WO2012146754A1 - Snap connector maintaining stable contact - Google Patents

Abstract

The invention relates to a connecting means (1) for establishing an electrical contact between an electrical conductor (3) surrounded by a textile sheet (2) and an electrically conductive contact surface (5) surrounded by a circuit carrier (4), wherein the connecting means (1) has locking elements (6) arranged in pairs, a contact punch (8), and an elastically deformable web (9), wherein the locking elements (6) and the contact punch (8) are connected to one another and spaced from one another by the web (9) and protrude from the web (9) in the same direction, and the locking elements (6) are designed to lock into a corresponding opening (7) in a circuit carrier (4), wherein the locking elements (6) penetrate a respective textile sheet (2) in the locked-in state, and the web (9) covers at least part of the respective textile sheet (2) in such a way that a circuit carrier (4) is mechanically fastened to a respective textile sheet (2), and wherein the web (9), with the locking elements (6) locked in, is elastically deformed in such a way that the contact punch (8) presses an electrical conductor (3) surrounded by a respective textile sheet (2) directly against an electrically conductive contact surface (5) and thus establishes and maintains an electrical contact between an electrical conductor (3) and a contact surface (5).

Description

 Contact stable snap connector

The invention relates to a connection means for producing an electrical contact between an electrical conductor encompassed by a textile surface and an electrically conductive contact surface arranged on a circuit carrier.

In the field of "smart textiles", it is necessary to integrate electronic circuits in or on textile surfaces, which involves firstly electrically connecting an electronic circuit to an electrical conductor encompassed by a textile surface - with this conductor in or on the surface textile surface can be arranged - on the other hand, the mechanical fixing of the circuit substrate to a textile surface.

In order to establish an electrical contact between two conductive bodies, it is necessary to bring the surfaces of the bodies at a distance from each other, from which an electron transfer between the bodies is possible. This is the case for a distance in the lower nanometer range due to the tunnel effect. For the technical application mentioned here, it is desirable for the bodies to be in physical contact with one another, forming a contact surface, the electrical contact being established via the formed contact surface. The stronger the bodies are on each other be pressed, the greater the trained contact area, the lower, up to a minimum limit, is the electrical contact resistance across the contact surface.

So far, solders or conductive epoxy adhesives are used for the electrical contacting, via which a mechanical fixation of a respective circuit substrate on a textile surface can also take place. As mechanical fixation also push buttons or crimping are used.

Connecting means according to the described prior art have the disadvantage that the temperatures necessary for soldering and for curing epoxy adhesives can damage a textile fabric. A permanent, mechanically loadable fixation of a respective circuit carrier, in particular a large-area circuit carrier, on a textile surface is not possible in this way according to previous findings. Accordingly, the low electrical contact resistance which is desirable for an electrical connection is not ensured over the entire service life of a smart textile. A mechanical fixation via push buttons or crimp eyelets has the disadvantage that they deform plastically during installation and are not readily destructible again solvable.

It is an object of the present invention to provide a connection means which enables long-term stable electrical contact between an electrical conductor encompassed by a textile surface and an electrically conductive contact surface arranged on a circuit carrier and at the same time mechanically fixes a respective circuit carrier to a respective textile surface ,

This object is achieved by a connecting means in that the connecting means comprises paired locking elements, a contact stamp and an elastically deformable web, wherein the locking elements and the contact stamp are connected by the web and spaced from each other and project from the web in the same direction and the latching elements are designed to engage in a recess of a circuit carrier, wherein the latching elements in the engaged state through a respective textile surface and the web covers at least a portion of a respective textile surface such that a circuit substrate is mechanically fixed to a respective textile surface, and wherein the web is elastically deformed with latched latching elements, such that the contact stamp comprises an electrical conductor encompassed by a respective textile surface directly against an electrically conductive Pressing contact surface and so establishes and maintains an electrical contact between an electrical conductor and a contact surface, wherein the connecting means comprises a plurality of contact stamps and paired locking elements which are arranged alternately on a surface of the connecting means. In this way, in each case a locking element pair includes at least one contact between a punch and are connected to each other via a web. The web does not have to be narrow, but may also have the shape of a larger-area connection bridge between the locking elements of a pair of locking elements. Thus, the bridge can also connect several locking elements together. Alternatively or additionally, the latching elements may be arranged annularly on a surface of the connecting means - more precisely: the web - and / or in pairs between each include at least one contact stamp.

