阅读说明：本技术 非接触电压变换器 (Non-contact voltage converter ) 是由 F·比尔曼 D·施莱夫利 W·特潘 于 2018-07-10 设计创作，主要内容包括：用于测量在交流电压导体系统的至少两个导体之间的电压的非接触电压变换器(2),该变换器包括两个或更多个电容电流测量单元(3),每个所述电容电流测量单元包括：围绕通道(6)的电极(4),该通道(6)用于通过其中接收交流电压导体系统的各个所述导体,围绕电极(4)的电极屏蔽件(8),电极信号处理电路部分(16),连接到电极(4)和电极屏蔽件(8)并被配置成输出模拟测量信号,以及基准电压信号生成器(10),连接到电极屏蔽件并被配置成生成基准电压源信号,其中,两个或更多个电容电流测量单元的基准电压信号生成器(10)在公共浮动电压连接点处连接在一起。(A non-contact voltage transformer (2) for measuring a voltage between at least two conductors of an alternating voltage conductor system, the transformer comprising two or more capacitive current measuring cells (3), each of said capacitive current measuring cells comprising: an electrode (4) surrounding a channel (6), the channel (6) for receiving therethrough respective said conductors of an alternating voltage conductor system, an electrode shield (8) surrounding the electrode (4), an electrode signal processing circuit portion (16) connected to the electrode (4) and the electrode shield (8) and configured to output an analogue measurement signal, and a reference voltage signal generator (10) connected to the electrode shield and configured to generate a reference voltage source signal, wherein the reference voltage signal generators (10) of two or more capacitive current measurement units are connected together at a common floating voltage connection point.)

1. A non-contact voltage transducer (2) for measuring a voltage between at least two conductors of an alternating voltage conductor system, the transducer comprising two or more capacitive current measuring cells (3), each of said capacitive current measuring cells comprising

An electrode (4) surrounding a channel (6), the channel (6) being adapted to receive therethrough a respective said conductor of an alternating voltage conductor system,

an electrode shield (8) surrounding the electrode (4),

an electrode signal processing circuit part (16) connected to the electrode (4) and the electrode shield (8) and configured to output an analog measurement signal, an

A reference voltage signal generator (10) connected to the electrode shield and configured to generate a reference voltage source signal,

wherein the reference voltage signal generators (10) of two or more capacitive current measurement units are connected together at a common floating voltage connection point.

2. The contactless voltage converter according to claim 1, wherein the conductor system is a multi-phase conductor system and the converter comprises one capacitive current measuring unit (3) for each phase of the conductive system and furthermore one capacitive current measuring unit (3) for the neutral conductor (1 n).

3. The contactless voltage converter of the preceding claim, wherein the conductor system is a two-phase or a three-phase conductor system.

4. A contactless voltage converter according to any of the preceding claims, further comprising an outer electrostatic shield (14) surrounding the two or more capacitive current measurement cells (3), and an additional reference voltage signal generator connected to the outer electrostatic shield and to the common floating voltage connection point.

5. The contactless voltage converter of any preceding claim, wherein the reference voltage signal generator is configured to generate the reference voltage source signal at a frequency higher than an alternating voltage frequency of the conductor system.

6. The contactless voltage converter of any preceding claim, wherein at least two of the reference voltage signal generators are configured to generate the reference voltage source signals at different frequencies from one another.

7. The contactless voltage converter of the preceding claim, wherein each reference voltage signal generator is configured to generate the reference voltage source signal at a different frequency than the other reference voltage signal generators.

8. A contactless voltage converter according to any preceding claim comprising a microcontroller circuit configured to calculate an electrode-conductor admittance matrix Y from the reference voltage source signal and the associated current output by the capacitive current measurement unit.

9. The contactless voltage converter of the preceding claim, wherein the microcontroller circuit comprises a digital-to-analog converter (DAC) for generating a reference voltage signal and an analog-to-digital converter (ADC) for receiving and processing an analog measurement signal response of the output capacitance current from each electrode.

