EP3152801A1

EP3152801A1 - Contact retaining part with secured pull-out protection

Info

Publication number: EP3152801A1
Application number: EP15725234.7A
Authority: EP
Inventors: Martin Zebhauser; Matthias Brixner; Till BREDBECK
Original assignee: Rosenberger Hochfrequenztechnik GmbH and Co KG
Current assignee: Rosenberger Hochfrequenztechnik GmbH and Co KG
Priority date: 2014-05-27
Filing date: 2015-05-26
Publication date: 2017-04-12
Anticipated expiration: 2035-05-26
Also published as: CN105981233A; CA2934471A1; DE202014004431U1; US20170117656A1; KR20170008199A; JP2017517103A; WO2015180836A1; TWM512236U; US9806452B2; EP3152801B1; CN105981233B

Abstract

The invention relates to a retaining part (10) for the pull-resistant holding of a pin-shaped contact element (100), comprising a housing (20) with an accommodation space (22) for accommodating the contact element (100) and at least one primary securing element (30) which protrudes into the interior of the accommodation space (22) and can be radially deflected, having an axial stop (32) for a projection (110) of the contact element in order to secure the contact element in a pull direction (Z) opposite to an insertion direction (E), wherein a secondary securing element (40), which in a securing position contacts at least in sections the outside of the primary securing element (30), is provided to prevent the radial (R) deflection of the primary securing element (30).

Description

Contact holding part with secured train protection

The invention relates to a holding part for tensile holding a pin-shaped contact element with a housing having a receiving space for receiving the contact element and at least one projecting into the interior of the receiving space and radially deflectable primary fuse. The primary fuse has an axial stop on which a projection of the contact element can strike, so that the contact element accommodated in the receiving space is secured in the holding part in a pulling direction directed counter to an insertion direction. Furthermore, the invention relates to a contact holder with a holding part according to the invention and a contact element held in tension thereto.

A pin-shaped contact element is generally understood to be an elongated electrical contact for transmitting electrical voltage or electrical signals, such as, for example, a contact pin, an inner conductor of a cable or the like. A contact element held in a tensile-resistant manner on a holding part can also be subjected to tensile force do not pull out of the holding part in one pulling direction. Such a holding part may be a part of a connector such as an insulating part of a plug, a female connector, a socket, a coupler, a mounting socket or the like. be, wherein in the holding part, for example, attached to a cable end Contact element is held such that even with a pulling action on the cable slipping out of the contact element is reliably prevented from the holding part.

Conventional retaining parts with clamping sections are known in order to frictionally clamp a cable or a contact element of the cable between the clamping sections. However, such a clamp is not sufficiently reliable when acting on the cable high tensile forces. Coaxial cable or other cables with an outer conductor such as a wire mesh can additionally be held tensile strength over the regularly particularly stable outer conductor to an outer conductor housing of the connector. Particularly difficult, however, is a tension-resistant attachment of cables which have only one or more comparatively thin contact pins as contact elements.

In this latter case, a Zugsicherung be provided with an axial stop on which abuts a projection of the contact element when a tensile force in the pulling direction acts on the contact element, so that withdrawal of the contact element from the holding member in the axial direction is prevented (both the insertion direction as well as the pulling direction opposite to the insertion direction are substantially parallel to the axial direction of the contact element). In order to enable a quick and user-friendly installation of the contact element in the holding part, the train protection is arranged radially deflectable, so that the projection of the contact element during assembly on the radially deflected paragraph past is easily inserted into the receiving space. It has been found, however, that the contact element despite this backup can solve at high tensile forces from the holding part.

In view of the problems described, it is the object of the present invention to provide a holding part in which a contact element can be mounted very quickly and easily and can withstand high tensile forces on the contact element at the same time. This object is achieved by a holding part according to claim 1. Advantageous developments of the holding part according to the invention are described in the dependent claims. The holding part according to the invention is characterized by a in a securing position at least partially radially outside of the primary fuse adjacent secondary fuse to prevent the radial deflection of the primary fuse. After insertion of the contact element in the receiving space, the secondary fuse can be attached to the outside of the primary fuse, the secondary fuse in the radial direction immobile or rigid, so that the inside of it applied primary fuse is no longer deflected to the outside and thus the contact element in any Case can release more.