The solution according to the invention includes the knowledge that many of the usual in electrical contacting techniques for use in smart textiles are not or only partially applicable.

The solution according to the invention thus has the advantage that a long-term stable electrical contact between an electrical conductor encompassed by a texturized surface and an electrically conductive contact surface arranged on a circuit carrier is made possible, and at the same time a respective circuit carrier can be mechanically fixed to a respective texturized surface.

The solution according to the invention can be supplemented by further advantageous embodiments. Some such embodiments are described below.

In the following the invention will be explained with reference to the exemplary embodiments shown in the drawings. The different features can, as in the embodiments described above, be combined with each other as desired.

In an advantageous embodiment of the web of the connecting means may have a planar surface element whose surface normal is oriented opposite to the Abstehrichtung the contact stamp. This ensures that an inserted in a smart textile fasteners is only slightly raised from the text area of the smart textile and is perceived as hardly disturbing. In the context of the present invention, a web is to be understood as meaning both a narrow bridge-like element and a planar element, that is to say, for example, a circular disk-like or a rectangular element. A web may for example also be formed as a base plate of the connecting means. The planar surface element can make up a predominant part of a projection surface of the connection means. The projection surface of the connecting means is defined by a parallel projection whose rays run parallel to the surface normal of the plane surface element. A flat surface element extending in this way has the advantage that it can be applied cost-effectively, for example by means of a vice or a pair of pliers.

In a particularly advantageous embodiment, the connecting means has a plurality of contact punches and paired locking elements. These are arranged annularly and alternately on a surface of the connecting means, whereby the connecting means is suitable for the electrical contacting and mechanical fixing of a large-area circuit carrier. This can be fixed in one step and all electrically conductive contact surfaces can be contacted simultaneously.

The locking elements may include in pairs between each at least one contact stamp. In a further embodiment, in order to provide a particularly uniform holding force, the locking elements in pairs include exactly one contact punch between them.

Inclusion of a contact stamp between two latching elements can be given in the circumferential direction of the connecting means. If, for example, a connecting means has a circular disk shape, then a contact stamp is considered to be enclosed between two latching elements when latching elements and plungers alternately follow one another along the circumference of the connecting means. Alternatively or additionally, a trapping of a contact stamp between two locking elements can be provided in a straight direction. A straight direction can be defined for example by the diameter of a circular disk-shaped connecting means, but also by a side-parallel section through a rectangular connecting means.

In a further embodiment, the contact stamp and the paired locking elements are strung together over a width of the connecting means. The con- clock stamp and the locking elements can be strung together single-row but also multi-row.

In a particularly advantageous embodiment, in each case a latching element and a contact stamp are diametrically opposite. As a result, an optimal stress distribution within the connecting means is ensured.

In order to be able to provide a substantially constant contact pressure independent of a respective conductor thickness, it has proved to be advantageous to design a contact stamp itself as resilient. A contact stamp can be sprung or resilient in the direction of its Abstehrichtung, in particular in the direction of its electrical functional surface.

A surface of the contact stamp of a connection means may be configured to open an insulation layer of an electrical conductor enclosed by a textile surface. A possibly required process of stripping the electrical conductor can thus be omitted. In order to avoid damage to an electrical conductor encompassed by a textile surface as far as possible, the transitions between the contact stamp and the web and / or the edges of the contact stamp can each be rounded or chamfered.

In a further advantageous embodiment, the connecting means is made monolithic, whereby a particularly cost-effective provision of the connecting means is given. A further cost savings may result from the fact that the connecting means is made of an injection-moldable plastic.

According to the requirements of the specific application, the connecting means can also be made of a metallic material or FR4 - a material from which standard circuit boards are produced. A particular advantage of manufacturing the connecting means from a standard printed circuit board material is that the mechanical and thermodynamic properties of connecting means and circuit carriers are the same.

Preferably, a connection means of the prescribed type together with a circuit carrier form a structural unit. The circuit carrier may have an electrically conductive contact surface which faces on a contact stamp Surface arranged and assigned to the contact stamp. Furthermore, the circuit carrier can have a recess matched to the latching element.

