alternating component that is meant to use floating capacitors to produce a trapezoidal voltage component superimposed to the dc one. [ABSTRACT FROM PUBLISHER]

Published

2012

30. Low-Ripple and High-Precision High-Voltage DC Power Supply for Pulsed Power Applications.

Author

Ahn, Suk-Ho, Ryoo, Hong-Je, Gong, Ji-Woong, and Jang, Sung-Roc

Subjects

*HIGH voltages, *ELECTRIC current converters, *ELECTRIC switchgear, *ELECTRIC potential, *ELECTRIC circuits

Abstract

This paper describes the design and implementation of a three-phase resonant converter with low ripple and high control accuracy. Based on a three-phase LCC-type resonant converter—which has advantages of low ripple, high-efficiency, and high-power density compared with a single-phase converter—a high-voltage power supply with low ripple (<0.1%) was designed. In addition to the general merits of an LCC-type resonant converter operating at continuous conduction mode—including soft switching, low conduction loss, and current source characteristics—the proposed scheme uses only one phase under a light-load condition by having different leg designs of the gate drive circuit and snubber parameters. This allows the design to overcome the operational constraints of the general LCC-type resonant converter. The distinctive design of the three-phase converter structure provides high efficiency and low ripple not only during rated operation, but also under light-load conditions. In order to analyze the high performance of the proposed scheme from no load to rated load, a PSPICE simulation was carried out. Comparison results with a conventional LCC-type resonant converter based on a single-phase structure are analyzed from the viewpoints of output ripple, losses, and operable load range. Using the proposed converter, a 20-kV, 20-kW high-voltage dc power supply design and implementation was presented with a superior gate drive circuit. Finally, the superiority of the proposed converter was verified through a simulation and experimental results. It was experimentally confirmed that the developed power supply achieves high performance in terms of efficiency (98%), operable load range (0.5–20 kV), and low ripple (0.05%), with a high power density. [ABSTRACT FROM PUBLISHER]

Published

2014

31. Parametric Measurements of Switching Losses of Insulated Gate Bipolar Transistor in Pulsed Power Applications.

Author

Strowitzki, Claus Fritz

Subjects

*INSULATED gate bipolar transistors, *BIPOLAR transistors, *CAPACITORS, *CHARGE transfer, *OSCILLOSCOPES, *ELECTRIC potential

Abstract

Insulated gate bipolar transistors (IGBTs) are the workhorse in power electronics. Due to recent improvements in IGBTs, they also find many applications in the field of pulsed power. The switching losses of an IGBT are normally given from the supplier, but not from typical converter applications. These data are not valid for pulsed power applications. In this paper, parametric measurements of turn-on losses are shown for IGBTs in a typical pulsed power application. [ABSTRACT FROM AUTHOR]

Published

2013

32. 300-kA Fast Linear Transformer Driver Stage.

Author

Liang, Tianxue, Jiang, Xiaofeng, Sun, Fengju, and Qiu, Aici

Subjects

*ELECTRIC potential, *ELECTRIC currents, *CAPACITORS, *ELECTRIC circuits, *ELECTRIC transformers

Abstract

A modular linear transformer driver (LTD) is a novel fast-discharge high-pulsed power source for primarily stored energy. In LTDs, a large number of stages (or cavities) can be connected in series or in parallel conveniently to directly generate high power pulses of 50–200 ns with the required voltage or current. This paper introduces an LTD stage developed by us recently. This LTD stage consists of 14 bricks in parallel. Each brick contains two 40-nF capacitors and a compact multigap gas spark switch in series. The switch is a modification of our original version, and the diameter and the height of which have been reduced to 98 and 127 mm, respectively. The circuit model of this stage is established in PSPICE, and its output parameters are obtained through simulation. Driving a rough-matched resistive load of 0.27 \Omega, its output current peak is 300 kA with an overall rise time of about 110 ns at a charged voltage of the capacitors of about \pm90 kV, agreeing well with its simulation result. [ABSTRACT FROM PUBLISHER]

Published

2012

33. Experiment and Research of Energy Depositing Rate of Exploding Wires Under Different Initial Capacitor Voltages for Thin Film Production.

Author

Yang, Jiazhi, Fan, Xingming, and Liu, Zhongyang

Subjects

*EXPLODING wire phenomena, *THIN films, *ELECTRIC potential, *COPPER wire, *FORCE & energy, *CAPACITORS, *ELECTRIC currents

Abstract

Thin film produced by exploding wires is affected by many factors; one of such factors is the energy depositing rate. The research in this paper focused on measuring the voltage and current of an exploding copper wire that was 15 cm long and 0.3 mm in diameter. The time-dependent wire resistance and the energy deposited into the wire were deduced from the measured voltage and current, and the maximum wire resistance was observed at the time when part of the wire mass was heated up to the boiling point, which was called critical time and critical point, respectively. From the experiment, the following statements could be surmised: The maximum wire resistance increases from about 224.4 to 266.1 \m\Omega, and the critical time reduces from about 8.8 to 7.2 \mu\s when the initial capacitor voltage changes from 10 to 20 kV, as well as the fact that the mean energy depositing rate varies from about 13.3 to 27.6 \J/\mu\s before the critical point. Also, thin copper film is prepared by this method under initial capacitor voltages of 10, 15, and 20 kV, respectively. The SEM micrographs of the film samples are also presented and analyzed. This result demonstrates that a faster energy depositing rate can help to heat up the wire mass more uniformly and more wire mass would evaporate before the critical time to create a greater wire resistance at the critical point, and the film surface is more uniform and has less void fraction. [ABSTRACT FROM AUTHOR]

Published

2011

34. A 12-kV High-Voltage Semiconductor Switch Based on 76-mm Reverse-Switching Dynistors.

Author

He, Xiaoping, Wang, Haiyang, Xue, Binjie, Chen, Weiqing, Zhou, Jingzhi, and Tang, Junping

Subjects

*SEMICONDUCTOR switches, *SWITCHING theory, *ELECTRIC generators, *ELECTRIC potential, *ELECTRIC transformers, *MAGNETIC cores, *CAPACITORS, *PULSE generators, *THYRISTORS

Abstract

This paper describes the construction and experimental tests of a 12-kV high-voltage high-action generator based on reverse-switching dynistor (RSD) assembly. The main RSD unit consists of seven 76-mm-diameter dynistor pieces connected in series with a blocking voltage of about 2.4 kV, a magnetic switch based on a 1K101 amorphous alloy core, the trigger system based on a saturable transformer, and a 16-mm RSD assembly; the trigger current could reach 2 kA in amplitude with 1-\mu\s duration under 10 kV. The working voltage rate of this RSD unit is about 8–12 kV. Experiment on a 2.2-mF capacitor test bed under 12 kV working voltage, the switch current amplitude reached 150 kA with 300-\mu\s duration; the transferred charge is about 26.5 C and the action is 2.94 \MA^2\s, respectively. [ABSTRACT FROM AUTHOR]

Published

2011

35. Deflection of Streamer Path in DC Electric Potential.

Author

Shashurin, Alexey, Scott, David, Shneider, Mikhail N., and Keidar, Michael

Subjects

*PLASMA jets, *ELECTRIC discharge research, *HELIUM, *CAPACITORS, *DIELECTRIC devices

Abstract

Nonequilibrium atmospheric plasma jets are associated with sequence of streamer breakdowns developing in helium-air mixture. In this paper, propagation of the streamer in plane capacitor is photographed, and deflection toward the positive capacitor plate is analyzed. [ABSTRACT FROM PUBLISHER]

Published

2014