ES2971918T3 - Control of the degradation of a vacuum bulb - Google Patents

Description

DESCRIPTION

Control of the degradation of a vacuum bulb

Technical field

The present invention relates to the control of the degradation of a vacuum bulb, in particular the vacuum bulb of a medium and/or high voltage cutting device.

State of the art

Vacuum bulb failure is known to be detected by detecting vacuum loss. For example, EP2463883 refers to a device for detecting vacuum loss in a vacuum cutting apparatus. However, vacuum loss is not the only problem that can affect a vacuum bulb. The inventors have identified that, as the vacuum bulb cuts off the electricity, a metallic deposit appears on the inner wall of the vacuum bulb. This metallic deposit degrades the dielectric performance of the vacuum bulb.

Description of the invention

The invention aims to solve the problems of the prior art by providing a device for controlling the degradation of a vacuum bulb of a switching apparatus, characterized in that it comprises:

• two electrodes that form a capacitor, arranged on the outer surface of the vacuum bulb,

• a capacitive measurement circuit connected to the two electrodes and adapted to measure an electrical parameter representative of the capacitance of the capacitor.

Capacitive measurement allows monitoring the level of degradation of the vacuum bulb, as the measured capacitance value changes as a metallic deposit appears on the inner wall of the vacuum bulb. In this way, the dielectric performance of the vacuum bulb is controlled during its period of use.

The invention provides a predictive maintenance means intended to be installed in the vacuum bulb. According to a preferred feature, the electrodes that form a capacitor comprise two portions of metal tape, each of which has a width between 2 and 20 millimeters, each end of one of the portions of metal tape being separated from one of the ends. from the other portions of metal tape for a distance greater than 8 millimeters.

According to alternative preferred characteristics:

• the capacitive measurement circuit comprises an inductor connected to the capacitor and a circuit for measuring a resonant frequency of an oscillator formed by the capacitor and the inductor, or

• the capacitive measurement circuit comprises a resistor connected to the capacitor and a circuit for measuring a charge or discharge time of the circuit comprising the capacitor and the resistance, or • the capacitive measurement circuit comprises a resistor and an inductor connected to the capacitor and a circuit for measuring the impedance of the circuit comprising the capacitor, the inductor and the resistor. The invention also relates to a vacuum bulb of a cutting apparatus, equipped with a degradation control device as presented above.

The invention also relates to a method for controlling the degradation of a vacuum bulb of a switching apparatus by means of a control device such as the one presented above, characterized in that it comprises the steps of:

• measurement of the value of an electrical parameter representative of the capacitance of the capacitor,

• comparison of the value of the previously measured electrical parameter with a reference value, and

• An alert is sent when the value of the electrical parameter representative of the capacitor capacitance reaches the reference threshold value.

The vacuum bulb and the procedure have similar advantages to those presented above.

Brief description of the drawings

Other features and advantages will become apparent from the following description of a preferred embodiment, given by way of non-limiting example, described with reference to the figures in which:

the [Fig. 1] illustrates a device for controlling the degradation of a vacuum bulb of a cutting apparatus, according to an embodiment of the invention,

the [Fig. 2] illustrates a variant of the measurement circuit included in the device of Fig. 1, according to an embodiment of the invention,

the [Fig. 3] illustrates a procedure for controlling the degradation of a vacuum bulb of a cutting apparatus, according to an embodiment of the invention, and

the [Fig. 4] shows a curve of resonance frequency measurements made according to the invention. The identical, similar or equivalent parts of the different figures carry the same numerical references to facilitate the transition from one figure to another.

The various parts that appear in the figures are not necessarily shown on a uniform scale, to facilitate reading of the figures.

The various possibilities (variants and embodiments) are to be understood as not mutually exclusive and can be combined with each other.

Detailed description of particular embodiments

Figure 1 shows a preferred embodiment of a device for controlling the degradation of a vacuum bulb 1. The vacuum bulb 1 is intended for use in a cutting apparatus for cutting an electric current in an electrical circuit, in particular a circuit of medium and/or high voltage.

Below, the terms "medium voltage" and "high voltage" are used in their usual sense. The term "medium voltage" refers to a voltage that exceeds 1,000 volts in alternating current and 1,500 volts in direct current, but does not exceed 52,000 volts in alternating current and 75,000 volts in direct current. The term "high voltage" refers to a voltage strictly greater than 52,000 volts in alternating current and 75,000 volts in direct current.

Hereinafter, the term "cutting apparatus" is used to designate an electrical device.

such as a contactor, a switch, a fuse switch or a closing device. Other types of cutting devices using a vacuum bulb are also possible.

In a manner known per se, the vacuum bulb 1 comprises a housing 11 of substantially cylindrical shape along an elongation axis X, closed by two end plugs. The housing 11 contains an electrode 4 that is fixed with respect to said housing and an electrode 5 that is movable with respect to said housing. At their free ends, the two electrodes 4 and 5 respectively support a fixed contact 6 and a mobile contact 7. The mobile electrode 5 moves between a contact position of the two contacts 6 and 7 and a separation position of the two contacts. .