Alternatively, the circuit carrier can have a region matched to the detent element, in which, upon application of the connection means, that is to say when the circuit carrier penetrates by means of the detent elements, a recess is created. For this purpose, the circuit carrier can be perforated or otherwise structurally prepared within the area matched to the latching element.

In a particularly advantageous embodiment, the structural unit has a plurality of connection means and the circuit carrier has a plurality of electrically conductive contacts. This configuration allows mechanical fixing and electrical contacting of a large area circuit substrate to a textile surface. A matched to the locking element recess can be provided by milling, punching or other common manufacturing processes in the circuit board.

Preferably, a connection means of the prescribed type is used to establish an electrical contact between an electrical conductor encompassed by a textile surface and an electrical contact surface arranged on a circuit carrier. As a result of this use of the prescribed connection means, a long-term stable electrical contact between an electrical conductor encompassed by a textile surface and an electrically conductive contact surface arranged on a circuit carrier is made possible, and at the same time a respective circuit carrier is mechanically fixed to a respective textile surface.

A textile surface which is referred to in this context and comprises an electrical conductor can be any textile surface which contains electrically conductive material through textile production techniques. A conductive material may be a wire, a stranded wire, a cable or a conductive made, for example, silvered thread of the textile itself. Accordingly, the conductive material may be within the tissue or on the surface of the tissue.

In this context, a textile surface itself is understood to mean a flat, flexible material, preferably a mesh-stable fabric. Preferably, tissues are suitable since they remain mechanically stable when they are penetrated by a latching element of the type described. An important feature of the textile surface is a limited elasticity, so as to absorb the mechanical forces can. Furthermore, a more closely meshed design of the textile surface is desirable.

Preferably, a textile surface may have openings which are congruent with the recesses of a circuit carrier. Alternatively, however, such openings can also only be created by the application of a bonding agent.

A circuit carrier has electrical components and electrical contact surfaces, wherein the electrical components are preferably applied to a surface of the circuit carrier, which is opposite to a surface carrying the electrical contact surfaces. An electrical contact surface can be applied or embedded on the circuit carrier, for example, by a metallization process. But alternative methods for producing such, in electrical engineering common electrical contact surfaces are conceivable.

A cross-section of a strand-like electrical conductor encompassed by a textile surface may typically be between 100 and 500 μm. A contact stamp of a connecting means, which is adapted to such a strand, can have a pressing surface of usually 1 mm ^{2 to} 10 mm ² . A dimensioning of the connecting means is carried out according to usual mechanical calculation methods, in particular the dimensioning is based on a bending beam calculation. In a typical dimensioning of the connecting means for said conductor cross-section, the connecting means is adapted to transmit a force of typically 5 to 10 N on the conductor via the contact stamp. With this contact force, an acceptably low resistance value of the electrical contact between the conductor and the conductive contact surface is already achieved. A connecting means designed as a clamp and made of FR4 typically has an outer dimension of 10 mm × 5 mm × 5 mm. In this typical example, the textile surface comprising the electrical conductor, about 300 μιτι to 500 μιτι strong. If the connecting means in the circuit carrier, which typically can be between 300 μm and 1 mm thick, is latched, it is achieved that the textile surface is compressed by 50 to 70%.

Alternatively, the connecting means may be made of FR4 and be disk-shaped and may typically have an outer dimension of 30mm x 5mm. A disk-shaped connecting means usually has a plurality of, for example, 5 contact punches. With regard to the dimensioning of the connecting means and the contact forces achieved the same applies. a schematic representation of an exemplary embodiment of a connecting means according to the invention; a schematic representation of the exemplary embodiment of a structural unit of a connecting means and a circuit substrate; a schematic representation of the exemplary embodiment of a connecting means according to the invention of Figure 1, which fixes a circuit substrate to a textile surface and contacted by an enclosed by the textile surface electrical conductor. a schematic sectional view of the arrangement shown in Figure 3; a schematic representation of another exemplary embodiment of a connecting means according to the invention; a schematic representation of an exemplary embodiment of a structural unit of a connecting means and a circuit carrier; a schematic representation of another embodiment of a connecting means according to the invention; a schematic representation of another embodiment of a connecting means according to the invention; a schematic representation of another embodiment of a connecting means according to the invention; a schematic representation of another embodiment of a connecting means according to the invention; a schematic representation of another embodiment of a connecting means according to the invention. A connecting means 1 in Fig. 1 has paired locking elements 6, a contact stamp 8 and an elastically deformable web 9. The locking elements 6 and the contact stamp 8 are interconnected by the web. Through the web 9, the locking elements 6 and the contact stamp 8 are spaced apart. Contact stamp 8 and locking elements 6 are from the web 9 in the same direction. The transitions between the contact stamp 8 and the web 9 are each rounded. The connecting means 1 is monolithically made of an injection-moldable plastic.

