DE102022116520A1 - Connector comprising a connector housing and a cable gland - Google Patents

Abstract

In order to maintain a particularly well conductive shield connection of a cable gland (3) to a connector housing (1) for a connector over the longest possible period of time, ideally over the entire life cycle of the connector, it is proposed to have a common contact surface (4) within for shield transfer a sealed area (B) of the connector, in particular to be arranged obliquely.

Description

The invention is based on a plug connector, having a plug connector housing and a cable gland, according to the preamble of independent claim 1.

Such connectors are required on the one hand for a plug-in connection to a mating connector and on the other hand for a connection to a cable. For this purpose, it is necessary to fasten the cable, which may in particular be a high-current cable, to the connector housing of the connector, which may be, for example, a high-current connector, by screwing using the cable gland. At the same time, it is usually necessary to connect the shield, for example a braided shield, of the cable to the connector housing in an electrically conductive manner. The connector, which is in particular a high-current connector, can be used in particular in the railway sector.

The shielding currents can be very high, especially in the railway area in question. For example, they can be higher than 10 A (“ampere”), in particular higher than 30 A, for example larger than 50 A, and even larger than 100 A, and according to the specifications, for example, can be up to 150 A and in individual cases even more .

State of the art

Cable glands are known in the prior art, which serve to fasten a cable to a connector housing of a high-current connector by screwing. In addition, it is known to connect a shield, in particular a braided shield, of the cable, for example in an electrically conductive manner, to the connector housing

In order to be able to transmit such shielding currents as well as possible, it is necessary to transfer the shielding current from the shield of the cable via the usually metallic cable gland to the usually metallic connector housing. For this purpose, it is known to first electrically connect the shield of the cable to the cable gland in order to then transmit the shield current, for example via the thread of the cable gland, to the connector housing. However, the aforementioned shield transfer via the thread is generally not permitted according to the relevant standards. Alternatively, it is known to establish electrical contact between the cable gland and the connector housing via at least one common contact surface. The disadvantage is that these contact surfaces are exposed to environmental influences such as moisture and dirt. It is therefore also known to treat this compound accordingly, for example by greasing it, in order to protect it from the aforementioned environmental influences. However, the grease, for example, can easily be removed accidentally and must be replaced regularly, for example in the form of complex maintenance. Therefore, there is currently no known satisfactory solution for the defined transmission of higher shielding currents, e.g. shielding currents that are more than 30A, to connector housings.

A disadvantage in the prior art is that the contact resistance between the cable gland and the connector housing is too high for the said high shielding currents and a good conductance of this connection, e.g. when using the connector in the field of railway technology, is required to transmit the said high Shield currents cannot be guaranteed over the entire life cycle of the connector.

Task

The object of the invention is therefore to provide a plug connector, having a plug connector housing and a cable gland, in which the contact resistance between the cable gland and the plug connector housing is consistently low over the longest possible period of time.

The task is solved by the subject matter of independent claim 1.

A connector having an at least partially metallic connector housing, a seal and an at least partially metallic cable gland for screw-fixing a cable to the connector housing.

The connector housing has a cable entry opening with a thread for cable entry in a cable entry direction. The cable gland has a mating thread with which the cable gland can be screwed to the thread of the cable opening.

When screwed, the seal is clamped in a sealing manner between the cable gland and the connector housing. This creates a sealed area inside the connector.

On the one hand, the cable gland can be electrically connected to a shield of the cable. On the other hand, when screwed, the cable gland is electrically conductive to the shield via a common contact surface Connector housing connected, said common contact surface being located within the sealed area.

Advantageous embodiments of the invention are specified in the subclaims and the following description.

A particular advantage is that the connector allows the transmission of high shielding currents of, for example, more than 10 A (“amps”), in particular more than 30 A, for example more than 50 A, and for example even more than 100 A, and possibly from up to up to 150 A and in individual cases even more over its entire service life.

The arrangement of the common contact surface within the sealed area is particularly advantageous because this common contact surface is protected from dirt and moisture.

