EP1769513B1 - Coupling electrode for capacitive voltage tapping within the insulation body of a duct or an insulator - Google Patents

Description

The invention relates to a coupling electrode for capacitive Spannungsabgriff within an insulating body of a component having at least one embedded in the insulator with acted upon high-voltage potential conductor portion having an electrode portion consisting of a semiconductive plastic and electrically connected to the electrode portion connecting element, which can be brought out of the insulating is.

The invention further relates to a component having at least one conductor section which can be acted upon by high-voltage potential and an insulating body made of insulating material, in which each conductor section is embedded.

Such a coupling electrode and such a component are known from EP 0 400 491 A2 already known. The coupling electrode shown there has an annular electrode section of a semiconducting plastic. At the electrode portion, a connecting element formed as a connecting pin is formed, so that there is an electrically conductive connection between the connecting pin and the electrode portion. The component shown there has an insulating body, in which the said coupling electrode is embedded. In this case, the connection element is led out of the insulating body, so that the potential of the electrode section can be tapped by appropriate connector on the connection element. In this case, the annular electrode portion encloses a conductor section, which also extends through the insulating body, wherein the conductor portion and the electrode portion are arranged coaxially with each other. The component described is used as a so-called implementation in high and medium voltage technology. In operation, the conductor section is subjected to a high-voltage potential, wherein the coupling electrode is used as a capacitive divider element, on which a potential proportional to the high-voltage potential is generated, with which the voltage of the conductor section can be followed. The previously known coupling electrode and the previously known component have the disadvantage that in the production of the insulating body of the component, the coupling electrode must be laboriously positioned on the connecting element. Such a holder of the coupling electrode during the Gießformprozesses is beyond error prone, so that it can lead to inaccuracies in measurement.

From the DE930777U1 is a coupling electrode for capacitive voltage tap within an insulating known.

The invention has for its object to provide a coupling electrode and a component of the type mentioned, which are inexpensive, with an accurate alignment of the coupling electrode is made possible within the cast-molded insulating.

The invention achieves this object by means of a holder consisting of a non-conductive material, which holder is connected to the electrode section and has the parking means with which an insulated mounting of the electrode section is made possible.

According to the invention, the coupling electrode has a non-conductive holder. Due to the non-conductivity, it is possible according to the invention, the coupling electrode with the Abstellmitteln the holder, for example on a later in a Application to bring earth potential having area of the component in contact, without affecting the electrical properties of the coupling electrode are adversely affected. In this way, the object of positioning the coupling electrode and the formation of an electrical connection point is separated according to the invention.

Conveniently, the insulator consists of cast resin. The selected semiconducting plastic, from which the electrode portion is made, and cast resin have a similar coefficient of thermal expansion, so that in particular at high temperature changes resulting mechanical stresses are avoided within the insulator.

Conveniently, a connector connected to a conductor is provided, which can be pushed onto the connection element. In this way, the coupling electrode is detachably connectable to other electronic devices, such as protective devices.

According to an expedient further development, sealing means are provided which are set up to hold the connection plug in the insulating body. The sealing means are arranged for example before insertion of the connector plug in the insulating body of the component. The connector is then simply plugged into the component and pushed onto the sealant. With the help of the sealant in addition to a simple electrical connection of the coupling electrode and an electrical insulation of the connector in the component allows. The sealants also prevent the entry of moisture or other contaminants. Of course, it is within the scope of the invention also possible, the sealant to the connector to attach before it is inserted into the insulating body.

In an expedient further development, the sealing means consist of an elastomer. The elastomer is advantageously an insulating material. A subsequent casting of the connection plug with sealing materials, which has become known from the prior art, is eliminated according to the invention. The elastomer is, for example, a suitable silicone rubber or the like.

In a preferred development of the invention, the sealing means in the insulating body of the component can be latched. For this purpose, for example, locking grooves are formed in the insulating body, in which the sealing means are pressed when inserting the connector plug. The detent grooves are located, for example, in a recess provided in the insulating body into which the connecting element protrudes. The sealing means have such elasticity that, on the one hand, penetration into the latching grooves and thus engagement behind the device is possible. On the other hand, the elasticity is adjusted so that a sufficiently high holding force is provided to prevent accidental slipping out of the connector plug from the insulating body. The sealing means are for example a single sealing element.

Advantageously, the semiconductive plastic contains polyphenylene sulfide and carbon fibers. With this mixture is provided for a sufficiently high conductivity, the coefficient of thermal expansion is largely matched to that of the casting resin commonly used in the production of the insulating body. Mechanical stresses between the electrode portion and the insulating body with Material breaks in the wake are avoided in this way. The semiconductive plastic preferably consists only of the two said components. However, customary additives can also be used in the context of this further development, with the specified proportion of the carbon fibers always referring to the total weight of the electrode section.

According to an expedient further development, the proportion of carbon fibers is between 15% by weight and 35% by weight. A carbon fiber content in this range has proven to be sufficient to provide the necessary conductivity.

