EP4038694A1 - Direct contacting device for fastening a conductor on a circuit board and placing the conductor in electrical contact with the circuit board - Google Patents

Abstract

The invention relates to a direct contacting device (101, 201) for fastening a conductor (113) on a circuit board (106) and placing the conductor in electrical contact with the circuit board. The circuit board has an opening (109, 209), which extends completely through the circuit board, and a contacting surface, which is associated with said opening. The direct contacting device comprises a conductor receptacle (103, 203), a first spring barb (107, 207) and a spacer (105, 211). The spacer connects the conductor receptacle (103, 203) and the first spring barb (107, 207) at a distance in accordance with the thickness of the circuit board (106) at the opening (109, 209). While being pushed into the opening (109, 209), the first spring barb (107, 207) compresses into a push-in position with a first extent, and after being pushed through the opening (109, 209), the first spring barb rebounds into a fastening position with a second, larger extent, such that the spacer (105, 211) is arranged in the opening and the conductor inserted into the conductor receptacle is clamped against the circuit board and is placed in electrical contact with the contacting surface.

Description

Direct contacting device for fixing and electrically contacting a conductor on a circuit board

The invention relates to a direct contacting device for fixing and electrically contacting a conductor on a circuit board, the circuit board having an opening that completely penetrates the circuit board and a contacting surface into which the direct contacting device can be inserted, with a conductor receptacle, a spring bar and a spacer element, as well as a circuit board and an electrical device.

In electrical devices, it is often necessary to provide electrical contact between a printed circuit board, which has electrical components, for example, and a conductor, for example a stranded wire.

[03] The prior art has classically known the crimping of conductors onto an electrical contact by means of screws. However, the constant pressure of the clamping screw causes the conductor material to flow over the long term, which worsens the contact pressure and the connection properties. In addition, screwing is a very complex technology, which harbors a high risk of errors in production.

The fixed connection by means of soldering is also known from the prior art. In the case of soldered connections, however, the contact properties deteriorate over time due to oxidation of the tin. This can negatively affect the functioning of the electronics. Furthermore, solders are usually expensive materials. In addition, the heat introduced into the circuit board during soldering leads to components and conductors on the Circuit board to premature aging, so that a functional failure is favored.

[05] As an alternative from the prior art, electrical direct contact is known, in which, for example, a force is exerted on the contact surface of the circuit board by means of a pressure spring. In order to establish a contact, however, the pressure spring must first be pushed back by means of a tool, for example by means of a screwdriver, so that the conductor, for example the stripped end of a stranded wire, can be inserted. Only rigid conductors can be inserted directly without the aid of a tool, without the need to expand the spring. Furthermore, such devices consist of numerous components.

Also known in the prior art are so-called press-fit technologies for pin contacts, which then implement the through-hole plating from the printed circuit board track to the conductor to be connected by means of additional contact elements. This technology is complex to use and requires several contact elements. In addition, this often results in an increased electrical transmission resistance.

[07] The object of the invention is to improve the state of the art.

[08] The object is achieved by a direct contacting device for fixing and electrically contacting a conductor on a circuit board, the circuit board having an opening which completely penetrates the circuit board, into which the direct contacting device can be inserted, and a contacting surface assigned to the opening, with a conductor receptacle, a first spring barbed hook, and a spacer element, wherein the spacer element connects the conductor receptacle and the first spring barbed hook spaced according to a thickness of the circuit board at the opening, and the first spring barbed hook when pushed into the opening in a push-in position with a first extension and after being pushed through the opening into a fixing position with a second, larger extension, so that the spacer element is arranged in the opening, and the conductor inserted into the conductor receptacle by means of a Force of the first spring barbs clamped against the circuit board and an electrical contact of the conductor with the contacting surface is realized.

