阅读说明：本技术 用于旋转电机的电刷架的电子设备及其制造方法 (Electronic device for brush holder of rotating electric machine and method of manufacturing the same ) 是由 L.勒杜 H.C.斯梅格 于 2019-07-30 设计创作，主要内容包括：一种用于旋转电机的电刷架的电子设备,特别是用于机动车辆,包括：用于从电子控制芯片散热的散热器,其在延伸平面中延伸；用于所述芯片的多个供电轨道,其与散热器电断开；以及接地轨道,其通过第一连接连接到散热器,其中,所述散热器与第一连接和接地轨道一体形成。(An electronic device for a brush holder of a rotating electric machine, in particular for a motor vehicle, comprising: a heat sink for dissipating heat from the electronic control chip, extending in an extension plane; a plurality of power supply rails for the chip electrically disconnected from the heat sink; and a ground rail connected to the heat sink through the first connection, wherein the heat sink is integrally formed with the first connection and the ground rail.)

1. An electronic device (30) for a brush holder of a rotating electrical machine, in particular for a motor vehicle, comprising:

-a heat sink (12) for the heat dissipation of the electronic control chip, extending on an extension plane (P' 2);

-a plurality of power supply tracks (14) for the chips, electrically disconnected from the heat sink (12); and

-a grounding rail (16) connected to the heat sink (12) by a first connection (11), wherein the heat sink (12) is integral with the first connection (11) and the grounding rail (12).

2. The electronic device (30) according to claim 1, wherein the heat sink (12) is offset from the ground rail (16) in a direction transverse to an extension plane (P' 2) of the heat sink, the first connection (11) having the form of a bend.

3. The electronic device (30) according to any one of the preceding claims, wherein the power supply track (14) and the heat sink (12) extend in two substantially parallel planes (P '1, P' 2).

4. The electronic device (30) according to any one of the preceding claims, wherein the supply track (14) and the ground track (16) extend on the same plane (P' 1).

5. A brush holder (70) of a rotating electrical machine, in particular for a motor vehicle, comprising:

-a housing (40) made of plastic material;

-an electronic control chip (60);

-an electronic device (30) according to any of claims 1-4.

6. A method for manufacturing an electronic device for a brush holder, the method comprising:

a-a step of manufacturing a plurality of supply tracks (14), heat sinks (12) and ground tracks (16), first connections (11) and a plurality of second connections (13) from a metal strip extending along a plane (P1),

the grounding rail (16) is connected to the heat sink (12) by the first connection (11),

the power supply track (14) is connected to the heat sink (12) by the plurality of second connections (13);

b a step of breaking the second connection (13) without breaking the first connection (11) and separating the power supply track (14) from the heat sink (12) while maintaining the electrical connection between the heat sink (12) and the ground track (16).

7. The method for manufacturing an electronic device of a brush holder according to claim 6, comprising:

c-a step of bending so that the heat sink (12) and the grounding rail (16) extend on two different planes (P '1, P' 2).

8. The method for manufacturing an electronic device of a brush holder according to claim 6 or 7, wherein steps b and c are simultaneous or concomitant.

9. A method for manufacturing a brush holder, comprising the steps of an electronic device for manufacturing a brush holder according to any one of claims 6 to 8, and comprising:

d-a step of molding a plastic housing on the power supply rail (14), the heat sink (12) and the grounding rail (16).

10. Method for manufacturing a brush holder according to claim 9, wherein during step d the power supply track (14), the heat sink (12) and the grounding track (16) are held in place by a set of retractable pins (24) extending in a direction transverse to the extension plane (P' 2) of the heat sink (12).

Technical Field

The present invention relates to an electronic device for a brush holder of a rotating electrical machine, and to an electronic device of this type and a method for manufacturing a corresponding brush holder. The invention has particular but not exclusive application in the field of alternators for motor vehicles which can convert mechanical energy into electrical energy and which can be reversible.

Background

Modern alternators for motor vehicles are compact devices in which means for control and regulation are integrated.

The brush holder generally supports a device for regulating the voltage of the current generated by the alternator, which constitutes a brush holder regulator assembly, which is connected to the wiring harness of the vehicle by means of terminals or connectors.

