EP2210323A1 - Arrangement having an insulating material body and method for the production of an insulating material body - Google Patents

Abstract

The invention relates to an insulating material body (1a, 1b, 1c, 1d) having a conductor receptacle (3a, 3b, 3c, 3d), which penetrates the insulating material body (1a, 1b, 1c, 1d). The insulating material body (1a, 1b, 1c, 1d) is limited by a circumferential surface (13). A recess (4a, 4b, 4c, 4d, 4e) ends in the surface (13). In order to configure a recess (4a, 4b, 4c, 4d, 4e), a measuring device (7) is cast into the insulating material body (1a, 1b, 1c, 1d).

Description

description

Arrangement with an insulating body and method for producing an insulating material

The invention relates to an arrangement with a Isolierstoff ^¬ body, which has a aligned in an axial direction of the conductor receiving and is limited by at least one wesent ^¬ union in the circumferential direction to the axial direction extending surface.

Such an arrangement is known, for example, from Offenlegungsschrift DE 197 25 311 A1. There is an insulating ^¬ material body is shown in the form of a disc insulator, wel- relative to an axial direction of a conductor receiving a substantially circular contour. Several adjacent substantially circumferentially extending to the axial direction surfaces surround and limit the insulating body. There are distributed around the circumference several circular formations breaking through the formations.

In lying between the projections areas of the insulating material of this can develop no insulation, since corresponding insulating material is not present there. This reduces the required amount of insulating material. In particular, when using the insulating material as a fluid barrier for the production of fluid-tight transitions correspondingly expensive sealing means are provided.

The invention is therefore based on the object to design a Anord ^¬ tion of the type mentioned, which has a reduced Isolierstoffbedarf and simplified as a fluid barrier can be used. According to the invention this object is achieved in an arrangement of the type mentioned above in that the Scheibeniso ^¬ lator has a recess with an access opening, wherein at least one extending transversely to the axial direction of the access opening limiting section in the surface.

An insulating body preferably serves to position an electrical conductor with respect to another body, wherein the insulating material has such a high impedance that the propagation of current paths between the electrical conductor and the other body is restricted. As Isolierstoffkörper Scheibeniso ^{¬ are} lators used, for example, which have a conductor receiving. In this case, the conductor receptacle is aligned such that an electrical conductor can pass through the insulating material body in the axial direction, the insulating material body encompassing and enclosing the electrical conductor. In this case, disk insulators have an essentially disk-like structure, whereby they can also have ribs, bends, bulges, web-like structures, etc., as a result of which the electrical insulation capacity or the mechanical properties of the insulation body are improved. A surface which extends in the circumferential direction to the axial direction may be formed, for example, in the manner of a section of a lateral surface of a cylinder. In addition, however, others can

Be provided surface curves, so that, for example, meh ^¬ rere surfaces abut or merge into and limit the insulating material in the radial direction. The surfaces can be flat or curved. The essentially borrowed transverse to the axial direction surfaces should be arranged circumferentially around the insulating body. The surface preferably extends on a coaxial to the Achsrich ^¬ circumferential orbit. In an ideal case, an area is in closed circular formed circumferentially around the axial direction.

By providing recesses in the insulating body, the necessary volume of insulating material can be reduced to form the disc-like structure of the insulating material, without adversely affecting a fluid tightness of the insulating material. With a suitable introduction and shaping of the recesses, on the one hand a low-mass insulating material body can be formed, which requires a correspondingly reduced volume of insulating material. On the other hand, despite the mass reduction, a mechanically stable insulating material can be formed.

Thus, it is possible, for example, to form an insulating body having an approximately circular contour in an axial plan view of the insulating body, wherein at least in its edge region one or more circumferential surfaces are provided. Thus, in the axial direction, for example, a sealing means may be arranged on the insulating body in order, for. B. establish a fluid-tight connection to a flange of an encapsulation ^¬ housing of a compressed gas-insulated electric energy transfer ^¬ device. This makes it possible to use the insulating material as a barrier to a Kapselungsgehäuse and prevent overflow of fluids between the interior of the encapsulating and an adjacent space by means of the insulating material. For this purpose, it can be advantageously provided that the conductor receptacle extends in a fluid-tight manner around the conductor to be accommodated. The conductor receptacle can extend channel-like in axial direction ^¬ tion and be designed, for example, rotationally symmetrical. A conductor may be flush with the conductor receptacle. Depending on requirements, it may be further provided in that the insulator body is provided with openings which pass through in the axial direction, so that channels for the overflow of fluids are formed through the insulator body. Such channels may additionally or exclusively also be provided on a conductor arranged within the conductor ^receptacle . This creates the possibility of using structurally identical insulating bodies on the one hand as a fluid-tight barrier on encapsulating housings or, with a slight modification by providing corresponding channels, of allowing communication of fluids of different spaces through the arrangement with the insulating body.