Using the direct contacting device can result in an arrangement in which there is a spring bar on an underside of the circuit board below the opening, a spacer element within the opening of the circuit board and the conductor receptacle with an inserted conductor on an upper side of the circuit board. The direct contacting device can thus be fixed in the opening of the circuit board, since the conductor arranged in the conductor receptacle contacts the top of the circuit board and thus counteracts the conductor receptacle being pushed into the opening. Furthermore, in the fixing position, the spring barbed hook can have an extension which is larger than the opening.

A core idea of the invention is based on the fact that a direct contacting device is provided with which a conductor is mechanically fastened to a contact surface of a circuit board, the direct contacting device itself being able to be fixed in the opening of the circuit board with the aid of the conductor and the spring bar.

[11] No tools are required for mechanically and electrically solid and reliable connection of the conductor to the circuit board, and the direct contacting device consists of a few or even just a single component. [12] The present type of contacting results in low volume resistances, which avoids thermal stress for components and reduces power loss. As a result, components and conductors age less quickly.

To connect a stripped conductor, in particular a stripped end of a stranded wire, all that is necessary is to insert the conductor into the conductor receptacle and then to insert the direct contacting device into the circuit board. Direct contact is therefore carried out in two steps, which can save time.

[14] The following terms are explained at this point:

[15] "Fixing" describes the mechanical fastening of the conductor on the circuit board. In particular, it can be used to clamp or otherwise fasten in the sense of strain relief.

An "electrical contact" describes the merging of the conductor, in particular a metallic part of the conductor with a suitable conductor track on the circuit board, so that an electric current can flow between the conductor and the circuit board or conductor track.

[17] A "conductor" can be any means or device which is suitable for conducting electrical current. In particular, such a conductor can be a cable, a wire, a stranded wire or any other suitable means. In particular, the conductive part is here such a cable, for example, that is not the insulation of the cable or the stranded wire, but for the mechanical function of fixing, this can also be the conductor with insulation, that is to say the cable as a whole. [18] A "circuit board", which is also referred to as a circuit board, is, for example, an electronic circuit board equipped with further components, which has, for example, resistors, capacitors or coils. The components and electrical connections of such a circuit board are also referred to as a circuit.

[19] An "opening" denotes an opening, a hole or a slot in the circuit board. This opening penetrates the full thickness of the circuit board, so, for example, an upper side and a lower side of the circuit board are accessible to each other.

[20] A “contacting surface” is, for example, a metallic surface of a conductor track which is suitable and designed to come into contact with the conductor and thus to exchange electrical current with it.

[21] A "ladder receptacle" can be, for example, a hole or a clip by means of which the conductor is accommodated, positioned and / or guided.

[22] A "spring barbed hook" can be an elastically arranged web, a projection or some other elastic device on the direct contacting device, which is set up and suitable to act as a latching element, clamping element or in a similar way one-piece and elastically molded component of the direct contacting device.

[23] A "spacer element" can be any device which separates the conductor receptacle and the first spring barbed hook from one another. This occurs in particular according to a thickness of the circuit board at the opening. This distance is selected according to the thickness of the circuit board so that the conductor receptacle through the spacer element is arranged far enough away from the spring barbed hook that this distance is equal to or slightly less than the thickness of the circuit board at the opening.

[24] An "insertion position" is that position of the direct contacting device in which the spring barbed hook is compressed. The direct contacting device thus assumes a first expansion, for example a compressed expansion, in this insertion position.

[25] A "fixing position" is that position in which the first spring barbed hook is rebounded. This spring barbed hook assumes a second, larger dimension so that the spacer element is arranged and / or fixed in the opening The conductor is clamped against the circuit board in this position by means of a force of the first spring barbed hook, and an electrical contact between the conductor and the contacting surface is also established.

In order to make the direct contacting device particularly safe and reliable and also easy to assemble, the first spring barbed hook is assigned a second spring barbed hook, the second spring barbed hook generating a force against the direction of a force of rebounding of the first spring barbed hook during its rebound, so that the first spring barbs and the second spring barbs are effective together, in particular in opposite directions of action to one another.