2 shows a structural unit 100 comprising a connecting means 1 and a circuit carrier 4. The connecting means 1 corresponds to that described with reference to FIG. 1, shown from a different perspective. The web 9 of the connecting means 1 has a planar surface element 1 1. The surface normal of this planar surface element 1 1 is opposite to the direction of the Abstehrichtung the contact stamp 8 oriented. The circuit carrier 4 has two recesses 7, which are associated with the locking elements 6 of the connecting means 1. The spacing of the recesses 7 in the circuit carrier 4 is dimensioned such that the latching elements 6 can engage in the respective recesses 7 under elastic deformation of the web 9. The circuit carrier 4 comprises an electrically conductive contact surface 5, this is, according to the arrangement of the contact stamp 8 between the paired locking elements 6 of the connecting means, arranged between the paired recesses in the circuit carrier. The planar surface element 1 1 of the web 9 makes up a predominant portion of a projection surface of the connecting means 1. The projection surface results from a parallel projection whose rays run parallel to the surface normal of the planar surface element 11.

FIG. 3 shows a connection means 1 which represents an electrical contact between an electrical conductor 3 encompassed by a textile surface 2 and an electrically conductive contact surface 5 (not shown in this figure) enclosed by a circuit carrier. The web 9 of the connecting means 1 covers a part of a respective textile surface 2, in particular a plurality of textile fibers arranged laterally within this textile surface. The contact stamp 8 exerts an immediate pressing action on the electrical conductor 3.

In Fig. 4 the arrangement shown in Fig. 3 is further illustrated by means of a schematic sectional view. The connecting means 1 has paired locking elements 6, a contact stamp 8 and an elastically deformable web 9, wherein the locking elements 6 and the contact stamp 8 are interconnected by the web and are spaced apart and project from the web 9 in the same direction. The locking elements 6 are formed to engage in a corresponding recess 7 of a circuit substrate 4, wherein the locking elements 6 in the engaged state through the textile surface 2. The web 9 covers at least part of the textile surface 2, so that a circuit substrate 4 is mechanically fixed to the textile surface 2. The web 9 is elastically deformed, so that the contact stamp 8 presses an electrical conductor 3 encompassed by the textile surface 2 directly against an electrically conductive contact surface 5. In this way, an electrical contact between the electrical conductor 3 and the contact surface 5 is produced and maintained permanently. Under the pressing action of the contact stamp 8, the electrical conductor 3 deforms such that an optimal, low contact resistance is established between the electrical conductor 3 and the contact surface 5. The web 9 of the connecting means 1 has a planar surface element 1 1, the surface normal opposite to the Abstehrichtung the contact stamp 8 is oriented. The planar surface element 1 1 occupies a predominant part of a projection surface of the connecting means 1. The projection surface is defined by a parallel projection whose rays run parallel to the surface normal of the planar surface element 11. According to the pairwise arrangement of the locking elements 6, the recesses 7 are provided in the circuit carrier 4. Under elastic deformation of the web 9, the paired locking elements 6 are approximated and can engage in the recesses 7. In the illustrated locked position of the elastically deformable web 9 is elastically deformed by the amount that is required to exert the corresponding pressing action on the electrical conductor 3.

The other exemplary embodiment of a connection means 1 shown in FIG. 5 has the same features as the connection means 1 described with reference to FIG. The connecting means 1 shown in Fig. 5 is in the form of a clamp and has typical dimensions of 10 mm x 5 mm x 5 mm. The connecting means 1 is optimized according to manufacturing considerations. Rounded transitions between the locking element 6 and the elastically deformable web 9 results in an improved voltage curve.

