1. Field of the Invention
The present invention relates to a plug connector technology for automotive applications.
2. Description of the Related Art
In conventional connector elements for automotive applications, contact elements are introduced into a contact carrier, for example, the housing of the connector element, after crimping, i.e., the connection of a cable to a contact element. In this context, the contact elements lock a so-called primary locking lance using either a flexible element on the contact element, or by a flexible element in the connector housing, which engages in a corresponding recess on the contact element.
For contact elements having a primary locking lance, it is frequently possible to achieve higher chamber extraction forces for a given overall size, since plastic undercuts provided for locking may be designed to be larger than plastic locking hooks of the connector element.
Conventional plastic locking hooks are frequently made up of a flexible bar, to which a detent is attached, which engages in an opening in the contact element or on an edge on the contact element.
a through 1c show embodiments of connector elements.
Connector elements having chambers into which the contact elements may be introduced are known. These chambers have locking hooks (see
Another embodiment uses locking hooks, in which the movement of the hooks is not limited by chamber walls. The elimination of rear or intermediate spaces between contact elements and latching elements makes it possible to reduce the space requirement per chamber.
The movement of a locking hook 6 may occur, for example, in a recess, which is present in any case, or also in the direction of an additional locking hook 6 (see
The dimensioning of a locking hook and thus also the buckling resistance to the extraction force are directly incorporated in the achievable row spacing in plug connector 2.
One aspect of the present invention may be seen in providing a locking concept using locking hooks in the housing of a connector element, which on the one hand makes it possible for the contacts to have high retention forces against extraction, and on the other hand minimizes the space requirements.
According to the present invention, two contact elements are in each case held in their position in the connector element by a locking hook situated between them having diametrically opposed detents. The two contact elements form, for example, a row of the connector element. Connector elements may in this connection be expanded arbitrarily and have both a plurality of rows just described and also more than two contact elements in one row.
In this connection, a latching element may be provided between each contact element. Alternatively, at least two adjacent contact elements each may be held in pairs by a latching element, in each case supplemented by two additional contact elements as well as one locking hook per row of the connector element. The latching elements have diametrically opposed detents, which engage in suitably formed openings in the contact element and fix it or set it in a form-fit connection. The openings may be designed in such a way that the latching element situated between two contact elements is pivotable or bendable in the direction of one of the two contact elements, resulting in the release of the form-fit connection to the other of the two contact elements, so that it is removable from the connector element or from the housing and in particular from the particular chamber of the contact element.
The combination of two detents on one latching element while using a flexible bar may reduce in particular the space requirement for a latching element per contact with essentially the same geometrical dimensioning and consequently comparable stability. Alternatively, a larger dimensioning of the flexible latching element may provide increased stability without requiring more space compared to known connector elements.
A connector element according to the present invention is thus designed in such a way that the detent of a latching element may be inserted unhindered into the particular other contact element or its recess during assembly or disassembly of a contact element, in order to thus release the particular contact element in which the latching element is not momentarily inserted.
Embodiments of the present invention are represented in the drawings and are elucidated in greater detail in the following description.
a-1c show conventional connector elements.
a and 2b show an exemplary embodiment of a connector element in the assembled state and during assembly/disassembly according to the present invention.
a shows a system of a connector element 2 in cross section, it being made up of a connector row of two contact elements 4 having an internal latching element 6. Latching element 6 has two diametrically opposed detents 8, which engage in suitably formed recesses 16 of contact elements 4, and provide a form-fit connection there by surface contact.
Connector element 2 has a terminal side 10b as well as a contact feed side 10a. Via terminal side 10b, connector element 2 is in conductive contact with a suitably designed connecting element, while individual contact elements 4 are introduced into housing 14 of connector element 2 via contact feed side 10a. Suitably designed elements 12 prevent contact elements 4 from sliding out of housing 14 of connector element 2 in the direction of terminal side 10b. Elements 12 and their functionality are only depicted schematically in the drawings.
Latching element 6 is formed to be pivotable or bendable, for example, from a suitable plastic, and may be pivoted in such a way that detents 8 penetrate into recesses 16 to a varying depth, in particular they penetrate far enough into recess 16 that the form-fit connection of particular diametrically opposed detent 8 to corresponding recess 16 of additional contact element 4 is released. This may subsequently be removed from connector element 2. When a contact 4 is introduced into connector element 2, latching element 6 is pivoted into the particular diametrically opposed position essentially automatically, so that no special or separate assembly step is required when the contact elements are assembled. On contact feed side 10a, contact elements 4 have a cable connection 18 which is depicted schematically in
The system according to the present invention may have both “male” and “female” contact elements, thus plug as well as socket elements.
b shows the system of a latching element 6 during assembly or disassembly of a contact element 4. As an example, latching element 6 is completely moved or pivoted in recess 16 of left contact element 4 using left detent 8 of latching element 6. This releases the form-fit connection to right contact element 4, so that it may be removed from housing 14 or may be introduced into its locking chamber of connector element 2. Such a pivoting of latching element 6 may be carried out, for example, by a manual intervention from the direction of terminal side 10b.
Connector element 2 may have a plurality of contact rows shown in
Alternatively, the locking according to the present invention may also be used for an odd number of contact elements per connector row, for example, 3, 5, 7, 9, etc., and engage detents, for example, from both sides into one (internal) contact element. This makes it possible, for example, to further increase the retention force available, at least for internal contact elements or those not adjoining an outer wall, by two form-fit connections provided per contact element.
Number | Date | Country | Kind |
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10 2013 206 561 | Apr 2013 | DE | national |
Number | Name | Date | Kind |
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5421744 | Hio | Jun 1995 | A |
20140295708 | Omori | Oct 2014 | A1 |
Number | Date | Country | |
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20140308856 A1 | Oct 2014 | US |