阅读说明：本技术 电气装置的组件和这种组件的制造方法 (Assembly of electrical devices and method for manufacturing such an assembly ) 是由 安德里亚斯·施拉德尔 英戈·沃尔那 于 2019-09-25 设计创作，主要内容包括：一种电气装置的组件(1),包括多个模块化地可沿串接方向(A)相互串接的接合装置(2),其分别具有一个壳体(20)和至少一个用于接合至少一个电导体(4)的接合点(200)。连接元件(3)具有基体(30)和在所述基体(30)上成形的连接区段(31)并且被构建成,将所述多个接合装置(2)中的两个沿所述串接方向(A)相邻的接合装置(2)连接在一起。为此,所述连接元件(3)通过所述连接区段(31)材料接合地与所述两个相邻的接合装置(2)中的至少一个的壳体(20)连接在一起。通过这种方式来提供一种电气装置的组件以及一种制造电气装置的组件的方法,所述组件和方法能够以可变的方式实现相邻接合装置的连接。(An assembly (1) of electrical devices comprises a plurality of modular joining devices (2) which can be connected to one another in series in a series direction (A) and each of which has a housing (20) and at least one joining point (200) for joining at least one electrical conductor (4). The connecting element (3) has a base body (30) and a connecting section (31) formed on the base body (30) and is designed to connect two adjacent joining devices (2) of the plurality of joining devices (2) together in the joining direction (A). For this purpose, the connecting element (3) is connected to the housing (20) of at least one of the two adjacent joining devices (2) by means of the connecting section (31) in a bonded manner. In this way, an assembly of electrical devices and a method of manufacturing an assembly of electrical devices are provided which enable the connection of adjacent joining means in a variable manner.)

1. An assembly (1) of electrical devices, comprising a plurality of joining devices (2) which can be connected to one another in a modular manner in series along a series direction (A), each having a housing (20) and at least one joining point (200) for joining at least one electrical conductor (4), characterized by a connecting element (3) which has a base body (30) and a connecting section (31) formed on the base body (30) and which is designed to connect two joining devices (2) which are adjacent to one another in the series direction (A) of the plurality of joining devices (2) together, wherein the connecting element (3) is connected to the housing (20) of at least one of the two adjacent joining devices (2) in a materially bonded manner by means of the connecting section (31).

2. Assembly (1) according to claim 1, characterized in that the connecting element (3) is connected together material-bonded by means of the connecting section (31) with at least one of the two adjacent joining devices (2) by gluing or by welding.

3. Assembly (1) according to claim 1 or 2, characterized in that said base body (30) extends along a plane perpendicular to said stringing direction (a).

4. Assembly (1) according to any one of claims 1 to 3, characterized in that the connecting section (31) extends at least partially around the base body (30).

5. Assembly (1) according to any one of the preceding claims, characterized in that the connecting section (31) extends at least partially around the housing (20) of at least one of the two adjacent joining devices (2) in the position in which the connecting element (3) is attached to at least one of the two adjacent joining devices (2).

6. Assembly (1) according to any one of the preceding claims, characterized in that the connecting section (31) projects from the base body (30) on at least one side in the stringing direction (a).

7. Assembly (1) according to one of the preceding claims, characterized in that the connection section (31) forms a tab section (312, 313) projecting from the base body (30) in the stringing direction (A).

8. Assembly (1) according to claim 7, characterized in that the tab section (312, 313) spans the housing (20) of at least one of the two adjacent joining devices (2) in a position in which the connecting element (3) is attached to at least one of the two adjacent joining devices (2) such that the tab section (312, 313) faces a connecting face (211, 221, 240, 241) arranged on the housing (20) transversely to the stringing direction (A).

9. Assembly (1) according to claim 8, characterized in that the tab section (312, 313) is made of a material permeable to a laser welding beam (L) and the housing (20) is made of a material absorbing the laser welding beam (L) at least on the connection face (211, 221, 240, 241).

10. The assembly (1) according to one of the preceding claims, characterized in that the housing (20) of at least one of the two adjacent engagement devices (2) has a step (210, 220) at the transition between a first housing side (21, 22) extending parallel to the base body (30) of the connecting element (3) and a second housing side (23, 25) extending transversely to the first housing side (21, 22), which step forms a connection face (210, 220) that is set back relative to the second housing side (23, 25), wherein the connection section (31) of the connecting element (3) snaps into the step (210, 220) for planar abutment against the connection face (210, 220).