In order to ensure as symmetrical a shape as possible of the insulating material, at least one wall should be retained on the recess, which has a connection with the area extending in the circumferential direction. The access opening should preferably extend substantially radially to the axial direction, so that a pocket-like recess is formed, which can be filled with other components, for example. As a result, the installation space required for insulation purposes is better utilized since, in the arrangement according to the invention, components previously to be arranged, for example, in the vicinity of an insulating body can also be integrated into the insulating body itself. When using the arrangement with the Isolierstoffkörper, for example, in an annular circumferential structure, the possibility is given in the radial direction, for example, to arranged within the recess devices, connections or supply lines through the ring encircling structure into the interior of the insulating insert , Since ^¬ by remain transverse to the axial direction surfaces free of attachments. Thus, these surfaces, which may be Fluids are exposed as possible free of impurities from ^¬ designed. For example, it may be provided that the arrangement with the insulating material in the manner of a cover spans an opening of an encapsulating housing. In the interior of the encapsulating it can electrically isolie ^¬-saving gases such as sulfur hexafluoride o. Ä. ^¬ be integrally arranged. These are usually subjected to increase their e- lectric insulation resistance with an increased pressure. If now a radial alignment of the recess is provided on the insulating body, the surfaces oriented transversely to the axial direction remain free of recesses. However, it can also be provided that the recess has an access opening which allows access both radially to the axial direction and axially to the axial direction. In this case, based on a plane which is aligned substantially transversely to the axial direction, only one wall provided axially adjacent to the recess is formed such that it is free of the access opening of the recess. One on the opposite side AXI al next to the recess arranged wall is beispielswei ^¬ se in this case not fully formed so that this wall does not open out in the area. As a result, an oblique access deviating from a radial direction is made possible via the access opening. Such recesses are for example advantageous if the arrangement with the

Insulating body in the manner of an end closure, for example ^¬ closes an encapsulating to prevent fluids located in the interior of the encapsulating housing from leaking. The region of the insulating material body facing away from the interior can then be accessible, for example, from the outside via the section of the access opening extending within a lateral wall of the insulating body. This can be used, for example, within the recess. The opening area of the recess or the access opening extends on the one hand in a substantially radial or skewed and on the other in a substantially aligned transversely to the axial direction surface.

It can advantageously be further provided that the off ^¬ recess is bounded by at least one extending transversely to the axial direction of flat wall.

A similar limitation on both sides of the recess bezo ^¬ gene on the axial direction makes it possible to form a defined Zu ^¬ opening opening, which is accessible in a simple manner from the radial direction. As a result, in the outer contour, with respect to a projection in the axial direction, the presence of recesses in the insulating body is not immediately recognizable. In such a case, the recess in its mouth region is completely bounded by one or more surfaces that circulate essentially in the circumferential direction to the axial direction. Thus, a possibility is given to use in a displacement of devices in the recess, the electrical insulating properties of the insulating material of the insulating material. In an advantageous case, the recess is introduced in the manner of a bag-shaped depression in the radial direction relative to the axial direction into the insulating body.

It can be advantageously provided that the recess is substantially slot-shaped.

A slot-shaped configuration of the recess allows an advantageous use of the available space in a sector-shaped portion of the insulating material. It can be provided that the recess has, for example, an arcuate course, so that a relatively volume-large space is provided to position other devices within the insulating material.

Advantageously, it can further be provided that a wall delimiting the recess is arched.

A wall bounding the recess may advantageously have a curvature. This makes it possible, depending on the location of the conductor receiving while maintaining the necessary e- lectric insulation distances on the insulating material to provide the largest possible volume for the recess. For example, it can be provided that the insulating material body has a circular contour, wherein the Ausneh ^¬ tion is arranged coaxially with a conductor receiving. However, it can also be provided that a plurality of conductor receptacles are provided within a circular outer contour, so that a plurality of electrical conductors can break through the insulating material body. Thus, for example, three conductor receptacles can be provided, which are arranged within the Isolierstoffkörpers such that they lie at vertices of an equilateral triangle. Due to the curvature of the wall, a suitable receptacle can furthermore be made available in order to position correspondingly oppositely shaped devices within the recess.

