DE202016102159U1 - Contacting arrangement between a stator and a printed circuit board - Google Patents

Abstract

Stator (1) for an electric motor, connected to a printed circuit board (20) comprising a stator housing (10) in which a plurality of winding assemblies (11) are arranged, consisting of wound into winding coils (12), further comprising contact carrier receptacles (14) on the stator housing (10) are formed, in each of which an insulation displacement contact element (30) is introduced, which produces an electrical contact between each one of the winding assemblies (10) and a wire bridge (21) on the circuit board (20).

Description

The invention relates to a stator with a printed circuit board.

Electric motors according to the prior art essentially consist of two components, namely the stator with its windings and the rotor.

The stator of an electric motor is in a fixed position while the rotor can rotate relative to the stator. At the stator there are winding frames around which the wires are wound. Such windings are referred to below as a winding arrangement or generally as a stator winding.

Each wound into a coil enamel wires that lead away from these winding frame must be electrically connected to the line structure in the interior of the electric motor, so that the windings can be energized.

The electrical connection of the enameled wires to the conductive structure is usually made by welding or brazing. For this purpose, first the enamel wires with intermediate terminals and the intermediate terminals are in turn connected to another line structure through the connection process.

However, this has the disadvantage that the electrical connection can be affected by poor welding. In addition, the production is relatively expensive depending on the number of connections.

From the DE 10 2015 208 425 DE discloses an improved solution in which a connection structure for a stator and a printed circuit board is proposed, wherein the connection structure comprises connection openings for receiving stator enameled wires and the stator and the circuit board are electrically connected to one another. The connection structure is characterized in that on the circuit board terminals are still arranged, which are arranged in such a way that the electrical connection of the circuit board to the stator is realized by the terminals are inserted into the connection openings. As an advantageous embodiment, a solution is proposed in which the terminals are arranged so that they contact the paint wires directly after insertion into the connection openings and establish a conductive connection, whereby the electrical connection of the stator is realized with the circuit board. The terminals on the circuit board and the connection holes on the stator are inserted directly into each other, so that the terminals cut into the insulating layer of the enamel wires in the connection openings and a conductive connection is formed, whereby the electrical connection of the circuit board is realized with the stator.

From the EP 2 557 665 A1 is a stator for an electric motor, in particular for an external rotor motor, comprising a main body with a stator lamination, as well as arranged on the stator lamination stator windings, each having a winding wire beginning and a winding wire end, each winding wire beginning is connected to pins, the body with a Encapsulated plastic sleeve is molded from the contact pins protrude at least partially. In order to reduce the production-related expense, it is proposed that a contact holder surrounded by the shell together with the base body is slid over the free end of the contact pins onto the base body, wherein the contact holder comprises the contact pins with a sealing section without a gap.

The DE 20212273 U1 relates to a stator for an electric motor, in particular for an external rotor motor, consisting of a stator lamination with stator windings and at least one end arranged insulating and a wiring arrangement for interconnecting winding wires of the stator windings with electrical leads, wherein in the insulating electrical, executed in insulation displacement contact elements are held for contacting the winding wires and the leads.

The EP 0 993 095 A1 describes a stator whose wiring arrangement has insulation displacement contact elements which sit in special contact chambers of the frontal insulating element. Specifically, it should be at least one multiple contact chamber, which is formed by sub-chambers on the one hand molded onto the laminated core insulating element (insulating end plate) and on the other hand, an additional winding head side mounted wiring plate such that the sub-chambers adjacent to each other in the mounted state of the wiring board are arranged, wherein they receive a common, connecting the sub-chambers contact element. In this case, ends of the winding wires are guided through the contact chamber during manufacture. After making all the windings, the wiring board is placed and fixed on the winding head side of the stator. All contact chambers are then equipped with insulation displacement contact elements by inserting the latter into the chambers. In this case, a contacting of the winding wires passing through the contact chambers takes place automatically, with the aid of a slot-shaped conductor receptacle Isolation is severed and the wire is clamped with electrical contact (insulation displacement technique).