11. Assembly (1) according to claim 10, characterized in that the connecting section (31) snaps into the step (210, 220) in such a way that the outer side (314) of the connecting section (31) facing outwards is flush with the second housing side (21, 22).

12. Assembly (1) according to any one of the preceding claims, characterized in that the connecting element (3) is configured to connect together a first pair (2A) of engagement devices (2) adjacent in the stringing direction (A) and a second pair (2B) of engagement devices (2) adjacent in the stringing direction (A), which are arranged offset with respect to the first pair (2A) of engagement devices (2) in a height direction (H) perpendicular to the stringing direction (A).

13. Assembly (1) according to claim 12, characterized in that the connecting element (3) is connected together with material bonding with the housing (20) of at least one engagement device (2) of the first pair (2A) of engagement devices (2) and at least one engagement device (2) of the second pair (2B) of engagement devices (2) by means of a connecting section (31).

14. A method for producing a component (1) of an electrical device, in which a plurality of modular joining devices (2) are connected in series to one another in a series direction (a), each having a housing (20) and at least one joining point (200) for joining at least one electrical conductor (4), characterized in that two joining devices (2) adjacent in the series direction (a) of the plurality of joining devices (2) are connected together by means of a connecting element (3) having a base body (30) and a connecting section (31) formed on the base body (30), in that the connecting element (3) is connected to the housing (20) of at least one of the two adjacent joining devices (2) in a bonded manner by means of the connecting section (31).

Technical Field

The present invention relates to an assembly of an electrical device according to the preamble of claim 1 and to a method of manufacturing an assembly of an electrical device.

Background

The assembly comprises a plurality of modular joining devices which can be connected to one another in series in a series direction and each of which has a housing and at least one joining point for joining at least one electrical conductor.

Such a joining device can be embodied, for example, as a joining terminal, such as a terminal strip. Such an engagement device can also be embodied, for example, as a plug connector for plug-in connection with a corresponding mating plug connector or as a so-called base strip for connecting a plurality of modular plug connectors.

By combining a plurality of joining means together, for example, a component is provided which is arranged on a printed circuit board, so that a plurality of electrical connections are realized on the printed circuit board. It is sometimes necessary to connect together joining devices that differ, for example, in the contour of the housing in order to variably build up a certain assembly, in order to provide different joining functions, for example, on a printed circuit board.

Conventional assemblies of this type are provided for positively connecting adjacent engagement means together, for example by a snap connection or a so-called dovetail-groove/spring combination. This type of positive connection requires a special adaptation of the joining devices connected in series with one another.

In the terminal block for an electricity meter disclosed in DE 29522289U 1, several terminal arrangements are connected by an intermediate plate. These intermediate plates are used to provide electrical insulation between adjacent terminal arrangements and are therefore made of shock resistant plastic.

In the terminal board system disclosed in EP 1434308B 1, one terminal board of a certain type is arranged between several terminal boards of another type and separated from these terminal boards of the other type by a partition board. These spacer plates take a certain width in order to attach the transverse connecting elements with contact pins in the form of tips to the junctions of all terminal plates.

A terminal strip arrangement is known from DE 202013104467U 1, in which a separating strip for electrical insulation is arranged between adjacent terminal strips.

In the terminal strip arrangement disclosed in DE 202010015731U 1, a support plate is arranged between two adjacent terminal strips, which support plate has a support arm for supporting the arrangement with respect to the printed circuit board.

Disclosure of Invention

It is an object of the present invention to provide an assembly of electrical devices and a method of manufacturing an assembly of electrical devices which enable the connection of adjacent engagement means in a variable manner.

The solution of the invention to achieve the object defined above is the subject matter of the features of claim 1.

According to the invention, the assembly has a connecting element with a base body and a connecting section on the base body. The connecting element is designed to connect two of the plurality of engagement devices that are adjacent in the series direction together, wherein the connecting element is connected to the housing of at least one of the two adjacent engagement devices in a material-bonded manner via the connecting section.

