JP2013532281A - System for calibrating capacitive sensors used in very fast transient overvoltage measurements - Google Patents

Abstract

A capacitive sensor calibration system for measuring fast transient overvoltages is provided. The system includes a high-pressure steep pulse generator (201), a conical transmission tube (202), a capacitance sensor (203), a resistance voltage divider (204), coaxial cables (205-1, 205-2), a first Oscilloscope (206) and a second oscilloscope (207). The high pressure steep pulse generator (201) is configured to generate a high pressure steep pulse. The high-pressure steep pulse is transmitted through a conical transmission tube (202) through a capacitance sensor (203) and a resistor voltage divider (203) installed on a gas-insulated metal closed switchgear (GIS). 204). The conical transmission tube (202) is connected coaxially with the GIS. The resistive voltage divider (204) transmits the resistive voltage division signal to the first oscilloscope (206) via the coaxial cable (205-1). The capacitance sensor (203) transmits a capacitance voltage division signal to the second oscilloscope (207) via the coaxial cable (205-2). The calibration system utilizes a high voltage steep pulse generator (201) as a signal source to match the actual waveform of a very fast transient over-voltage (VFTO). In order to calibrate the capacitance sensor (203) under almost actual installation conditions, the capacitance sensor (203) and the resistive voltage divider (204) are installed on the GIS.
[Selection] Figure 2

Description

  The present invention relates to the field of capacitive sensors, and more particularly to a system for calibrating capacitive sensors used in very fast transient overvoltage measurements.

  A system for calibrating capacitive sensors used in very fast transient over-voltage (VFTO) measurements to detect whether the performance of the capacitive sensor can meet the requirements , And used to determine the partial pressure ratio.

  A general system for calibrating a capacitive sensor used in VFTO measurement is shown in FIG. 1 and includes a steep pulse generator 101, a coaxial cable 102, an attenuator 103, a capacitive sensor 104, and a first sensor. The oscilloscope 105 and the second oscilloscope 106 are provided. The operating principle of this system is as follows. The steep pulse generator 101 is used as a signal source that generates a voltage pulse, and then the voltage pulse is transmitted to the attenuator 103 and the capacitive sensor 104 via the coaxial cable 102; 103 and a capacitance sensor 104, and an attenuator 103 is provided for comparison purposes; the voltage on the attenuator 103 is observed on a first oscilloscope 105 connected to the attenuator 103. The voltage on the capacitive sensor 104 can be observed on a second oscilloscope 106 connected to the capacitive sensor 104; on the first oscilloscope 105 and the second oscilloscope 106 By comparing the voltage waveform and the voltage amplitude, the performance and the voltage division ratio of the capacitance sensor 104 can be verified.

  However, the steep pulse generator of such a system that calibrates the capacitive sensor used in the VFTO measurement cannot generate a sufficiently high and steep voltage, thus simulating the VFTO generation environment. Can not. In addition, the existing calibration system does not use a gas insulated switchgear (GIS, Gas Insulated Switchgear), but the GIS switching operation is necessary in an actual system. In the prior art, only one steep pulse generator is used to simulate the pulse wave generated by the GIS switching operation, and the amplitude and steepness are far from those of the actual system. Therefore, a capacitance sensor calibrated in a low pressure environment in the prior art cannot be used in an actual high pressure environment and cannot meet the requirement of VFTO response time.

  A technical problem to be addressed by the present invention is to provide a system for calibrating a capacitive sensor used in very fast transient overvoltage measurements, which calibrates the capacitive sensor for VFTO measurements. can do.

  Very fast transient overvoltage measurement with high voltage steep pulse generator, conical transmission tube, capacitance sensor, resistive voltage divider, coaxial cable, first oscilloscope and second oscilloscope A system for calibrating a capacitive sensor used in is provided in one embodiment of the present invention.

  A high-pressure steep pulse generator is used to generate a high-pressure steep pulse, and the high-pressure steep pulse is placed on the GIS via a conical transmission tube that is coaxially connected to a gas insulated switchgear (GIS). To the capacitive sensor and the resistive voltage divider.

  The resistive voltage divider transmits a resistive voltage division signal to the first oscilloscope via a coaxial cable.

  The capacitance sensor transmits a capacitance voltage division signal to the second oscilloscope via the coaxial cable.

  Preferably, the conical transmission pipe includes a conical transmission inner pipe and a conical transmission outer pipe.

  The conical transmission inner tube and the inner conductor of the GIS are coaxially arranged, and the lower radius of the conical transmission inner tube is the same as the radius of the inner conductor.

  The conical transmission outer tube and the GIS housing are coaxially arranged, and the lower radius of the conical transmission outer tube is the same as the radius of the housing.