10. The contactless voltage converter of the preceding claim, wherein the converter comprises an energy harvesting unit configured to harvest power from a conductor of the system to be measured, the energy harvesting unit comprising one or more induction coils arranged coaxially or axially adjacent around the one or more electrodes for mounting around the one or more conductors.

11. A contactless voltage converter according to any of the preceding claims wherein the converter includes an autonomous power source in the form of a battery.

12. A contactless voltage converter according to any of the preceding claims, wherein the converter comprises a wireless communication module connected to the processor of the converter to wirelessly transmit measurement signals and receive commands or requests from external systems.

13. An autonomous fully contactless voltage transformer (2) without any direct electrical connection to an external system for measuring the voltage between at least two conductors of an alternating voltage conductor system of the external system, the transformer comprising a wireless communication module for wirelessly transmitting a measurement signal and two or more capacitive current measurement units (3), each of said capacitive current measurement units comprising

An electrode (4) surrounding a channel (6), the channel (6) being adapted to receive therethrough a respective said conductor of an alternating voltage conductor system,

an electrode shield (8) surrounding the electrode (4),

an electrode signal processing circuit part (16) connected to the electrode (4) and the electrode shield (8) and configured to output an analog measurement signal, an

A reference voltage signal generator (10) connected to the electrode shield and configured to generate a reference voltage source signal,

wherein the reference voltage signal generators (10) of two or more capacitive current measurement units are connected together at a common floating voltage connection point.

14. The autonomous non-contact voltage transformer of claim 13, further comprising any of the features of claims 2-12.

15. A method of measuring a voltage between at least two conductors of an alternating voltage conductor system without galvanic connection, comprising:

providing a non-contact voltage transformer according to any preceding claim,

generating a reference voltage signal

Identifying an admittance Y matrix in a processing circuit of the converter based on the reference voltage signal and the corresponding output capacitance current signal,

an impedance matrix Z derived from the admittance matrix Y is calculated in the processing circuitry of the transformer to provide an identification of the conductor system.

16. The method of the preceding claim, comprising

Measuring electrode current of conductor system

In the processing circuit of the converter, the alternating voltage to be measured between the at least two conductors is calculated using the impedance matrix Z.

Technical Field

The present invention relates to a converter for measuring an alternating voltage in a contactless manner.

Background

It is known to measure Alternating Current (AC) voltage and relative phases (typically three phases and neutral) between two or more conductors without interruption and without contacting the conductors. The conductors may for example be in the form of cables, and a capacitive transducer, for example with split electrodes, is placed around each cable. The non-contact transducer facilitates installation and reduces hazards to personnel and equipment, especially in hazardous voltage applications.

In order to reduce the effect of unknown coupling capacitance between the cable and the transducer, and thus enhance the measurement accuracy, two (or more) reference voltage sources may be used as described in US5,473,244.

The main disadvantage of the system described in US5,473,244 and other non-contact voltage measurement systems such as that described in US 6,470,283 is the need to have a ground terminal. The ground connection may not be easily accessible at the location of installation of the voltage measuring transducer, and the need to install current connections increases the cost and complexity of the voltage measuring arrangement.

Furthermore, for hazardous voltage applications, the need to make galvanic connections may increase the safety risk for personnel installing, maintaining or using the measurement equipment.

Disclosure of Invention

In view of the foregoing, it is an object of the present invention to provide a contactless voltage converter that is accurate and reliable without requiring a ground connection.

It would be advantageous to provide a non-contacting voltage converter that is safe and easy to install.

It would be advantageous to provide a non-contact voltage transformer that is cost effective to manufacture and install.

The object of the invention is achieved by providing a contactless voltage converter according to claim 1 or claim 13 and a method according to claim 15.