This connects two adjacent engaging means together with the connecting element located therebetween. The connecting element is connected to at least one of the adjacent devices to be connected to one another in a material-bonding manner, so that in the connected state there is a material bond between the connecting element and the corresponding connecting device.

The materially bonded connection can be established, for example, by gluing or welding the connecting elements together with corresponding bonding means. When the bonding is performed, the connecting sections of the connecting element are wetted by a suitable adhesive and attached to the corresponding joining means, thereby bonding the connecting element and the joining means together. The welded connection can be produced, for example, by laser welding, in particular by laser transmission welding, ultrasonic welding or another welding process, in particular for welding plastic parts.

The housings of adjacent engagement devices can be variably connected by means of a connecting element, wherein the housings can have the same or different housing profiles. The connecting element is connected in a material-bonding manner to at least one, preferably two, of these adjacent joining devices, so that the housings of these joining devices can differ in their form and size. The connection is established by a connecting element which is connected to one or two adjacent engaging means in a material-bonded manner, which enables the user to variably configure the assembly by combining different engaging means together.

In order to produce the assembly, the joining devices are connected to one another in series in the series direction, wherein a connecting element is arranged between each two joining devices adjacent in the series direction. In particular, the connecting element is joined to one, preferably both, of the adjacent joining devices in a material-bonded manner by means of gluing or welding, so that the joining devices are held together by the connecting element located therebetween.

The connecting element has a base body and a connecting section formed on the base body. The base body preferably extends along a plane perpendicular to the joining direction and forms a surface section which extends in a planar manner between adjacent joining devices when the joining devices are connected. In the case of a connecting element made of an electrically insulating plastic material, electrical insulation can be provided between adjacent engaging means by the base body.

In one embodiment, the connecting section for producing a material-bonded connection with the at least one joining device extends at least partially circumferentially around the main body. In one embodiment, the base body is limited by a connecting section in a plane perpendicular to the joining direction, wherein the connecting section extends at the upper end of the base body. The connecting section may extend, for example, around the base body over the entire circumference, thus enclosing the base body in a closed manner (viewed in the circumferential direction of the joining direction). Alternatively, the connecting section may extend on two or three sides of the base body, thus only partially limiting the base body.

In one solution, the connecting section extends at least partially around the housing of the engaging means in the position in which the connecting element is attached to at least one of the two adjacent means. The connecting element is thereby attached to the housing of the corresponding engagement device in such a way that the connecting section extends outside the housing and around it. The connection of the connecting element with the corresponding engagement means is established by the connecting section, so that a firm and force-able connection is established between the connecting element and the corresponding engagement means by the circumferential extension around the housing.

In one embodiment, the connecting section projects from the base body on at least one side in the series direction. The connecting section can be designed, for example, as a web section which projects from the base body in the joining direction and is used to attach the connecting element to the housing of the corresponding joining device, so that the connecting element and the joining device are connected together in a materially bonded manner.

For this purpose, the tab section can be attached to the housing of the corresponding joining device such that the tab section spans the housing of the joining device in the position in which the connecting element is attached to the joining device such that the tab section, viewed in a direction transverse to the stringing direction, faces the connecting surface arranged on the housing. In this way, a connection can be produced between the connecting element and the housing of the connecting device, in particular by means of gluing or welding, by means of the web section, wherein the web section is materially bonded to the connecting surface of the housing by means of gluing or welding.

The web section, viewed in a direction transverse to the joining direction, faces the connecting surface, so that an abutment is formed between the web section and the connecting surface in a direction transverse to the joining direction. In particular in the case of the production of a material bond by laser beam welding, the above-described solution provides for the laser beam to be directed from the outside in a direction transverse to the joining direction toward the arrangement of the joining device and the connecting element, so that a material-bonded connection is produced between the connecting element and the housing of the joining device by melting of the material of the web section and/or the connecting surface.