The invention is based on the knowledge that although the radial deflection of the primary fuse while mounting the contact element in the receiving space can be simplified, but on the other hand, even if the primary fuse presses under a bias against the contact element, it is not excluded that the Primary fuse slides over the projection of the contact element and thus releases the contact element in the pulling direction. Such a "levering" of the elastic primary safety threatens, for example, when exposed to a particularly high or obliquely directed tensile force.

A particularly effective securing of the primary fuse against a radial deflection of the same is made possible by the fact that the primary fuse has a parallel to the insertion direction extending outer contact surface on which rests in the securing position parallel to an inner bearing surface of the secondary fuse. The two surface abutting contact surfaces of primary and secondary fuse can be curved at least in sections in the circumferential direction and, for example, be designed as a cylinder jacket partial surfaces, or they can alternatively be formed as a plane and parallel to the insertion direction extending (guide) surfaces. The secondary fuse may be arranged such that it can be displaced relative to the primary fuse in an axial direction such that a space for a possible axial compensating movement of the contact element accommodated in the receiving space can be adjusted by displacement of the secondary fuse. For this purpose, the secondary fuse from a first securing position in the axial direction in a second securing position and / or vice versa adjustable be set, the secondary fuse in each of the fuse positions at least partially radially outwardly applied to the primary fuse and thus prevents radial deflection of the primary fuse. In this displacement of the secondary fuse slides in the axial direction extending inner bearing surface of the secondary fuse along the adjoining outer contact surface of the primary fuse.

On the other hand, to prevent the contact element in the insertion direction is inserted too far into the receiving space or on the front side of the holding part can be brought out, the secondary fuse preferably has a further axial stop for the projection of the contact element. In this way, the contact element is not only secured in the pulling direction, but also in this opposite direction of insertion. The attacks of primary fuse and secondary fuse are facing each other such that the projection or a plurality of projections of the contact element are receivable therebetween and depending on the axial position of the contact element on one or the other stop.

In order to adjust an axial compensation possibility of the contact element as needed in a desired amount, it is advantageous if the distance between the axial stop of the primary fuse and the further axial stop of the secondary fuse in the second securing position is greater than in the first securing position. In the first securing position, the distance may, for example, substantially correspond to an axial dimension of the projection, in which case no axial compensation of the contact element is possible, so that the contact element is held substantially immovably in the axial direction with respect to the holding part. In the second securing position, the distance may be more than 1.5 times, preferably more than 2 times, the axial dimension of the projection, and more preferably more than 1 mm, in particular more than 2 mm, larger than these. The contact element is then with an axial play of more held as 1 mm, in particular 2 mm or more tensile strength in both directions in the holding part. Preferably, the holding part according to the invention has a fixing mechanism for fixing the secondary fuse in one or more securing positions. Further, a holding mechanism may be provided by which a detachment of the secondary fuse is prevented by the housing.

A particularly effective primary safety device is characterized by an inner surface facing the receiving space, which extends in such a way that it gradually tapers the clear width of the receiving space in the insertion direction, at least in sections. When inserting the contact element in the receiving space, the primary fuse is gradually pressed by the inner surface facing the projection of the contact element to the outside until the projection engages behind the primary fuse. In the insertion direction, the tapering inner surface of the transverse, in particular approximately perpendicular to the insertion radially outwardly extending axial stop can be connected. In a relaxed state of the primary fuse, the clear width of the receiving space is smaller than the contact element in the region of the projection, so that the contact element can only be moved past the primary fuse after it has been pushed away. After insertion of the contact element, the inner wall of the primary fuse at least partially abut closely against the contact element, so that both a positive and a non-positive connection between the contact element and holding part is made.

In a preferred embodiment, the secondary fuse is part of a second housing part which is displaceably held on the housing in the axial direction, such as a cap with a side wall which continues the receiving space in the direction of insertion. The cap preferably has attachment means for attachment to the housing, the attachment allowing guided axial movement from the first securing position to the second securing position and vice versa. A front end of the contact element may project beyond a front end of the cap. Alternatively or additionally, the cap may have a passage opening for passing through the contact element. The primary safety device preferably has an elastically resiliently arranged flap part, such as a leaf spring part, which is set up in such a way that it is biased radially outwards during the insertion of the contact element into the receiving space by a projection of the contact element and engages behind the projection.

