EP0447910B1 - Plug socket - Google Patents

Description

The invention relates to a socket according to the preamble of the first claim.

In a known socket of this type DE-A 36 11 462, an inner cone recess is formed in an insulating body from one end face, to the bottom of which a hollow bell-shaped plug contact is axially connected. A hat-shaped field control body is connected to this plug contact, which is embedded in the insulating body and extends over the part length of the inner cone recess to open it. In the area of the end face of the insulating body there are fastening fittings which are oriented axially parallel. In addition, a current transformer coil is embedded in the insulating body at the opposite end of the plug contact, from which a further ring-shaped field control body extends to the inner cone recess and surrounds the plug contact over a partial length. This further field control body also forms an electrode for displaying a voltage or for voltage measurement via a radially leading measuring line. This arrangement results in an axially elongated structure, in which the electrical breakdown resistance field distortion occurs due to the fastening fittings located in the area of the opening in the inner cone recess.

In another known socket (DE-A 36 44 890) an insulating body penetrates an opening in the wall of a high-voltage device. The insulating body has an end opening of an inner cone recess into which a cable plug can be inserted. A hat-shaped field control body is connected to a plug contact arranged in the inner cone recess, which is embedded in the insulating body and the free edge of which points towards the end face adjacent to the housing wall. Fastening fittings are cast into the insulating body, concentrically to the opening of the inner cone recess, through which the plug socket is screwed to the housing wall or the cable connector with the insertion of a pressure ring. Instead of a fastening fitting, an electrode set back relative to the end face is provided, which is capacitively coupled on the one hand to the field control body and, on the other hand, is connected via an electrical plug connection to electrical measuring devices arranged outside the device housing. The end face of the insulating body is seated gas-tight on the housing wall with the interposition of a seal. Due to the required high voltage dielectric strength, the electrode must be at a considerable distance from the field control body. The consequence of this is that the electrical capacitance value between the electrode and the field control body is very low, and thus the capacitance is very high. As a result, highly sensitive measuring devices are required to detect the voltage present at the plug contact, the capacitive load due to the earth capacitance of adjacent earthed parts and the shielded electrical line from the electrode to the measuring device being considerable. In addition, the head of the electrode is expanded spherically, so that the profile the mounting fittings in the radial direction are exceeded accordingly.

The invention has for its object to take measures in a socket according to the preamble of the first claim, by means of which an improvement in the electrical field pattern in the region of the end-side fastening fittings is achieved with an optimal capacitance value of the electrode arrangement.

In the construction of a plug socket according to the invention, the arrangement of an electrode around the inner cone recess results in a large-area coupling to the plug contact or the associated field control body and thus a substantial increase in the capacitance value. The electrode has a plurality of individual partial electrodes which are arranged in the circumferential direction between adjacent fastening fittings and are electrically connected to one another. As a result, an almost complete adaptation of the electrical field image to the electrical field image already specified by the fastening fittings is achieved. This also contributes to the homogenization of the field image, because there are now electrode sections between the individual fastening fittings. This results in an overall electrode shape approximating the ideal ring electrode with the resulting uniform field distribution. The overall electrode profile need not protrude beyond the radial profile specified by the fastening fittings. The partial electrodes are preferably hood-shaped and with the rounded end directed towards the field control body, which is connected to a high-voltage plug-in contact part at the end of the inner cone recess. The rounding of the partial electrodes results in a large area which is executed for the field control body, which increases the capacitance value and also a favorable electrical field distribution. The electrodes are preferably made of sieve or grid-like material, so that an intimate, detachment-free connection occurs with the casting resin used for the production of the insulating body. The connecting line of the individual partial electrodes can run between the fastening fittings and the outer surface of the inner cone recess. In the area of fastening fittings, the connecting conductor, which is preferably in the form of a ribbon cable, can be flattened in the region of fastening fittings and fixed there using small insulation supports on the fastening fitting concerned before it is poured into the casting resin. Preferably, however, the connecting line is provided in the area of two partial electrodes with a connecting lug, which is arranged axially with the inner cone recess and points to the end face in a recess open to the end face. In the casting mold, the connecting conductor with the partial electrodes attached to it can be held in a correspondingly designed holding device in the casting mold until the casting resin mass solidifies. At least one of the connecting lugs can then be removed from the Cast a plug for connecting a measuring device to be plugged in. To mount the socket on a correspondingly perforated device wall, a spacer ring is placed on the end face as a counterpart, with the edge of the opening required for the insertion of a cable plug protruding between the end face and the spacer ring. The spacer ring is used for uniform pressure distribution over the circumference of the opening, so that the end face of the socket with an annular seal provided there is pressed gas-tight over the entire circumference to the housing wall in question when the screws are screwed into the associated fastening fittings from the spacer ring. The arrangement of the connecting line and possibly areas of the partial electrodes is preferably such that they lie in the field shadow of a shield, which is inserted into the inner cone recess when a cable connector is inserted. This grounded shield prevents a conductor guided inside the cable connector from being capacitively coupled to the connecting line or adjacent areas of the partial electrodes. As a result, the capacitance value desired for the voltage coupling is determined in particular by the geometry between the field control body and the partial electrodes. The high-voltage value detected via the partial electrodes is thus changed only slightly when the cable plug is inserted or removed.