  Preferably, the capacitive sensor is provided on the flange of the GIS housing.

  Preferably, the resistive voltage divider is provided on the inner conductor of the GIS and passes through the GIS housing, and the resistive voltage divider and the capacitive sensor are symmetrically arranged along the central axis of the GIS.

  Preferably, the system further comprises a matching resistor provided on one end of the GIS.

  Preferably, the system further comprises a support insulator provided on the upper surface of the GIS between the inner conductor and the housing.

  Preferably, the first matching resistor and the second matching resistor are radial water resistors.

  Preferably, the high-voltage steep pulse generator includes an adjustable DC power supply, a first resistor, a second resistor, a first capacitor, and a first switch.

  The first resistor, the first capacitor, and the second resistor are connected in series between the negative electrode and the positive electrode of the adjustable DC power supply.

  In the adjustable DC power supply, this positive electrode is grounded.

  The first switch is connected in parallel between the common terminal of the first resistor and the first capacitor and the ground.

  The common terminal of the first capacitor and the second resistor is a high voltage steep pulse output terminal of the high voltage steep pulse generator.

  Preferably, the voltage of the high voltage steep pulse generated from the high voltage steep pulse generator has an amplitude adjustable between 5 kV and 100 kV, and the rising time of the high voltage pulse is 3 ns or less.

  Preferably, the width of the high-pressure steep pulse generated from the high-pressure steep pulse generator is 100 ns.

  Compared with the prior art, the present invention has the following advantages.

  A system for calibrating a capacitive sensor used in very fast transient overvoltage measurements is a high-pressure pulse generated by a steep pulse generator, which is supplied via a conical transmission tube to the electrostatic capacitance provided on the GIS tube. Send to capacitive sensor and resistive voltage divider. Since the conical transmission tube can further reduce the distortion of the high-pressure steep pulse wave, the influence on the high-pressure steep pulse during transmission can be reduced. Also, the conical transmission tube has good performance with respect to test repeatability. The calibration system uses a high-pressure steep pulse generator as a signal source that is more compatible with the actual VFTO. In addition, a capacitive sensor and a resistive voltage divider are provided on the GIS tube, so that the capacitive sensor can be calibrated under nearly actual installation conditions.

FIG. 1 is a structural diagram of a system for calibrating a capacitance sensor used in VFTO measurement in the prior art. FIG. 2 is a structural diagram of a system for calibrating a capacitance sensor used in the VFTO measurement provided in the present invention. FIG. 3 is a structural diagram of a system for calibrating a capacitive sensor used in VFTO measurement provided in another embodiment of the present invention. FIG. 4 is a structural diagram of a steep pulse generator provided in an embodiment of the present invention.

  In order for those skilled in the art to better understand and implement the present invention, some terminology is introduced below.

  High-voltage steep pulse generator: a pulse voltage source having a small rise time (preferably 3 ns in this embodiment) and a half-value width (about 100 ns in this embodiment) satisfying certain requirements.

  Conical transmission tube: A transmission line with a changing radius having a gradually changing wave impedance (variable impedance line) or constant impedance (in this embodiment, an equivalent impedance line, that is, constant impedance).

  In order to make the above objects, features, and advantages of the present invention more apparent, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  Referring to FIG. 2, FIG. 2 is a structural diagram of a system for calibrating a capacitance sensor used in the VFTO measurement provided in the present invention.

  A system for calibrating a capacitance sensor used in VFTO measurement provided in this embodiment includes a high-voltage steep pulse generator 201, a conical transmission tube 202, a capacitance sensor 203, and a resistance voltage divider. 204, a coaxial cable 205, a first oscilloscope 206, and a second oscilloscope 207.

  The high-pressure steep pulse generator 201 is configured to generate a high-pressure steep pulse, and the high-pressure steep pulse is provided on a gas-insulated switchgear (GIS) via a conical transmission tube 202. And the conical transmission tube 202 is coaxially connected to the GIS.

  The high-voltage steep pulse generator 201 of the present embodiment has a voltage amplitude adjustable from 5 kV to 100 kV, and the rise time is 3 ns or less. The high pressure steep pulse generator 201 uses high pressures up to 100 kV for calibration, so that it can meet the requirements of ultra high pressure calibration.

  The conical transmission tube 202 can cause small distortions in the wave and has good performance for test repeatability.

  The resistance voltage divider 204 transmits a resistance voltage division signal to the first oscilloscope 206 via the coaxial cable 205.

  The capacitance sensor 203 transmits a capacitance voltage division signal to the second oscilloscope 207 via the coaxial cable 205.