In the case of a connection of the connecting element with the corresponding joining device by laser transmission welding, the web section is made, for example, of a (plastic) material which is permeable to the laser welding beam, while the connection surface of the housing is made of a material which absorbs the energy of the laser welding beam and is thereby melted by the laser welding beam. The material that is permeable to the laser welding beam can be made of a thermoplastic material, for example. Whereas a material absorbing the laser welding beam can be obtained, for example, by mixing particles, such as carbon black particles, into the thermoplastic. When laser transmission welding is used, the laser welding beam is aligned from the outside with the web section through which the laser welding beam is transmitted. The laser welding beam penetrates the web section and impinges on the connection surface, on which the laser welding beam is at least partially absorbed, which is melted by the energy in the laser welding beam, so that a materially bonded connection is produced between the connection surface and the web section.

In one embodiment, the housing of the coupling device, which is connected to the coupling element in a materially bonded manner, has a step at the transition between a first housing side, which extends parallel to the base body of the coupling element, and a second housing side, which extends transversely to the first housing side, which step forms a connection surface that is set back relative to the second housing side. The connecting element can be attached to the housing of the joining device in such a way that the connecting section of the connecting element engages with the step so as to form a planar abutment with the connecting surface on the step. A materially bonded connection can be established between the connection section and the connection face in the region of the step in order to connect the connection element with the joining device.

Advantageously, the housing of each engaging means has at least one such step for coupling together with the corresponding connecting element.

It is further advantageous if the housing has at least one step on each of the housing sides formed by the housing sides spaced apart from one another in the series direction in order to connect the coupling device to a respective connecting element on the housing sides facing away from one another.

In one embodiment, the connecting section of the connecting element is clamped in the step in such a way that the outward outer side of the connecting section is flush with the second housing side. The coupling surface formed on the step is retracted relative to the second housing side and the coupling section of the coupling element snaps into the step, so that an assembly can be created which is flat and flush on the second side of the coupling device without the coupling element projecting with it outward toward the coupling section of the second housing side.

In one embodiment, pairs of engagement devices which are offset from one another in the height direction perpendicular to the stringing direction can be connected together by a connecting element. Advantageously, the connecting element can be configured to connect a first pair of engagement devices adjacent in the stringing direction with a second pair of engagement devices adjacent in the stringing direction, which are arranged offset in relation to the first pair of engagement devices in a height direction perpendicular to the stringing direction. Two (or more) rows of splicing devices can then be connected by such connecting elements to create an assembly of variable configurations to provide multiple splice points for splicing electrical conductors. In this case, the connecting element is connected in a bonded manner to at least one of the first pair of engagement means and to at least one of the second pair of engagement means, wherein preferably the connecting element forms a bonded connection with both the first pair and the second pair of engagement means, so that these engagement means are fixed in a bonded manner.

Another solution of the invention for achieving the object is a method for producing a component of an electrical device, in which a plurality of modular joining devices, each having a housing and at least one joining point for joining electrical conductors, are connected in series with one another in a series direction. According to the method, two of the plurality of engagement devices adjacent in the joining direction are connected together by a connecting element having a base body and a connecting section formed on the base body, in that the connecting element is connected together material-tightly with a housing of at least one of the two adjacent engagement devices by the connecting section.

The advantages and advantageous solutions set forth above with regard to the components also apply analogously to the method, so reference is made to what has been set forth above.

Drawings

The basic idea of the present invention will be described in detail below with reference to the embodiments shown in the drawings. Wherein:

FIG. 1 is a view of an assembly having two engagement devices connected by a connecting element;

FIG. 2 is an isolated view of a portion of one of the engagement devices;

FIG. 3 is a partial isolated view of the connecting element;

FIG. 4 is a view of an assembly having two pairs of engagement means connected by a common connecting element, an

Fig. 5 is an exploded view of the arrangement shown in fig. 4.

Detailed Description

Fig. 1 shows an embodiment of an assembly 1 with several joining devices 2 in the form of modular joining terminals that can be connected in series with each other in a series direction.

Each coupling device 2 has a housing 20 which contains a coupling point in the form of a socket 200 and an actuating opening 201 formed therein. The electrical conductor 4 can be inserted with its stripped conductor end 40 into the plug socket 200 in the plug-in direction E in order to make electrical contact with the electrical contact sections (e.g. busbars) inside the housing 20 in a suitable contact device in the form of a spring contact, a screw contact, a cutting contact, a crimping contact or another electrical contact terminal. For example, an actuating element, such as a press for releasing a spring contact or a screw element for clampingly locking or unlocking the electrical conductor 4, can be actuated by actuating the opening 201.

