DE202015103733U1 - Damping device for an electrical line - Google Patents

Abstract

Damping device (1) for damping movements of an electrical line, comprising - an at least partially hollow cylindrical cap (2) having a centrally disposed passage opening (7) for passing the electrical line, - a plurality of clamping elements (11) on a frontal web (9) of the cap (2) are arranged so that between an inner circumferential surface (8) and the clamping elements (11) has a gap (15) is formed, - a plug part (3) for mating with the cap (2), and - a plurality of pressing elements (21), which are arranged on an inner circumferential surface (8) of the plug part (3), - wherein during mating of the cap (2) and the plug part (3), the pressing elements (21) in the intermediate space (15 ) come into contact with the clamping elements (11) and thereby the clamping elements (11) from the inner circumferential surface (8) ago applying a clamping force to the electrical Press the line.

Description

Technical area

The present invention relates to a damping device for damping movements of an electrical line, in particular for damping movements of the line relative to an electrically conductive contact region of a connector attached thereto. A possible field of application of such a damping device is a wiring harness or wiring harness of a vehicle, in particular a power, hybrid or electric vehicle.

State of the art

From practice in vehicle technology it is known that in a wiring harness for a vehicle electrical system of a vehicle, a plurality of connectors is used, which are exposed in the vehicle environment partly high mechanical loads. If the mechanical loads exceed the load limit of a connector, this can also cause the failure of vehicle functions in unfavorable circumstances.

The stresses experienced by a connector in a vehicle include, among other things, uncontrolled movement and vibration of the associated electrical leads, particularly when the leads are not particularly routed or fastened. Stress is also the introduction of line movements, especially in the longitudinal direction of the line, us vibrations in the electrically conductive contact areas of a connector. Friction corrosion in the contact area or deformations of individual contacts of the contact area can also occur due to undesired movements. Through these deformations and contact gaps can be widened, which causes higher contact resistance and thus a poorer electrical conductivity. There is therefore a desire for effective prevention or at least reduction of unwanted movements of a line.

Description of the invention

An object of the invention is therefore to reduce the use of structurally simple means as possible movements of an electrical line relative to a connector attached thereto.

The object is solved by the subject matter of the independent claim. Advantageous developments of the invention are specified in the dependent claims, the description and the accompanying figures.

A damping device according to the invention is designed to dampen movements of an electrical line, in particular with respect to a connector attached to the line. The damping device has an at least partially hollow cylindrical cap which has a centrally disposed passage opening for passing the electrical line. The cap is in principle part of a connector. At a front-side web of the cap a plurality of clamping elements is arranged so that between a inner circumferential surface of the hollow cylinder of the cap and the clamping elements, a gap is formed. Furthermore, the damping device has a plug part, which forms a further part of the plug connector, for mating with the cap and a plurality of pressing elements, which are arranged on an inner circumferential surface of the plug part. When mating the cap and the male part, the pressing elements come into contact with the clamping elements in the intermediate space of the cap and thereby press the clamping elements of the inner circumferential surface ago applying a clamping force to the electrical line.

In other words, the cap and the connector plugged together so cooperate so that the associated electrical line is clamped by the clamping elements and thereby ideally no or at least only significantly damped, that is weakened or reduced movements against a connected to the line connector can perform. The cap and / or the plug part can be made as an injection molded part of a particular thermoplastic material. The clamping elements are preferably designed so that they have a larger inner diameter than the cladding diameter of the line to be clamped in the passage of the line through the cap. As a result, the cap can be pushed onto the line with little effort. By plugging together with the plug part, the clamping elements are pressed radially inward toward the line. In this position, the clamping elements and thus the clamped by this line can perform no or only negligible movements, so that the line is fixed by clamping.

Thus, the damping device according to the invention has the advantage that movements of the line are no longer initiated in a contact region of the connector. As a result, fretting corrosion, deformation and other damage to the contact area can be avoided. The damping device according to the invention thus increases the life and also the Functional safety of electrical connectors. Advantageously, the elements required for damping movement are thus already in the connector, which can be assigned to the cap and the connector part, integrated, so that no additional elements for line fixation are necessary.