  The system for calibrating a capacitance sensor used in the VFTO measurement provided in this embodiment uses a high-voltage steep pulse generator 201 that can be accurately adjusted over a wide range as a signal source. The generated pulse voltage is simultaneously transmitted to the capacitance sensor 203 and the resistor voltage divider 204 provided on the GIS, and the voltage on the voltage divider 204 becomes a reference voltage, in order to determine the performance of the capacitance sensor. The voltage on the capacitance sensor 203 is compared with the voltage on the resistive voltage divider 204. The voltage on the capacitive sensor 203 can be observed on the second oscilloscope 207 and the voltage on the resistive voltage divider 204 can be observed on the first oscilloscope 206.

  A system for calibrating a capacitive sensor used in a VFTO measurement sends a high voltage pulse generated by a steep pulse generator to a capacitive sensor and a resistive voltage divider on the GIS via a conical transmission tube. Since the conical transmission tube can further reduce the distortion of the high-pressure steep pulse wave, the influence on the high-pressure steep pulse during transmission can be reduced. Also, the conical transmission tube has good performance with respect to test repeatability. The calibration system uses a high-pressure steep pulse generator as a signal source that is more compatible with the actual VFTO environment. In addition, capacitive sensors and resistive voltage dividers are provided on the GIS so that the capacitive sensors can be calibrated in a better manner in relation to actual GIS operation.

  Hereinafter, the specific structure of the system for calibrating the capacitance used in the VFTO measurement provided in the present invention will be described in detail with reference to FIG.

  Referring to FIG. 3, FIG. 3 is a structural diagram of a system for calibrating a capacitance sensor used in VFTO measurement provided in another embodiment of the present invention.

  As shown in FIG. 3, the conical transmission tube includes a conical transmission inner tube 202b and a conical transmission outer tube 202a.

  The conical transmission inner tube 202b and the GIS inner conductor 301a are coaxially arranged, and the lower radius of the conical transmission inner tube 202b is the same as the radius of the inner conductor 301a.

  The conical transmission outer tube 202a and the GIS housing 301b are coaxially arranged, and the lower radius of the conical transmission outer tube 202a is the same as the radius of the housing 310b.

  The capacitance sensor 203 is provided on the flange of the GIS housing 301b.

  The resistive voltage divider 204 is provided on the GIS inner conductor 301a and passes through the GIS housing 301b, and the resistive voltage divider 204 and the capacitive sensor 203 are arranged symmetrically along the central axis of the GIS.

  The system for calibrating a capacitance sensor used in the VFTO measurement provided in this embodiment further includes a matching resistor provided at one end of the GIS. In this embodiment, preferably a hand hole for mounting six matching resistors is provided on one end of the GIS, and the number of matching resistors can be determined as needed. Please keep in mind. The most common test configuration is to provide three matching resistors on the same annular surface with an angle between all other matching resistors of 120 °. FIG. 3 shows only two matching resistors, namely a first matching resistor R1 and a second matching resistor R2, respectively.

  Note that the round surface on which these matching resistors are located is closer to the bottom surface of the GIS than the resistive voltage divider and capacitance sensor.

  Note that in this embodiment, the first matching resistor R1 and the second matching resistor R2 are preferably radial water resistors. A radial water resistor can effectively eliminate the total reflection phenomenon, thus achieving wave improvement.

  The system for calibrating the capacitive sensor used in the VFTO measurement further comprises a support insulator provided symmetrically on the upper surface of the GIS between the inner conductor 301a and the housing 301b. In addition, it should be noted that the number of supporting insulators is not limited. The support insulator is used to support and secure the inner conductor and is thus provided in an annular shape formed by the inner conductor 301a and the housing 301b to secure the location of the inner conductor. For example, three support insulators with an angle between all other support insulators of 120 ° may be provided on the same annular surface in an annular shape formed by the inner conductor and the housing.

  Hereinafter, the structure of the high-voltage steep pulse generator provided in an embodiment of the present invention will be described in detail in conjunction with FIG.

  Referring to FIG. 4, FIG. 4 is a structural diagram of a high-voltage steep pulse generator provided in an embodiment of the present invention.

  The high-voltage steep pulse generator provided in the present embodiment includes an adjustable high-voltage DC power supply 401, a first resistor Ra, a second resistor Rb, a first capacitor C1, and a first switch. K1.

  The first resistor Ra, the first capacitor C1, and the second resistor Rb are sequentially connected in series between the negative electrode and the positive electrode of the adjustable high-voltage DC power supply 401.

  The positive electrode of the high voltage DC power supply 401 is connected to the ground.

  The first switch K1 is connected in parallel between the common terminal of the first resistor Ra and the first capacitor C1 and the ground.

  The common terminal of the first capacitor C1 and the second resistor Rb is the high-voltage steep pulse output terminal of the high-voltage steep pulse generator.

