The invention relates to a medium voltage connection, comprising:

- a first conductor and a second conductor electrically attached to each other;

- a first isolating layer arranged around the first conductor and a second isolating layer arranged around the second conductor, leaving an airgap between both isolating layers;

- an isolating rubber sleeve arranged between the first isolating layer and the second isolating layer to fill the airgap between the two isolating layers.

Such medium voltage connections are known and are used in switchgear to connect for example inbound or outbound cables to the switchgear. These medium voltage connections are also used to connect the busbars of adjacent panels of switchgear.

In some applications of the medium voltage connections at least the first conductor is provided with a ground screen. Such a screen is for example used at busbar connections or with current transformers, which are typically used to provide a low voltage signal for measuring the current in the first conductor. In this last application, it is necessary to have a grounding screen between the first conductor and the coil arranged around the conductor to prevent flash over to the low voltage side. It is known to embed a grounding screen in the isolating layer around the conductor. In manufacturing, a perforated tube is positioned concentrically around the conductor, where after a resin is cast around the conductor and the screen. The perforations ensure that the resin can penetrate the screen. It proves however that this manufacturing method results in a high number of rejected products. This is the result of misaligned screens, deformed screens and air pockets in the resin. Another disadvantage of the known screens, is that a high field density is present around the edge of the screens. Because the screen is embedded in isolating material, the field density will extend into the air surrounding the medium voltage connection, which is undesired, especially with low voltages components near the medium voltage connection. This could lead to undesired electrical discharges.

Yet another disadvantage of the known medium voltage connection, is that when connecting for example a cable to the first conductor with embedded screen in the isolating layer, the medium voltage connection is subjected to substantial mechanical stresses. These mechanical stresses are caused by the weight of the cable and by the expanding and shrinking of the isolating material due to heating and cooling of the connection. In time, this results in cracks in the isolating layer.

It is an object of the invention to reduce or even remove the above mentioned disadvantages.

This object is achieved with a medium voltage connection according to the invention, which is characterized in that a conducting layer is arranged on the first isolating layer; and in that the rubber sleeve is provided with a conducting portion, which overlaps with the conducting layer.

By providing a conducting layer on the isolating layer, it is ensured that the grounding screen provided by the conducting layer is always correctly positioned. It is no longer necessary to already position the screen before casting the isolating layer, but with the invention the isolating layer can be cast first and afterwards, the conducting layer can be arranged. This substantially reduces the number of rejects during manufacturing, as positioning of the screen will always be correct.

The conducting portion of the rubber sleeve ensures that the end of the screen is extended into the airgap between the two isolating layers. The high field

concentration typically present at the edge of the screen is in this way moved to a position well enveloped by isolating material. An additional advantage of arranging the conducting layer on the isolating layer of the conductor, is that with the same outer dimensions a thicker layer of insulating material is present between the screen and the conductor. This substantially increases the dielectric robustness.

As the screen is arranged on the outside and no longer embedded in the isolation layer, as with the prior art, the mechanical stresses have less influence, resulting in a better durability. In a preferred embodiment of the medium voltage connection according to the invention, the transition between the conducting portion and isolating portion of the rubber sleeve is positioned between the first and second isolating layers.

The rubber sleeve can be composed out of two separate materials, one isolating portion and one conducting portion. The conducting portion is brought in electrical contact with the conducting layer. In this way, the electrical screen is extended and the edge of the screen is displaced to in between the isolating layers. Any high electrical field concentrations will be kept with the isolating material. In another embodiment of the medium voltage connection according to the invention the second isolating layer partially envelopes the rubber sleeve and the first isolating layer. This further increases the thickness of isolating material over the extended edge of the screen. Preferably the conducting portion of the rubber sleeve is carbon black filled. Carbon black provides electric conducting properties and can be reliably processed in the manufacturing of the rubber sleeve.

In yet another preferred embodiment of the medium voltage connection according to the invention, a secondary coil is arranged around the first conductor for measuring the current in the first conductor. The invention is typically, but not exclusively, suited for use in current transformers, in which it is mandatory that the secondary coil is shielded by a grounding screen from the medium voltage conductor. Preferably, the conducting layer is a conducting paint layer. Such a conducting paint layer is easily applied on the surface of the isolating layer surrounding the conductor. These and other features of the invention, will be elucidated in conjunction with the accompanying drawings. Figure 1 shows a cross sectional view of an embodiment of a medium voltage connection according to the prior art.

Figure 2 shows a cross sectional view of an embodiment of a medium voltage connection according to the invention.

Figure 1 shows an embodiment 1 of a medium voltage connection according to the prior art. This connection 1 has a first conductor 2 and a second conductor 3, which can be bolted together by the threaded holes 4, 5. The first conductor 3 is provided with a first isolating layer 6. Within the isolating layer 6, a metal screen 7 is embedded. The edge 8 of the metal screen 7 is bent back to reduce the electrical field concentration.

The second conductor 3 is also provided with an insulating layer 9, which has extending edges 10 enveloping the end of the conductor 2.

A rubber sleeve 11 is arranged in between the first isolating layer 6 and the isolating layer 9, 10 to fill the gap. Because the edge 8 of the screen 7 is at a distance from the rubber sleeve 11 and the extending edges 10, the electrical field surrounding this edge 8 easily extends into the air around the medium voltage connection 1. Figure 2 shows a cross sectional view of an embodiment 20 of the invention. The medium voltage connection 20 has a first conductor 21 and a second conductor 22, which can be bolted together via the threaded holes 23, 24. The first conductor 21 is provided with an isolating layer 25, while the second conductor 22 is also provided with an isolating layer 26 having extending edges 27 to envelope the end of the first conductor 21.

The outer surface of the first isolating layer 25 is provided with a conducting coating 28 of for example conducting paint. This conduction coating 28 provides a grounding screen.

A rubber sleeve 29, 30 is arranged between the first isolating layer 25 and the second isolating layer 26. This rubber sleeve 29, 30 has a isolating portion 29 and a conducting portion 30.

This conducting portion 30 is in contact with the conducting coating 28, such that the edge 31 of the screen 28 is formed by the interface between the conducting portion 30 and the isolating portion 29.

As a result, the edge 31 of the screen is embedded between isolating edge 27 and the isolating layer 25.