The invention is explained in more detail below with reference to the drawings of exemplary embodiments.

• Fig. 1 einen Längsschnitt durch eine an eine Gehäusewand angesetzte Steckbuchse, und
• Fig. 2 eine Draufsicht auf die freie Stirnseite der Steckbuchse nach Figur 1 mit Darstellung der Einzelteile nach Art einer Röntgenaufnahme.

Show it:

• Fig. 1 shows a longitudinal section through a socket attached to a housing wall, and
• Fig. 2 is a plan view of the free end face of the socket of Figure 1 showing the individual parts in the manner of an X-ray.

A socket 1 of an inner cone plug coupling, as is customary for the connection of high-voltage cables in medium-voltage switchgear, has an insulating body 2 made of cast resin, in which an inner cone recess 3 is formed, which is open to an end face 4. At the opposite end, the inner cone recess 3 is followed by an axially identical plug contact part 5, which is to be connected to high-voltage internals in the encapsulated high-voltage device. Fastening fittings 6 and 7 are incorporated into the insulating body 2 from the end face 4 and are axially parallel to the central axis 8 of the inner cone recess. The fastening fittings are located on circular lines concentric to the opening of the inner cone recess, radially outside the inner cone recess. The end face 4 of the socket 1 lies in one plane on a wall 9 of a housing, within which high-voltage switchgear parts are located. In the area of the inner cone recess, this wall 9 is provided with a corresponding opening through which a cable connector 10 can be inserted from the outside. A hat-shaped field control body 11 is also attached to the high-voltage plug contact part 5, which is also embedded in the insulating body 2 and encompasses the adjacent section of the inner cone recess in a ring.

By a capacitive voltage tap for measuring the contacts on the plug contact part 5 or the field control body 11 To create high voltage, a capacitively acting counter-coating to the field control body 11, an electrode 12, which is electrically insulated from it, is arranged in the region of the end face 4 and is arranged around the inner cone recess 3.

According to FIG. 2, this electrically insulated electrode 12 is formed from a plurality of partial electrodes 12.1 which are arranged in the circumferential direction between adjacent fastening fittings 6 and 7, respectively. These partial electrodes 12.1 are electrically connected to one another via a connecting line 13, the electrical connecting line 13 being embedded within the insulating body 2 in the insulating compound. The electrodes 12 and the connecting conductor 13 are preferably made of sieve or grid-like material, so that there is an intimate embedding which prevents the insulating compound from separating from the electrode or the connecting line during the shrinking process during the curing of the casting resin and forming dielectric defects become. The partial electrodes 12.1 can extend in the radial direction over the same area as the fastening fittings and on the other hand largely occupy the space between adjacent fastening fittings 6, 7 and in the axial direction as far as into the insulating body 2 as the fittings 6, 7. This results in an extensive symmetrization of the electrical field, after which the spaces between adjacent fastening electrodes 6, 7 are then provided with electrically conductive parts which, at least approximately like the fastening fittings, are electrically almost at ground potential. The partial electrodes 12.1 are hood-shaped and have the rounded end facing the field control body 11. The rounding contributes to the favorable field distribution and forms a relatively large area compared to the field control body, the one correspondingly high capacity value. The resulting low capacitive resistance value enables the pending high voltage to be detected with relatively simple measuring devices. The connecting line 13, which also serves as an assembly aid for the positioning of the partial electrodes 12.1 in a casting mold, is flattened in the radial area of fastening fittings 6, deviating from the circular ring shape, and is provided on the flattened part with a small support insulator 14, which is fixed to the fastening fittings 6 concerned, around the Center partial electrodes 12.1 during the casting process of the insulating body 2. Preferably, however, for positioning the partial electrodes 12 in the relevant mold, instead of the support insulators 14 in the area of at least one, but preferably in the area of a plurality of partial electrodes 12.1, a connecting lug is attached to the connecting conductor 13, which projects into the space enclosed by the respective partial electrode 12 and is axially aligned is arranged to the inner cone recess in a recess 16 which is open to the end face 4. The connecting lug 15 also points with its free end to the end face 4. As a result, the respective terminal lug can be inserted into a holder corresponding to the recess 16, which is located within the casting mold which is used to produce the insulating body 2 with the internals. The connecting line 13 is located in the area that lies between the wall of the inner cone recess 3 and the fastening fittings 6, 7. In the axial direction, the connecting line 13 does not extend beyond the fastening fittings 6, 7.