To increase the stability of the holding part, the primary fuse can be integrally formed, in particular in one piece with the housing. Preferably, the primary fuse and the remaining housing sections are made of a non-conductive material such as a plastic. In this case, the housing together with the associated primary fuse can be molded integrally from the plastic material. Also, the cap may be integrally molded together with the secondary fuse connected thereto from an insulating material such as a plastic material.

According to a further, particularly important aspect, the invention relates to a holding part for tensile holding a contact element with a housing having a receiving space for receiving the contact element and at least one projecting into the receiving space and radially deflectable arranged primary fuse with an axial stop on which a projection of the received in the receiving space contact element can strike, so that the contact element is secured in the direction opposite to the insertion direction pulling direction. Instead of or in addition to the secondary fuse described above, the holding part may have an additional primary fuse in the form of a likewise extending into the interior of the receiving space above additional assurance with an axial securing stop for the projection of the contact element. The projection of the contact element strikes at a force acting on the contact element tensile force on both the stop of the primary fuse and on the securing stop of the additional assurance and is thus doubly secured in the pulling direction. The additional security differs from the primary security in particular in that it is rigid and not resilient or resiliently arranged in the radial direction.

Thus, there is no risk that the additional backup radially outward in the action of a tensile force on the contact element unlike the primary fuse snaps back and releases the contact element in the pulling direction. At the same time during insertion of the contact element in the holding part insertion of the contact element in the receiving space in the insertion over the two radially inwardly projecting stops away, since the primary fuse in the radial direction sufficiently far yields, so that the projection of the contact element on both stops can slide away.

For this purpose, preferably both the primary fuse and the additional fuse on the inside width of the receiving space in the insertion at least partially gradually tapered inner surface to allow for the assembly as smooth as possible sliding of the projection over the paragraphs away. In the direction of insertion, the stop or securing stop, which extends approximately radially outward, advantageously adjoins the inner surfaces, so that the projection of the contact element can engage behind the primary securing device or behind the additional securing device.

As a further precautionary measure, the above-explained secondary fuse can be provided, which rests radially on the outside of the primary fuse in order to prevent the radial deflection of the primary fuse in a securing position. The secondary fuse may be part of a second housing part, such as a cap, which is attached to the housing after insertion of the contact element into the receiving space. With regard to further features of the secondary fuse and the primary fuse, reference is made to the above statements. With regard to a particularly good securing effect, it has proved to be advantageous for the additional securing device to be arranged essentially in the direction of insertion at the level of the primary securing device. In particular, the stop of the primary fuse can lie approximately in the same radial plane as the securing stop of the additional fuse. Namely, in this case, a single circumferential projection of the contact element, such as a collar, can be simultaneously secured to both the stopper and the securing stopper. Furthermore, in this case, the projection is held by the primary fuse at the same time both behind the axial stop of the primary fuse and behind the securing stop. Alternatively or additionally, a plurality of spaced apart in the insertion elastic primary fuses and / or inelastic additional fuses can be provided. Advantageously, each additional securing one or more elastically trained primary fuses opposite. In this case, the contact element may have more than one projection, for example two or three projections which are spaced apart from one another in the insertion direction.

Alternatively or additionally, more than one elastic primary fuse and / or more than one inelastic additional fuse can be provided in the same radial plane, which are, for example, spaced apart in the circumferential direction.

It is particularly advantageous if the additional fuse of the primary fuse is just opposite, that is, if the additional fuse is spaced in the circumferential direction by about 180 ° from the primary fuse is particularly advantageous. Then presses the primary fuse namely the contact element particularly effective in the recess behind the securing paragraph.

According to a further aspect, the invention relates to a contact holder with a holding part according to the invention and a pin-shaped contact element held tensile in its receiving space. In the present case, a "pin-shaped contact element" is understood to mean an elongated contact element, such as a contact pin, an inner contact or the like.