Electrical contacting via the common contact surface has the advantage over shield transfer via the thread that it has a defined size. Finally, it is not defined within the thread at which points and to what size the thread and mating thread touch each other, so that the size of the electrically effective contact surface of the thread is not defined.

The said common contact surface, on the other hand, can be formed on the one hand by an outer contact surface of the cable gland and on the other hand by an inner contact surface of the connector housing. This inner contact surface and this outer contact surface can lie flat against each other in the screwed state and touch each other in order to make electrical contact with one another over a particularly large area. The common contact surface is then formed by the common, comparatively large area in which they are mechanically connected to one another in order to make electrical contact.

In a preferred embodiment, the inner contact surface of the connector housing and the outer contact surface of the cable gland - and thus also the common contact surface in the screwed state - are each designed to be circumferential.

The common contact surface forms an angle to the cable insertion direction that is smaller than 90°. In other words, the common contact surface is tapered towards the connector housing.

The said angle, which is formed between the common contact surface and the cable insertion direction, can, for example, be greater than 20° and less than 60°, preferably greater than 25° and less than 50° and in particular greater than 30° and less than be 45°.

This inclination allows the common contact area to increase significantly, so that the electrical resistance between the cable gland and the connector housing continues to be significantly reduced.

In an advantageous embodiment, the common contact surface can be at least 50 mm ² , in particular at least 100 mm ² , for example at least 150 mm ² , for example at least 200 mm ² , for example at least 500 mm ² and even up to 1000 in the case of a very large plug connector mm ² and in some cases particularly large connectors can even be more.

The common contact surface preferably connects to the thread on the connector housing side, which is formed in particular by an internal thread, and on the cable gland side to the mating thread, which is formed in particular by an external thread. For example, the outer contact surface of the cable gland can connect to the thread, namely in this case to the external thread of the cable gland. The inner contact surface of the connector housing can connect to the mating thread, in the aforementioned case to the internal thread of the connector housing. For example, the particularly oblique contact surfaces can each be arranged between the respective thread/counter-thread and the seal.

It is particularly advantageous if the connector housing is made in one piece, because it can then better compensate for the mechanical stress caused by the pressure generated from the inside by the conical contact surfaces. With a two-part connector housing, the two halves could possibly be pushed apart.

In a preferred embodiment, the seal can be an O-shaped sealing ring (“O-ring”), which can be made of rubber, for example.

Embodiment example

• 1a ein Steckverbindergehäuse mit Kabelverschraubung im Schnitt;
• 1b eine Vergrößerung aus der vorangegangenen Darstellung;
• 1c ein Steckverbindergehäuse mit Kabelverschraubung in einer 3D-Darstellung;
• 1d eine weitere Vergrößerung.

An exemplary embodiment of the invention is shown in the drawings and is explained in more detail below. Show it:

• 1a a connector housing with cable gland in section;
• 1b an enlargement from the previous illustration;
• 1c a connector housing with cable gland in a 3D representation;
• 1d a further enlargement.

The figures contain partly simplified, schematic representations. In some cases, identical reference numbers are used for identical but possibly not identical elements. Different views of the same elements could be scaled differently. Directional information such as “left”, “right”, “up” and “down” are to be understood with reference to the respective figure and can vary in the individual representations compared to the object shown.

The 1a and 1c show a connector housing 1 with a cable gland 3 and a seal 2, which is designed as an O-shaped sealing ring.

The seal creates an unsealed, outer area A and an inner, sealed area B. In the outer area A, the material of the connector is exposed to environmental stresses. In the inner area B, however, the environmental impact is significantly reduced.

In addition to a cable outlet 30, the cable gland 3 has an external thread 33 with which it can be screwed into an internal thread 13 of a cable entry opening 10 of the connector housing 1.

This screwing of the two threads 33, 13 already creates an electrically conductive connection between the cable gland 3 and the connector housing 1, which can be used to transmit low shielding currents.