Disclosed herein is a non-contact voltage transducer for measuring a voltage between at least two conductors of an alternating voltage conductor system, the transducer comprising two or more capacitive current measuring cells, each of said capacitive current measuring cells comprising

Electrodes surrounding a channel for receiving therethrough each of said conductors of the alternating voltage conductor system,

an electrode shield surrounding the electrode and having a plurality of electrodes,

an electrode signal processing circuit part connected to the electrode and the electrode shield and configured to output an analog measurement signal, an

A reference voltage signal generator connected to the electrode shield and configured to generate a reference voltage source signal,

wherein the reference voltage signal generators of two or more capacitive current measurement units are connected together at a common floating voltage connection point.

Also disclosed herein is a fully autonomous non-contact voltage transformer without any direct electrical connection to an external system for measuring the voltage between at least two conductors of an alternating voltage conductor system of the external system, the transformer comprising a wireless communication module for wirelessly transmitting a measurement signal and two or more capacitive current measurement units, each of said capacitive current measurement units comprising

Electrodes surrounding a channel for receiving therethrough each of said conductors of the alternating voltage conductor system,

an electrode shield surrounding the electrode and having a plurality of electrodes,

an electrode signal processing circuit part connected to the electrode and the electrode shield and configured to output an analog measurement signal, an

A reference voltage signal generator connected to the electrode shield and configured to generate a reference voltage source signal,

wherein the reference voltage signal generators of two or more capacitive current measurement units are connected together at a common floating voltage connection point.

In an advantageous embodiment, the conductor system is a multi-phase conductor system, and the converter comprises one capacitive current measuring unit for each phase of the conductive system and furthermore one capacitive current measuring unit for the neutral conductor.

In an advantageous embodiment, the converter may further comprise an external electrostatic shield surrounding the two or more capacitive current measurement cells, and an additional reference voltage signal generator connected to the external electrostatic shield and to the common floating voltage connection point.

In an advantageous embodiment, the reference voltage signal generator is configured to generate the reference voltage source signal at a frequency higher than an alternating voltage frequency of the conductor system.

In an advantageous embodiment, at least two of the reference voltage signal generators are configured to generate said reference voltage source signals at different frequencies from each other.

In an embodiment, each reference voltage signal generator may be configured to generate the reference voltage source signal at a different frequency than the others.

In an embodiment, the voltage converter may comprise a microcontroller circuit configured to calculate the electrode-conductor admittance matrix Y from the reference voltage source signal and the associated current output by the capacitive current measurement unit.

In an embodiment, the microcontroller circuit comprises a digital-to-analog converter (DAC) for generating the reference voltage signal and an analog-to-digital converter (ADC) for receiving and processing an analog measurement signal response of the output capacitance current from each electrode.

Also disclosed herein is a method of measuring a voltage between at least two conductors of an alternating voltage conductor system without galvanic connection, comprising:

there is provided a non-contact voltage transformer as described above,

generating a reference voltage signal

And measuring the corresponding output capacitive current signal of the electrode

Identifying an admittance matrix Y in a processing circuit of the converter based on the reference voltage signal and the corresponding output capacitance current signal,

an impedance matrix Z derived from the admittance matrix Y is calculated in the processing circuitry of the transformer to provide an identification of the conductor system.

The method may further comprise

Measuring electrode current of conductor system

And is

In the processing circuit of the converter, the alternating voltage to be measured between the at least two conductors is calculated using the impedance matrix Z.

Further objects and advantageous aspects of the invention will become apparent from the claims and from the following detailed description and the accompanying drawings.

Drawings

The invention will now be described with reference to the accompanying drawings, which illustrate the invention by way of example, and in which:

FIG. 1 is a schematic simplified diagram of an electrical layout of a non-contact voltage converter according to an embodiment of the present invention;

FIG. 2 is a schematic simplified diagram of the non-contact voltage converter of FIG. 1 for one phase, showing capacitive coupling between conductive elements of the converter;

fig. 3 is a schematic simplified diagram showing an equivalent circuit of the non-contact voltage converter.