Thus, for example, forces of the first spring barbed hook and of the second spring barbed hook can act against one another within the direct contacting device, so that the direct contacting device can be inserted and installed relatively force-free by one person.

[28] "Opposite direction of action" here refers to a state in which the forces released by the first spring barbed hook and the second spring barbed hook act against each other. This effect does not have to be mathematically exactly in opposite directions, but essentially opposite and opposite. This includes a deviation of -30 ° to + 30 °. Angle specifications relate here to a full angle of 360 °.

[29] In one embodiment, the first spring barbed hook and / or the second spring barbed hook is or are designed to taper in relation to the opening in the fixing position, so that the conductor is clamped in a pressing manner against the circuit board.

[30] This ensures that even when the material of the conductor flows through a constant pressure of the direct contacting device, there is always a sufficient force acting on this conductor so that the contact is reliably maintained.

[31] "Tapering" denotes an embodiment in which, for example, end areas of the spring barbs or the spring barbs are beveled or beveled in the direction of the opening so that the forces of the spring barbs or the spring barbs are supported by means of these inclined surfaces against the circuit board If the conductor is now deformed, for example by permanent force, this design of the spring barbs or the spring barbs automatically changes the position of the direct contacting device, which continues to maintain the corresponding contact pressure on the conductor.

[32] "Pressing" here refers to a state in which a force always acts on the conductor, so that the conductor is not only fixed, but also pressed against the contact surface of the circuit board. [33] In order to be able to assemble the direct contacting device particularly easily, an end region of the first spring barb and / or the second spring barb, facing the opening in the insertion position, is or are designed to be tapered so that it is easier to insert the spring barb into the opening.

In this case, "tapered" describes a geometric configuration in which an end region facing the opening is narrower than, for example, a remainder of the direct contacting device. In particular, the transition from this end region to other regions of the direct contacting device is uniform, for example in the form of a Wedge, trained.

In a further embodiment, the spring barbed hook has a recess that is open on one side and parts of the flanks of the recess are essentially reversibly bendable with respect to one another, so that the spring barbed hook has a resilient effect.

Such a shape of the spring barbed hook facilitates production and makes the component particularly reliable.

[37] A "recess open on one side" can be designed in the manner of a slot or in the form of a bay, so that a part of the same, which is delimited by the direct contacting device, results as a spring barbed hook.

[38] A "flank", which can also be referred to as an edge or edge, is, for example, the resulting edges of the spring barbed hook that are oriented perpendicular to the surface orientation.

[39] "Essentially reversibly bendable" here refers to a state in which the behavior can show essentially through elastic deformation and, to a small extent, also plastic deformation. For example, the plastic portion of the deformation is used to introduce the Facilitating direct contacting device in the opening of the circuit board. The elastic component of the deformation then means that the spring barbed hook can fulfill its function, namely rebound.

In order to be able to manufacture the direct contacting device simply and economically, the conductor receptacle, the spring barbed hook and / or the spacer element is or are manufactured by means of punching or cutting. In addition, the direct contacting device can be manufactured using another suitable technology, for example for processing a sheet metal as the starting material. This technology can be, for example, laser cutting, water jet cutting or another suitable processing method.

[41] The direct contacting device can also be made of a material with spring properties, which also has, for example, a shrinkage behavior close to zero. This is e.g. a metal sheet, which can also be hardened or otherwise heat-treated. This ensures that the spring barbs can reliably perform their function and yet no undesired change in the geometry of the direct contacting device occurs due to shrinkage, flowing or similar deformation, so that the direct contacting device can be fitted with a precisely fitting fit. Such a shrinkage behavior is characterized, for example, by a shrinkage of less than 1%, in particular less than 0.5% or less than 0.2%.

In a further embodiment, the conductor receptacle, the spring barbed hook and / or the spacer element is or are manufactured by means of bending, pressing or casting, in particular by means of injection molding.