The contact element is preferably, but not necessarily substantially rotationally symmetrical, for example, designed approximately cylindrical. Starting from a base part of the contact element, one or more radially outwardly projecting projections may be provided, which preferably have front and / or rear side surfaces extending perpendicular to the insertion direction, so that the side surfaces can lie flat against the stops which are also perpendicular to the insertion direction. In a preferred embodiment of the invention, the projection is formed as an annular collar, which rotates in a ring-like manner over a substantially cylindrical base part of the contact element. In this way, it is ensured that the fuses of the holding part engage independently of the rotational position of the contact element behind the projection. Alternatively, the contact element may have more than one projection, each one the projections may be associated with a primary fuse and / or an additional fuse.

The pointing in the direction of insertion side surface of the projection is preferably facing the axial stop of the secondary fuse, while the pointing in the direction of the pulling direction side surface of the projection is preferably facing the axial stop of the primary fuse and / or the securing stop of the additional assurance. Preferably, the holding part has two or more juxtaposed receiving spaces, each having at least one primary fuse, secondary fuse and / or additional fuse for each contact element. In this way, for example, a two- or multi-core cable or a wire bundle can be coupled to the holding part and is then connected tensile strength with this. In a particularly preferred embodiment, the holding part is an insulating part for the tensile strength receiving the cable end of a (possibly unshielded) twisted pair cable with two twisted wires to which, if necessary, in each case a contact pin is attached. For example. the holding part is part of a connector such as a HSD coupler. In the following description, the invention will be explained with reference to the accompanying drawings, to which reference is expressly made with respect to essential features of the invention, which are not described in detail in the description. 1 shows a schematic sectional view of a holding part according to the invention with a contact element held therein in a first securing position I,

Fig. 2 is a schematic sectional view of the holding part shown in Fig. 1 in a second securing position II.

1 shows a partial region of a holding part 10 according to the invention with a contact element 100 received therein, schematically in a longitudinal section. The cutting plane runs parallel to the insertion direction E, in which the contact element 100 is inserted into the holding part 10, or parallel to the oppositely directed pulling direction Z.

The holding part 10 has a housing 20 with a receiving space 22 for receiving the contact element 100 and a second housing part 45 attached to the housing 22. The second housing part 45 forms a side wall 48 which continues the receiving space 22 in the insertion direction E.

The housing 20 is an insulating part of a connector such as a coupler, and the second housing part 45 forms a cap covering a front portion of the coupler.

The housing 20 has an elastically formed primary fuse 30 connected thereto, and the second housing part 45 has an associated secondary fuse 40 for securing the primary fuse 30 against an elastic deflection in a securing position.

In which in the insertion direction E extending receiving space 22 of the housing 20, a contact element 100 is held tensile strength in the form of a contact pin. In other words, the contact element 100 can not be pulled out of the receiving space 22 even under application of a tensile force in the pulling direction Z. This is because a projecting from a substantially cylindrical base portion of the contact element 100 radially outwardly projecting projection 110 on an axial stop 32 of the primary fuse 30. By abutting the axial stop 32 projection 1 0 a positive connection between the contact element 100 and the housing 20 is made.

The axial stop 32 of the primary fuse 30 is formed by an in the insertion direction E front surface of an obliquely from a side wall of the housing 20 in the direction of the contact element 100 protruding tab portion. The inner surface 36 of the flap part extends in the insertion direction E gradually in the direction of the contact element 100, up to a contact region 39, in which the flap part fits tightly against the contact element 100. Because of this gradually tapering course of the receiving space 22 up to the contact area 39, the flap part when inserting the contact element 100 into the receiving space 22 by the projection 110 gradually pushed radially outward until the stop 32 springs back behind the projection 110 against. The inner wall 36 abruptly in the perpendicular to the insertion direction E extending stop 32, so that upon application of force to the contact element in the pulling direction Z springing back of the flap part is prevented, at least at only a moderate tensile force.

As already indicated, the primary fuse 30 is designed to be deflectable in the radial direction R for the purpose of simple mounting of the contact element 100. However, after the insertion of the contact element 100, after the projection 10 is locked behind the stop 32, a radial deflection of the primary fuse 30 must be prevented in any case, since thereby the contact element 100 would be released in the pulling direction Z. Therefore, in the securing position illustrated in FIGS. 1 and 2, the secondary fuse 40 for securing the primary fuse 30 against a radial deflection is provided on the outside of the primary fuse 30.