Detailed Description

Referring to the drawings, a non-contact voltage transformer 2 according to an embodiment of the invention comprises two or more capacitive current measuring cells 3, each capacitive current measuring cell 3 comprising an electrode surrounding a channel 6, the channel 6 being adapted to receive therethrough a respective conductor 1, 1n of a conductor system comprising at least two conductors at least one of which carries an alternating voltage.

In an embodiment, the conductors of the conductor system may belong to a multi-phase alternating voltage conductive system. The conductive system may be two-phase, three-phase, or have four or more phases, and may further include a neutral conductor. It may be noted, however, that the invention is not limited to multi-phase systems and may be applied to any conductor that exhibits a relative alternating voltage between the measured conductors.

The conductor may be in the form of a conventional insulated wire or cable, or an insulated conductor rod or rod, for example, or have other configurations known per se. In a variation, the conductor may also be uninsulated, and the non-contact voltage transformer includes an insulating layer on the electrode configured to dielectrically separate the electrode from the uninsulated conductor.

The electrode 4 may completely surround the conductor channel 6 or may only partially surround the conductor channel 6, e.g. leaving a gap to allow insertion of a conductor in the channel 6.

The electrodes may be arranged in a housing with a movable part to allow insertion of the conductor to be measured in the corresponding channel 6 of the electrode.

The contactless voltage converter 2 is configured to measure the relative alternating voltage between any two or more conductors 1, 1n of the electrical conduction system. The contactless voltage transformer 2 may also be configured to measure the relative phase between any two or more conductors 1, 1n of the electrical conduction system.

Each capacitive current measuring cell 3 further comprises an electrode shield 8 surrounding the electrode 4, connected to the electrode 4 and the electrode shield 8 and configured to output an analog measurement signal S₁、S₂、S₃、S₄And is connected to the measurement shield and configured to generate a voltage signal V₁、V₂、V₃、V₄The voltage signal generator 10. The voltage signal generators 10 of the plurality of capacitive current measuring cells are connected at a common floating voltage connection point 11Are connected together.

The contactless voltage converter 2 may further comprise a processing unit configured to process the analog measurement signal S₁…S₄Analog-to-digital processing circuit 12.

In an embodiment, the voltage converter may further comprise an outer shield 14 surrounding the plurality of capacitive current measuring cells 3.

In an embodiment, the analog-to-digital processing circuit 12 comprises a microcontroller circuit comprising a digital-to-analog converter (DAC) for generating the reference voltage signal and for receiving and processing the analog measurement signal S₁、S₂、S₃、S₄A responsive analog-to-digital converter (ADC).

The invention relies on the principle of measuring the capacitive current between an electrode and a conductor over an initially unknown capacitance. To measure these capacitances, an additional (small) known voltage signal is applied to the electrode shield by a voltage generator, so that the voltage and current can be determined, and then the impedance can be calculated.

The electrodes are at relatively close potentials to each other, thus enabling a single electronic system to process measurements from all conductors of a multi-conductor conductive system. The electrostatic shield and electrodes around all electrodes simplify the coupled impedance system.

In prior art systems, in order to determine and thus adjust the capacitance current flowing via an unknown ground capacitance, a known high frequency voltage is injected between two electrodes using a voltage source connected to ground potential to calibrate the converter. However, in the present invention, no ground connection is required, so the voltage source is connected to the floating point voltage. The converter according to embodiments of the present invention may be provided without any connection to the external conductor. A transducer according to an embodiment of the invention can thus be mounted without any electrical connection to the conductor to be measured or to the equipment or equipment in which the transducer can be mounted. Advantages include increased ease of installation and increased safety.

