The present invention relates to a capacitor for taking measurements of the primary voltage of high-voltage equipment. The invention relates in particular to gas-insulated metal-clad high-voltage electrical equipment, such as a gas-insulated cable, or a gas-insulated high-voltage substation element.
Such a capacitor is known from patent documents, e.g. FR 2 828 003 or FR 2 705 492.
The capacitor described in Patent Document FR 2 828 003 has a casing (ENV) connected to a “zero” reference potential, typically to the electrical ground of the host equipment. The casing (ENV) has an annular inside surface against which a printed circuit (CI) is pressed mechanically and resiliently, i.e. in a manner such as to allow the printed circuit (CI) to expand while it remains pressed against the inside face of the casing (ENV).
The element subjected to the high voltage to be measured is connected electrically to a high-voltage electrode (HT) of the capacitor. The high-voltage electrode (HT) of the capacitor is generally constituted by a cylindrical metal bar. It is surrounded by a low-voltage electrode (BT), which is implemented by means of an electrically conductive track of the annular printed circuit (CI). The printed circuit (CI) both mechanically positions the low-voltage electrode (BT) relative to the casing (ENV) and also electrically insulates said low-voltage electrode (BT) from the casing (ENV). The high-voltage electrode (HT), the printed circuit (CI), and the inside surface of the casing (ENV) are assembled together coaxially.
That capacitor structure causes two capacitors to appear, namely a high-voltage capacitor Cht and a low-voltage capacitor Cbt. The plates of the capacitor Cht are respectively the high-voltage electrode (HT) and the low-voltage electrode (BT), and its dielectric is the gas with which the casing is filled. The plates of the capacitor Cbt are respectively the low-voltage electrode (BT) and the casing (ENV), and its dielectric is the substrate of the printed circuit, which substrate is typically made of a composite material based on epoxy resin and on glass fibers, or the like.
The stability and the accuracy of the measurement are dependent on the stability and on the accuracy of the capacitance Cht, whose value is given by the following relationship:
where ∈0 is the permittivity of vacuum, ∈r is the relative permittivity of the dielectric gas, D is the diameter of the low-voltage electrode, d is the diameter of the high-voltage electrode, and S is the area of the low-voltage electrode (BT) that is influenced by the high-voltage electrode (HT). If the low-voltage electrode (BT) is implemented in the form of a plurality of electrode elements connected in parallel, S represents the total area of the electrode elements.
In order to obtain a voltage measurement that is of very high accuracy, it is thus necessary to implement a capacitance Cht that is very accurate and very stable.
That type of capacitor is generally associated with high-voltage electrical equipment that is subjected to temperature variations due to climatic conditions and to operating conditions. Such temperature variations typically span the range −25° C. to +55° C. for usual applications, and go well beyond that range for special applications.
Such temperature variations cause the component materials of the capacitor to expand and to contract, which modifies the capacitance of the capacitor Cht, unless special precautions are taken. The arrangements described in Patents FR 2 828 003 and FR 2 705 492 are intended to solve those problems of the materials expanding and contracting.
In addition to the problems of the materials expanding and contracting, the capacitance Cht is dependent on the relative permittivity ∈r of the gas used as the dielectric. That permittivity is in turn dependent on the density of the gas filling the casing (ENV), which density can vary between a rated filling value and a minimum allowed value due to possible gas leaks. That dependence is expressed by the following relationship, deduced from the Clausius-Mosotti equation:
where k is a constant that is characteristic of the gas, related to its electron polarizability and to its atomic mass, and ρ represents the density of the gas. In practice, k·ρ<<1. Therefore, while maintaining good accuracy, the formula becomes:
∈r≈1+3·k·ρ
A technique known from the state of the art consists in continuously measuring the density ρ of the gas in order to make corrections automatically by computing variations in its relative permittivity deduced from knowledge of ρ. Said density can be measured either directly by means of a densimeter per se, or indirectly by using a method that consists in measuring the pressure P and the temperature T of the gas, and in computing the density ρ by means of the gas equation, which method is applicable both for a pure gas and for a mixture.
Unfortunately, in practice, the density of gas used in high-voltage equipment is non-uniform, due to the temperature gradients generated by the combined effects of the environment (sun, rain, etc.) and of the heating generated by the primary currents in the equipment. However, the pressure P is uniform, and measuring it poses no difficulties.
An object of the present invention is to continue to solve the problems related to the component materials of the capacitor expanding and contracting, and also to improve the accuracy with which the density ρ is measured by improving measurement of the mean temperature T of the gas between the high-voltage and the low-voltage electrodes of the capacitor Cht.
To this end, the invention provides a highly temperature-stable capacitor for taking measurements on a high-voltage line as described in above-mentioned Patent Application FR 2 828 003, said capacitor having a high-voltage electrode (HT), an annular printed circuit (CI) surrounding said high-voltage electrode (HT) coaxially and having at least one electrically conductive track that forms a low-voltage electrode (BT), the capacitor of the invention being characterized in that the printed circuit (CI) also has at least one temperature-sensitive resistor (TH).
A temperature-sensitive resistor is a two-pole component whose resistance varies with a known relationship as a function of the temperature to which it is subjected.