The secondary fuse 40, which is preferably formed integrally with the second housing part 45 made of plastic, has a parallel to the insertion direction E extending, the primary fuse 30 facing inner bearing surface 44 which rests against a parallel thereto extending outer bearing surface 34 of the primary fuse 30. This course of the two contact surfaces 34, 44 is particularly important because it allows a guided displacement of the second housing part 45 relative to the housing 20 in or against the insertion direction E while maintaining the securing effect of the secondary fuse 40.

In Fig. 1, a first securing position I is shown, in which the second housing part 45 is pushed far in the direction of the housing 20. In this position, a distance A between the axial stop 32 of the primary fuse 30 and a further axial stop 42 of the secondary fuse is only slightly larger than an axial dimension of the projection 110, which is arranged between the two stops 32, 42. Thus, the contact element 100 in this position only a small clearance in the axial direction.

In the second securing position II shown in FIG. 2, the second housing part 45 is advanced far in the direction of the insertion direction E with respect to the housing 20. In In this position, a distance A between the stops 32, 42 is about twice as large as the axial dimension of the projection 110 disposed between the stops 32, 42, so that the contact element has room for axial compensating movements. It is important that in both securing positions I, II parallel to the insertion direction E extending contact surfaces 34, 44 of primary fuse and secondary fuse abut each other, so that regardless of the axial position of the secondary fuse no radial deflection of the primary fuse is possible.

The secondary fuse 40 shown in Fig. 1 has a plurality of stages extending outward sections. On the inner abutment surface 44 of an outer step, the outer abutment surface 34 of the primary fuse 30 abuts in the securing position, an outer surface of the protrusion 110 abuts against the inner surface 47 of a middle step 47, and an outer surface of a base section of the inner step 43 of an inner step Contact element 100 abut. As a result, the diameter of the receiving space 22 is respectively adapted to the diameter of the contact element 100, whereby a particularly stable guidance of the contact element 100 in the axial direction is made possible.

According to a particularly important aspect of the invention, the housing 20 in addition to the elastic primary fuse 30 on an inelastic additional fuse 50. The additional safety device 50 has an axial safety stop 52, which lies substantially in the same radial section plane as the stop 32 of the primary safety device 30. In particular, the additional safety device 50 is located substantially opposite the primary safety device 30 within the receiving space 22. Also, the auxiliary fuse 50 has a clear width of the receiving space 22 in the insertion direction E gradually tapering inner surface along which the projection slides along during insertion 1 0 and the opposite primary fuse 30 thereby gradually pushes out until the projection 110 behind the two stops 32, 52 engages, wherein the biased at this time primary fuse 30 jumps back inside. The clear width of the receiving space 22 at its narrowest point between primary fuse 30 and additional fuse 50 is thus smaller than the diameter of the contact element 100 in the region of the projection 1 0. Behind the stops 32, 52 in the insertion direction E, the diameter of the receiving space 22 in contrast Essentially the diameter of the contact element 100 in the region of the projection 110 correspond, so that the contact element in the region of the arranged between the stops 32, 42 projection 10 is stably displaced in the axial direction, since it has no radial play. The second housing part 45 is fastened to the housing 20 in a displaceable manner in the axial direction via a fixing mechanism (not shown).

A particularly reliable securing of the contact element 100 in the receiving space 22 of the holding part 10 against acting tensile forces is given when the holding part has both the primary and the secondary and the additional assurance. Because of the secondary fuse 40 not only the primary fuse, but indirectly also the inelastic additional fuse 50 is secured.

Alternatively, however, an inventive holding part 10 is conceivable that only the primary fuse and the secondary fuse or only the primary fuse and the auxiliary fuse.