Advantageously, the nonconductive material is polyphenylene sulfide. As has already been explained in connection with the electrode portion made semiconductive by the carbon content, polyphenylene sulfide has a coefficient of thermal expansion which largely corresponds to that of the casting resin. Thus, stresses between the holder and the insulating body are inventively avoided.

By contrast, the non-conductive material comprises a mixture of polyphenylene sulfide and glass fibers. The glass fibers reinforce the holder so that increased mechanical strength is provided. In this way, destruction or deformation of the coupling electrode can be avoided for example in the manufacturing process.

The electrode section expediently has a roughened surface. The roughened surface improves the adhesion of the electrode section in the insulating body. This is a free transfer between Ensures electrode portion and insulator and prevents occurrence of discharge processes.

Advantageously, the holder has a retaining ring connected to the electrode section.

In a related expedient development of the retaining ring is connected to Abstellfüßen whose free end form the Abstellmittel.

The component according to the invention has a coupling electrode as described above and is easier and less expensive to produce due to the simpler positioning of the coupling electrode.

Expediently, the component is a bushing with the aid of which a passage of conductor sections with a high-voltage potential through a wall subjected to ground potential, for example, is made possible without discharge processes taking place.

Notwithstanding this, the component is a so-called supporter whose free ends are connected on the one hand with components at high voltage potential and on the other hand with components at ground potential.

Advantageously, the coupling electrode is completely embedded in the insulating body.

Figur 1

eine perspektivische Ansicht eines Ausführungsbeispiels der erfindungsgemäßen Koppelelektrode,

Figur 2

eine Querschnittsansicht eines Ausführungsbeispiels des erfindungsgemäßen Bauteils,

Figur 3

eine vergrößerte Darstellung des Bauteils gemäß Figur 2 in einer Querschnittsansicht und

Figur 4

ein weiteres Ausführungsbeispiel des erfindungsgemäßen Bauteils in einer Querschnittsansicht zeigen.

Further expedient embodiments and advantages of the invention are the subject of the following descriptions of embodiments with reference to the figures of the drawing, wherein like reference numerals refer to like-acting components and wherein

FIG. 1

a perspective view of an embodiment of the coupling electrode according to the invention,

FIG. 2

a cross-sectional view of an embodiment of the component according to the invention,

FIG. 3

an enlarged view of the component according to FIG. 2 in a cross-sectional view and

FIG. 4

show a further embodiment of the component according to the invention in a cross-sectional view.

FIG. 1 shows an embodiment of the coupling electrode 1 according to the invention in a perspective view. The coupling electrode 1 has an annular electrode portion 2 and an electrically connected thereto pin 3 as a connecting element, which in the in FIG. 1 shown example is attached to the lower ring side of the electrode portion 2 and protrudes from there to the outside.

The coupling electrode 1 also has a holder 4, which is fixedly connected to the electrode section 2 on its fastening side 5. For this purpose, the holder 4 a clamped to the electrode portion retaining ring 4a, are integrally formed on the three identically formed L-shaped support legs 4b. The longer legs of the L-shaped support feet 4b of the holder 4 are designed as free ends, so that parking means 7 are formed. Define the three free ends 7 a flat storage area on which the coupling electrode 1 can be stored safely and stably.

The electrode section 2 of the coupling electrode 1 is made of a semiconductive plastic and in this case of polyphenylene sulfide with a carbon content of 30 wt.%. The electrically non-conductive support 4, however, is made of pure polyphenylene sulfide, which has been mechanically reinforced with glass fibers.

FIG. 2 and 3 shows an embodiment of a component 8 according to the invention in a cross-sectional view. The component 8 shown here has a rotationally symmetrical insulating body 9, which consists of cast resin. Through the insulating body 9, a conductor section 10 extends through, which is equipped at its two free ends with fastening means 11 and 12. By fastening means 11, 12 of the conductor portion with high-voltage potential leading conductors can be connected, so that in the operating state of the conductor portion 10 itself is at a high voltage potential.

To fasten the component 8, which is a bushing here, in the passage opening of a housing at ground potential, a flange 13 is used, which extends with its free end 14 into the insulating body 9 and sealed there with an elastic material 15 is. For measuring the potential of the conductor section 10, the coupling electrode 1 is arranged with its electrode section 2 concentrically around the conductor section 10 and likewise embedded in the insulating body 9. In this case, the holder 4 with its Abstellmitteln 7 on the flange 13. For tapping off the potential of the electrode section 2 on the connecting pin 3 is a with a connecting line fourteenth connected connector 15 is provided, wherein the connecting line 14 and up to the pin 3 contacting insertion end and the connector 15 are surrounded by an insulating flexible. The connector 15 is held by insulating means 16, which are made of an elastic and non-conductive material, such as silicone or silicone rubber, insulated from the outside environment to the insulating body 9. By pressing the connector 15 in a formed in the insulating body 9 recess 17, the sealing means 16 is pressed into locking grooves which are formed in the recess 17. This results in jamming of the connector 15 in the recess 17 by the latched sealing means 16, so that a stable and electrically sealed mounting of the connector 15 is provided.