A brush holder regulator of this type is described, for example, in document FR 2969411. The brush holder regulator comprises axial connection terminals and a connector designed to be connected to an electronic unit for controlling the heat engine. The connection terminals and the connector are connected to the electronic chip of the regulator and the braided wire of the brush through a circuit. The electronic chip is cooled by the heat sink.

In particular, in this type of brush holder regulator, it is necessary to ground the chip to eliminate the electromagnetic compatibility problem.

The grounding of the chip mounted on the heat sink can be achieved by making a connection between the grounding rail of the brush holder and the heat sink located below the chip via aluminum wires. As a variant of the brush holder of the packaged chip type described in document FR1460280, the grounding is achieved by means of self-forming screws mounted between a curved grounding rail of the brush holder and a heat sink located below the chip.

Therefore, grounding by this method requires additional steps and components.

Disclosure of Invention

The object of the present invention is to effectively obviate this drawback by proposing an electronic device for a brush holder of a rotating electrical machine, in particular for a motor vehicle, comprising: the radiator is used for radiating the heat of the electronic control chip and extends on the extension plane; a plurality of power supply rails for the chip electrically disconnected from the heat sink; and a ground rail connected to the heat sink by a first connection, wherein the heat sink is integrated with the first connection and the ground rail.

The invention thus makes it possible to eliminate the additional elements, such as aluminum wires or self-forming screws, necessary to reconnect the radiator to the ground. In addition, the invention makes it possible to use the extension of the ground circuit of the brush holder as a heat sink and as a connection for all other circuits. This type of electronic device will be more robust than existing solutions and easier to implement while minimizing the number of steps and bringing economic benefits, especially saving material.

As a variant, the heat sink is offset from the ground rail in a direction transverse to the extension plane of the heat sink, the first connection having the form of a bend.

This type of offset can standardize the architecture of these electronic devices compared to the existing case.

As a variant, the power supply track and the heat sink extend in two substantially parallel planes.

As a variant, the supply track and the grounding track extend on the same plane.

According to another aspect, the subject of the invention is a brush holder for a rotating electrical machine, in particular for a motor vehicle, comprising a casing made of plastic material, an electronic control chip and an electronic device.

According to another aspect, the subject of the invention is a method for manufacturing an electronic device for brush holders, characterized in that it comprises: a step of manufacturing a plurality of power supply rails, a heat sink and a ground rail, a first connection and a plurality of second connections from a metal strip extending along a plane, the ground rail being connected to the heat sink by the first connection, the power supply rails being connected to the heat sink by the plurality of second connections; and a step of cutting off the second connection without cutting off the first connection and separating the power supply rail from the heat sink while maintaining the electrical connection between the heat sink and the ground rail.

This type of approach may limit the number of steps without having to recreate connections between components or add other components.

As a variant, the method comprises the step of bending so that the heat sink and the grounding rail extend on two different planes.

As a variant, the steps of creating and cutting are simultaneous or concomitant.

This makes it possible to reduce the number of steps as much as possible.

As a variant, the method comprises the additional step of moulding a plastic housing on the power supply track, the heat sink and the grounding track.

This makes it possible to dispense with the need to reconnect the radiator to ground in a further step.

As a variant, in this method, during the molding step, the power supply track, the heat sink and the grounding track are held in position by a set of retractable pins extending in a direction transverse to the plane of extension of the heat sink.

This makes it possible to ensure good retention without compromising a good seal of the finished housing against the connection.

The invention will be better understood upon reading the following description and examining the appended drawings. These drawings are provided by way of illustration only and in no way limit the invention.

Drawings

Fig. 1a and 1b are views showing a rail including a grounding rail, a heat sink, and a power supply rail cut out from a metal strip.

Fig. 2a, 2b, 2c, 2d show steps that make it possible to separate the supply track from the heat sink.

Fig. 3a, 3b, 3c are top, perspective and cross-sectional views, respectively, of an electronic device when the connection between the heat sink and the ground rail is completed in a bend.

Fig. 4a, 4b, 4c show a stamping device using a set of pins and the positioning of the pins under and over the track, respectively.