A manufacturing process for producing a contact holder according to the invention comprises the following steps: First, the contact element 100 is inserted in the insertion direction E in the receiving space 22 of the holding part 10, wherein the outside of the primary fuse 30 is still no secondary fuse 40 is arranged, so that the primary fuse 30 radially is deflectable to the outside. As a result, the projection slides 1 10 under deflection of the primary fuse 30 on the stops 32, 52 of primary fuse 30 and additional fuse 50 away (the flap part springs back) until the primary fuse 30 snaps back behind the projection 110, so that the contact element 100 at forces in effect is held in the pulling direction Z zugfest. Subsequently, the secondary housing 40 having the second housing part 45 is so connected to the housing 20, as shown in Figures 1 and 2, so that the holding part 0 is in the securing position. In this position, the contact element 100 is secured by the further axial stop 42 of the second housing part 45 even with a tensile force in the insertion direction E.

Claims

claims:

Holding part (10) for holding a pin-shaped contact element (100) in a manner that is resistant to tension

a housing (20) having a receiving space (22) for receiving the contact element (100)

and at least one in the receiving space (22) projecting and radially deflectable arranged primary fuse (30) having an axial stop (32) for a projection (1 0) of the contact element to this in a counter to an insertion direction (E) directed pulling direction ( Z) to secure

marked by

a secondary fuse (40), which bears against the primary fuse (30) at least in sections in a securing position, for preventing the radial (R) deflection of the primary fuse (30).

Holding part according to claim 1, characterized in that the primary fuse (30) has a parallel to the insertion direction (E) extending outer bearing surface (34) on which in the securing position a parallel thereto extending inner bearing surface (44) of the secondary fuse (40) ,

Holding part according to claim 1 or 2, characterized in that the secondary fuse (40) for adjusting an axial mobility of the contact element (100) from a first securing position (I) in the axial direction in a second securing position (II) and / or vice versa is adjustable, in which the secondary fuse (40) rests at least in sections radially (R) on the outside of the primary fuse (30).

4. holding part according to one of the preceding claims, characterized in that the secondary fuse (40) has a further axial impact (42) for a projection (110) of the contact element (100) to secure it in the insertion direction (E).

Holding part according to claims 3 and 4, characterized in that the distance (A) between the axial stop (32) of the primary fuse (30) and the further axial stop (42) of the secondary fuse (40) in the second securing position (II) larger is as in the first securing position (I).

Holding part according to one of the preceding claims, characterized in that the primary securing device (30) has an inside surface (36) which gradually narrows the clearance of the receiving space (22) in the insertion direction (E) at least in sections, to which the insertion direction (E) preferably the transverse, in particular approximately perpendicular to the insertion radially outwardly extending axial stop (32) connects.

Holding part according to one of the preceding claims, characterized in that the secondary fuse (40) part of a displaceable in the axial direction of the housing (10) second housing part such as a cap (45) with a receiving space (22) in the insertion direction (E ) is continuing sidewall.

Holding part according to at least one of the preceding claims, characterized in that the primary fuse (30) has an elastically resiliently arranged flap part, which is set up in such a way that, when the contact element (00) is introduced into the receiving space (22), it is replaced by the projection (110). of the contact element radially (R) is biased outwardly and behind the projection (110) engages.

Holding part according to at least one of the preceding claims, characterized in that the primary fuse (30) is integrally formed, in particular in one piece with the housing (10), in particular integrally formed therewith from a plastic material.

10. holding part, in particular according to one of the preceding claims, characterized by a in the interior of the receiving space (22) projecting additional fuse (50) having an axial securing stop (52) for a projection (110) of the contact element (100) to this in the opposite to the direction of insertion (E) directed pulling direction (Z) to secure, the additional safety (50) is set inelastic.

Holding part according to claim 10, characterized in that the additional safety device (50) in the insertion direction (E) is arranged substantially at the level of the primary safety device (30), wherein the stop (32) of the primary safety device (30) is preferably located approximately in the same radial plane the safety stop (52) of the additional safety device (50).

Contact holder with a holding part (10) according to one of the preceding claims and a pin-shaped contact element (00) which is held in a tension-proof manner in its receiving space.

Contact holder according to claim 12, characterized in that the projection (10) of the contact element (100) is designed substantially as a collar, one side surface facing the axial stop (32) of the primary fuse and / or the securing stop (52) of the additional fuse, and / or the other side surface facing the further axial stop (42) of the secondary fuse.