Patent Grant
11189969
Priority is claimed to German Patent Application No. DE 10 2019 112 532.4, filed on May 14, 2019, the entire disclosure of which is hereby incorporated by reference herein.
The invention relates to a plug-in connector system, to an electrical device, and to a method for encoding a plug-in connector system.
Such a plug-in connector system comprises a first plug-in connector part and a second plug-in connector part which can be connected together in a plug-in manner along a plug-in direction. The connector system also includes an encoding device having a first encoding part connectable to the first plug-in connector part and a second encoding part connectable to the second plug-in connector part. The first encoding part and the second encoding part can be arranged together on the second plug-in connector part in a pre-assembly position. The first encoding part is adapted to connect to the first plug-in connector part when the first plug-in connector part and the second plug-in connector part are connected together, and to remain on the first plug-in connector part when the first plug-in connector part and the second plug-in connector part are detached from one another.
In a plug-in connector system known from EP 2 091 108 B1, encoding parts of an encoding device for pre-assembly can be arranged together on an associated plug-in connector part by connecting an encoding part of the encoding device to the plug-in connector part in a latching manner via spring arms. In a pre-assembly position, another encoding part is held on the encoding part and through it on the associated plug-in connector part. If the plug-in connector part together with the encoding device arranged thereon is connected to another plug-in connector part, the further encoding part comes into contact with this other plug-in connector part and remains on the other plug-in connector part when the plug-in connector parts are detached from one another. After the plug-in connector parts have been detached from one another again, an encoding is thus produced on the plug-in connector parts in that one encoding part comes to rest on one plug-in connector part and the other encoding part comes to rest on the other plug-in connector part. By virtue of the fact that the encoding parts can be joined together in exactly one position, an encoding is created in this way on the plug-in connector parts which ensures that only specified plug-in connector parts that are assigned to one another can be connected to one another.
In existing encoding devices, the number of encoding possibilities can be limited. Thus, there may not be enough distinguishing possibilities if there are a plurality of pairs of plug-in connector parts in order to clearly distinguish all pairs of plug-in connector parts from one another.
In an embodiment, the present invention provides a plug-in connector system, comprising: a first plug-in connector part and a second plug-in connector part, which are connectable to one another in a plug-in manner along a plug-in direction; and an encoding device having a first encoding part connectable to the first plug-in connector part and a second encoding part connectable to the second plug-in connector part, wherein the first encoding part and the second encoding part are arrangeable together on the second plug-in connector in a pre-assembly position and the first encoding part is configured to connect with the first plug-in connector part during connecting of the first plug-in connector part and the second plug-in connector part and to remain on the first plug-in connector part during detaching of the first plug-in connector part and the second plug-in connector part from each other, wherein one of the second plug-in connector part and the second encoding part has a locking section and an insertion opening and an other of the second plug-in connector part and the second encoding part has a locking element, and wherein for connecting the second encoding part to the second plug-in connector part, the locking element is guidable through the insertion opening along the plug-in direction and the locking element is configured to be brought into form-fitting engagement with the locking section by rotation of the second encoding part and the second plug-in connector part relative to one another.
The present invention will be described in even greater detail below based on the exemplary figures. The invention is not limited to the exemplary embodiments. Other features and advantages of various embodiments of the present invention will become apparent by reading the following detailed description with reference to the attached drawings which illustrate the following:
In an embodiment, the present invention provides a plug-in connector system which makes it possible to provide an encoding on plug-in connector parts in a simple manner with a potentially comparatively large number of encoding possibilities via the encoding device.
Accordingly, in the plug-in connector system, one of the second plug-in connector part and the second encoding part has a locking section and an insertion opening, and the other of the second plug-in connector part and the second encoding part has a locking element, wherein for connecting the second encoding part and the second plug-in connector part, the locking element can be guided through the insertion opening and the locking element can be brought into form-fitting engagement with the locking section by rotation of the second encoding part and the second plug-in connector part relative to one another.
This is based on fixing the second encoding part to the associated second plug-in connector part via a connection in the manner of a bayonet connector. In this case, the second encoding part should be firmly held on the associated second plug-in connector part when in the connected position, in particular along the plug-in direction, with the second encoding part preferably also being secured in its rotational position relative to the second plug-in connector part.
To produce the encoding, the encoding device is arranged on the second plug-in connector part. For this purpose, the second encoding part—together with the first encoding part arranged on the second encoding part—is connected to the second plug-in connector part in that the locking element is guided through the insertion opening and is form-fittingly engaged with the locking section by rotation of the second encoding part relative to the second plug-in connector part. Through the engagement of the locking element with the locking section, the second encoding part is thus fastened to the second plug-in connector part, so that the second encoding part is arranged in a fixed position on the second plug-in connector part.
