DE202020107616U1 - Cable clamping device and its use - Google Patents

Abstract

Device (1) for clamping at least one electrical cable (9), which has at least one electrical conductor, in an electrical installation, the device (1) having at least one cable bushing area (2) through which the cable (9) to be clamped can be passed, has a counter bearing (4) and a clamping body (3) which is movable relative to the counter bearing (4) and has a cable clamping surface (7) for contact with the cable (9), the cable feedthrough area (2) being separated from the movable clamping body (3 ) and is limited on an opposite side by the counter bearing (4), characterized in that
- the movable clamping body (3) is rotatably mounted and that
- When the movable clamping body (3) is rotated with a movement of the cable clamping surface (7) directed at least partially counter to a conductor insertion direction (L), the cable feedthrough area (2) is reduced compared to an initial position.

Description

The invention relates to a device for clamping at least one electrical cable, which has at least one electrical conductor, in an electrical installation, the device having at least one cable bushing area through which the cable to be clamped can be passed, a counter bearing and a clamping body which is movable relative to the counter bearing a cable clamping surface for contacting the cable, wherein the cable feedthrough area is delimited on one side by the movable clamping body and on an opposite side by the counter bearing. The invention also relates to the use of such a device for clamping an electrical cable, as strain relief and/or as a shield conductor connection.

The invention generally relates to the field of electrical installation technology, in particular using electrical cables that have at least one electrical conductor in an electrical installation, such as a switch cabinet. There is a need to adequately fix the electrical cable and to protect electrical components connected to the cable from tensile stress, i.e. to provide strain relief. In addition, a secure contact should be made available in the event that a shield conductor connection is required.

From the DE 20 2015 102 037 U1 a construction clamp is known in which a cable can be clamped via a screw and a pressure plate. Such a solution with a clamping screw has the disadvantage that the tight fit of the clamp has to be checked regularly and the clamping screw has to be tightened if necessary.

The invention is based on the object of specifying an improved device for clamping at least one electrical cable and advantageous uses of the device.

• - der bewegliche Klemmkörper drehbar gelagert ist und dass
• - bei einer Drehung des beweglichen Klemmkörpers mit einer zumindest teilweise entgegen einer Leitereinführungsrichtung gerichteten Bewegung der Kabelklemmfläche der Kabeldurchführungsbereich gegenüber einer Ausgangslage verkleinert ist.

This object is achieved in a device of the type mentioned in that

• - the movable clamping body is rotatably mounted and that
• - When the movable clamping body is rotated with a movement of the cable clamping surface directed at least partially counter to a conductor insertion direction, the cable feedthrough area is reduced compared to an initial position.

In this case, the movable clamping body can be eccentrically rotatably mounted or non-eccentrically rotatably mounted, e.g. centrically and/or centrally mounted. The arrangement is self-reinforcing when the conductor is run, i.e. the more the electrical cable is pulled against the direction of conductor insertion, the stronger the clamping effect. In the initial position, when the electric cable is inserted into the cable bushing area, the clamping body can, for example, initially rest loosely with its cable clamping surface on the electric cable. A tensile force applied to the cable against the conductor insertion direction can then, for example, cause the movable clamping body to rotate and thus reduce the cable bushing area compared to the initial position.

Such a device can be implemented with little structural effort and therefore inexpensively. The device is characterized by simple operation by the user. In particular, the cable can be clamped very easily and quickly, since no clamping screw has to be actuated. Thanks to the movable clamping body, which can be rotated eccentrically or non-eccentrically, the cable can be fixed simply by inserting it into the cable bushing area and clamping it with a short movement in the opposite direction. The rotary bearing generates a self-reinforcing clamping force, i.e. the more the cable is pulled in the opposite direction, the stronger the clamping force exerted on the cable by the clamping body.

In particular, the device according to the invention can be implemented in a very compact and small-sized manner, since a clamping screw does not protrude on one side. Since no clamping screw is required, the risk of damage to the cable during clamping is reduced since overtightening with the clamping screw cannot occur as in the prior art.