[43] These processes also ensure an economical production of the direct contacting device. In order to make the contact even more secure, the conductor receptacle, the spring barbed hook and / or the spacer element has or have an electrically conductive material, in particular a metal. In addition, it can thereby also be achieved that electrical contacting can also be carried out indirectly, in that the direct contacting device makes contact with the contact surface and at the same time receives, electrically contacts and fixes the conductor.

In one embodiment, the conductor receptacle has an eyelet for leading the conductor through, the conductor being able to be pressed against the contacting surface by means of the eyelet.

[46] Such an eyelet can easily accommodate the conductor and press it against the contacting surface with its edge areas.

[47] An "eyelet" can be any opening in the direct contacting device, for example a hole, a punching or a bore.

[48] In order to be able to securely receive strands, that is to say conductors which consist of several individual conductors, the conductor receptacle has a hook, the conductor being able to be pressed against the contacting surface by means of the hook.

[49] A "hook" can be any element that engages around the conductor and can press it against the contacting surface. Such a hook can also be a correspondingly shaped area of the direct contacting device, for example a bent area.

In a further aspect, the object is achieved by a printed circuit board which is connected to the conductor by means of a direct contacting device according to the embodiments described above. Such a printed circuit board can be connected in a particularly simple manner to, for example, a large number of conductors if a corresponding large number of direct contacting devices are implemented. The construction of the circuit board is very simple and inexpensive because no additional components are required and only one breakthrough or opening has to be made in the circuit board for each conductor.

[52] In a further aspect, the object is achieved by an electrical device which has a direct contact-making device according to one or more of the embodiments described above.

[53] Such an electrical device is particularly simple, reliable and can be installed with a good possibility for quality assurance and is therefore particularly economical to manufacture. In addition, apart from the direct contacting device, no additional components are required.

[54] The invention is explained in more detail below on the basis of exemplary embodiments. Show it

Figure 1 is a schematic representation of a

Direct contacting device with a stranded eye, a web and a clamping spring,

FIG. 2 shows the direct contacting device with a stripped end of a braid inserted into the braid eyelet and one of the braids

Direct contacting device associated opening of a circuit board,

FIG. 3 shows the direct contacting device introduced into the opening of the circuit board,

Figure 4 is a schematic representation of a

Front of an alternate Direct contacting device with a stranded eye, a long web and two spring lugs,

FIG. 5 shows a schematic representation of a rear side of the alternative direct contacting device with the stranded eyelet, the long web and the two spring lugs,

FIG. 6 shows the alternative direct contacting device with a stripped end of a stranded wire inserted into the stranded eyelet and an associated opening in a printed circuit board, and FIG

FIG. 7 shows the direct contacting device introduced into the opening in the printed circuit board.

A direct contact-making device 101 is manufactured from sheet metal by means of stamping. The

Direct contacting device 101 has a stranded eye 103, a web 105 and a clamping spring 107.

The strand eyelet 103 has a hole circumference which essentially corresponds to the outer circumference of a stripped end 113 of a strand 111, as a result of which the stripped end 113 of the strand 111 can be inserted into the strand eyelet 103.

The web 105 is a central section of the direct contacting device 101, which connects the stranded eyelet 103 to the clamping spring 107. The web 105 has essentially the same length as a depth of an opening 109 of a circuit board 106. This depth corresponds to the thickness of the board 106 at the opening 109. The opening 109 forms two longitudinal edges 116 and two short edges 118 at the top and bottom of the board 106.

[58] The circuit board 106 has a conductor track, that is to say an electrically conductive coating, on the side facing the stranded wire 111. This conductor track is connected to further electronic components (not shown) which are to be contacted by means of the strand 111.

[59] Starting from the web 105, the clamping spring 107 has an essentially U-shaped area 115 with two outwardly angled legs 112, 114. The clamping spring 107 is closed at an open end 108 by an inwardly directed angled area 117. The clamping spring 107 is thus designed to be elastic and can be elastically deformed by an external force. This is done by compressing the U-shaped area 115.