The housing 11 thus forms a ceramic enclosure closed by the two end caps, through which the two electrodes 4 and 5 pass respectively.

The bulb 1 also comprises one or more dielectric screens 8, in particular metallic, generally placed around the fixed contact 6 and the mobile contact 7. Other screens or screen positions not shown are also possible.

The degradation of the vacuum bulb is characterized by the appearance of a metallic deposit on the inner wall of the vacuum bulb in the deposition zones 9, in particular in the areas of the inner wall not protected by a dielectric screen. This metallic deposit degrades the dielectric performance of the bulb.

The device for controlling the degradation of the vacuum bulb 1 comprises two electrodes 21 and 22 that form a capacitor 2, arranged on the outer surface of the vacuum bulb. The two electrodes are identical and are formed by two portions of metal tape, for example copper, each of which has a width of between 2 and 40 millimeters, or even between 2 and 20 millimeters. In one embodiment, the width of the electrodes is, for example, 12 millimeters.

The two electrodes are pressed against the outer surface of the bulb, being arranged in the same ring perpendicular to the elongation axis metal deposit. These deposition zones 9 are, in particular, those of the inner wall not protected by the dielectric screen 8. However, the two electrodes can also be partially or completely opposite a part of the inner wall protected by the dielectric screen 8. Each electrode has a length of less than half the perimeter of the cylinder of the enclosure 11, so that the ends of the electrodes 21 and 22 are opposite each other and separated, for example, by at least 8 millimeters, for example a distance of between 10 and 15 millimeters.

The vacuum bulb degradation monitoring device 1 also includes a capacitive measuring circuit 3 to which the two electrodes 21 and 22 are connected. The capacitive measuring circuit 3 is adapted to measure a value representative of the capacitance of the capacitor 2. formed by the two electrodes 21 and 22.

The capacitive measuring circuit 3 is supplied with energy, for example by a power circuit that recovers energy from the cutting device. According to a first variant, a magnetic field created by the current in the medium or high voltage circuit of the switching device is concentrated by a ferromagnetic core and an induction coil generates the supply voltage for circuit 3. According to a second variant, A voltage can be directly recovered between two armatures placed at different potentials. This energy recovery avoids the use of an external power source, such as a battery, which would have to be replaced in the event of failure. However, the use of such an external energy source can be envisaged, especially for short-term control (for example, in an accelerated aging process).

The vacuum bulb degradation control device 1 is preferably mounted on the vacuum bulb inside the cutting apparatus.

The capacitive measurement circuit 3 comprises a first circuit comprising an inductor, or a resistor, or an inductor and a resistor, connected to the capacitor 2.

The capacitive measurement circuit 3 comprises a second circuit adapted to measure a value of an electrical parameter characteristic of the first circuit. This electrical parameter is correlated with the capacitance of capacitor 2.

Alternative versions of the capacitive measurement circuit 3 will be described below.

Referring to Figure 2, a first variant of the capacitive measurement circuit 3 comprises a first circuit that includes a predetermined value inductor 31 connected in parallel with the capacitor 2. The capacitive measurement circuit 3 also includes a second circuit 32 for measuring the resonance frequency of an oscillator formed by capacitor 2 and inductor 31.

The resonance frequency f of the circuit formed by capacitor 2 and inductor 31 is equal to:

/ = 1/2 WZC

where L is the value of the inductance 31 and C is the value of the capacitance of the capacitor 2.

Knowing the value of inductance 31 and measuring the resonance frequency f allows us to deduce the value of the capacitance C of capacitor 2.

In practice, the resonance frequency measurement circuit 32 comprises, for example, an electronic circuit dedicated to measuring the resonance frequency of an LC oscillator, such as the LDC1000 component sold by the company "Texas Instruments".

Alternatively, instead of the inductor 31, the first circuit of the capacitive measurement circuit 3 comprises a resistor of predetermined value connected in parallel with the capacitor 2. The second circuit 32 of the capacitive measurement circuit 3 is capable of measuring a charging time or discharge of the RC circuit comprising capacitor 2 and resistor connected in parallel.

According to another variant, the first circuit of the capacitive measurement circuit 3 comprises an association of an inductor of predetermined value and a resistor of predetermined value with the capacitor 2. The second circuit 32 of the capacitive measurement circuit 3 is capable of measuring the impedance of the circuit comprising the capacitor, inductance and resistance at a given frequency, for example greater than 100 Hz. This impedance can be measured with any suitable component, for example the AD8302 component sold by “Analog Device”.

Figure 3 illustrates the procedure for controlling the degradation of a vacuum bulb in a cutting apparatus. The bulb is equipped with the device described above. The procedure comprises steps E1 to E3.