A further advantage of the device according to the invention compared to fixing by means of a screw is that the movable clamping body adjusts itself if, for example, the cable gives way a little or vibrations occur. A permanent clamping force is exerted on the cable without any manual adjustments having to be made.

• - Wartungsfrei
• - Rüttelfest
• - Vibrationsfest
• - Für das Festklemmen des Kabels ist kein Werkzeug nötig
• - Zeitsparend
• - Platzsparend
• - Höhere Haltekräfte für die Zugentlastung.

The invention thus ensures the secure and maintenance-free attachment of one or more cables in an electrical installation or as a maintenance-free shield conductor connection. The advantages of the invention can be briefly summarized as follows:

• - Maintenance free
• - Vibration resistant
• - Vibration resistant
• - No tools are required to clamp the cable
• - Time saving
• - Space saving
• - Higher holding forces for the strain relief.

The clamp body may be shaped like an eccentric cam. The pivot axis of the clamping body can run transversely to the direction of passage of the cable through the cable passage area, e.g. perpendicular thereto. The counter bearing can be a fixed or a movable counter bearing. For example, the counter bearing can be designed as a movably mounted second clamping body. A fixed counter bearing, which is arranged at least essentially immovably on the device, is particularly advantageous. As a result, the device can be implemented in a particularly compact and space-saving manner, since the counter bearing can be designed to be relatively small, e.g. as a pressure plate. The cable entry area can also be limited by side walls, i.e. closed on four sides. On its side facing the counter bearing, the clamping body has a cable clamping surface for clamping the cable. The cable clamping surface comes into contact with the cable during clamping.

The movably mounted clamping body and/or the movably mounted second clamping body can be rigid, in contrast to a clamping body with resilient properties, such as those present in a clamping spring. Such a rigid clamping body is dimensionally stable when used as intended.

Insofar as a cable is mentioned in this application, this means an electrical cable which has an outer insulating layer which surrounds the electrical conductor or conductors of the cable. The cable can also have an outer shielding layer that is electrically conductive. In this case, the insulating layer, which in turn surrounds the electrical conductor or conductors, is located within the shielding layer.

According to an advantageous embodiment of the invention, it is provided that a force acts on the movable clamping body, as a result of which the cable feedthrough area is reduced compared to an initial position. In this way, the movable clamp body is loaded with a force directed towards the counter bearing, e.g. by gravity, which acts on the clamp body's own weight. This has the advantage that the clamping body does not have to be actuated manually by the user, but moves automatically in the direction of the counter bearing and can accordingly automatically clamp the cable.

According to an advantageous embodiment of the invention, it is provided that the device has a prestressed spring, the spring exerting a force on the movable clamping body. Such a spring allows the movable clamping body to be loaded with a force directed toward the counter bearing. Such a spring-loaded clamping body has the advantage that it reliably automatically causes the desired clamping of the cable, regardless of the installation position of the device, i.e. also against the force of gravity.

According to an advantageous embodiment of the invention, it is provided that the spring is designed as a spiral spring, torsion spring or torsion spring. This allows a simple implementation of a spring-loaded clamping body. Such a spring can be integrated into the device in a structurally favorable manner, in particular in the area of the axis of rotation of the clamping body. The spring can, for example, surround the axis of rotation, with which the movable clamping body is rotatably mounted, on the outer circumference.

According to an advantageous embodiment of the invention, it is provided that the device has a holding frame on which the counter bearing is arranged and on which the movable clamping body is mounted. The holding frame can be U-shaped, for example. For example, the support frame may be formed by side walls and a top wall. The counter bearing preferably connects the two side walls, so that a closed frame is formed, within which the clamping body is mounted.

According to an advantageous embodiment of the invention, it is provided that the device has mounting rail fastening elements with which the device can be fastened to a mounting rail. This has the advantage that the device can be easily attached in a standard electrical installation, namely on a standard mounting rail. The mounting rail fastening elements can be locking elements with which the device can be snapped onto a mounting rail. The mounting rail can be a standard mounting rail used in electrical installation technology, e.g. a C-rail or a top-hat rail.