Fig. 5a, 5b are perspective and top views, respectively, of a molded housing around an electronic device.

Fig. 6a and 6b are a perspective view and a top view, respectively, of a brush holder with an electronic chip.

The same, similar or analogous elements retain the same reference numbers from the figures.

Detailed Description

A specific embodiment of an electronic device for a regulator brush holder corresponding to a specific application of the invention will now be described.

In a first step, as shown in fig. 1a, by cutting, stamping or punching a metal strip, a track 10 is formed, which comprises a portion designed to form a heat sink 12, a ground track 16 connected to the heat sink by a first connection 11, and a plurality of supply tracks 14 for the chips, which supply tracks 14 are connected to the heat sink by a plurality of second connections 13.

The supply rail 14 is designed to ensure, in particular, an electrical connection to the brush braid, to the positive B + and negative B-poles of the vehicle battery, and to the phases of the alternator.

The track 10 also includes a frame 18 surrounding the aforementioned elements. The rail 10 extends integrally on a plane P1.

After completion of this first step, the power supply tracks 14 are therefore mechanically connected to each other by the heat sink 12, the heat sink 12 itself being mechanically connected to the ground track 16, all of these being mechanically connected to the frame 18. In fact, the first and second connections 11, 13 ensure the mechanical rigidity of the power supply track 14 with respect to the heat sink 12 and the ground track 16, all of which are therefore in the form of a single portion 10.

As shown in fig. 1b, a cut is then made to separate the frame 18 from the track 10.

Fig. 2 then shows the step of cutting the second connection 13, thereby separating the power supply rail 14 from the heat sink 12. This type of procedure makes it possible to separate the electrical tracks from each other for their different purposes of connection to the chip.

This step can be carried out by stamping with the aid of a tool. The track 10 is then placed in the embossing device 20 (fig. 2 a).

The embossing device comprises for example an embossing tool 23. The stamping tool is for example in the form of a collar 23 which can be actuated and is supported on the rail 10 in a direction substantially transverse to the plane P1 of the rail. The stamping device 20 further comprises, for example, an upper part 21 and a lower part 22, the rail 10 being accommodated in the lower part 22, and a stamping tool 23 being guided by the upper part 21 to be supported on the rail when the upper part 21 and the lower part 22 are brought closer to each other, as shown in fig. 2b and 2 c. After retracting the ferrule 23, the electronic device 30 is obtained, wherein the power supply track 14 is separated from the heat sink 12.

As a variant, the two connections 13 can be cut by laser.

An accompanying or additional step makes it possible to bend the first connection 11 between the heat sink 12 and the grounding rail 16. Thus, after this step is completed, the heat sink 12 is advantageously integrated with the first connection 11 and the grounding rail 16, as shown in fig. 3 a. After this step is completed, the heat sink 12 is offset from the ground rail 16 in a direction transverse to the extension plane P1, the first connection 11 having the form of a bend, as shown in fig. 3 c.

Such steps are performed with the same tool as the previous cutting step or with a different tool. A single tool may for example have a cutting portion in contact with the second connection 13 for cutting and a non-cutting portion in contact with the first connection 11 for bending.

In the electronic device 30 thus formed after completion of the cutting and bending steps, the heat sink 12 and the grounding rail 16 extend on two different planes (P '1 and P' 2, respectively), which are advantageously substantially parallel, as shown in fig. 3 b. These planes will typically be spaced apart by a distance of about 2 mm.

The supply track 14 and the heat sink 12 then also extend in two planes, which are advantageously substantially parallel. The supply track 14 and the ground track 16 extend, for example, at this stage on the same plane P '1, while the heat sink 12 extends on the plane P' 2, as shown in fig. 3 b.

The portion with reference number 17, which corresponds to the lug for connecting the brush braid, extends substantially perpendicular to plane P1.

Hereinafter, the embossing step will be referred to as a step of cutting and bending.

These embossing steps will advantageously be performed while holding the track 10 before embossing and then holding the electronic device 30 after embossing by means of a system of telescopic spindles 24, as shown in fig. 4.