Subsequently, the outer leads are pressed according to the required interconnection of the stator in slots of the contact chambers and contact elements. Again, the insulation of the leads is severed and thereby the electrical contact is made. Only after this connection of the outer leads, the further assembly of a rotor can be done with its axis, and the engine can go through further operations until its completion. Thus, the outer leads must be connected individually one after the other and even at a very early stage of manufacture. This is particularly disadvantageous because the further production is charged with the connecting cables, d. H. the connection cables could hinder the further production and assembly process.

A disadvantage of the aforementioned and known in the prior art solutions is the fact that they are still relatively expensive and therefore relatively expensive to install and depending on the design are still given complex arrangements and a high number of parts for the production of compounds the windings of the circuit board.

The invention is therefore based on the object to overcome vorbesagte disadvantages and to provide a cost-effective, simple and universally applicable solution for a connection between a stator and a printed circuit board.

This object is achieved by the feature combination according to protection claim 1.

A basic idea of the present invention is to produce a particularly simple, compact and efficient connection concept between the winding wires and the printed circuit board. For this purpose, isolated wire sections in the form of wire bridges, preferably in or parallel to the circuit board plane are provided on the circuit board for electrical contact with the winding wires to contact these wire bridges by means of a insulation displacement connection of a insulation displacement contact.

According to the invention, therefore, a stator, in particular an electric motor stator with a printed circuit board is proposed, comprising a stator housing in or on which a plurality of winding arrangements (stator windings) are arranged consisting of winding wires, further contact carrier receptacles are formed on the stator housing, in each of which a insulation displacement contact element is introduced which is intended to produce or produce an electrical contact between in each case a winding arrangement and a wire bridge on the printed circuit board.

In a particularly advantageous embodiment of the invention it is provided that the insulation displacement contact elements provide at least one insulation displacement connection, which protrudes from the contact carrier receptacle (in which the insulation displacement contact element is mounted) and penetrates with its insulation displacement terminals at the insulation displacement connection, the insulation of a provided on the circuit board for contacting wire bridge.

It is particularly advantageous if the respective wire bridge extends within or parallel to the plane of extent of the printed circuit board in that region in which an electrical connection is made with an insulation displacement contact element. In this way, a particularly simple assembly can be realized in an overall compact design, since then the mounting direction can extend transversely to the circuit board level, while the circuit board can be arranged in the axial direction A of the stator at one end directly above the stator.

In a further advantageous embodiment of the invention, it is provided that, for contacting the insulation displacement contact elements, the respective wire bridges of the printed circuit board extend with their contacting region above or below an opening made in the printed circuit board. As a result, on the one hand a very compact design can be realized while z. B. through the circuit board opening through an additional optical control of the insulation displacement connection is possible.

In other words, this means that the insulation displacement contact elements protrude in the contacting state through the respective opening provided in the circuit board at least with its front end or thereby are visible.

If the conductor bridge is mounted transversely underneath the printed circuit board opening, a particularly compact assembly and a secure cutting of the wire bridge within each fitted contact carrier can furthermore take place since the insulation displacement contact elements can then be completely received by the contact carrier receptacle. In such a case, it is further advantageous if the respectively provided for connection wire bridge is designed as a U-shaped wire bridge, which protrudes in the direction of the stator housing from the underside of the circuit board. In the contacting state, the contacting section of the U-shaped wire bridge extends within the contact carrier receptacle.

In a particularly advantageous embodiment of the invention it is provided that the insulation displacement contact elements are each formed as a double-cutting terminal contact elements with two insulation displacement connection terminals, wherein a insulation displacement connection terminal penetrates the winding wire of a winding assembly, while the second insulation displacement connection terminal penetrates the insulation of a wire bridge on the circuit board.

It is also advantageous if the contact carrier receptacles for receiving the insulation displacement contact elements are pocket-like, wherein the respective insulation displacement contact element is partially or completely inserted into the pockets in the axial direction A of the stator.

Preferably, the insulation displacement contact elements are formed with at least one locking lug, which lock the insulation displacement contact elements in the contact carrier receptacle or fix against falling out.

It is also advantageous if the wire bridges are formed either from an enameled wire, an insulated wire or a wire-shaped metal tongue sheathed with an insulating layer.