Referring to the figures, in the embodiment shown, each conductor 1 is capacitively coupled (capacitance C)₁) To the electrode 4, andthe electrode is capacitively coupled to the electrode 4 (capacitance C)₂) And conductor 1 (capacitor C)₃) Is surrounded by the shield 8. When a voltage is applied to the shield 8 by the voltage generator 10, the associated capacitive current through the electrode can be measured by the signal processing circuitry portion 16. The signal processing circuit part may be, for example, a current-to-voltage conversion circuit, which in its simplest form may comprise a resistor across which a voltage output corresponding to the capacitive current is measured. In the illustrated embodiment, the signal processing circuit includes an operational amplifier that accepts a capacitive current as an input and gives an output voltage proportional to the capacitive input current. The exemplary circuit arrangement shown is also referred to as a transimpedance amplifier.

Each voltage generator 10 supplies a reference alternating voltage source (e.g., a sinusoidal waveform having a frequency of 1 kHz) to the electrode shield, which generates a reference alternating voltage to the electrode shield from these voltage sources V₁…V₄Current of drive I₁…I₄Corresponding output signal S₁…S₄. Reference AC voltage source V₁…V₄And a measured output current I₁…I₄Can be used to derive a previously unknown electrode-conductor admittance matrix Y.

In an embodiment, the additional voltage source V₅May also be used to drive the outermost electrostatic shield 14 of the inverter. In a variant, the system may comprise a plurality of assembled shielding enclosures, wherein the electrodes are connected to a central shielding unit by shielded cables, each shielding enclosure enclosing one or more capacitive current measuring units 3.

The admittance matrix Y is processed in the microcontroller of the transformer to derive the impedance matrix Z. With the impedance matrix Z, the unknown voltage on the conductors 1, 1n can be determined from measurements of the current flowing from the conductors 1, 1n to the electrode 4 at a known or identified alternating voltage frequency f. The known or identified frequency f may be, for example, a 50Hz or 60Hz mains frequency with a substantially sinusoidal characteristic. However, the invention may be implemented in conductor systems having other alternating voltage frequencies, or conductor systems carrying multi-tone voltage signals, or conductor systems having alternating voltages exhibiting non-sinusoidal characteristics.

In the present invention, the voltage reference signal may also be used to estimate the quality of the system identification and, if the quality degrades, automatically and adaptively change the processing method, for example by changing the voltage reference signal, by changing the filter time constant or other processing parameters, to provide an optimal response for identifying the system under various conditions. For example, when the system changes rapidly, a long time constant is not good for a better estimation, and in this case it is preferable to switch to a filtering time constant that coincides with the system time constant. The error may be higher than for a stable system but smaller than when applying non-optimal filtering.

Signal processing for a non-contact voltage transformer having a two conductor system (example neutral and phase or interphase) with an outermost shield that is driven will now be described by way of example. The exemplary process for a two conductor system can be easily adapted to a system with more conductors, thus the admittance matrix is increased by a corresponding number of columns and lines.

The signal processing according to the invention comprises two important processing steps performed by the processing circuitry of the converter:

■ use a reference/calibration voltage source based on the measurement

Carrying out the identification of the admittance Y matrix,

■ use impedance Z matrix derived from admittance Y matrix identification and measured electrode current

To perform conductor voltage calculations.

Y matrix identification

The admittance matrix Y gives the relationship between voltage and current in the system (see fig. 3).

Wherein

Wherein

And is

For k ≠ j, all k'

Is the current in branch j generated by the reference source of branch j.Is the reference source for branch j.

And

is a complex number.

Injected reference voltage V^refThe measured resulting capacitance current I^refAnd the admittance matrix can be expressed in a generalized compact form as:

I^ref＝Y(jω)V^ref

in the normal case Y_ijIs a complex number or even a complex function of the frequency Y (ω). In this example, we identify the admittance matrix Y at only one frequency, and we correct, convert, or scale the admittance matrix Y for other frequencies (see below)

). If the electrode-conductor system is only capacitive, then the real part of the admittance matrix Y is zero (i.e. assuming no resistive losses). However, this is not the case if the dielectric (PVC or other) surrounding the conductor is lost. For example if they are connected one after the otherAll sources, or each source being a sinusoidal signal having a different frequency or various other characteristics, then