According to an advantageous embodiment of the invention, it is provided that the cable clamping surface has a convexly curved profile in a sectional plane running transversely to the pivot axis of the clamping body. Due to the convex curve, the cable clamping surface lies down gently rolling onto the cable, so to speak, so that damage to the cable insulation through edges on the cable clamping surface is avoided.

In an advantageous embodiment of the invention, the clamping body has friction-increasing elements, at least in the area of the cable clamping surface, such as a roughened surface or other elements, as described below. This ensures that the cable does not slip out of the device when it is loaded in the clamping direction. Sufficient friction between the cable and the clamp body in particular supports clamping due to the eccentric shape.

According to an advantageous embodiment of the invention, it is provided that the movable clamping body has clamping and/or holding edges, corrugations and/or teeth running transversely to the direction of passage of the cable through the cable passage area, at least on its side facing the counter bearing. Such friction-increasing elements make clamping of the cable even more secure. In an advantageous embodiment of the invention, the clamping and/or holding edges, corrugations and/or teeth are comparatively small and not extremely sharp-edged, so that damage to the cable, in particular to its insulation, is avoided.

Such clamping and/or holding edges, corrugations and/or teeth can have a longitudinal extension that extends at least essentially parallel to the pivot axis of the movable clamping body.

According to an advantageous embodiment of the invention, it is provided that the movable clamping body has at least one groove or trough running in the direction of passage of the cable through the cable passage area on its side facing the counter bearing. In this way, safe cable routing in the cable bushing area can be ensured. The groove or trough thus extends along the course of the cable in order to at least partially encompass and guide the cable. The friction-increasing elements can also be present in the area of the groove or trough.

The shape and dimensions of the groove or trough can be adapted to the desired cable to be clamped or its diameter.

According to an advantageous embodiment of the invention, it is provided that at least one component of the device that delimits the cable feedthrough area is electrically conductive. This has the advantage that, for example, an outer shield of the cable can be electrically contacted directly by the device, for example by the device making electrical contact with the mounting rail on which the device is attached. For example, the counter bearing and/or the side walls can be electrically conductive. The support rail fastening elements can be electrically conductive and they can be electrically conductively connected to the electrically conductive component that delimits the cable feedthrough area.

According to an advantageous embodiment of the invention, it is provided that the device has a further movable clamping body, which forms the counter bearing. In this way, the cable can be clamped on both sides by a clamping body, in each case from one side of the cable.

According to an advantageous embodiment of the invention, it is provided that the further movable clamping body is mounted in an eccentrically rotatable manner. In this way, the further movable clamping body behaves in a manner comparable to the first-mentioned movable clamping body. In particular, the advantageous self-reinforcing clamping effect can then be realized on both sides due to the eccentric mounting.

The previously mentioned further configurations of the movable clamping body can also be realized in whole or in part on the further movable clamping body.

A tool, for example a screwdriver, which is inserted into a receiving opening of the clamping body, can be used to release a cable clamped by the clamping body. The clamping body can then be deflected manually with the tool and released here by the clamping. According to an advantageous embodiment of the invention, the movable clamping body therefore has a receiving opening for an actuating tool at a point that is easily accessible manually, in particular on a side facing away from the clamping surface.

The object mentioned at the outset is also achieved by using a device of the type explained above for clamping an electrical cable, which has at least one electrical conductor, in an electrical installation and/or as a strain relief for the cable and/or as a shield conductor connection for the cable. The advantages explained above can also be realized in this way.

For the purposes of the present invention, the indefinite term “a” does not include a numeral stand. If, for example, a component is mentioned, this is to be interpreted in the sense of "at least one component". If angles are specified in degrees, these refer to a circular measurement of 360 degrees (360°).

The invention is explained in more detail below on the basis of exemplary embodiments using drawings.

• 1 eine Einrichtung in seitlicher Schnittdarstellung vor dem Festklemmen eines Kabels und
• 2 die Einrichtung gemäß 1 mit festgeklemmtem Kabel und
• 3 eine Draufsicht auf die Einrichtung gemäß 2 und
• 4 einen exzentrisch drehbar gelagerten Klemmkörper in Schnittdarstellung.