In stage E1, the value of an electrical parameter representative of the capacitance of capacitor 2 is measured.

According to the first device variant, the electrical parameter is a resonance frequency of an oscillator formed by the capacitor 2 and the inductor 31.

According to the second variant of the device, the electrical parameter is a charging or discharging time of the circuit comprising the capacitor 2 and a resistor.

According to the third device variant, the electrical parameter is the impedance of the circuit comprising the capacitor 2, an inductor and a resistor at a given frequency, for example greater than 100 Hz.

The next step E2 consists of comparing the value of the electrical parameter representative of the capacitance of capacitor 2 with a reference threshold value. This comparison may involve a step of calculating the actual value of the capacitance of the capacitor 2 from the value of the previously measured electrical parameter, for comparison with a threshold value of capacitance, or it may be carried out directly by comparing the value of the representative electrical parameter. of the capacitance of capacitor 2 with a parameter threshold value.

The reference threshold value can be determined by performing accelerated aging measurements on a set of test vacuum bulbs, correlating a desired dielectric strength threshold with a value of the electrical parameter representative of the capacitance of the capacitor 2 that should not be exceeded. The reference threshold value can also be determined by a calibration operation in which an initial measurement of the electrical parameters is made in the new bulb.

Steps E1 and E2 are carried out, for example, periodically or after each opening of the cutting apparatus or each time a predetermined number of openings of the cutting apparatus have occurred.

If steps E1 and E2 are carried out after each opening of the cutting device, the degradation control device is only powered when the circuit including the cutting device is open, that is, after each change in the degradation level.

The values of the measured electrical parameters and/or the calculated capacitance values can be stored as steps E1 and E2 are performed. In this way, it is possible to control changes in the value of the electrical parameter and/or the capacitance depending on the number of interruptions made by the switching device. This evolution is expressed, for example, in the form of a curve.

Comparison and curve determination can be performed directly within the capacitive measurement circuit or remotely using a dedicated calculation element; in the latter case, the electrical parameter representative of the capacitance of the capacitor 2 is transmitted, for example wirelessly, to this calculation element.

Figure 4 shows a curve of resonant frequency measurements as a function of the number of interruptions made by the cutting apparatus, in the case where the capacitive measurement circuit 3 includes an inductor 31 as shown in Figure 2 (LC circuit) .

A gradual decrease in the resonance frequency is observed as the cutting apparatus makes more cuts and a steeper slope towards the 10th abscissa of the scale, which corresponds to a gradual increase in the value of the capacitance of capacitor 2 with the number of cuts made and is an indicator of vacuum bulb degradation. The reference threshold value for the resonant frequency is set, for example, to a value of the order of 1.6 MHz.

Referring again to Figure 3, step E2 is followed by step E3 of issuing an alert when the value of the electrical parameter representative of the capacitance of capacitor 2, or the value of the capacitance of capacitor 2, reaches the threshold value predetermined. This alert may trigger an operation to replace the defective bulb.

Claims (7)

1. Device for controlling the degradation of a vacuum bulb (1) of a cutting device, characterized in that it comprises: - two electrodes (21, 22) that form a capacitor (2), arranged on the outer surface of the vacuum bulb (1), - a capacitive measurement circuit (3) connected to the two electrodes and adapted to measure an electrical parameter representative of the capacitance of the capacitor (2). 2. Control device according to claim 1, wherein the electrodes (21, 22) that form a capacitor comprise two portions of metal tape each of which has a width of between 2 and 20 millimeters, each end being a of the metal tape portions separated from one of the ends of the other of the metal tape portions by a distance greater than 8 millimeters. 3. Control device according to claim 1 or 2, wherein the capacitive measurement circuit (3) comprises an inductor (31) connected to the capacitor (2) and a circuit (32) for measuring a resonant frequency of an oscillator formed by the capacitor and the inductor. 4. Control device according to claim 1 or 2, wherein the capacitive measurement circuit (3) comprises a resistor connected to the capacitor (2) and a circuit for measuring a charge or discharge time of the circuit comprising the capacitor and the resistance. 5. Control device according to claim 1 or 2, wherein the capacitive measurement circuit (3) comprises a resistor and an inductor connected to the capacitor (2) and a circuit for measuring the impedance of the circuit comprising the capacitor, the inductor and resistance. 6. Vacuum bulb (1) of a cutting apparatus, equipped with a degradation control device according to any one of claims 1 to 5. 7. Procedure for controlling the degradation of a vacuum bulb (1) of a cutting device by means of a control device according to any one of claims 1 to 5, characterized in that it comprises the steps of: - measurement (E1) of a value of an electrical parameter representative of the capacitance of the capacitor, - comparison (E2) of the value of the previously measured electrical parameter with a reference value, and - issuance (E3) of an alert when the value of the electrical parameter representative of the capacitance of the capacitor reaches the reference threshold value.