Now, the second plug-in connector part is connected in a plug-in manner to the first plug-in connector part, with a first encoding part located on the second encoding part in the pre-assembly position. When connecting, the first encoding part interacts with the assigned first plug-in connector part in such a way that, when the first plug-in connector part and the second plug-in connector part are detached from each other again, the first encoding part remains on the first plug-in connector part and thus—when the plug-in connector parts are detached—the first encoding part comes to rest on the first plug-in connector part and the second encoding part comes to rest on the second plug-in connector part.
The encoding parts thus provide encoding in that, when the plug-in connector parts are connected again, the encoding parts have to be brought together and joined to one another in the intended manner. Only plug-in connector parts with a matching encoding defined on the basis of the position of the encoding parts can be joined to one another, so that plug-in connector parts with incorrect encoding can be prevented from being connected to one another by means of the encoding parts.
The encoding is simple to produce by means of the encoding device. By virtue of the fact that the second encoding part can be arranged in different positions on the associated second plug-in connector part, a variable encoding with a comparatively large number of different encoding possibilities can also be provided.
In one embodiment, the locking section extends in a ring shape, wherein the insertion opening interrupts the locking section at one location when viewed along a circumferential direction about the plug-in direction. The locking section can, for example, be formed circumferentially on the second encoding part and is interrupted by the insertion opening in such a way that the locking element formed on the second plug-in connector part in this case can be moved past the locking section through the insertion opening in order to establish a form-fitting engagement between the locking element and the locking section by subsequent rotation of the second encoding part relative to the second plug-in connector part and thereby to fix the second encoding part to the second plug-in connector part.
In one embodiment, one of the parts, that is to say the second plug-in connector part or the second encoding part, has a connection shaft which is, for example, cylindrically shaped and extends along the plug-in direction. In this case, the respective other part, that is to say the second encoding part or the second plug-in connector part, has a connection opening into which the connection shaft can be inserted in order to arrange the second encoding part on the second plug-in connector part.
The locking section may extend, for example, on the connection shaft in that the locking section is formed circumferentially on the connection shaft and protrudes from the connection shaft radially with respect to the plug-in direction. If the connection shaft is a component of the second encoding part, the locking section is thus associated with the second encoding part. Alternatively, however, the connection shaft may also be a component of the second plug-in connector part and may be introduced into a connection opening of the second encoding part. In this case, the locking section is part of the second plug-in connector part.
A connection in the manner of a bayonet connector is created by the locking section interrupted by the insertion opening on one of the parts and the locking element on the other of the parts. In this case, both the locking section and the locking element can be rigidly formed on the associated component in each case. To connect, the locking element is guided through the insertion opening interrupting the locking section, and the locking element is brought into form-fitting engagement with the locking section by subsequent rotation.
It is also conceivable and possible here to provide more than one locking element, which can accordingly be passed through more than one insertion opening interrupting the locking section. In this way, the connection between the second encoding part and the second plug-in connector part can be secured and fixed at a plurality of locations.
In one embodiment, the second encoding part has a first latching device, while the second plug-in connector part comprises a second latching device. The first latching device and the second latching device together define a plurality of discrete rotational positions which are angularly spaced apart from one another about the plug-in direction, in which positions the second encoding part and the second plug-in connector part are held latched to one another. The latching devices thus predefine rotational positions in which the second encoding part can be brought to the second plug-in connector part. These rotational positions define different encoding positions for providing encoding between the plug-in connector parts.
The first latching device can be formed, for example, by one or more latching projections which project radially from a connection shaft of the second encoding part and are angularly spaced apart from one another. In this case, the second latching device on the second plug-in connector part can be formed, for example, by one or more latching pockets angularly spaced apart from one another, for example on a wall surrounding a connection opening of the second connector part. Alternatively, the first latching device can be formed by one or more latching pockets, while the second latching device is formed by one or more latching projections. A combination of latching pockets and latching projections on each latching device is also conceivable and possible.
In a predetermined rotational position corresponding to an encoding position, the latching devices engage in a latching manner with one another in such a way that the second encoding part and the second plug-in connector part cannot be easily rotated out of the rotational position, in any case not without exceeding a certain threshold force. The second encoding part can thus be brought into different, defined positions relative to the second plug-in connector part, so that a desired encoding can be set as a function of the position of the second encoding part.