The clamping elements may be resilient or flexible to allow a predetermined deflection and a predetermined contact pressure on the line. By a computer-aided simulation or by trial and error, the required assembly forces and clamping forces can be determined in advance and the clamping elements are adapted to different cable cross-sections. There are at least two opposing, but preferably three, four or more clamping elements arranged equidistantly distributed over the inner circumference of the cap to accomplish a uniform clamping of the line.

A particularly advantageous embodiment of the damping device according to the invention provides that exactly four clamping elements are arranged distributed equidistantly over the circumference of the inner circumferential surface. This represents a good compromise between material costs and clamping effect on the line.

In order to press the clamping elements as flexible as possible in the direction of the line, it has proved to be advantageous if the clamping elements extend away from an inner diameter of the frontally molded web to form the gap in the longitudinal direction of the cap. The inner diameter of the web is spaced from the inner circumferential surface of the cap by the web width, which is preferably a few millimeters. This means that the inner diameter of the web projects radially inwards from the inner lateral surface of the cap so that the clamping elements extending therefrom are likewise spaced from the inner lateral surface. As a result, the clamping elements of the line to be clamped towards the inner circumferential surface can bend freely at least within limits. In this case, the clamping elements may be formed integrally with the web. The clamping elements may have one or more spring arms, which allow a certain flexibility due to the plastic material used and the material thickness.

For the largest possible terminals of the line, it is advantageous if the clamping elements have a substantially parallel to the inner circumferential surface of the cap cap extending contact surface for contact with the electrical line. This means that the contact surface is arranged on the side facing away from the intermediate space of the clamping elements. The contact surface may extend in the circumferential direction of the hollow cylindrical cap between two spring arms, so that the contact surface can bend with these. Due to the parallelism to the inner circumferential surface, the contact surface is adapted to the geometric shape of the line to be clamped.

In order to protect the line against scrubbing in the area of the direct clamping and thereby increase the service life of the line, a silicone-comprising sealing agent can be applied to the contact surfaces. Silicone, in particular the poly (organo) siloxanes, have good lubricating properties, so that the application of silicone reduces the friction between the clamping elements and the line. Because the silicone is also contained in a sealant, the lubricity of the silicone can be combined with a longitudinal seal of the connector. The silicone may be self-adhesive or non-adhesive.

For a particularly good longitudinal sealing of the damping device having connector, it has proved to be advantageous if the clamping elements are encapsulated with a silicone comprehensive sealing. Thus, for example, spring arms together with contact surfaces of the clamping elements, intervening free spaces and (plastic) material recesses may be encapsulated with the sealing means. By the sealing means so that the free spaces and recesses are filled, yet the clamping elements remain flexible. At the same time a longitudinal seal of a connector is achieved.

An introduction of the sealing means can take place, for example, in that the silicone-comprising sealing means is self-adhesive and therefore adheres to the damping device by its own adhesive effect, in particular positive and / or non-positive. Alternatively, the silicone comprehensive sealant may be non-adhesive and therefore held by additional mechanical holding means, for example, purely positive fit on the damping device. Additionally or alternatively, the sealing means can also be formed separately from the damping device and glued into it with the aid of an adhesive.

The longitudinal seal can be further improved if the sealing means extends from an outer end face of the front-side web in the axial direction up to the clamping elements. In this case (recesses) may be provided on the front-side web in the vicinity of each clamping element, which extend in the radial direction of the web, so reduce the web at these points. By replacing the plastic material by the silicone comprehensive sealant is increases the flexibility and flexibility in the area of the clamping elements and in addition further improves the longitudinal seal of the damping device.

In order to further improve the longitudinal seal, however, a further embodiment variant of the invention provides that a sealing lip extending along its inner circumference is formed on the end-face web. This means that adjoins the plastic-formed frontal web in the radial direction towards a central axis of the cap the sealing lip. The sealing lip may be formed by the same silicone comprehensive sealing means, which is also described above. In particular, the front-side web can be encapsulated along its inner circumference, that is to say the inner radius with a sealing means comprising silicone. Due to the comparatively soft nature of the sealing means, it can advantageously be achieved that the cap in the region of the sealing lip fits snugly against the line to be clamped, thereby further improving the longitudinal sealing of the damping device.