For this purpose, it can be advantageously provided that the wall is arched in the manner of a cylinder jacket surface to form a cylinder axis.

A curvature in the manner of a cylinder jacket surface can be used favorably, for example, screen assemblies, antennas or the like to be positioned within the recess. The curvature of the corresponding device and the wall should be coordinated with each other, so that a gegenglei ^¬ che shape is given. This ensures that the device is relatively close to the curved wall of the insulating material, so that a large portion as possible ^¬ SSER of insulating material of the insulating material is filled between ^¬ the device and an e- lektrischen conductors in a conductor receiving. This ensures that a defined environment is given on the device. For example, edge ^¬ conditions in terms of insulating properties of the Isolierstoffmaterials compared to an undefined material mix are determined simplified.

A further advantageous embodiment can provide that the cylinder axis of the curved wall extends substantially parallel to the axial direction.

By a substantially parallel arrangement of the cylinder axis of the curved wall to the axial direction of a symmetrical structure of the arrangement is made possible with the insulating body. Due to the symmetrical structures comparatively large recesses can be arranged within the body ^¬ Isolierstoff so that a material saving of insulating material is made possible without affecting the mechanical stability of the insulating material to an excessive extent.

Advantageously, it can further be provided that at least one wall has a rear grip in the bottom region of the recess.

The Hintergreifung can for example be used to position a device to be introduced into the recess. Advantageously, it can be provided that two mutually opposite walls have mutually opposite ^¬ aligned recesses. Thus may be done, for example, with elastic deformation of holding elements of a recess to be introduced into the training device a form-locking positio ^¬ discrimination of the device.

It can be advantageously provided that the recess receives a measuring device.

A measuring device can serve for example for monitoring a state of a position in a conductor receiving ^¬ the electrical conductor. For example, the measuring device can detect an electrical voltage or an electrical current on an electrical conductor. It can be advantageously provided, for example, that a charging a measuring surface of the measuring device is provided for the voltage ^¬ measurement, so that, for example, qualitative or quantitative information about a voltage, with which an e- lectrical conductor is applied, can be made.

Advantageously, it can be provided that the measuring device includes a domed ^¬ to the axial direction of the measuring surface on ^¬.

By means of a curved around the axial direction measuring surface of the space, which is available to receive the measuring surface within the recess, are used favorably. In order to enable an improved evaluation of the measurement signals, the curved measurement surface of the arcuate wall should be ^¬ arranged. As a result, for example, the dielectric between an electrical conductor arranged in a conductor receptacle and the measuring surface is substantially offset by the insulating material. Defined substance of the insulating material. Thus the surrounding environment ^¬ the measuring device for extended periods should be regarded as stable.

A further advantageous embodiment can provide that a fluid is arranged between the curved wall and the measuring surface.

An introduction of a fluid into a space which is arranged between the curved wall and the curved measuring surface leads to a dielectric stabilization of this region. For this purpose the measuring surface can be arranged spaced to the vault ^¬ th wall. Direct contact between measuring surface and curved wall poses the risk of transporting partial discharges within this range.

Partial discharges could adversely affect both the insulating material and the measuring surface.

A further object of the invention is to specify a simplified method which is suitable for producing an insulating material body with a conductor receptacle extending in an axial direction and with a recess in the insulating material body.

Previous methods for producing a Isolierstoffkörpers intended to bring this example, by machining in its final form. Such Nachbear ^¬ processing is complicated and expensive. It is therefore an object of the invention to provide a method which produces an improved arrangement with reduced effort.

According to the invention the object is achieved with a method of the type mentioned at the outset a ^¬ characterized in that for the formation of Recess a measuring device is shed with the insulating body.

Potting the measuring device with the Isolierstoffkörper gives the possibility to position the measuring device directly to the insulating body. In this case, the shape of the measuring device is used to introduce a recess in the insulating body, that is, the measuring device is at least partially used as a mold for the insulating material, said after casting this mold remains in ^¬ example, on the insulating body. As a result, on the one hand a simple positioning of the measuring device is given, on the other hand, an introduction of the measuring device can be made in the insulating material as free as possible of disturbing foreign substances.