FIG. 3 shows an enlarged view of the connecting line 14 with the connector 15 and the sealing means 16. In this illustration, it can be seen that the electrode portion 2 is clamped on an outer ring portion 4a of the holder 4. The connecting pin 3 is not integrally formed with the electrode portion 2 in the embodiment shown. Rather, the terminal pin 3 is positioned in a press-fit opening of the electrode section 2 and clamped with this. The sealing means 16 are realized in the embodiment shown as a single elastic silicone element.

It may also be expedient in the context of the invention to coat the connector 15 outside with a heat-shrinkable tube prior to insertion onto the connecting pin 3. In this way, we increased the tightness in cooperation with the sealing means 16. It should also be noted that the sealing means 16 can not only extend within the recess 17, but can also be guided out of this.

FIG. 4 shows a further embodiment of a component according to the invention, which is a so-called support insulation 18 or in other words is a supporter. The support insulation 18 again has a conductor portion 19 which, however, does not extend completely through the insulating body 9 of the support insulation 18, but has a free end which is completely embedded in the insulating body 9. The conductor section 19 again has fastening means 11 for fastening a conductor, not shown, with high-voltage potential. At the opposite end of the attachment means 11 of the support insulation 18, this forms a storage area, on which the support insulation 18 can be fastened to a surface lying at ground potential. Extending screens 20 serve to increase the creepage distance along the outer surface of the support insulation. Furthermore, it can be seen that in the insulating body 9, the coupling electrode 1 according to the invention is embedded. In the exemplary embodiment shown, the connection element 3, which is firmly and electrically conductively connected to the electrode section 2, is not pin-shaped, but bent at a 90 ° angle, with its free end projecting into a recess 21 of the insulating body 9.

The insertion end of the connector 15 is adapted to the depth of the recess 21, so that a secured tap of the potential of the electrode portion 2 is made possible also in this embodiment of the component 18. Again, a latchable sealant 16 is used for secure attachment of the connector 15 to the insulating body 9 and the electrical Sealing of the connector 15 and to prevent the entry of moisture into the recess 21st

Claims (14)

1. Coupling electrode (1) for capacitive voltage tapping within an insulating body (9) of a component (8, 18) which has at least one conductor section (10, 19) which is embedded in the insulating body (9) and to which a high-voltage potential can be applied, having an electrode section (2) which is composed of a semiconductive plastic, and having a connecting element (3) which is electrically connected to the electrode section (2) and is designed such that it can be passed out of the insulating body (9),
   characterized by
   a holder (4) which is composed of a non-conductive material, is connected to the electrode section (2) and has the positioning means (7), which allow isolated mounting of the electrode section (2), and
   in that the holder (4) has a holding ring (4a) which is connected to the electrode section (2).
2. Coupling electrode (1) according to Claim 1,
   characterized by
   a connecting plug (15) which is connected to a conductor (14) and can be pushed onto the connecting element (3).
3. Coupling electrode (1) according to Claim 2,
   characterized by
   sealing means (16), which are designed to hold the connecting plug (15) in the insulating body (9).
4. Coupling electrode (1) according to Claim 3,
   characterized in that
   the sealing means (16) are composed of an elastomer.
5. Coupling electrode (1) according to Claim 3 or 4, ch
   aracterized in that
   the sealing means (16) can be latched in the insulating body (9, 19).
6. Coupling electrode (1) according to one of the preceding claims,
   characterized in that
   the semiconductive material contains polyphenylene sulfide and carbon fibres.
7. Coupling electrode (1) according to Claim 6,
   characterized in that
   the proportion of the carbon fibers is between 15% by weight and 35% by weight of the total weight of the semiconductive material.
8. Coupling electrode (1) according to one of the preceding claims,
   characterized in that
   the non-conductive material is composed of polyphenylene sulfide.
9. Coupling electrode (1) according to one of Claims 1 to 7,
   characterized in that
   the non-conductive material contains a mixture of polyphenylene sulfide and glass fibers.
10. Coupling electrode (1) according to one of the preceding claims,
    characterized in that
    the electrode section (2) has a roughened surface.
11. Coupling electrode (1) according to Claim 1,
    characterized in that
    the holding ring (4a) is connected to positioning feet (4b) whose free ends form the positioning means (7).
12. Component (8, 18) having at least one conductor section (10, 19) to which a high-voltage potential can be applied and having an insulating body (9) which is made of insulating material and in which each conductor section (10, 19) is embedded,
    characterized by
    a coupling electrode (1) according to one of the preceding Claims.
13. Component (8, 18) according to Claim 12,
    characterized in that
    the coupling electrode (1) is completely embedded in the insulating body (9).
14. Component (8, 18) according to Claim 12 or 13,
    characterized in that
    latching grooves for latching of sealing means are provided in the insulating body (9).

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