The positioning of the temperature-sensitive resistor on the printed circuit of the low-voltage electrode makes it possible to measure the temperature of the gas between the electrodes of the capacitor as close as possible to the capacitor, and in particular to its dielectric. As in the above-mentioned prior art, the printed circuit is preferably held resiliently against the inside wall of the casing ENV.
In a preferred embodiment of the capacitor of the invention, a metal screen (EM) is interposed between the temperature-sensitive resistor and the high-voltage electrode (HT) so as to protect the temperature-sensitive resistor from the influence of the high voltage.
In another preferred embodiment of the capacitor of the invention, the temperature-sensitive resistor is constituted by at least one electrically-conductive track of the printed circuit.
This configuration of the temperature-sensitive resistor makes it possible to measure the temperature very reliably because it gives a mean view of the temperature over a large area inside the capacitor.
In another preferred embodiment of the invention, the electrically conductive track of the temperature-sensitive resistor is a copper track because copper is the basic material in printed-circuit technology and has thermal properties that are ideal for making temperature-sensitive resistors, in particular for the most common temperature ranges considered for high-voltage equipment.
The capacitor of the invention may, in addition, have the following features:
The track of the temperature-sensitive resistor is flanked on either side by a guard track that is connected to a “zero” reference potential.
In an embodiment, the low-voltage electrode BT is coupled to a circuit which electronically servo-controls its voltage to a reference voltage.
The present invention will be better understood on reading the following description and on examining the figures that accompany it. The description is given merely by way of indicative and in no way limiting example of the invention. The references used in the following description are the same as the references used above to describe the prior art, when the elements perform the same function as in the prior art. In the figures:
As shown in
It has a high-voltage electrode HT that extends along a main axis AX.
The tracks BT1, BT2, TH1, TH2 form circular bands that surround the high-voltage bar HT, and they are represented in
It should be noted that the printed circuit CI can also have a wide conductive track over its outside face, said conductive track being connected to ground via the structure. This provision guarantees that the value of the auxiliary capacitance Cbt is kept better under control.
In the capacitor of the invention, temperature is measured by means of a temperature sensor having distributed constants and sharing the same printed circuit CI as the low-voltage electrode BT. Said sensor constituted by the temperature-sensitive resistor TH gives an overall measurement of the temperature over its entire area. Similarly, the low-voltage electrode BT gives an overall measurement of the capacitance Cht over its entire area. The temperature-sensitive resistor TH is formed, in this example, by one or more electrically conductive tracks whose resistivity varies with varying temperature. It can be seen in
Starting from the measurement of the resistance R of the temperature-sensitive resistor, the surface temperature of the printed circuit is deduced from the relationship R=f(T), which is a good estimate of the mean temperature T of the dielectric gas of the capacitor. This measurement then makes it possible firstly to correct the effects of the permittivity variations generated by gas leaks, and secondly to correct the residual temperature drift of the capacitance Cht due to expansion and other thermal effects.
Therefore, it is very simple to make a capacitor having a sensor for measuring the temperature of the gas that is inexpensive and that is very compact. Said sensor is situated directly in the zone in which the capacitance is situated, the value of the capacitance making it possible to determine the value of the dielectric constant of the gas.
The high-voltage electrode HT, the printed circuit CI, the metal screen(s) EM and the inside surface of the casing ENV are, as in the preceding example, assembled together coaxially.
In the preferred embodiment of the invention, the voltage of the low-voltage electrode BT is electronically servo-controlled to a reference voltage, e.g. ground voltage, by means of a circuit 10 shown in
The low-voltage electrode BT is connected at a first inlet N of a differential amplifier AOP through a first resistor R1, e.g. of resistance of the order of about one hundred ohms. A second inlet P of the differential amplifier AOP is connected to ground which thus constitutes the reference voltage. The outlet S of the differential amplifier AOP is looped back to the inlet N by means of a second resistor R2.
The capacitor Cbt appears as an auxiliary capacitor that plays no part in measuring the voltage at industrial frequencies but that grounds the very high frequency interference generated by the movements of switch elements (circuit-breakers or disconnectors) in the network or grid on which the equipment is installed.
The current that then flows through the capacitor Cht and that emerges from the low-voltage electrode BT is thus a faithful image of the time derivative of the voltage of the high-voltage electrode HT. Signal processing (not described herein) makes it possible, e.g. by digital integration, to retrieve an accurate image of the voltage from its time derivative as measured in this way.
Therefore, measuring the voltage applied to the capacitor of the invention reduces to measuring the current flowing through the high-voltage capacitor Cht.
As can be seen in
The annular printed circuit CI can be made up of a plurality of pieces that then together form a single printed circuit.
Number | Date | Country | Kind |
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05 50360 | Feb 2005 | FR | national |
Number | Name | Date | Kind |
---|---|---|---|
4052668 | Schmitt et al. | Oct 1977 | A |
4931843 | Goetz | Jun 1990 | A |
5444599 | Dupraz et al. | Aug 1995 | A |
5482793 | Burns et al. | Jan 1996 | A |
20030030962 | Gutalj et al. | Feb 2003 | A1 |
Number | Date | Country |
---|---|---|
24 09 595 | Aug 1975 | DE |
0 780 692 | Jun 1997 | EP |
2 705 492 | Nov 1994 | FR |
2 828 003 | Jan 2003 | FR |
Number | Date | Country | |
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20080007889 A1 | Jan 2008 | US |