[60] An outer edge 119 and an outer edge 121 of the angled region 117 of the clamping spring 107 run obliquely in the direction of the strand eyelet 103. The clamping spring 107 is designed such that the clamping spring 107 is wider than a longitudinal orientation 110 of the opening 109 of the circuit board 106 in a rebounded state and narrower than the longitudinal orientation 110 of the opening 109 of the circuit board 106 in a compressed state.

[61] The contacting process is described below:

The stripped end 113 of the strand 111 is pushed into the strand eyelet 103. The direct contact-making device 101 connected to the strand 111 is then pushed into the opening 109 of the circuit board 106 from above. The outer edges of the angled legs 112, 114 contact the short edges 118, as a result of which the clamping spring 107 is compressed (spring-loaded). As soon as the end 120 of the legs 112, 118 has passed the opening 109, the clamping spring 107 springs in and, in an end position, presses the stripped end 113 of the stranded wire 111 against the upper side of the circuit board 106.

[63] In this case, an electrical contact is already established between the stripped end 119 of the strand 111 and a contact surface (not shown) on the top of the board. A movement of the direct contacting device 101 against the original insertion direction is prevented by the contacting of the clamping spring 107 with the underside of the board, so that the clamping spring 107 acts like a spring barbed hook. The direct contacting device 101 is thus locked to the printed circuit board and the direct contacting device 101 and the stripped end of the stranded wire 113 are fixed in the locked position. In the event that the strand 113 loses its diameter or shape due to the material flowing under the pressure of the direct contacting device 101 and the force would decrease the strand 111 and thus the quality of contact, the elasticity of the clamping spring 111 with the inclined edge 119 and the inclined Edge 121 ensures that the direct contact-making device 101 re-tensions itself and that the stranded wire 111 is still reliably contacted with the circuit board 106.

[65] An alternative direct contacting device 201 has a stranded eye 203, a long web 205 and two spring lugs 207.

The strand eyelet 203 has an inner circumference which is larger than an outer circumference of a stripped end 113 of a strand 111, so that the stripped end 113 of the strand 111 can be inserted into the strand eyelet 203.

The direct contact-making device 201 is manufactured from a sheet metal by means of punching. At the level of the strand eyelet 203, the alternative direct contacting device 203 has a section 215 bent over by 90 °.

The direct contact device 201 is W-shaped. The two outer legs are designed as spring lugs 207, the inner area is formed by the long web 205 which is partly divided in the middle. The strand eyelet 203 is arranged at the upper end of the long web 205. The spring lugs 207, starting from the connection with the long web 205, are bent by a little less than 180 °. At their end 120, the spring lugs 207 have an inwardly bent end 217.

[70] The contacting process is described below:

[71] The stripped end of the strand 113 is pushed into the strand eyelet 203. The direct contact-making device 201, which is loosely connected to the strand 111, is then pushed from above into an opening 209 in the circuit board 106 from the first alternative. Here, too, the outer edges 223 of the direct contact-making device 201 contact the short edges 118, as a result of which the clamping spring 107 is compressed (spring-loaded). As soon as the end 120 of the legs has passed the opening 209, the clamping spring 107 springs in and in an end position presses the stripped end 113 of the stranded wire 111 against the top of the circuit board 106 and thus against the conductor track, so that it is safely contacted

[72]. In the event that the strand 111 loses its diameter or shape due to the material flowing under the pressure of the direct contacting device 201 and the force of the strand 111 and thus the quality of the contact would decrease, the elasticity of the spring lugs 207 with their oblique tapering towards the circuit board 106 Ends 217 ensure that the direct contact-making device 201 re-tensioning itself and that the stranded wire 111 is also reliably contacted with the circuit board 106. List of reference symbols

101 direct contacting device

103 litz wire eyelet

105 bridge

106 circuit board

107 spring clip

108 end

109 opening

110 Longitudinal Orientation

111 strand

112 legs

113 stripped end

114 legs

115 area

116 long edge

117 area

118 short edge

119 margin

120 kink

121 margin

201 Direct contact device

203 strand eyelet

205 long bridge

207 feather nose

209 opening

211 area

213 area

215 area

217 end

223 edge

Claims

Patent claims:

1. Direct contacting device (101, 201) for fixing and electrically contacting a conductor (113) on a printed circuit board (106), the printed circuit board having an opening (109, 209) which completely penetrates the printed circuit board and into which the direct contacting device can be inserted, and one of the Associated with opening (109, 209)

Has contacting surface, with a conductor receptacle (103, 203), a first spring barbed hook (107, 207) and a spacer element (105, 211), the spacer element being the conductor receptacle (103, 203) and the first

Spring barbs (107, 207) corresponding to a strength of the

PCB (106) at the opening (109, 209) at a distance and the first spring barbed hook (107, 207), when pushed into the opening (109, 209), compresses into an insertion position with a first extension and after being pushed through the opening ( 109, 209) rebounds into a fixing position with a second, larger extension, so that the spacer element (105, 211) is arranged in the opening, and the conductor inserted into the conductor receptacle is clamped against the circuit board by means of a force of the first spring bar and an electrical contact of the conductor is realized with the contacting surface.

2. Direct contacting device according to claim 1, characterized in that the first spring barbed hook (107, 207) is assigned a second spring barbed hook (107, 207), the second spring barbed hook (107, 207) in his

Rebound generates a force counter to the direction of a force of rebound of the first spring barbed hook (207), so that the first spring barbed hook (107, 207) and the second spring barbed hook (107, 207) are effective together, in particular in opposite directions of action.

3. Direct contacting device according to claim 1 or 2, characterized in that the first spring barbed hook (107, 207) and / or the second spring barbed hook (107, 207) is or are tapered in the fixing position opposite the opening (109, 209), so that the conductor (111) is clamped pressing against the circuit board (106).

4. direct contacting device according to one of the preceding claims, characterized in that one of the opening

(109, 209) end area facing in the insertion position

(117, 217) of the first spring barbed hook (107, 207) and / or of the second spring barbed hook (107, 207) is or are tapered so that it is easier to insert the spring barbed hook (107, 207) into the opening (109, 209) is.

5. direct contacting device according to one of the preceding claims, characterized in that the spring barbed hook

(107, 207) has a recess open on one side and

Parts of flanks (119, 121) of the recess to one another in the

Are essentially reversibly bendable, so that there is a resilient effect of the spring barbed hook (107, 207).

6. direct contacting device according to one of the preceding claims, characterized in that the conductor receptacle

(103, 203), the spring barbed hook (107, 207) and / or the

Spacer element (105, 211) is or are manufactured by means of stamping or cutting.

7. Direct contacting device according to one of the preceding claims, characterized by a material with a shrinkage of less than 1%, in particular less than 0.5% or less than 0.2%.

8. Direct contacting device according to one of the preceding claims, characterized in that the conductor receptacle (103, 202), the spring barbed hook (107, 207) and / or the

Distance element (105, 211) by means of bending, pressing or

Casting, in particular injection molding, is or are made.

9. direct contacting device according to one of the preceding claims, characterized in that the conductor receptacle

(103, 202), the spring barbed hook (107, 207) and / or the

Spacer element (105, 211) an electrically conductive

Material, in particular a metal, has or have.

10. Direct contacting device according to one of the preceding claims, characterized in that the conductor receptacle

(103, 203) has an eyelet for leading the conductor through, wherein the conductor (111, 113) can be pressed against the contacting surface by means of the eyelet.

11. Direct contacting device according to one of the preceding claims, characterized in that the conductor receptacle

(103, 203) has a hook, the conductor (111,

113) can be pressed against the contacting surface by means of the hook.

12. Printed circuit board (106), which by means of a

Direct contact-making device (101, 201) according to one of the preceding claims is connected to a conductor (111, 113).

13. Electrical device, which is a

Direct contact-making device (101, 201) according to one of Claims 1 to 11 or a printed circuit board according to Claim 12.