In this case, it can be provided that the first encoding part and the second encoding part can (exclusively) be joined to one another along the plug-in direction in a predetermined angular position relative to one another. The position of the second encoding part on the second plug-in connector part thus defines the position of the first encoding part in which the first encoding part can be joined to the second encoding part. Only when the first encoding part is in a matching position assigned to the second encoding part—after the encoding has been produced—can the plug-in connector parts be connected to one another along the plug-in direction without being hindered by the encoding parts.
In one embodiment, one of the encoding parts has an encoding shaft, while the other of the encoding parts forms an encoding opening. The encoding shaft can be joined to the encoding opening along the plug-in direction (exclusively) in a predetermined angular position, due for example to the fact that the encoding shaft and the encoding opening have an asymmetrical shape, for example a D shape or a wedge shape, in cross-section transverse to the plug-in direction. The encoding shaft and the encoding opening can thus exclusively be joined together in a specified position. Thus, if the first encoding part and the second encoding part have no matching positions with respect to one another, the encoding shaft and the encoding opening prevent the encoding parts from being joined to one another.
In one embodiment, the encoding shaft has at least one fitting section with an interference fit with the encoding opening. Such a fitting section can be formed, for example, by a ridge extending axially on the outside of the encoding shaft which has an interference fit with the encoding opening and thus deforms when the encoding shaft is joined to the encoding opening. Using such a fitting section, a frictional connection between the encoding shaft and the encoding opening can be achieved which secures the first encoding part and the second encoding part axially to one another, in particular in their pre-assembly position.
In one embodiment, the first encoding part has a first collar with at least one first encoding element formed thereon. On the other hand, a second collar with at least one second encoding element formed thereon is formed on the second encoding part. The first encoding element and the second encoding element can be joined together along the plug-in direction in a predetermined angular position, so that a (further) encoding between the encoding parts is provided via the encoding elements.
The first encoding element can be embodied, for example, as an encoding projection which can be brought into engagement with an associated second encoding element in the form of an encoding recess. Conversely, the first encoding element can also form an encoding recess which can be joined to an associated second encoding element in the form of an encoding projection. The encoding elements are arranged asymmetrically around the plug-in direction on the first collar and the second collar, so that the encoding elements together define a (single) rotational position of the encoding parts relative to one another in which the encoding parts can be joined to one another.
In one embodiment, the first encoding part has at least one latching element for a latching connection to the first plug-in connector part. To produce the encoding, the first encoding part is first arranged together with the second encoding part on the second plug-in connector part. When the plug-in connector parts are first connected to one another, the first encoding part then engages with the first plug-in connector part, so that the first encoding part remains on the first plug-in connector part and thus the encoding is provided by the encoding parts on the different plug-in connector parts. The connection of the first encoding part to the assigned first plug-in connector part can take place in a latching manner in that one or more latching elements of the first encoding part engage form-fittingly with the first plug-in connector part in such a way that the first encoding part is firmly and durably connected to the first plug-in connector part along the plug-in direction.
For example, in one embodiment, the first encoding part can have an engagement section which can be brought into engagement axially along the plug-in direction with an associated receiving opening of the first plug-in connector part. Here, the at least one latching element can be formed on the engagement section transversely to the plug-in direction, so that, in a connected position, the at least one latching element engages behind an edge of the receiving opening of the first plug-in connector part, for example, and thus the first encoding part is fixed to the first plug-in connector part.
In one embodiment, one of the plug-in connector parts, for example the second plug-in connector part, has at least one plug-in section with an electrical contact element arranged thereon. The at least one plug-in section can be connected in a plug-in manner along the plug-in direction to an associated plug-in opening of the other plug-in connector part, so that the electrical contact element of the plug-in section is electrically contacted with an electrical contact element of the plug-in opening and thus an electrical connection is established between the plug-in connector parts. On each plug-in connector part, for example, multiple plug-in sections can be formed in series which can be connected with multiple plug-in openings formed in series on the respective other connector. In this way, multipolar electrical contacting between the plug-in connector parts can be produced.
An electrical device comprises a plug-in connector system as described above. Such an electrical device may, for example, have a housing with a fastening device formed therein for arranging the electrical device on a support rail. In this way, the electrical device can be combined in particular with other electrical devices on a support rail, wherein the electrical devices on the support rail can be attached to one another in order to create an electrical installation for providing different electrical or electronic functions.
For example, the first plug-in connector part can be fixedly connected to the housing of the electrical device. On the other hand, terminal devices can be arranged on the second plug-in connector part in the manner of screw terminals or spring force terminals via which electrical conductors can be connected to the second plug-in connector part. Electrical conductors can thus be connected to the electrical device via a plug-in connection by connecting the second plug-in connector part to the first plug-in connector part on the side of the electrical device in a plug-in manner.