However, for high shielding currents, a sufficiently good electrical contact via the two threads cannot be guaranteed, as the threads usually only touch each other in a few narrow places.

For this reason, a common contact surface 4 is provided. This should - and given the circumstances - be as large as possible in order to provide a "low-resistance", i.e. electrical contact that is as conductive as possible, between the cable gland and the connector housing.

The common contact surface 4 is formed by an inner contact surface 14 of the connector housing 1 and an outer contact surface 34 of the cable gland 3 through their common contact area in which they touch each other.

The 1b shows an enlargement from the 1a and thus makes the designation easier.

In the 1 d the angle α is shown, which is formed between the insertion direction and the common contact surface 4. The contact surface 4 is therefore tapered and circumferential towards the connector housing.

From this illustration it is clear that the contact surface 4 increases due to its inclination. The more the angle α deviates from a right angle, i.e. 90° (in this example it is approximately 30°), the larger the contact surface 4 becomes and thus also the electrical conductance of the connection.

The common contact surface 4 is located within the sealed area B of the plug connector, namely between the seal 2 and the respective thread 13, 33. As a result, the common contact surface 4 is usually not exposed to any significant environmental influences such as moisture and dirt. This allows the connector to maintain its particularly good shield connection over a long period of time, ideally over its entire life cycle.

Reference symbol list

1

Connector housing

10

Cable entry opening

13

Thread / internal thread

14

poetry

2

Cable gland

3

Cable gland

30

Cable outlet

33

Counter thread / external thread

34

outer contact surface of the cable gland

4

common contact surface

A

External area

b

sealed inner area

Claims (12)

Connector having an at least partially metallic connector housing (1), a seal (2) and an at least partially metallic cable gland (3) for screwing Fixing a cable on the connector housing (1), the connector housing (1) having a cable entry opening (10) with a thread (13) for cable entry in a cable insertion direction (100), the cable gland (3) having a counter thread (33), with which the cable gland (3) can be screwed to the thread (13) of the cable opening (10), the seal (2) being sealed in the screwed state between the cable gland (3) and the connector housing (1), whereby inside the connector a sealed area (B) is formed, and wherein the cable gland (3) on the one hand can be electrically conductively connected to a shield of the cable and wherein the cable gland (3) on the other hand is electrically conductive in the screwed state via a common contact surface (4) for the purpose of shield transfer is connected to the connector housing (1), said common contact surface (4) being within said sealed area (B). Connectors according to Claim 1 , wherein said common contact surface (4) is formed on the one hand by an outer contact surface (34) of the cable gland (3) and on the other hand by an inner contact surface (14) of the connector housing (1), said inner contact surface (14) and said outer contact surface (34) in the screwed state to form the common contact surface (4) lie flat against each other and touch each other in order to electrically contact each other over as large an area as possible. Connectors according to Claim 2 , wherein the inner contact surface (13) of the connector housing (1) and the outer contact surface (34) of the cable gland (3) are each designed to be circumferential. Plug connector according to one of the preceding claims, wherein the common contact surface (4) forms an angle (α) to the cable insertion direction (100) that is smaller than 90°, whereby the common contact surface (4) is tapered towards the plug connector housing (1). . Connectors according to Claim 7 , where said angle (α) is greater than 20° and less than 60°. Connectors according to Claim 6 , where said angle (α) is greater than 30° and less than 45°. Connector according to one of the preceding claims, wherein the common contact surface (4) is at least 50 mm ² . Connector according to one of the preceding claims, wherein the common contact surface (4) is at least 200 mm ² . Connector according to one of the preceding claims, wherein the common contact surface (4) is at least 500 mm ² . Plug connector according to one of the preceding claims, wherein the common contact surface (4) connects to the thread (13) on the connector housing side and to the mating thread (33) on the cable gland side. Plug connector according to one of the preceding claims, wherein the plug connector housing (1) is made in one piece. Connector according to one of the preceding claims, wherein the seal (2) is an O-shaped sealing ring.

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