Furthermore, it may be advantageously provided that at least one sealing means is arranged on the measuring device, which prevents backflow of the measuring device with fluid insulating material on a side of the measuring device facing away from a measuring surface.

The use of a sealant allows recesses to be provided on the insulating body having an access opening extending substantially radially to an axial direction. The sealant is designed such that a backflow of the measuring device is prevented with a liquid insulating material and thus an externally accessible pocket is formed in the insulating body. As a sealant, for example, circumferential O-rings, which on the one hand develop a sealing effect and on the other hand ensure a resilient mounting of the measuring device after curing of the insulating material. At least because of one Partial non-binding of applied from the measuring surface side of the measuring device, can continue to be accessed on the measuring device and, for example, maintenance or assembly work on the measuring device can be made. If an arrangement of a corresponding separating means is provided in the region of the measuring device, the measuring device can be removed from the I-solulant body after curing of the insulating body and optionally replaced.

In the following, an embodiment of the invention is sche ^¬ matically shown in a drawing and described in more detail below. It shows the

Figure 1 is a plan view in the axial direction of an insulating material in a first embodiment variant, the

Figure 2 is a plan view in the axial direction of an insulating material body in a second embodiment variant, the

3 shows a section through a section of the insulating material in the first embodiment variant with a recess, the

Figure 4 shows a third embodiment variant of an insulating ^¬ body partially cut and the

FIG. 5 shows a section along an axis II as marked in FIG. FIG. 1 shows a first embodiment variant of an insulating material body 1a. The first embodiment ^¬ variant of the insulating material Ia has a circular cross-section. The first embodiment variant of an insulating body Ia is coaxial about an axis 2 which defines an axial direction. The axis 2 protrudes ^¬ perpendicular to the plane of the figure 1 out. Next ^¬ out is permitted with a first conductor receiving 3a of a second conductor receiving 3b and a third conductor receiving 3c ^¬ the first embodiment variant of an insulating material ^¬ body Ia. The conductor receivers 3 a, 3 b, 3 c pass completely through the first embodiment variant of an insulating body 1 a in the direction of the axis 2. The conductor receivers 3 a, 3 b, 3 c are designed essentially as the first variant of an insulating body 1 a completely penetrating recesses with a rotationally symmetrical course. In the conductor receptacles 3a, 3b, 3c electrical conductors can be used. The electrical conductors should preferably be inserted in a fluid-tight manner in the conductor receptacles 3a, 3b, 3c. The conductor receivers 3 a, 3 b, 3 c each have the same radial distance from the axis 2 and are distributed uniformly about the axis 2.

The first embodiment variant of an insulating body 1a is shown in FIG. 1 in a cut form.

In this case, the first embodiment variant of an insulating body 1a has a substantially cylindrical outer contour, whereby surfaces of the first embodiment variant of an insulating body 1a can also be provided with ribs, bulges, etc., or the insulating body itself with a curved shape while maintaining the circular circumference or similar shape may be provided. Distributed symmetrically on the circumference are a first recess 4a, a second recess 4b and a third recess 4c arranged on ^¬ . The recesses 4a, 4b, 4c are respectively symmet ^¬ driven via conductor chucks 3a, 3b, 3c arranged. In this case, one of the recesses 4a, 4b, 4c is assigned to one of the conductor receptacles 3a, 3b, 3c. The recesses 4a, 4b, 4c have a slot-like structure, wherein ih re ^¬ access openings each open in an area which surrounds the periphery of the first embodiment variant of an insulating material ^¬ body Ia. The walls which are aligned parallel to the plane of the drawing and delimit the recesses 4a, 4b, 4c have a planar structure. The bottom portions of the Ausneh ^¬ rules 4a, 4b, 4c are provided with arcuate walls. In this case, the axis of curvature of these curvatures is parallel to the axis 2. Furthermore, the recesses 4a, 4b, 4c in the direction of rotation of the surface frontally bounding walls are provided with undercuts 5. These undercuts 5 are incorporated in the transition region between the curved bottom wall and the end walls disposed perpendicularly thereto in the insulating material of the first embodiment variant of an insulating material 1.

For example, resins or other organic and inorganic substances are suitable as insulating material.