In an embodiment, the invention also provides a method for encoding a plug-in connector system. The plug-in connector system includes a first plug-in connector part and a second plug-in connector part which can be connected together along a plug-in direction. In the method, a first encoding part and a second encoding part of an encoding device are arranged together on the second plug-in connector part in a pre-assembly position, and then the first plug-in connector part and the second plug-in connector part are connected to each other, wherein when the first plug-in connector part and the second plug-in connector part are connected to each other, the first encoding part engages with the first plug-in connector part and remains on the first plug-in connector part when the first plug-in connector part and the second plug-in connector part are detached from each another. In this case, it is provided that one of the first plug-in connector part and the second encoding part has a locking section and an insertion opening, and the other of the second plug-in connector part and the second encoding part comprises a locking element, the locking element being guided through the insertion opening along the plug-in direction and the locking element being brought into form-fitting engagement with the locking section by rotation of the second encoding part and the second plug-in connector part relative to one another.
The advantages and advantageous embodiments described above for the plug-in connector system also apply analogously to the method, so that reference should be made to the above statements in this regard.
In the exemplary embodiment of
In the exemplary embodiment of
In the exemplary embodiment shown in
In the exemplary embodiment in
In the exemplary embodiment of
In the exemplary embodiment in
The first plug-in connector part 2 according to
While in the examples of the second plug-in connector parts 3 which are shown in
Electrical lines can be connected to associated first plug-in connector parts 2 on the side of an electrical device 1 via the second plug-in connector parts 3 of the exemplary embodiments according to
For this purpose, encoding devices 4 are provided in the plug-in connector parts 2, 3 which have encoding parts 40, 41 and provide such an encoding between the plug-in connector parts 2, 3 that only plug-in connector parts 2, 3 that are encoded to match one another can be connected to one another.
Each encoding device 4 is formed by two encoding parts 40, 41, as can be seen from
As can be seen from
On a side facing away from the encoding shaft 410, engagement sections 412 extend from the collar 411 and serve to engage in the receiving opening 23 of the first plug-in connector part 2 (see
Two mutually opposite encoding elements 416 and a further encoding element 417 arranged between the encoding elements 416 in the form of encoding recesses are formed on the collar 411. An edge section 415 protrudes axially toward the encoding shaft 410 from the collar 411.
As can be seen from
On the collar 401, on a side facing away from the connection shaft 402, encoding elements 406, 407 are formed in the form of encoding projections, of which two encoding elements 406 lie opposite one another and a third encoding element 407 is arranged between the encoding elements 406. The encoding elements 406, 407 are complementary to the encoding elements 416, 417 of the first encoding part 41 in such a way that the encoding elements 406, 407, 416, 417 can be matchingly engaged with each other when the encoding parts 40, 41 are connected (in a way corresponding to the encoding).
Diametrically opposed fitting sections 418 are formed on the encoding shaft 410 in the form of axially extending, outwardly projecting ridges that have an interference fit with the encoding opening 400. When connecting the encoding parts 40, 41 to one another, the encoding shaft 410 of the first encoding part 41 thus engages with the encoding opening 400 of the second encoding part 40 in an interference fit, so that the encoding parts 40, 41 are held together at least in a captive manner when in the joined state.
The second encoding part 40 is assigned to the second plug-in connector part 3 and is to be attached to a socket 33 on the body 30 of the plug-in connector part 3. As can be seen from
A locking element 331 protrudes radially inward into the connection opening 330 and serves for the locking connection of the second plug-in connector part 3 to the encoding part 40. Thus, the encoding part 40 is inserted into the connection opening 330 for connection such that the locking element 331 is passed through the insertion hole 405 of the locking section 404 until the locking section 404 has passed the locking element 131. By rotation, the encoding part 40 can then be fixed to the socket 33 in that the locking element 331 engages with the locking section 404 in a form-fitting manner.
At the outwardly facing edge of the connection opening 330, outwardly curved exposed areas 333 are formed which serve as insertion aids and can be used to engage latching devices 408 in the form of radially outwardly projecting latching projections on the bearing section 403 of the encoding part 40 in order to connect the encoding part 40 to the socket 33.
The latching devices 408 in the form of the latching projections interact with the latching devices 332 in the form of latching pockets in the interior of the connection opening 330 in order to hold the encoding part 40 in a latched position in the connection opening 330 in predetermined discrete rotational positions.
A viewing window 334 through which a user can visually inspect whether a connection between the encoding part 40 and the socket 33 has been established as intended is formed in a foot region of the socket 33.
