DE29805316U1 - Electrically conductive coupling for shielding an electrical line - Google Patents

Description

GR 98 G 4047 DE

Description

Electrically conductive coupling for shielding an electrical cable
5

The invention relates to an electrically conductive coupling for shielding an electrical line, in particular a control and/or measuring line of electronic devices exposed to strong dielectric interference, which are arranged in a housing made of a conductive material.

Sensors are used in devices in a wide variety of fields of technology to monitor these devices. If a deviation from the target value of parameters that are important for the functionality of these devices is detected, actuators provided at a central location are activated via control and/or measuring lines in order to ensure the functionality or protection of the devices. Sensors are also used to ensure the functionality and protection of devices in high-voltage switchgear.

If these are used in high-voltage circuit breakers, signals are exchanged with the switch control.

To ensure that these signals are not influenced by strong dielectric interference and that the drive control remains unaffected by such interference, the control and/or measuring lines are surrounded by a shield that is galvanically connected to the housing made of a conductive material. The galvanic connection of the shield to the housing is made using a soldered connection on the circumference of the shield.

GR 98 G 4047 DE

which is carried out during assembly. However, this involves a time expenditure which impairs the assembly work.

The invention is based on the problem of creating an electrically conductive coupling according to the preamble of claim 1, which ensures the dissipation of dielectric interference via the housing made of a conductive material without additional time expenditure for producing the electrically conductive coupling of the shield to the housing.

This problem is solved by the fact that the shield can be connected to the housing by means of a self-resilient contact that rests on the shield and is connected to the housing, and by means of a contact element that presses on the shield on the side opposite the self-resilient contact.

According to an advantageous embodiment, the spring travel of the self-resilient contact is limited on its side facing away from the shield by one leg of an angle profile, between the second leg of which and the housing an angled section of the self-resilient contact is clamped.

In a further development of the invention, the contact element pressing on the shield consists of a contact body that is under the force of a spring body acting in the direction of the shield and is slidably connected to the housing via a guide in such a way that a bolt connected to the housing engages in an elongated hole in the contact body. Both a compression spring and a tension spring can be used as the spring body.

The contact body, which is connected to the housing via the guide, is used for the electrically conductive coupling of the

GR 98 G 4047 DE

Shielding of the control and/or measuring line on the housing when the contact pressure is applied to the shielding and thus to the control and/or measuring line is not tied to an electrical contact, but this can also be just a mechanical contact, since when the contact pressure is applied the electrically conductive coupling between the shielding and the housing is made by the self-springing contact.

In order to securely hold the control and/or measuring line when the contact pressure is exerted by the contact body, the latter has at least one recess on its side facing the shield, which should preferably be V-shaped or semi-circular and can also have a sawtooth-shaped surface. If several control and/or measuring lines are fed into the housing, each control and/or measuring line is advantageously assigned a V-shaped or semi-circular recess.

0 Based on this design of the contact element which presses on the shield and is designed as a movable contact body under the force of a spring body acting in the direction of the shield, the contact body can be arranged inside or outside the housing.

In a further embodiment of the invention, the at least one recess can also be integrated into an elongated hole in the contact body that accommodates the control and/or measuring line, which is now arranged inside the housing and is conductively connected to the housing via a self-resilient contact.

If the contact body under the force of a spring body acting towards the shield is within the

GR 98 G 4047 DE

housing, it can be moved from both inside and outside the housing. If this movement is to be carried out from the inside, the contact body is provided with an operating lever that protrudes into the housing. However, if the contact body is to be moved from the outside, which simplifies handling during assembly work, the contact body is provided with an operating lever that protrudes from the housing via an elongated hole inside the housing.

Finally, in the electrically conductive coupling of the shield designed according to the invention, the control and/or measuring line is advantageously attached to one leg of the angle profile. However, the control and/or measuring line must be attached at a distance from the leg of the angle profile and the spring travel of the self-springing contact must be guaranteed.

The invention is explained in more detail using an embodiment.

The accompanying drawings show:

Figure 1 shows the section of a device for electrically conductive coupling of a shield of an electrical line to

a housing and

Figures 2, 3 and 4 show the top view of three design variants of the contact body pressing on the shield of the device according to Figure 1.

According to Figure 1, a measuring line 1 is led through the opening 2 into a housing 3 made of a conductive material, which, for example, houses a drive control (not shown) of a high-voltage circuit breaker.

GR 98 G 4047 DE

which is activated when signals from sensors (also not shown) within the switching chamber of the high-voltage circuit breaker that deviate from the setpoint are delivered via the measuring line 1. The measuring line 1 is stripped in the area of the opening 3 so that the shield 4 can be electrically connected to the housing 3 in order to dissipate dielectric interference via the housing 3.

The electrically conductive coupling of the shield 4 to the housing 3 is carried out according to Figure 1 by a device which essentially consists of a self-resilient contact 5 and a contact element 6 which presses on the shield 4, through which the shield 4 is also pressed against the self-resilient contact 5. The spring travel of the self-resilient contact 5 when the shield is pressed against the self-resilient contact 5 is limited by the leg 7 of an angle profile 8, to which the measuring line is also attached by a cable tie 9, whereby an angled section 11 of the self-resilient contact 5 is clamped between the second leg 10 of the angle profile 8 and the housing 3. This ensures an electrically conductive coupling of the shield 4 to the housing 3 via the self-resilient contact 5.