A structural unit 100 shown in FIG. 6 comprises a connecting means 1 and a circuit carrier 4. The connecting means 1 has latching elements 6 arranged in pairs, a contact stamp 8 and an elastically deformable web 9. The locking elements 6 and the contact stamp 8 are connected to each other by the web 9 and spaced from each other and stand from the web 9 in the same direction. The locking elements 6 are trained to engage in a corresponding recess 7 of a circuit substrate 4. The web 9 of the connecting means 1 has a planar surface element 1 1, the surface normal opposite to the Abstehrichtung the contact stamp 8 is oriented. The planar surface element 1 1 makes up a predominant part of a projection surface of the connection means 1. The projection surface is defined by a parallel projection whose rays run parallel to the surface normal of the planar surface element. The contact stamps 8 and the latching elements 6 are arranged annularly and alternately on a surface of the connecting means 1. In each case, a latching element 6 and a contact punch 8 are diametrically opposed to each other. The connecting means 1 is monolithically made of an injection-moldable plastic. The circuit carrier 4 in this case has a plurality of electrically conductive contact surfaces 5 and a plurality of matched to the locking elements 6 recesses 7. The electrical contact surfaces 5 and the recesses 7 are annular and arranged alternately. In each case a recess 7 and a contact surface 5 are diametrically opposite each other. The connecting means 1 shown in FIG. 6 is structurally matched to the circuit carrier 4. Each contact stamp 8 is a corresponding conductive contact surface 5, each latching element 6 associated with a corresponding recess 7.

Further embodiments of a connecting means will now be explained below with reference to FIGS. 7 to 1 1. In each case, a) shows a plan view of the connecting means, b) a section through the connecting means along the section line A-A, and c) a perspective view of the connecting means. Some reference symbols are provided with single quotes in the sense of a clear description.

The connecting means 1 in Fig. 7 has exactly three contact pins 8 ', 8 "and 8"', and exactly three locking elements 6 ', 6 "and 6"' on. The three locking elements 6 ', 6 "and 6"' are arranged in pairs. In this case, the locking elements 6 'and 6 "form a first locking element pair, the locking elements 6" and 6 "' a second locking element pair and the locking elements 6 '' and 6 'a third locking element pair. Furthermore, the locking elements 6 ', 6 "and 6"' and the contact pins 8 ', 8 "and 8"' are arranged alternately on the circumference of the connecting means. In the circumferential direction U close the locking elements in pairs between each at least one contact stamp, specifically closes the first pair consisting of the locking elements 6 'and 6 "between the contact punch 6" a etc. Furthermore, each a locking element and a contact stamp are diametrically opposite. Thus, the locking elements 6 'the contact stamp 8 "opposite, etc. Well recognizable in Fig. 8 is the surface round formation of the web 9. A planar surface element 1 1 extends over the entire web. 9

The embodiment shown in FIG. 8 differs from that shown in FIG. 7 only in that it has five contact punches and five locking elements. Again, the locking elements 6 'and 6 "form a first locking element pair, the locking elements 6" and 6 "' a second locking element pair, etc. In principle, any high number of circumferentially distributed contact stamping and locking elements is conceivable.

A further embodiment of a connecting means in Fig. 9, which, like the one shown in Fig. 7 exactly three contact stamp and exactly three locking elements has. In contrast to FIG. 7, the contact punches 8 ', 8 "and 8"' are of a resilient design, ie resiliently or parallel to their direction of departure A from the web 9.

Another embodiment of a connecting means is shown in FIG. 10. The connecting means 1 has exactly one contact stamp 8 and exactly four locking elements 6, 6 ', 6 "and 6"'. The latching elements are arranged annularly around the contact stamp 8 and on a surface of the connecting means 1. In Fig. 10, the mutually opposed latching elements 6 and 6 "form a first pair which includes the contact punch 8 in the straight direction of the diameter D. The opposing latching elements 6 'and 6"' form a second first pair running in the straight direction of the Diameter D, the contact stamp 8 also includes.

A rectangular connecting means is shown in Fig. 1 1. The latching elements 6 and 6 'here form a first pair, which in the direction of a first side-parallel section S1 through the rectangular connecting means 1 includes a contact punch 8. The latching elements 6 "and 6" 'form a second latching element pair, which encloses a contact punch 8' in a straight direction of a second, side-parallel cut S2 through the rectangular connecting means 1.