By connecting a plurality of joining devices 2 in series in a series direction a, an assembly 1 can be created on which a plurality of joining points 200 for joining a plurality of electrical conductors 4 are provided. The component 1 may, for example, be arranged on the printed circuit board 5 and electrically connected to the printed circuit board 5 via contact points 50, so that a joining component is provided on the printed circuit board 5 by the component 1 in order to join the electrical conductor 4 to the printed circuit board 5.

Within the frame of the assembly 1, two adjacent engaging means 2 are connected by a connecting element 3.

As shown in fig. 3, the connecting element 3 has a base body 30 in the form of a surface section, which extends in a plane perpendicular to the joining direction a and forms an intermediate layer between two adjacent joining devices 2 when these joining devices 2 are connected.

The base body 30 is bounded on three sides by a connecting section 31 which is formed on the end face on the base body 30 and protrudes bilaterally from the base body 30 in the joining direction a with two web sections 312, 313. On both sides of the base body 30, steps 310, 311 are thus formed at the transition between the base body 30 and the connecting section 31, which serve to interact with the housing 20 of the respectively adjacent joining device 2 in order to establish a material-bonded connection.

As shown in fig. 1, the connecting section 31 of the connecting element 3 extends around the housing 20 of the joining device 2 on three sides when the joining device 2 is connected. By means of the web sections 312, 313, the connecting element 3 bridges the housing 20 of the joining device 2 in the joining direction a, so that the connecting section 31 abuts against the connecting surfaces 211, 221, 240, 241, shown in fig. 2, formed on the housing 20 of the joining device 2.

The housing 20 of the joining device 2 is preferably made of an electrically insulating plastic and encloses one electrical contact device in each case in an electrically insulating manner inside the housing 20. Steps 210, 220 are formed at the transition between the lateral housing sides 21, 22 and the upper housing side 23 and at the transition between the lateral housing sides 21, 22 and the lower housing side 25 (see fig. 1), into which steps a connecting element 3 attached to one housing side 21, 22 can be snapped with its connecting section 31 in order to establish a connection between the housing 20 of the coupling device 2 and the connecting element 3, see fig. 1.

With the connecting element 3 attached to the counter-engaging device 2, the connecting section 31 with its outer side 314 is flush with the upper housing side 23 and with the lower housing side 25 of the counter-engaging device 2, so that the connecting element 3 with its connecting section 31 does not project from the housing 20 of the counter-engaging device 2 in a height direction H perpendicular to the stringing direction a.

Steps 210, 220 are formed on both the upper housing side 23 and the lower housing side 25, while no step with a connection surface 240, 241 that is set back relative to the front housing side 24 is provided in the region of the front housing side 24. In this case, the connecting portion 31 of each counter-connecting element 3 rests against the housing side 24 on the front side and projects from the housing side 24 in a depth direction T perpendicular to the series direction a and perpendicular to the height direction H, see fig. 1.

The connecting element 3 can be connected to two adjoining joining devices 2 in a material-bonded manner. The joining of such material bonds can be produced in different ways.

In one solution, the joining device 2 can be connected by the connecting element 3 by: the connecting element 3 is glued to the housing 20 of the joining device 2. For this purpose, the connecting element 3 is wetted, for example in the region of its web sections 312, 313, with a suitable adhesive, so that it is adhesively connected to the housing 20 of the joining device 2.

In another embodiment, the connecting element 3 is connected to the housing 20 of the joining device 2 by laser welding, in particular by laser transmission welding. For this purpose, the laser welding beam L can be directed perpendicularly to the joining direction a from the outside onto the web sections 312, 313 along the surface normal of the connecting section 31, see fig. 1, in order to weld the connecting section 31 to the housing 20 of the joining device 2 on the web sections 312, 313.

