The invention is based on a device for electrically contacting electrical components with a printed circuit board as claimed in the genus of independent claim 1.
Contacting mechanisms of this type are required in order to be able to fit printed circuit boards with electrical components in a cost-effective manner.
Methods for soldering electrical components to printed circuit boards in an automated manner are known from the prior art, for example the so-called “SMT” (Surface Mounted Technology) or the so-called THR (Through Hole Reflow).
It is further known that heat-sensitive components, for example microprocessors, should be connected with a base in an electrically conductive manner by way of a plug connection only after the soldering process, which base in turn was previously soldered to the printed circuit board by way of a soldering process of this type.
The connecting contacts of less heat-sensitive components are usually directly connected with contacts of a printed circuit board in an electrically conductive manner and are mechanically fixed to said contacts of a printed circuit board, for example by way of a solder connection. Alternatively, the so-called “press-in” technology is also known for connecting with the printed circuit board, with which technology components are pressed into a printed circuit board through-contact, without being soldered to their connecting contacts, in order to mechanically and electrically connect them with the corresponding through-contact of the printed circuit board. In addition, the connecting contacts generally have an eyelet, in the region of which they possess sufficient deformability for this purpose.
Finally, insulation displacement contacts are known from documents DE 92 03 355 U1 and U.S. Pat. No. 8,105,105 B2, for example. Document EP 2 862 237 B1 describes their application in a printed circuit board plug connector.
A disadvantage of this prior art is that automated fitting methods for printed circuit boards are only worthwhile for high quantities. By contrast, individual solutions and small series are expensive and complex and are currently often realized at great expense in terms of manual labor.
The object of the invention involves specifying a device which simplifies the process of fitting a printed circuit board, even for small series, in a cost-effective manner.
This object is achieved by the features of the independent claims.
Advantageous configurations of the invention are specified in the respective subclaims.
The device for electrically contacting a printed circuit board with a plurality of electrical connections of an electrical component and/or with a plurality of conductors of an electrical cable possesses a contact carrier and a plurality of electrically conductive contact elements which are held therein or thereon, wherein the contact carrier has a contact side and oppositely a connection side, and wherein the contact elements each have the following:
The invention has the advantage that contacting the device with the printed circuit board can be automated in large quantities, for example by way of a so-called “SMT” (Surface Mounted Technology) method and/or a so-called “press-in” method. The printed circuit boards which are fitted with the device according to the invention in this way can furthermore be applied universally. Finally, they can be fitted with electrical components and connections in a very flexible manner with only little, for example manual, effort. The printed circuit boards can thus initially be produced in large quantities and can only be adapted to their respective object by being fitted, i.e. their respective application is therefore extremely flexible.
In one preferred configuration, the contact elements are arranged in contacting chambers of the contact carrier, wherein the contacting chambers each have a contact opening at the contact side of the contact carrier, and wherein the clamping regions of the contact elements point in the direction of the respective contact opening or protrude out of it. As a result, the respective clamping region of the contact element is advantageously mechanically protected, and the electrical connections of the respective component and/or the conductors of the corresponding cable are connected with the clamping region in a particularly secure manner.
In this case, the contact carrier can have a respective through opening between its connection side and its contacting chambers, in which through opening a section of the connecting contact of the contact element is received and fixed in a form-fitting manner, and out of which through opening the connecting contact protrudes on the connection side for contacting the printed circuit board. This is particularly advantageous, since the contact carrier is held stable in the contact chamber in this manner, and the connecting contact can be connected with electrical contacts of the printed circuit board in an electrically conductive manner.
It is particularly advantageous for contacting the conductors of the cable if the bars of the contact elements each possess a cutting edge in the direction of the slot, in order to thus cut through an insulation of the conductors if necessary, in order to electrically contact the conductors, which are electrical wires. In this case, the contact elements are insulation displacement terminals, which are well known to the person skilled in the art.
The connecting contact can be designed as a solder contact for soldering with contacts of the printed circuit board. This ensures a high degree of mechanical stability and a particularly effective electrically conductive connection.
Alternatively, the connecting contact can be designed as a so-called “press-in” contact. This has the advantage that the corresponding connection technology is less complex.
The contact elements are advantageously made of metal, for example substantially of copper or iron or aluminum, or an alloy which possesses copper or iron or aluminum as an essential component.
In one preferred configuration, the electrical component can be designed as an upper part of a plug connector. Advantageously, it has an insulating body with through openings and plug contacts arranged therein. In particular, each of the plug contacts can possess a plug-in region and oppositely a connection region with an electrical connection for introducing into the respective slot of a contact element.
In another preferred configuration, the electrical component is designed as a separate connecting element in which the conductors of the electrical cable can be arranged for contacting the contact elements of the contact carrier. In order to simultaneously introduce the conductors into the respective slot of the contact element, in particular an insulation displacement terminal, said conductors of the electrical cables introduced therein are held, in particular fixed, at an angle, in particular perpendicularly, to the insulation displacement terminal. In addition, the connecting element can possess a splice element which splits the conductors of an electrical cable, which has been pushed in, and diverts them in the desired directions respectively. In this way, the conductors which are inserted into the splice element can be deflected separately from one another, in order to hold them, during insertion into the respective insulation displacement terminal, on the connecting element at an angle, in particular perpendicularly, to the slot thereof in a suitable position for this purpose. This is particularly advantageous since the conductors of a cable are generally mechanically flexible and, in this manner, not only experience their configuration which is necessary for contacting, but in particular also experience being fixed on the connecting element in a position which is suitable for contacting. Advantageously, all conductors, together with the connecting element, in particular simultaneously, can be inserted into their respective contact elements, in particular insulation displacement terminals. In this case, the connecting element can be understood as an electrical component. In this case, the ends of the conductors form its electrical connections.
A method for fitting the printed circuit board with an electrical component, such as the upper part of the plug connector or the abovementioned connecting element, for example, has the following steps:
In particular, a method for connecting a multi-conductor electrical cable to the printed circuit board possesses the following steps:
One exemplary embodiment of the invention is depicted in the drawings and is explained in greater detail below. In the drawings:
The figures include partially simplified, schematic depictions. Identical reference numbers are partially used for the same, but not necessarily identical elements. Different views of the same elements could be scaled differently.
Even if different aspects or features of the invention are each shown in combination in the figures, it is clear to the person skilled in the art—unless otherwise specified—that the depicted and discussed combinations are not the only possible combinations. In particular, mutually corresponding units or feature complexes from different exemplary embodiments can be exchanged with one another.
Number | Date | Country | Kind |
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10 2017 124 594.4 | Oct 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2018/100853 | 10/16/2018 | WO | 00 |