The contact element 6 pressing on the shield 4 consists of a contact body 12 which is slidably connected to the housing 3 and which is subject to the force of a spring body 13 acting in the direction of the shield 4, which in this device is a compression spring. This is accommodated in a housing 14 which is attached to the housing 3. In order to securely hold the measuring line 1 and thus the shield 4 through the contact body 12 when the shield 4 is pressed against the self-resilient contact 5 in order to ensure an electrically conductive connection, the contact

GR 98 G 4047 DE

body 12 has a recess 15 which, as shown in Figures 2 and 3, can be V-shaped or semi-circular. According to Figures 1 to 3, this recess 15 is integrated into an elongated hole 16 of the contact body 12 which accommodates the measuring line 1 and is conductively connected to the housing 3 via a self-resilient contact. This also results in an electrically conductive coupling of the shield 4 to the housing 3 via the self-resilient contact 17 through the contact body 12, which has a further elongated hole 18 to enable it to be moved, into which a bolt 19 connected to the housing 3 engages.

In order to facilitate handling when establishing the electrically conductive connection between the shield 4 and the housing 3, the contact body 12 is provided with an actuating lever 20, by means of which the contact body 12 is first retracted and then released when the measuring line 1 is inserted into the housing 3, so that the compression spring is effective and the electrically conductive connection is established. Of course, the actuating lever 20 can also be led out of the housing 3 and the contact body 12 can thus be moved outside the housing 3. In this case, however, the actuating lever 20 must be led out of the housing via an elongated hole (not shown) inside the housing.

Figure 2 shows the contact body 12 according to Figure 1 under the force of the spring body 13 in a top view, in a position in which the contact body 12 is released by the actuating lever 20 and thus, taking into account the force of the spring body 13 received by the housing 14, presses on the measuring line 1 received by the slot 16 and thus on the shield 4. The measuring line 1 is thereby pushed out of the recess 15, which is V-shaped and integrated into the slot 16 of the contact body 12.

GR 98 G 4047 DE

is securely in place to ensure electrically conductive
Coupling recorded.

As shown in Figure 3 with a partially shown contact body 12, the recess 15 of the elongated hole 16 can also be semicircular in order to securely hold the measuring line 1.
However, it is then expedient if the surface of the recess 15 is sawtooth-shaped, and
This is the case even if the contact body 12 also provides an electrically
conductive coupling of the shield 4 to the housing 3 should take place as shown in Figure 1.

The design of the contact body 12 according to Figure 4 corresponds
essentially that of Figure 2, but the elongated hole 16 of this contact body 12 has two recesses 15, 21, each of which accommodates a measuring line 1, 22.

Claims (9)

GR 98 G 4047 DE ti· Protection claims 1. Electrically conductive coupling for the shielding (4) of an electrical line, in particular a control and/or measuring line (1) of electronic devices exposed to strong dielectric interference, which are arranged in a housing (3) made of a conductive material, characterized in that the shielding (4) can be connected to the housing (3) by a self-resilient contact (5) lying against it and connected to the housing (3) and by a contact member (6) pressing on the shielding (4) on the side opposite the self-resilient contact (5). 2. Electrically conductive coupling according to claim 1, characterized in that the spring travel of the self-resilient contact (5) on its side facing away from the shield (4) is limited by one leg (7) of an angle profile (8), between the second leg (10) of which and the housing (3) an angled section (11) of the self-resilient contact (5) is clamped. 3. Electrically conductive coupling according to claim 2, characterized in that the contact member (6) pressing on the shield (4) consists of a contact body (12) which is under the force of a spring body (13) acting in the direction of the shield (4), which is slidably connected to the housing (3) via a guide in such a way that a bolt (19) connected to the housing (3) engages in an elongated hole (18) of the contact body (12). GR 98 G 4047 DE 4. Electrically conductive coupling according to claim 3, characterized in that the contact body (12) has at least one recess (15) on its side facing the shield (4). 5 5. Electrically conductive coupling according to claim 4, characterized in that the at least one recess (15) of the contact body (12) is V-shaped or semi-circular. 10 6. Electrically conductive coupling according to claim 5, characterized in that the at least one recess (15) is integrated into an elongated hole (16) of the contact body (12) which accommodates the control and/or measuring line (1), which is arranged inside the housing (3) and is conductively connected to the housing (3) via a self-resilient contact (17). 7. Electrically conductive coupling according to one or more of claims 1 to 6, characterized in that the spring body (13) is a compression spring. 8. Electrically conductive coupling according to one or more of claims 1 to 6, characterized in that the spring body (13) is a tension spring. 9. Electrically conductive coupling according to one or more of claims 1 to 8, characterized in that the control and/or measuring line (1) is attached to one leg (7) of the angle profile (8).