As shown in fig. 4a, the mandrel extends, for example, from the upper portion 21 and the lower portion 22.

The mandrel 24 has an adjustable length so that during the stamping step, the plane of the power supply rail 14 relative to the ground rail 16 and the heat sink 12 can be changed while the components of the electronic device 30 are held relative to each other.

Thus, the track 10 housed in the lower portion 22 is kept a small distance from the base of the lower portion 22 by the mandrels before each step, and then the embossing tool slides between the mandrels and embosses the track 10. The mandrel is then partially retracted to compensate for the varying planes of the different elements of the electronic device 30. After the embossing step is completed, the different elements of the electronic device 30 thus continue to be held in position relative to each other by the mandrel. For example, these elements will be held on different horizontal planes P '1 and P' 2 by a set of spindles. The various components of the electronic device 30 are also held near but not in contact with the base of the lower portion 22 so as to be able to be coated with plastic during molding, as will be described later.

The inter-orbital and axial positioning of the electronic device 30 during molding is ensured by a set of movable mandrels advantageously positioned in the mold.

For example, as shown in fig. 4, the set of retractable spindles comprises a spindle 241 for inter-rail retention on an extension plane P1 and an axial retention spindle 242 for retaining elements of the electronic device 30 in a direction transverse to the plane P1.

The spindles for inter-rail holding shown in fig. 4a and 4c extend on one side of the rail 10 in a direction transverse to the extension plane P1. These mandrels are placed between components of the electronic device. This type of mandrel can prevent displacement in the plane of the components of the electronic device 30 that will tend to move toward each other during molding, as will be described below.

The spindle for axial retention shown in figures 4a, 4b and 4c also extends in a direction transverse to the plane P1, but on both sides of the rail, so as to axially retain the rail.

As shown in fig. 5a, the electronic device 30 is then overmolded with a plastic housing. Thus, the circuits 14, 16 and the heat sink 12 are overmolded in the housing.

To this end, the electronic device 30 is positioned in the mold 50.

As a mold 50, after withdrawing the imprint ferrule, the previous imprint device 20 will advantageously be used.

Thus, the electronic device 30 is held in place near the base of the lower portion 22 by the system of retractable mandrels 24. The mould is then closed, the two portions 21, 22 are brought close to each other, and material is injected into the casing of the mould surrounding the electronic device 30, closing it to form a brush holder, which is then removed from the mould.

For example, during the injection of the material into the mould, the mandrels are retracted by the action of the jacks, so that the material is distributed in particular around the entire power supply track. As a variant, they are retracted by other mechanical or hydraulic means. Retracting the mandrel while injecting makes it possible to prevent the area around the power supply track from remaining open, in particular from the penetration of water.

The material will advantageously be plastic.

After moulding, the mandrel 24 is thus fully retracted and only a small mark remains on the final part.

Thus, as shown in fig. 5b, the moulding of the housing has a first window 41 on one side thereof, facing the heat sink 12 and facing the end of the electrical connection track 14 located near the heat sink. The housing 40 also leaves the end of the ground rail 16 opposite the heat sink 12 uncovered.

The window 41 defines a socket for the electronic chip, which is designed to be in thermal contact with the heat sink 12. On the opposite side, the housing 40 comprises a second window 42, which is larger in size than the first window 41, in order to allow air to come into contact with the heat sink 12 (not shown).

As shown in fig. 5, the resulting brush holder 70 includes, in addition to the power supply rail 14, the ground rail 16, and the heat sink 12, which are overmolded with plastic:

-a support plate for mounting the brush holder on a rear bearing of the alternator;

-a socket for an electronic control chip;

-a socket for a brush; and

lugs for fixing to the rear bearing and to the electrical connection terminals of the alternator.

The electronic chip 60 shown in fig. 6a and 6b is then placed in its socket above the heat sink 12 and electrically connected to the power supply tracks 14 (not shown).

It is to be understood that the above description is provided by way of example only and is not limiting on the field of the invention, as departures from the present disclosure may be made by replacing various elements in any other equivalent manner.

Furthermore, different features, variations and/or embodiments of the invention may be associated with each other according to various combinations, as long as they are not incompatible or mutually exclusive.