The encoding part 41 is assigned to the first plug-in connector part 2 and is to be received in a receiving opening 23 on the body 20 of the plug-in connector part 2. On one side to which the encoding part 41 is to be attached, each receiving opening 23 of the plug-in connector part 2 is surrounded by a plurality of support elements 32 with which the collar 411 of the encoding part 41 comes into contact during connection. The latching elements 413 can run on the engagement sections 412 on an edge surrounding the receiving opening 23 via run-up slopes 231 in order to snap into latching engagement with the edge surrounding the receiving opening 23 and thus to produce a form-fitting connection between the encoding part 41 and the first plug-in connector part 2.
In order to produce an encoding between the plug-in connector parts 2, 3, an encoding device 4 is attached to each socket 33 on the body 30 of the second plug-in connector part 3, as can be seen from
As can be seen from
In the joined state, the fitting sections 418 are inserted in the encoding opening 401 with an interference fit, as can be seen from
In this joined state, the encoding devices 4 are attached to the plug-in connector part 3, as can be seen from
As can be seen from
The encoding device 4 can now be rotated as a whole—by placing a tool 5 in the form of a screwdriver into the central engagement 414 between the engagement sections 412 as shown in
As can be seen from
When the encoding devices 4 on a plug-in connector part 3 have been brought into a desired position, as is illustrated by way of example in
As shown by way of example in
If the plug-in connector parts 2, 3 are to be connected to one another again, this is only possible with correct encoding. Thus, only mutually encoded, mutually associated plug-in connector parts 2, 3 can be joined to one another, namely those plug-in connector parts 2, 3 in which the encoding parts 41 on the plug-in connector part 2 fit into the encoding parts 40 on the plug-in connector part 3.
For each encoding device 4, the encoding shaft 410 and the encoding opening 400 provide a primary encoding, which allows the encoding parts 40, 41 to be joined in a matching orientation and interact first during a plug-in process. The encoding elements 406, 407, 416, 417 on the collars 401, 411 provide a secondary encoding and can likewise only be joined together in a matching orientation, but in particular also serve to visualize the rotational position of the encoding parts 40, 41 for a user, so that a user can easily recognize whether an encoding is appropriate and plug-in connector parts 2, 3 can be joined to one another or not.
The idea underlying the invention is not limited to the exemplary embodiments described above, but can in principle be realized in a different manner.
In particular, encoding devices of the type described are not restricted to use on plug-in connector parts of the designs illustrated in the figures, but can be used on any desired plug-in connector parts which are to be connected to one another. In this respect, the use of such an encoding device is also not limited to the connection of lines to an electrical device to be arranged on a support rail.
In this case, one, two or even more encoding devices can be used on two plug-in connector parts. By using a plurality of encoding devices, the encoding possibilities can be broadened so that a larger number of plug-in connector parts can be distinguished in the encoding.
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. It will be understood that changes and modifications may be made by those of ordinary skill within the scope of the following claims. In particular, the present invention covers further embodiments with any combination of features from different embodiments described above and below. Additionally, statements made herein characterizing the invention refer to an embodiment of the invention and not necessarily all embodiments.
The terms used in the claims should be construed to have the broadest reasonable interpretation consistent with the foregoing description. For example, the use of the article “a” or “the” in introducing an element should not be interpreted as being exclusive of a plurality of elements. Likewise, the recitation of “or” should be interpreted as being inclusive, such that the recitation of “A or B” is not exclusive of “A and B,” unless it is clear from the context or the foregoing description that only one of A and B is intended. Further, the recitation of “at least one of A, B and C” should be interpreted as one or more of a group of elements consisting of A, B and C, and should not be interpreted as requiring at least one of each of the listed elements A, B and C, regardless of whether A, B and C are related as categories or otherwise. Moreover, the recitation of “A, B and/or C” or “at least one of A, B or C” should be interpreted as including any singular entity from the listed elements, e.g., A, any subset from the listed elements, e.g., A and B, or the entire list of elements A, B and C.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102019112532.4 | May 2019 | DE | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3491330 | Barnhart | Jan 1970 | A |
| 4032213 | Snyder | Jun 1977 | A |
| 6302745 | Landis | Oct 2001 | B1 |
| 6814625 | Richmond | Nov 2004 | B2 |
| 20090209140 | Heggemann | Aug 2009 | A1 |
| 20110177715 | Buck et al. | Jul 2011 | A1 |
| Number | Date | Country |
|---|---|---|
| 102007052606 | Jun 2009 | DE |
| 2091108 | Apr 2016 | EP |
| 2262001 | Jun 1993 | GB |
| Number | Date | Country | |
|---|---|---|---|
| 20200366032 A1 | Nov 2020 | US |