Show it

• 1 a device in side section before clamping a cable and
• 2 the facility according to 1 with clamped cable and
• 3 a top view of the device according to FIG 2 and
• 4 a sectional view of an eccentric rotatably mounted clamping body.

the 1 shows a device 1 according to the invention in a lateral sectional view. The device 1 has a cable bushing area 2 through which the cable 9 to be clamped can be passed. The cable bushing area 2 is delimited on one side (above here) by a movable clamping body 3 and on a side opposite the clamping body 3 by a counter bearing 4 . The counter bearing 4 is not movable in the exemplary embodiment shown, ie it is rigidly fixed to parts of the device 1 . In this case, the abutment 4 is designed, for example, as a pressure plate against which the clamped cable 9 can be pressed by the clamping body 3 .

The clamping body 3 is rotatably mounted via a rotation axis 5 . The axis of rotation 5 passes, for example, completely or partially through the clamping body 3 and is fixed to the side walls 12 of the device 1 . As can be seen, the axis of rotation 5 does not pass through the clamping body 3 centrically, but rather eccentrically, ie the clamping body 3 is mounted eccentrically rotatably by the axis of rotation 5 . In the area of the axis of rotation 5 there is also a prestressed spring 6, by means of which the clamping body 3 is loaded with a basic spring force F ₁ directed towards the counter bearing 4. The clamping body 3 can be deflected manually against this basic spring force F ₁ , for example by inserting the cable 9 into the cable bushing area 2 in accordance with the 1 shown arrows.

On its surface side facing the counter bearing 4 , the clamping body 3 has a cable clamping surface 7 , which is used to clamp the cable 9 . Friction-increasing elements 8 are arranged on the cable clamping surface 7, by means of which the friction between the clamping body 3 and the cable 9 is adjusted to a desired range.

The device 1 can be designed like a closed cage in the upper region in which the clamping body 3 is arranged, namely with an upper wall 13 which connects a left and a right side wall 12 to one another. In the lower area, the side walls 12 are connected to one another via the counter bearing 4 . In this way, a holding frame 16 can be formed which is U-shaped and is formed by the side walls 12 and the top wall 13 . The counter bearing 4 preferably connects the two side walls 12 so that a closed frame is formed, within which the clamping body 3 is mounted.

The side walls 12 can transition downwards into mounting rail fastening elements 10 in an area which is used to fasten the device 1 to the mounting rail. The support rail fastening elements 10 can thus be arranged behind the counter bearing 4 when viewed from the clamping body 3 . The carrier rail fastening elements 10 have respective holding recesses 11 with which the device 1 can be fastened to a carrier rail, e.g. by snapping it on.

the 2 shows a cable 9 passed through the cable bushing area 2 , which is clamped by the clamping body 3 and the counter bearing 4 . The clamping is initially caused by the basic spring force F ₁ of the spring 6 . If a tensile force F ₂ is now applied to the cable 9 , this increases due to the eccentric effect of the clamping body 3 to an increased contact pressure force F ₃ . In this way, self-reinforcement of the clamping force is brought about. In this way, the cable 9 is strain-relieved in the direction of the tensile force F ₂ .

If the clamped cable 9 is to be removed from the device 1 or repositioned, the clamping can be released manually. For this purpose, the clamping body 3 has a receiving opening 14 for receiving a tool 15 . If the tool 15 , for example a screwdriver, is inserted into the receiving opening 14 , the clamping body 3 can be pivoted to the right and thus released from the cable 9 by manually applying an opening force F ₄ . In this way the clamping is released.

the 3 shows the arrangement according to 2 in a top view. The mounting of the clamping body 3 via the axis of rotation 5 between the side walls 12 of the device 1 can be seen is also that the cable clamping surface 7 can be designed in the manner of a groove or trough, which can have a course which is essentially adapted to the outer circumference of the cable 9 . The friction-increasing elements 8 in the form of teeth or edges can also be seen. The abutment 4 can also have a contour that is correspondingly rounded toward the cable bushing area 2 and by means of which the cable 9 is centered and guided in the cable bushing area 4 . The contour of the cable clamping surface 7 or of the counter bearing 4 can be suitable for different cable diameters.