Other advantageous developments of the invention are characterized in the subclaims or are shown in more detail below together with the description of the preferred embodiment of the invention with reference to FIGS.

Show it:

1 an exploded view of a first embodiment of a stator according to the invention without a printed circuit board;

2 an exploded view of the stator according to the invention according to 1 with a printed circuit board, once in a pre-assembly position (left view) and once in a contacting position (right view);

3 a sectional view through a contacting region of the first embodiment;

4 an exploded view of an alternative embodiment of a stator according to the invention with a printed circuit board to be mounted;

5 a schematic sectional view through the embodiment according to 4 and

6 a sectional view through a contacting region of the embodiment according to 4 ,

In the following the invention will be described by means of exemplary embodiments of the invention with reference to FIGS 1 to 6 explained in more detail, wherein like reference numerals refer to the same structural and / or functional features.

In the 1 is an exploded view of a first embodiment of a stator according to the invention 1 for an electric motor not shown in detail.

The stator 1 includes a stator housing 10 in the six winding arrangements 11 (three pairs of stator windings) consisting of winding wires wound into coils 12 are arranged. At the stator housing 10 are also six contact carrier recordings 14 educated. In the left view of the 1 are three insulation displacement contact elements 30 above the pocket-shaped receptacles 15 of three of the existing contact carrier recordings 14 arranged, which each side hook-like locking elements 33 have in the in the 1 in the right-hand view shown mounted position in the pockets 15 the contact carrier recordings 14 to hook (see also the sectional view in the mounted position in the 3 ).

The electrical contact is between each of a specific winding arrangement 10 from a pair of two winding arrangements 10 and one of these winding arrangement 10 associated wire bridge 21 the circuit board 20 as shown in the exploded view of the 2 , once in a pre-assembly position (left view) and once in a contacting position (right view) is shown in more detail.

In this embodiment, the three insulation displacement contact elements 30 an IDC connection terminal 31 ready, the front side of the contact carrier receptacle 14 protrudes and with its cutting clamps 32a . 32b the insulation 22 a wire bridge provided on the circuit board 21 penetrates. Like in the 2 also recognizable, runs the respective wire bridge 21 in the area in which an electrical connection between the conductor 26 with an insulation displacement contact element 30 is produced, parallel to the plane E of the circuit board 20 and thus transverse to the mounting direction, which corresponds to the axial direction A of the stator.

The wire bridges 21 the circuit board 20 run with their contact area 21a above each in the circuit board 20 introduced openings 25 ,

The 3 shows a sectional view through a contacting region of the insulation displacement contact element 30 of the first embodiment.

The insulation displacement contact elements 30 are here as Doppelschneidklemmkontaktelemente with two insulation displacement connection terminals 31 . 31 ' formed, wherein the one insulation displacement connection terminal 31 ' the winding wire 12 a winding arrangement 11 penetrates while the second insulation displacement connection terminal 31 the insulation 22 a wire bridge 21 on the circuit board 20 penetrates, wherein the insulation displacement contact elements 30 with the insulation displacement connection terminal 31 through the openings 25 protrude.

The 4 shows an exploded view of an alternative embodiment of a stator according to the invention with a circuit board to be mounted and the 5 a schematic sectional view through the embodiment according to 4 , where the wire bridges 21 U-shaped and formed on the underside of the circuit board 20 protrude.

Furthermore, in the sectional view through a contacting region of this embodiment 4 recognizable that the insulation displacement contact elements 30 with the insulation displacement connection terminal 31 not as in the first embodiment, the front side of the contact carrier receptacle 14 protrude, but the insulation displacement contact elements 30 completely from the contact carrier receptacle 14 are included. Hereby make sure that the side walls 14a the contact carrier recording 14 are laterally open so far that the wire of the wire bridge deep enough in the contact carrier receptacle 14 can dive.