When carrying out laser transmission welding, the connecting element 3 is made of a material that is transparent to the laser welding beam L at least in the region of the web sections 312, 313 of the connecting section 31, so that the laser welding beam L can penetrate the web sections 312, 313 and be incident on the respective housing 20 in the region of the respective connecting surface 211, 221, 240, 241. The housing 20 is made of a material that absorbs laser light in the region of the respective connection surface 211, 221, 240, 241, so that the energy of the laser welding beam L is absorbed on the side of the housing 20 and the housing 20 is partially melted in the region of the connection surface 211, 221, 240, 241. In this way, the housing 20 is connected in a material-bonded manner, in particular to the connecting section 31, so that the connecting element 3 is connected in a material-bonded manner to the adjacent housing 20.

The connecting section 31 extends around the housing 20 of the coupling device 2 on three sides, so that the coupling devices 2 are fixedly and forcibly connected by the connecting element 3. In order to produce a materially bonded connection, the housings 20 adjoining the bonding device 2 do not necessarily have to have the same contour, but the housings 20 can differ in their design.

In case these joining means 2 are connected by the connecting element 3 to create the assembly 1, the assembly 1 can be attached to the printed circuit board 5, for example, by the lower housing side 25 of the joining means 2, so that the assembly 1 is mechanically and electrically mounted on the printed circuit board 5.

In the embodiment shown in fig. 1 to 3, the joining devices 2 can be connected in series with each other in the series direction a and connected by the connecting element 3 with an intermediate layer between adjacent joining devices 2, thereby creating a single-row configuration of the joining devices 2. Whereas in the embodiment shown in fig. 4 and 5, there are provided a plurality of rows of engaging means 2, which are connected by connecting elements 3, so as to provide a multi-row assembly 1 of engaging means 2.

In the embodiment shown in fig. 4 and 5, two pairs 2A, 2B of engaging means 2 are connected by a connecting element 3. The engaging devices 2 of these pairs 2A, 2B are mutually offset in a height direction H perpendicular to the stringing direction a, so that the engaging devices 2 of the first pair 2A are arranged above the engaging devices 2 of the second pair 2B. The connecting element 3 extends over the common height of the pairs 2A, 2B of joining devices 2 attached to each other in the height direction H and connects the two pairs 2A, 2B of joining devices 2 to each other.

The embodiment of the housing 20 of the engaging means 2 is the same as previously explained in connection with the embodiment shown in fig. 1 to 3. The connecting element 3 extends over twice the height (of the connecting element 3 shown in fig. 1 to 3) and can be connected in a material-to-material manner to the joining device 2 joined in the joining direction a.

The engaging means 2 attached to each other in the height direction H form grooves where they are attached to each other due to steps on the top and bottom sides of the housing 20, see fig. 5. As shown in fig. 5, the connecting element 3 has central latching tabs 32 projecting from the base body 30 on both sides and extending in the depth direction T for latching into recesses between mutually adjoining coupling devices 2 in the height direction H when the coupling devices 2 are attached to one another, so that the coupling devices 2 are supported against one another by the latching tabs 32.

In particular in the case of a material-bonded connection established by adhesive bonding, it is also possible to apply adhesive in the region of the snap tab 32 so that a material-bonded adhesive connection is established in the region of the snap tab 32.

The connecting element 3 of the embodiments shown in fig. 1 to 3 and of the embodiments shown in fig. 4 and 5 is preferably made of an electrically insulating plastic material, so that an (additional) electrically insulating effect between the joining means 2 can be provided by the connecting element 3.

The basic idea of the invention is not limited to the embodiments described above but may also be implemented in different ways.

Joining means of the type described herein can take a very different technical solution and are in particular realized in the form of a spring joint, a screw joint, a cutting joint, a crimping joint or the like.

The joining device can be realized as a terminal strip, a plug connector or a base strip and can preferably be attached to the printed circuit board in series with one another.

Description of the reference numerals

1 assembly

2 bonding device

2A, 2B pairs

20 casing

200 junction (socket)

201 steering opening

21, 22 shell side

210, 220 step part

211, 221 connecting surface

23 side of the housing

24 shell side

240, 241 connection face

25 side of the housing

26 side of the housing

3 connecting element

30 base body

31 connecting section

310, 311 steps

312. 313 tab section

314 outside

32 snap tab

4 electric conductor

40 conductor terminal

5 printed circuit board

50 contact point

A direction of series connection

E direction of insertion

L laser welding beam