Meaning that the source labeled k can be compared with

The source regions are separated. For example, a voltage reference generator may be caused to produce quadrature signals (cross-correlation of 0). These signals may be in the form of bandwidth limited pseudo-random sequences which cover the bandwidth of the signal to be measured but are long enough so that the probability distribution of cross-correlation with the signal to be measured remains close to a very low value most of the time. The emphasis is on using the reference voltage waveform so that the source in branch j can be determined without any ambiguity

Generated current in branch i

The same applies for the reference voltage waveform and the measured voltage waveform, such as 50Hz or 60Hz conducting systems and possible harmonics thereof.

In an embodiment, for example, a sinusoidal waveform may be used for reference voltage sources having different frequencies just above 100Hz (i.e., 127Hz, 113Hz, and 109 Hz). In this way, the reference voltage sources can be easily distinguished from each other, and from the measured voltage waveforms (such as 50Hz or 60Hz power systems and possible harmonics thereof). However, in variations, other methods may be used to identify and characterize the system.

In an embodiment, reference voltage signals may be generated by corresponding voltage generators on each line at a plurality of different frequencies, e.g., 40Hz, 60Hz, 80Hz, 100Hz, and 120Hz, in order to generate a plurality of admittance matrices to better identify and characterize the system, and to account for the effects that varying voltages may have on the identified system impedance. In an embodiment, the reference voltage signal may be in the form of a multi-tone signal or a signal comprising a non-sinusoidal waveform.

More generally, the reference voltage signal may generate any signal sequence that is at least partially orthogonal to the measured signal and at least partially orthogonal to other reference signals. The response to the reference voltage signal sequence can be extracted by correlation.

In an embodiment, the admittance matrix Y may be calculated in the following approximate manner (even though the real and imaginary parts do not necessarily have the same frequency correlation). We can approximate that the real part, which can be associated with dielectric losses, should be small. The imaginary part associated with the capacitive conductor-electrode coupling is frequency dependent. This simplified approximation method gives good results when the dielectric losses are small (but if the dielectric losses are high, the method should be tuned).

Conductor voltage calculation using impedance matrix Z

An impedance matrix Z is calculated from the admittance matrix Y. In the general case, the impedance matrix Z is the pseudo-inverse of the admittance matrix Y.

Z＝pinv(Y)

In this example, we use

Z^*＝pinv(Y^*)F

Using the impedance matrix Z, we can now be based on the currents generated by those sources in the electrode

To calculate the conductor voltage

In a compact form, this can be summarized as:

V^meas＝Z^*I^meas

the voltage difference between conductors i and j is given by (also applicable to the outer shield)

In the above example, the admittance matrix includes the reference voltages of the shields

The latter may however be optional and in this case the calculation of the admittance matrix Y will be simplified to:

in this case, the system becomes square, and we can calculate the voltage difference between the conductor 1 and the conductor 2 based on the following relationship

Z^*＝inv(Y^*)

In an embodiment, the converter may also include an onboard autonomous power source such as a battery. In a variant, the converter may comprise an energy harvesting unit configured to harvest power for operation of the converter from the conductors of the system to be measured. The energy harvesting unit may for example comprise one or more induction coils arranged coaxially or axially adjacent around the one or more electrodes for mounting around the one or more conductors.

In an embodiment, the transducer may further comprise a wireless communication module connected to the processor of the transducer to wirelessly transmit the measurement signal and receive commands or requests from the external system.

Thus for a simple and versatile installation a fully autonomous wireless converter without any galvanic connection can be provided.

List of reference numerals in the drawings:

2 Voltage converter

3 capacitive current measuring cell

4 measuring electrode

16 electrode signal processing circuit

18 operational amplifier

20 input (-V)_in、+V_in)

22 output

6 channel

8 Electrostatic electrode Shield

10 voltage signal generator

16 electrode signal processing circuit

12A/D processing circuit

14 external electrostatic shield

V voltage

I current