the 4 shows the rotatable mounting of the clamping body 3 via the axis of rotation 5 in an enlarged detailed representation. The spring 6, which can be designed as a torsion spring, can also be seen. The spring 6 is fixed on the one hand on the axis of rotation, which is immovably connected to a side wall 12, and on the other hand on the clamping body 3. The cable clamping surface 7 with the friction-increasing elements 8 can also be seen.

Reference List

1

furnishings

2

cable entry area

3

movable clamping body

4

counter bearing

5

axis of rotation

6

Feather

7

cable clamping surface

8th

friction-increasing elements

9

Cable

10

mounting rail fastener

11

holding recess

12

Side wall

13

top wall

14

intake opening

15

Tool

16

holding frame

F1

basic spring force

F2

tensile force on cable

F3

pressing force

F4

opening force

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 202015102037 U1 [0003]

Claims (16)

Device (1) for clamping at least one electrical cable (9), which has at least one electrical conductor, in an electrical installation, the device (1) having at least one cable bushing area (2) through which the cable (9) to be clamped can be passed, has a counter bearing (4) and a clamping body (3) which is movable relative to the counter bearing (4) and has a cable clamping surface (7) for contact with the cable (9), the cable feedthrough area (2) being separated from the movable clamping body (3 ) and is delimited on an opposite side by the counter bearing (4), characterized in that - the movable clamping body (3) is rotatably mounted and that - when the movable clamping body (3) rotates with an at least partially counter to a conductor insertion direction (L ) directed movement of the cable clamping surface (7), the cable feedthrough area (2) is reduced compared to an initial position. Device (1) according to claim 1 , characterized in that the movable clamping body (3) is mounted eccentrically rotatable. Device (1) according to one of the preceding claims, characterized in that the counter-bearing (4) is designed as a movably mounted second clamping body. Device (1) according to one of the preceding claims, characterized in that the movably mounted clamping body (3) is rigid. Device according to one of the preceding claims, characterized in that a force (F ₁ ) acts on the movable clamping body (3), as a result of which the cable feedthrough area (2) is reduced compared to an initial position. setup after claim 5 , characterized in that the device (1) has a prestressed spring (6), the spring (6) exerting a force (F ₁ ) on the movable clamping body (3). setup after claim 6 , characterized in that the spring (6) is designed as a spiral spring, torsion spring or torsion spring. Device (1) according to one of the preceding claims, characterized in that the device has a holding frame (16) on which the counter bearing (4) is arranged and on which the movable clamping body (3) is mounted. Device according to one of the preceding claims, characterized in that the device (1) has carrier rail fastening elements (10) with which the device (1) can be fastened to a carrier rail. Device according to one of the preceding claims, characterized in that the clamping body (3) has on its side facing the counter bearing (4) a cable clamping surface (7) for clamping the cable (9) which is in a direction transverse to the pivot axis (5) of the Clamping body (3) running section plane has a convex curved course. Device according to one of the preceding claims, characterized in that the movable clamping body (3) has friction-increasing elements (8) at least on its side pointing towards the counter bearing (4). Device according to one of the preceding claims, characterized in that the movable clamping body (3) has on its side facing the counter bearing (4) at least one groove or trough running in the direction of passage of the cable (9) through the cable passage region (2). Device according to one of the preceding claims, characterized in that at least one component of the device (1) delimiting the cable bushing area (2) is electrically conductive. Device according to one of the preceding claims, characterized in that the device (1) has a further movable clamping body which forms the counter bearing (4). setup after Claim 14 , characterized in that the other movable clamping body is mounted eccentrically rotatable. Use of a device (1) according to one of the preceding claims for clamping an electrical cable (9), which has at least one electrical conductor, in an electrical installation and/or as strain relief for the cable and/or as a shield conductor connection for the cable (9).

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