For a structurally simple construction of the damping element, a further development provides that the pressing elements are ribs which extend inwardly away from the inner lateral surface of the plug part. In this case, the width, the height (ie, the increase relative to the inner circumferential surface) and the distance from one another are such that the pressure elements in at least one orientation of the cap relative to the plug part in the spaces between the clamping elements to be pressed and the inner circumferential surface of the cap (a) are pluggable. The rib shape of the pressing elements can be easily molded in one injection molding process in one piece with the remaining plug part.

In order to be able to plug together the plug part and the cap with the least possible expenditure of force, it has proved to be advantageous if the pressure elements are beveled in the longitudinal direction of the plug part to the clamping elements of the cap. As a result, an insertion bevel is formed, by which the pressure elements slide well against the clamping elements, in particular at their inner circumferential surfaces of the cap (inner) surfaces.

As a result, the cap and the connector part can be assembled with little effort.

For a functionally reliable clamping of the line, it has proven to be advantageous if at least two, but preferably four pressing elements are arranged distributed equidistantly over the circumference of an inner circumferential surface of the plug part. Ideally, this number corresponds to the number of clamping elements of the cap.

The damping device according to the invention can be used particularly advantageously in a wiring harness or wiring harness of a vehicle, in particular in a power, commercial, hybrid or electric vehicle.

Short description of the figures

Hereinafter, an advantageous embodiment of the invention will be explained with reference to the accompanying figures. Show it:

1 a perspective top view of a damping device according to the invention, which has a cap and a plug part,

2 a perspective top view of a cap of a damping device according to the invention,

3 a perspective bottom view of a cap of a damping device according to the invention,

4 a perspective top view of a cap of a damping device according to the invention, wherein portions of the cap are molded with a sealing means,

5 a perspective bottom view of a cap of a damping device according to the invention, wherein portions of the cap are molded with a sealing means,

6 a top perspective view of an illustrated as a single part connector part of a damping device according to the invention, and

7 a side sectional view of a damping device according to the invention, in which a cap and a plug part are plugged together.

The figures are merely schematic representations and serve only to illustrate the invention. Identical or equivalent elements are consistently provided with the same reference numerals.

1 shows a perspective plan view of a damping device according to the invention 1 , This serves for the damping, that is the suppression, reduction or attenuation, of movements of a connected electrical line.

Out 1 shows that the damping device 1 essentially a cap 2 and a plug part 3 having. The cap 2 and the plug part 3 are set up for nesting and stitching together as in 1 is indicated by the dashed line with the plug-in direction indicating arrow between the two elements. Accordingly, the cap is 2 according to 1 from above on the plug part 3 attached. For fixing the two elements 2 . 3 one another has the cap 2 on its outer circumference two opposing locking tabs 4 and the plug part 3 on its outer circumference two opposing locking lugs 5 to releasably engage with each other. The (not shown here) electrical line extends in the assembled state according to 1 from the cap 1 upwards away.

In 2 is the cap 2 shown as a single part in a perspective plan view. It can be seen that the cap 2 a substantially hollow cylindrical body 6 with a central passage opening 7 and an inner circumferential surface 8th having. At one end of the cap 2 is a jetty 9 molded, which in this embodiment by a plastic injection molding process integral with the body 6 is trained. The jetty 9 extends from the main body 6 in the radial direction inward (ie in the direction of the cylinder center axis) and causes at this point in principle a reduction of the inner diameter of the cap over the larger inner diameter of the body 6 ,

From the inner circumference 10 of the footbridge 9 extend several clamping elements 11 in the longitudinal direction of the cap 2 in the interior of the hollow cylindrical body 6 into it. In this embodiment, exactly four clamping elements 11 arranged in an equidistant distribution over the inner circumference of the basic body, wherein in the in 2 shown view only two clamping elements 11 can be seen. The clamping elements 11 serve to clamp the through the through hole 7 the cap 2 guided (not shown here) electrical line.