  The voltage amplitude of the high-voltage steep pulse generator can be adjusted between 5 kV and 100 kV, the rise time is 3 ns or less, and the pulse width is 100 ns.

  The operating principle of the high-voltage steep pulse generator is as follows. The adjustable high voltage DC power supply charges the first capacitor to a constant amplitude (adjustable from 5 kV to 100 kV) via the first resistor and the second resistor. As shown in FIG. 4, using the first switch K1, one terminal of the first capacitor is grounded and the other terminal outputs a high speed leading edge high voltage pulse. When the adjustable high voltage DC power supply outputs a negative voltage, a positive pulse voltage is obtained at the output where terminal b is located.

  The above descriptions are merely preferred embodiments of the present invention and are not any limitation of the forms of the present invention. Although the invention has been disclosed with preferred embodiments as described above, the preferred embodiments are not intended to limit the invention. Without departing from the scope of the technical solutions of the present invention, anyone skilled in the art will recognize from the methods and technical contents disclosed above many possible variations and modifications to the technical solutions of the present invention. Modifications or equivalents can be created. Accordingly, all simple modifications, equivalents, and modifications made to the above embodiments based on the technical essence of the present invention should be considered without departing from the content of the technical solutions of the present invention. It belongs to the scope of the technical solution of the present invention.

Claims (10)

A system for calibrating a capacitive sensor used in very fast transient overvoltage (VFTO) measurement comprising:
A high-voltage steep pulse generator, a conical transmission tube, a capacitance sensor, a resistance voltage divider, a coaxial cable, a first oscilloscope, and a second oscilloscope;
The high-pressure steep pulse generator is configured to generate a high-pressure steep pulse, and the high-pressure steep pulse is arranged on the gas-insulated switchgear (GIS) via the conical transmission tube. And the conical transmission tube is coaxially connected to the GIS,
The resistive voltage divider sends a resistive voltage split signal to the first oscilloscope via a coaxial cable;
The capacitive sensor calibrates the capacitive sensor used in very fast transient overvoltage measurements, wherein the capacitive sensor transmits a capacitive voltage split signal to the second oscilloscope via a coaxial cable. system. The conical transmission pipe includes a conical transmission inner pipe and a conical transmission outer pipe,
The conical transmission inner tube and the inner conductor of the GIS are arranged coaxially, and the lower radius of the conical transmission inner tube is the same as the radius of the inner conductor;
The conical transmission outer tube and the housing of the GIS are coaxially arranged, and the lower radius of the conical transmission outer tube is the same as the radius of the housing of the GIS. A system for calibrating a capacitive sensor used in the very fast transient overvoltage measurement according to Item 1.   The system for calibrating a capacitive sensor used in a very fast transient overvoltage measurement according to claim 2, wherein the capacitive sensor is provided on a flange of the GIS housing.   The resistive voltage divider is provided on the inner conductor of the GIS, passes through the housing of the GIS, and the resistive voltage divider and the capacitive sensor are symmetrically disposed along a central axis of the GIS. A system for calibrating a capacitive sensor used in a very fast transient overvoltage measurement according to claim 3.   The system for calibrating a capacitive sensor used in a very fast transient overvoltage measurement according to claim 1, further comprising a matching resistor provided on one end of the GIS.   The capacitive sensor used in very fast transient overvoltage measurement according to claim 1, further comprising a support insulator provided on an upper surface of the GIS between the inner conductor and the housing. A system to calibrate.   6. The system for calibrating a capacitive sensor used in a very fast transient overvoltage measurement according to claim 5, wherein the matching resistor is a radial water resistor. The high-voltage steep pulse generator includes an adjustable DC power supply, a first resistor, a second resistor, a first capacitor, and a first switch.
The first resistor, the first capacitor, and the second resistor are connected in series between a negative electrode and a positive electrode of the adjustable DC power source;
The adjustable DC power supply has its positive electrode grounded,
The first switch is connected in parallel between a common terminal of the first resistor and the first capacitor and ground,
The very high-speed transient overvoltage measurement according to claim 1, wherein the common terminal of the first capacitor and the second resistor is a high-voltage steep pulse output terminal of the high-voltage steep pulse generator. System to calibrate the capacitive sensor used in the.   The voltage of the high-voltage steep pulse generated from the high-voltage steep pulse generator has an amplitude adjustable between 5 kV and 100 kV, and the rising time of the high-voltage pulse is 3 ns or less. 2. A system for calibrating a capacitive sensor used in the very fast transient overvoltage measurement of 1.   9. The system for calibrating a capacitance sensor used in a very fast transient overvoltage measurement according to claim 8, wherein a width of the high-voltage steep pulse generated from the high-voltage steep pulse generator is 100 ns. .

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