FIG. 2 shows a second embodiment variant of an insulating body 1b. Notwithstanding the representation of Figure 1, however, it is provided that the second Ausgestal ^¬ tion variant of an insulating material Ib has only a single conductor receiving 3d. The single conductor receptacle 3d is arranged with its circular cross-section concentric with the axis 2. Since only a single conductor receiving ^¬ 3d is provided, the second embodiment variant of an insulating material Ib is also only a single Recess 4d assigned. The axis 2 and the curvature axis of the bottom portion of the single recess 4 d are cover ^¬ same arranged. The other construction and operation ent ^¬ says the representation of FIG. 1

FIG. 3 shows a section of the first recess 4a of the first embodiment variant of an insulating material body 1a. In the first recess 4a a measuring device 7 is introduced. The measuring device 7 has a bow-like running structure, which conforms to the bottom wall of the first recess 4a. The arcuate structure of the measuring device 7 is formed substantially in the manner of a hollow cylinder segment. In this case, in the present case the measuring device has an electrically insulating carrier material, which is provided on its side facing the first conductor receptacle 3a with an electrically rechargeable measuring surface. Between the mutually facing regions of the measuring device 7 and the first recess 4a a spacing is provided, whereby a cavity 6 is formed. The cavity 6 can be filled with a fluid, for example with an electrically insulating gas. The ends of the measuring device 7 are inserted into the Hintergreifungen 5 of the first recess 4 a, so that the position of the measuring device 7 is set within the recess 4 a. It may be provided, for example, that the measuring device 7 is designed elastically deformable and is inserted under elastic deformation in the recesses 5. As elastically deformable carrier material, for example, a silicone may be provided, which may be provided with a corresponding electrically conductive coating for forming the measuring surface. The circular structure of the first embodiment variant of an insulating material clasping Ia, the first off ^¬ design variant of a insulating material Ia is assigned a ring. 8 The ring 8 surrounding the first insulating body of a Ausgestaltungsvarian- te Ia and closes this completeness, a ^¬ dig. By means of the ring in the radial direction to the axis 2 lying access opening of the first recess 4a is covered. As a result, the measuring device lying within the first recess 4a is bounded or covered on all sides by walls of the insulating material body 1a or by the ring 8. The ring 8 further has a channel 9, through which connection lines 10 are passed for the measuring device 7.

For positioning the measuring device 7, a sealing element IIa is arranged on the side of the measuring device 7 facing away from the first conductor receiving 3a. The sealing element IIa is designed in the form of an O-ring, which rests in the region of body edges of the arcuate part of the measuring device 7. As a result, on the one hand a positioning of the measuring device is supported within the first recess, on the other hand, the above the measuring device 7 between the measuring device 7 and the ring 8 extending space against the cavity 6 is carried out sealed. This provides a possibility, for example, to expose the measuring device 7 with its sections facing the first conductor receptacle 3a and the cavity 6, for example, to another medium than the space extending above the measuring device 7 between the measuring device and the ring 8. For example, it may be provided that the cavity 6 is filled with an electrically insulating gas under elevated pressure and that the above the measuring device. 7 between the measuring device 7 and the ring 8 formed space is filled, for example, with atmospheric air.

It will now be described with reference to FIG. 3 how a formation of the first recess 4a in a first embodiment variant of an insulating body 1a can take place.

For the preparation of the first embodiment variant of a Iso ^¬ lierstoffkörpers Ia a mold is first prepared. As a mold, for example, the ring 8 serve. With regard to the casting mold, the measuring device 7 is then positioned and this is preferably provided with a sealing element 11. After completion of the preparation of the casting mold, an insulating material in fluid form is introduced into this mold. The insulating material clings to the mold and cures there. After hardening of the insulating material, the mold is removable, wherein the measuring device 7 remains connected to the insulating material. During the casting process, the sealing element 11 serves to prevent backflow of the measuring device 7 with liquid insulating material. It can be provided that the casting mold, as shown in the example of FIG. 3, furthermore remains connected to the insulating body as an annular frame. During the casting, the conductor on ^¬ acquisition 3a, 3b, 3c are also formed. It can be provided that during casting with training of the conductor receiving

3a, 3b, 3c electrical conductors are inserted into the conductor receptacles 3a, 3b, 3c.