Each clamping element 11 consists essentially of two mutually parallel spring arms 12 and one between the two spring arms 12 in the circumferential direction of the body 6 extending contact surface 13 , The contact surface 13 serves the direct support on an outer jacket of the firmly clamped electrical line. The spring arms 12 and the contact surface 13 are each integral with the bridge 9 formed, for example by application of the same injection molding process. The geometry and material thickness of the spring arms 12 are sized so that the clamping elements 11 opposite the main body 6 and the jetty 9 are resiliently flexible in the radial direction. It is in 2 to recognize that the contact surface 13 substantially parallel to the inner circumferential surface 8th of the basic body 6 extends, so follows its cylindrical basic shape.

Furthermore goes out 2 forth that the jetty 9 for each clamping element 11 a frontal recess 14 which extends between the respective spring arms 12 extends in the radial direction from the inner periphery of the web to the outside. As a result, among other things, the springs and the flexibility of the spring arms 12 additionally supported. By molding the clamping elements 11 to the jetty 9 also results between the inner circumferential surface 8th and the respective clamping element 11 a gap 15 , which is approximately the radial width of the web 9 equivalent. Due to the resilient flexibility of the clamping elements 11 they can be separated from the gap 15 bend inward in the radial direction.

In 3 is the cap 2 out 2 shown in a perspective bottom view. In this illustration is the gap 15 behind the respective clamping elements 11 even better to see. In addition, it can be seen that the clamping elements 11 on one of the contact surface opposite, so the inner surface 8th each side facing two crescent-shaped indentations 16 exhibit.

4 shows the cap 2 in a perspective plan view. Deviating from the 2 and 3 is the cap 2 here in sections with a silicone comprehensive sealant 17 molded. By a silicone inherent adhesive effect, the sealant adheres to the surface of the cap 2 ,

So are in particular the clamping elements 11 together with the spring arms 12 and the contact surfaces 13 as well as the recesses 14 of the footbridge 9 silicone sealant 17 molded. Here are the recesses 14 complete with the sealant 17 filled, but also on the jetty 9 extends radially inward. This is a circumferential sealing lip or wiper lip 18 formed, which due to the soft nature of the sealant 17 can adapt well to the outer contour of the line to be clamped and thereby a longitudinal seal of the damping device 1 creates. By the encapsulation of the clamping elements 11 and in particular the contact surfaces 13 is the thus clamped line well protected against scrubbing due to the good lubricating properties of the silicone. Through the recesses 14 and the bookings 16 has the sealant 17 a firm grip for gluing with the cap 2 ,

In 5 is the one with the sealant 17 overmolded cap 2 shown in a perspective bottom view. It can be seen that the through the sealant 17 formed sealing lip 18 is formed circumferentially. In addition, goes out 5 that the sealant 17 from the jetty 9 up to a longitudinally lower end of the clamping elements 11 is consistently applied. This results in a good longitudinal seal of the damping device 1 ,

6 shows again the plug part 3 out 1 as a single part in a perspective top view. The plug part has in accordance with 6 upper region of a substantially hollow cylindrical body 19 on, in particular in the field of locking lugs 5 , In an unspecified, according to 6 lower area houses the plug part 3 an electrically conductive contact area with electrical contacts, which are connectable to conductors of the line to be clamped.

In the main body 19 has the plug part 3 on its inner surface 20 one of the number of clamping elements corresponding number of pressing elements 21 on. In this embodiment, exactly four pressing elements 21 equidistant over the inner circumference of the body 19 arranged distributed. The pressing elements 21 are considered to be from the inside surface 20 extending away, in the longitudinal direction of the plug part 3 running ribs formed whose width in the circumferential direction and height in the radial direction of the plug part 3 to the size and shape of the clamping elements 11 are adjusted. At an axial end, each pressure element 21 a bevel 22 as an insertion aid for sliding on the clamping elements 11 on.