The socket 1 is fixed to the wall 9 with the interposition of a sealing ring 17. For this purpose, a spacer ring 18 is attached from the opposite side of the wall, which engages under the end face 4 with its radially inner part and with the radially outer part Part rests on the wall 9. This spacer ring 18 has an opening 19 which is aligned with the respective connecting lug 15 and merges into a groove 20 which extends radially outward. Through the opening 19, a plug 21 can thus be plugged into the terminal lug 15, from which an electrical line 22 can be guided through the groove 20 to a measuring device, not shown. On the other hand, a flange 23 of the cable connector 10 is seated on the spacer ring 18, a screw being able to be screwed into the associated fastening fitting 7 through the flange 23 and the spacer ring 18 and the wall 9. Via the mounting fittings 6, the socket 1 is fixed on the spacer ring 18 on the wall 9. The cable connector 10 has an electrical shield 24 which is guided in the outer jacket region and is connected to earth potential and extends axially beyond the connecting line 13 into the inner cone recess 3. It thus shields not only the connecting line 13 but also adjacent areas of the partial electrodes 12.1 from a conductor running axially within the cable connector 10. This conductor thus does not have a direct capacitive effect on the connecting line 13 or the relevant area of the partial electrodes 12.1, so that the voltage measured at the partial electrodes 12.1 is largely independent of whether the cable connector 10 is inserted into the socket 1 or not. The capacitive coupling thus takes place even when the cable connector 10 is inserted via the rounded ends of the partial electrodes 12.1 facing the field control body 11. The shielding 24, by virtue of its arrangement with respect to the connecting line 13 and the partial electrodes 12.1, causes the electrical field generated by the cable connector 10 to be largely shaded with respect to the electrode 12.

Claims (9)

1. Plug socket (1) of a female cone plug-in connector for cables in a high-voltage device, in particular for a medium-voltage switchgear, with an insulating body (2) having on its front end (4) an aperture of a female cone recess (3) and concentrically thereto a plurality of axially parallel fixings (6) disposed radially on the exterior, and with an embedded electrode (12.1, 13) for capacitive voltage output having an electric terminal (15) and a plug-in contact (5), characterised in that in the circumferential direction individual partial electrodes (12.1) are disposed between adjacent fixings (6, 7) around the female cone recess (3), which are electrically interconnected within the insulating body (2).
2. Plug socket according to claim 1, characterised in that the partial electrodes (12.1) are in the form of a hood whose rounded end faces away from the front end (4).
3. Plug socket according to claim 1 or 2, characterised in that an annular connecting lead (13) flattened in the radial region by fixings (6) connects the partial electrodes (12.1) together.
4. Plug socket according to claim 3, characterised in that the connecting lead (13) is connected to at least one fixing (6) via at least one supporting insulator (14).
5. Plug socket according to claim 1 or one of the subsequent claims, characterised in that in the region of at least one partial electrode (12.1), a terminal lug (15) is disposed coaxially with the female cone recess (3) and points towards the front end (4) in a recess (16).
6. Plug socket according to claim 5, characterised in that a spacer ring (18) is mounted on the front end (4) and has a gap (19) aligned with the terminal lug (5) and a groove (20) extending radially outwards.
7. Plug socket according to claim 1 or one of the subsequent claims, characterised in that the electrode (12) or partial electrodes (12.1) consist of gauze-like or grid-like material.
8. Plug socket according to claim 1 or one of the subsequent claims, characterised in that the connecting lead (13) extends into the region lying between the wall of the female cone recess (3) and at least one fixing (6, 7).
9. Plug socket according to claim 1 or one of the subsequent claims, characterised in that the connecting lead (13) and optionally regions of the partial electrodes (12.1) lie in the field shadow of the screen (24) of an inserted cable plug (10).

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