Figures 4 and 5 show a third embodiment variant of a Isolierstoffkörpers Ic. In the figure 4 an off ^¬ is cut to the third embodiment variant of an insulating material body ^¬ Ic sectionally shown. The third Ausges ^¬ taltungsvariante one insulating material Ic also has a substantially circular contour. In the edge region, the third embodiment variant of an insulating body Ic is circumferentially stepped off. Thereby, in Randbe ^¬ rich circular peripheral grooves 12a, 12b formed which serve, for example, a guide of a frame. In a surface 13, which circumscribes about the axis 2, the third embodiment ^¬ variant of an insulating material Ic, a recess 4e is introduced. As can be seen from the free-cutting, the recess is provided with an access opening, which is relative to the axis 2, accessible only from the radial direction. The walls which define the recess 4e transverse to the axis 2, are designed such that they extend similarly to the surface 13 ^¬ out. Thereby, the disc-shaped form of the third embodiment variant of an insulating material body ^¬ Ic is given on both sides of a boundary of the recess. The recess 4e in this case has a slot-shaped structure, so that within the Isolierstoffkörpers a kind of bag is created, which may be provided for receiving further devices.

Alternatively, however, it can also be provided that only one of the two walls, which delimit the recess 4e transverse to the axis 2, is pulled into the surface 13, so that only part of the access opening of the recess 4e opens into the surface 13. With a corresponding reduction of one of the lateral walls, an at least partially axial access of the access opening of the recess 4e is thus also made possible.

FIG. 5 shows a supplement to the third embodiment variant of an insulating material body Ic shown in FIG. 4 in a section along the axis II. A frame 8a is continuously placed around the axis 2 to the third embodiment variant of an insulating material Ic. In this case, the frame 8a is guided by means of the recesses 12a, 12b. The frame 8a covers the access opening of the recess 4e in the radial direction. The recess 4e is limited in the axial direction on both sides of similar walls of the third embodiment variant of an insulating material Ic. The access ^¬ opening has an arcuate curvature and opens into a coaxially to the axis 2 circumferential surface. 13

Claims

claims

1. Arrangement with an insulating body (Ia, Ib, Ic), which has a in an axial direction (2) aligned Leiterauf- measures (3a, 3b, 3c, 3d) and of at least one substantially in the circumferential direction to the axial direction (2) extending surface (13) is limited, characterized in that the insulating material (Ia, Ib, Ic) has a recess (4a, 4b, 4c, 4d, 4e) having an access opening, wherein at ^¬ least one in circumferential direction to the axial direction (2) extending the access opening limiting section in the surface (13) opens.

2. Arrangement according to claim 1, characterized in that the recess (4a, 4b, 4c, 4d, 4e) of at least one transversely to the axial direction (2) extending flat wall is limited.

3. Arrangement according to one of claims 1 or 2, d a d u r c h e c e n e z e c h e n e, t a s s the recess (4 a, 4 b, 4 c, 4 d, 4 e) is substantially slit-shaped.

4. Arrangement according to one of claims 1 to 3, d a d u r c h e c e n e e c e s e s, a t a s the a recess (4 a, 4 b, 4 c, 4 d, 4 e) limiting wall is curved.

5. Arrangement according to claim 4, characterized in that the wall is arched in the manner of a cylinder jacket surface to a Zy ^¬ linderachse.

6. An arrangement according to claim 5, characterized in that the cylinder axis of the curved wall substantially pa ^¬ rallel to the axial direction (2).

7. Arrangement according to claim 1, wherein at least one wall in the bottom region of the recess has a rear gripping (5).

8. Arrangement according to one of claims 1 to 7, d a d u r c h e k e n e z e c h e n e, t a s s the recess (4 a, 4 b, 4 c, 4 d, 4 e) receives a measuring device (7).

9. Arrangement according to claim 8, characterized in that the measuring device (7) has a measuring surface curved around the axial direction (2).

10. Arrangement according to claim 9, characterized in that the measuring surface is arranged at a distance from the curved wall of the recess (4a, 4b, 4c, 4d, 4e).

11. Arrangement according to claim 10, characterized in that between the curved wall and the measuring surface, a fluid is arranged.

12. Method for producing an insulating body (Ia, Ib, Ic, Id), which has a conductor receptacle (3a, 3b, 3c, 3d) extending in an axial direction (2) and a recess (4a, 4b, 4c, 4d, 4e) characterized in that for forming the recess (4a, 4b, 4c, 4d, 4e) a measuring ^{¬ device} (7) with the insulating material (Ia, Ib, Ic, Id) is shed.

13. Method according to claim 12, wherein at least one sealing means (11) is arranged on the measuring device (7) which prevents the measuring device (7) from flowing behind with fluid insulating material on a side of the measuring device (7) facing away from a measuring surface.