• i) Positionieren der Leiterplatte 20, welche die passende Anzahl an Drahtbrücken 21 zur Kontaktierung mit den Wicklungsanordnungen 10 des Stators 1 aufweist relativ zum Stator 1, derart, dass die korrespondierenden Schneidklemmkontaktelemente 30 axial in der Flucht mit den zu kontaktierenden Drahtbrücken 21 liegen und
• ii) Zusammenfügen des Stators 1 und der Leiterplatte 20, derart dass die zu den Drahtbrücken 21 korrespondierend angeordneten Schneidklemmkontaktelemente 30 die Isolierung der jeweiligen Drahtbrücke 21 durchdringen und die Drahtbrücke 21 in elektrischen Kontakt mit dem jeweiligen Schneidklemmkontaktelement 30 gebracht wird.

The assembly takes place with the following steps:

• i) Positioning the circuit board 20 which has the appropriate number of jumper wires 21 for contacting with the winding arrangements 10 of the stator 1 has relative to the stator 1 such that the corresponding insulation displacement contact elements 30 axially in alignment with the wire bridges to be contacted 21 lie and
• ii) Assembly of the stator 1 and the circuit board 20 , so that the to the wire bridges 21 correspondingly arranged insulation displacement contact elements 30 the insulation of the respective wire bridge 21 penetrate and the wire bridge 21 in electrical contact with the respective insulation displacement contact element 30 is brought.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102015208425 [0007]
• EP 2557665 A1 [0008]
• DE 20212273 U1 [0009]
• EP 0993095 A1 [0010]

Claims (9)

Stator ( 1 ) for an electric motor, connected to a printed circuit board ( 20 ) comprising a stator housing ( 10 ) in which several winding arrangements ( 11 ), consisting of wound into coils winding wires ( 12 ), further comprising contact carrier receptacles ( 14 ) on the stator housing ( 10 ) are formed, in each of which a insulation displacement contact element ( 30 ), which makes electrical contact between in each case one of the winding arrangements ( 10 ) and a wire bridge ( 21 ) on the printed circuit board ( 20 ). Stator ( 1 ) according to claim 1, characterized in that the insulation displacement contact elements ( 30 ) at least one insulation displacement connection terminal ( 31 ) and with its insulation displacement terminals ( 32a . 32b ) the insulation ( 22 ) or the cable jacket of a directly on or on the circuit board provided wire bridge ( 21 ) penetrates. Stator ( 1 ) according to claim 1 or 2, characterized in that the respective wire bridge ( 21 ) in the region in which an electrical connection with an insulation displacement contact element ( 30 ), within or parallel to the plane of extent of the printed circuit board ( 20 ) runs. Stator ( 1 ) according to claim 1, 2 or 3, characterized in that for contacting the insulation displacement contact elements ( 30 ) the respective wire bridges ( 21 ) of the printed circuit board ( 20 ) with its contacting area ( 21a ) above or below one in the printed circuit board ( 20 ) opening ( 25 ). Stator ( 1 ) according to one of the preceding claims, characterized in that the insulation displacement contact elements ( 30 ) as double-cutting clamp contact elements with two insulation displacement connection connections ( 31 . 31 ' ), wherein the one insulation displacement connection ( 31 ' ) the winding wire ( 12 ) of a winding arrangement ( 11 penetrates while the second insulation displacement connection terminal ( 31 ) the insulation of a wire bridge ( 21 ) on the printed circuit board ( 20 ) penetrates. Stator ( 1 ) according to one of the preceding claims, characterized in that the contact carrier receptacles ( 14 ) for receiving the insulation displacement contact elements ( 30 ) pocket-like pictures ( 15 ) into which the respective insulation displacement contact element ( 30 ) in the axial direction (A) of the stator (A) 1 ) is inserted. Stator ( 1 ) according to one of the preceding claims, characterized in that the insulation displacement contact elements ( 30 ) with a catch ( 33 ) are formed, which the insulation displacement contact elements ( 30 ) in the contact carrier receptacle ( 14 ) lock. Stator ( 1 ) according to one of the preceding claims, characterized in that the wire bridges ( 21 ) of an enameled wire, an insulated wire or one with an insulating layer ( 22 ) sheathed wire-shaped metal tongue are formed. Stator ( 1 ) according to one of the preceding claims 4 to 8, characterized in that the insulation displacement contact elements ( 30 ) in the contacting state through the respective opening ( 25 ) in the printed circuit board ( 20 ) at least with its front end ( 30a ) protrude.

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