Claims

claims

1. connecting means (1) for producing an electrical contact between one of a textile surface (2) encompassed electrical conductor (3) and one of a circuit carrier (4) comprised electrically conductive contact surface (5), characterized in that the connecting means (1 ) arranged in pairs latching elements (6), a contact stamp (8) and an elastically deformable web (9), wherein the latching elements (6) and the contact stamp (8) through the web (9) are interconnected and spaced from each other and of the Web (9) protrude in the same direction and the locking elements (6) are formed to engage in a corresponding recess (7) of a circuit substrate (4), wherein the locking elements (6) in the engaged state by a respective textile surface (2) and the web (9) covers at least a part of a respective textile surface (2) such that a circuit carrier (4) on a respective textile surface (2) me is chanically fixed, and wherein the web (9), with latched locking elements (6), is elastically deformed such that the contact stamp (8) of a respective textile surface (2) encompassed electrical conductor (3) directly against an electrically conductive Contact surface (5) presses and so establishes and maintains an electrical contact between an electrical conductor (3) and a contact surface (5), wherein the connecting means (1) comprises a plurality of contact stamps (8) and paired locking elements (6) are alternately arranged on a surface of the connecting means (1).

2. connecting means (1) for producing an electrical contact between one of a textile surface (2) encompassed electrical conductor (3) and one of a circuit carrier (4) comprised electrically conductive contact surface (5), wherein the connecting means (1) arranged in pairs Latching elements (6), a contact stamp (8) and an elastically deformable web (9), wherein the locking elements (6) and the contact stamp (8) through the web (9) connected to each other and spaced from each other and from the web (9 ) protrude in the same direction and the latching elements (6) are formed to engage in a corresponding recess (7) of a circuit carrier (4), wherein the latching through a respective textile surface (2) and the web (9) covers at least part of a respective textile surface (2) such that a circuit carrier (4) on a respective textile surface (2) mechanically is fixed, and wherein the web (9), with latched locking elements (6), is elastically deformed such that the contact stamp (8) of a respective textile surface (2) encompassed electrical conductor (3) directly against an electrically conductive contact surface (5) presses and thus establishes and maintains an electrical contact between an electrical conductor (3) and a contact surface (5), wherein the locking elements (6) are arranged annularly on a surface of the connecting means (1) and in pairs between each at least one Include contact stamps.

Connecting means according to claim 1 or 2, characterized in that the web (9) has a planar surface element (1 1), the surface normal opposite to the Abstehrichtung of the contact stamp (8) is oriented.

Connecting means according to one of claims 1 to 3, characterized in that the planar surface element (1 1) makes up a predominant part of a projection surface of the connecting means (1), wherein the projection surface is defined by a parallel projection whose rays parallel to the surface normal of the planar surface element (1 1).

Connecting means according to one of claims 1 to 4, characterized in that the connecting means (1) has a plurality of contact stamps (8) and paired locking elements (6), which are arranged annularly and alternately on a surface of the connecting means (1).

Connecting means according to one of claims 1 to 5, characterized in that in each case a latching element (6) and a contact punch (8) are diametrically opposed.

Connecting means according to one of claims 1 to 6, characterized in that a surface of the contact stamp (8) is formed to open an insulating layer of an area covered by a textile surface (2) electrical conductor (3).

8. Connecting means according to one of claims 1 to 7, characterized in that the transitions between the contact stamp (8) and the web (9) and / or the edges of the contact stamp (8) are each rounded or chamfered.

9. Connecting means according to one of claims 1 to 8, characterized in that the connecting means (1) is monolithic.

10. Connecting means according to one of claims 1 to 9, characterized in that the connecting means (1) is made of an injection-moldable plastic.

Assembly (100) comprising a connection means (1) according to one of Claims 1 to 10 and a circuit carrier (4), wherein the circuit carrier (4) has an electrically conductive contact surface (5) arranged on a surface facing the contact stamp (8) and the contact stamp (8) is associated with, and on the latching element (6) tuned recess (7).

Assembly according to claim 1 1, characterized in that the assembly comprises a plurality of connecting means (1) and the circuit carrier (4) has a plurality of electrically conductive contact surfaces (5), wherein in each case a connecting means (1) is associated with a contact surface.

Use of a connection means according to one of claims 1 to 10 for producing an electrical contact between an electrical conductor (3) encompassed by a textile surface (2) and an electrically conductive contact surface (5) arranged on a circuit carrier (4).