7 shows a side sectional view of the plug part 3 put together, with silicone comprehensive sealant overmolded union nut 2 , It can be seen that the pressing elements 21 when mating the two elements 2 . 3 in between the clamping elements 11 and the inner circumferential surface 8th the cap 2 formed gap 15 intervene and engage with the contact surfaces 13 opposite sides of the clamping elements 11 are in plant. By the after the chamfers 22 increasing height of the pressing elements 21 are the resiliently flexible clamping elements 11 bent radially inward and thereby pressed against the (not shown here) line. As a result, the line is frictionally, namely clamping within the damping device 1 held.

In 7 can also be seen that the locking tabs 4 the union nut 2 in the state shown mated together with the locking lugs of the plug part 3 are in releasable latching engagement. As a result, the pressing elements 21 within the space 15 fixed so that the clamping elements 11 are permanently pressed against the line in this state and this against the (not shown) contact region of the plug part 3 fix.

LIST OF REFERENCE NUMBERS

1

attenuator

2

Nut

3

plug part

4

Locking tab (s)

5

Latching nose (s)

6

hollow cylindrical body

7

Through opening

8th

Inner surface area

9

web

10

Inner circumference / inner diameter (of the web)

11

Clamping element (s)

12

Spring arm (s)

13

Abutment surface (s)

14

Recess (es)

15

gap

16

Indentation (s)

17

sealing

18

Sealing lip / wiper lip

19

hollow cylindrical body

20

Inner surface area

21

Pressing element (e)

22

Chamfer (s)

23

electrical line

Claims (10)

Damping device ( 1 ) for damping movements of an electrical line, with - an at least partially hollow cylindrical cap ( 2 ), which has a centrally arranged passage opening ( 7 ) for passing the electrical line, - a plurality of clamping elements ( 11 ), which at a front-side web ( 9 ) the cap ( 2 ) are arranged so that between an inner circumferential surface ( 8th ) and the clamping elements ( 11 ) a gap ( 15 ), - a plug part ( 3 ) for mating with the cap ( 2 ), and - a plurality of pressing elements ( 21 ), which on an inner circumferential surface ( 8th ) of the plug part ( 3 ) are arranged, - whereby during mating of the cap ( 2 ) and the plug part ( 3 ) the pressing elements ( 21 ) in the space ( 15 ) with the clamping elements ( 11 ) come into contact and thereby the clamping elements ( 11 ) from the inner circumferential surface ( 8th ) Press on applying a clamping force to the electrical line. Damping device ( 1 ) according to claim 1, characterized in that the clamping elements ( 11 ) of an inner circumference ( 10 ) of the front-side molded web ( 9 ) forming the gap ( 15 ) in the longitudinal direction of the cap ( 2 ) away. Damping device ( 1 ) according to claim 1 or 2, characterized in that at least two, but preferably four clamping elements ( 11 ), equidistant over the circumference of the inner circumferential surface ( 8th ) are arranged distributed. Damping device ( 1 ) according to one of the preceding claims, characterized in that the clamping elements ( 11 ) is substantially parallel to the inner surface ( 8th ) the cap ( 2 ) extending contact surface ( 13 ) for contact with the electrical line. Damping device ( 1 ) according to claim 4, characterized in that on the contact surfaces ( 13 ) a silicone comprehensive sealant ( 17 ) is applied. Damping device ( 1 ) according to one of the preceding claims, characterized in that the clamping elements ( 11 ) with a sealing agent comprising silicone ( 17 ) are sprayed over. Damping device ( 1 ) according to any one of the preceding claims, characterized in that on the front-side web ( 9 ) one along its inner circumference ( 10 ) extending sealing lip ( 18 ) is trained. Damping device ( 1 ) according to one of the preceding claims, characterized in that the pressure elements ( 21 ) Are ribs extending from the inner surface ( 20 ) of the plug part ( 3 ) extend inwards. Damping device ( 1 ) according to one of the preceding claims, characterized in that the pressure elements ( 21 ) in the longitudinal direction of the plug part ( 3 ) to the clamping elements ( 11 ) the cap ( 2 ) are beveled. Damping device ( 1 ) according to one of the preceding claims, characterized in that at least two, but preferably four pressing elements ( 21 ) equidistantly over the circumference of an inner circumferential surface ( 20 ) of the plug part ( 3 ) are arranged distributed.

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