EP3704783A1

EP3704783A1 - Interface for connecting an electric motor to a wiring harness, and electric motor

Info

Publication number: EP3704783A1
Application number: EP18789774.9A
Authority: EP
Inventors: Frank Kummer; Eiji Hirao; Toshiyuki Yahari
Original assignee: U Shin Deutschland Zugangssysteme GmbH
Current assignee: Minebea AccessSolutions Deutschland GmbH
Priority date: 2017-10-30
Filing date: 2018-10-19
Publication date: 2020-09-09
Also published as: CN208174425U; DE102017125410A1; WO2019086278A1; CN111279590A; US20210066839A1

Abstract

The invention relates to an interface for connecting an electric motor (10) to a wiring harness, comprising a motor-side housing (12), in which two plugging chambers (14) are provided. A contact blade (16) of the electric motor (10) extends into each plugging chamber (14). Each plugging chamber (14) is provided with a stop (22) for a plugging sleeve (30) and with a latching element (24) for the plugging sleeve (30). The invention further relates to an electric motor (10) having such an interface.

Description

Interface for connecting an electric motor to a wiring harness and electric motor

The invention relates to an interface for connecting an electric motor to a wiring harness and an electric motor with such an interface.

In many applications, it is common that those cables over which the electrical energy is provided for operating the electric motor are soldered to the corresponding terminals of the electric motor. Although this is advantageous in terms of contact security (at least if the Lotstelle is performed properly). However, a soldering is associated with a lot of effort.

It is also known that the cables are provided with plug contacts, which are plugged onto the electrical connections of the electric motor. However, this is not optimal with regard to the contact security. The object of the invention is to reliably connect an electric motor to a cable harness, without the need for a high effort to be operated.

To achieve this object, an interface for connecting an electric motor is provided according to the invention to a wiring harness, with a motor-side housing, in which two plug-in chambers are provided, hineinerstreckt into each plug-in chamber, a contact blade of the electric motor, each plug-in chamber with a stop for a socket and a locking element is provided for the plug-in sleeve. To solve this problem, an electric motor is provided with such an interface according to the invention. The invention is based on the idea of integrating into the electric motor a mechanical latching device which ensures a mechanical latching both during insertion and against unintentional release. This results in a high contact security, while at the same time the socket can be mounted in the usual way, namely can be plugged onto the contact blade of the electric motor.

According to a preferred embodiment of the invention, the stop and the locking element are formed by opposite end faces of a constriction of the plug-in chamber. Thus, the two elements can be compact on one and the same component form, namely at the constriction.

Preferably, the constriction is located approximately at the level of the free end of the contact blade. This ensures that the receptacle has to be pushed far enough onto the contact blade of the electric motor before a locking spring provided on the receptacle engages behind the constriction.

The plug-in chamber preferably has an insertion bevel for the plug-in sleeve, so that the plug-in sleeve is reliably guided into the plug-in chamber.

The housing, in which the plug-in chambers are integrated, is preferably a brush holder housing of the electric motor, so that no additional components are required.

The brush holder housing can accommodate a printed circuit board on which a motor sensor is arranged. With the motor sensor speed and / or angular position signals can be detected. The integration into the brush holder housing allows the corresponding sensor to be arranged at a suitable location with little effort.

The circuit board preferably has a recess which is arranged concentrically with the motor shaft. It is thus possible to mechanically support the motor shaft, if, for example, a pinion is pressed onto the motor shaft on the opposite side.

The circuit board may be secured to the housing by at least one plastically deformed retaining pin. Such a retaining pin, for example, after it has been heated, can be suitably shaped so that it reliably holds the printed circuit board in the manner of a rivet, without the risk of the connection between the printed circuit board and the housing becoming detached during vibration. On the circuit board, a connector for connecting the motor sensor is preferably provided. This makes it easier to fully connect the electric motor to the wiring harness.

Preferably, the plug-in chambers extend in the axial direction. This makes it easier to contact the contact blades of the electric motor, since the back of the electric motor is usually comparatively easily accessible.

According to one embodiment of the invention, the housing is provided with a torque support, with which a torque of the electric motor can be supported. The torque support prevents the electric motor from rotating in the receptacle provided for it when a particularly high torque acts. If the electric motor were to twist, this could result in damage to the cables of the wiring harness or the plug connection between the cables and the electric motor.

The invention will be described below with reference to an embodiment shown in the accompanying drawings. In these show:

Figure 1 is a perspective view of an embodiment of an interface according to the invention;

Figure 2 is a plug-in chamber used in the interface in a first sectional view; and FIG. 3 shows the plug-in chamber of FIG. 2 in a second sectional view.

In Figure 1, an electric motor 10 is seen, which is particularly intended to be used in actuators, such as those used in motor vehicles. An example is a spindle drive.

On its side facing away from the output side of the electric motor is provided with an interface that serves to connect it to a wiring harness. The interface serves both to transmit the electrical energy for operating the electric motor 10 and to connect the electric motor 10 with a controller.

The interface has a housing 12, which is designed here as a brush holder housing. In the housing 12 are two plug-in chambers (see also the FIGS. 2 and 3), which are arranged so that a contact blade 16 of the electric motor extends into each plug-in chamber 14. The two contact blades 16 serve to transmit the electrical drive power to the electric motor 10. Each plug-in chamber 14 is provided with a constriction 20 which has a shoulder on opposite sides. The shoulder arranged on the outside of the plug-in chamber 14 constitutes a stop 22, and the shoulder arranged on the inside of the plug-in chamber 14 constitutes a latching element 24. As can be seen in FIG. 2, the constriction lies in the axial direction of the contact blade 16 considered, approximately at the height of the free end of the contact sword.

Each plug-in chamber 14 is also provided with chamfers 26, which guide a connector when it is inserted into the plug-in chamber 14 in the correct position.

To contact the contact swords 16 sockets 30 are used, each having a terminal end 32, which serves to connect the wires of a cable. The cable can be crimped for example with the sockets.

Each receptacle 30 further comprises a contact portion 34 which serves to contact the corresponding contact blade 16.

In the region of the contact section 34, the plug-in sleeve 30 has two latching tabs 36, which serve to latch behind the latching elements 24 of the constriction 20 when the plug-in sleeve is completely inserted.

Finally, each plug-in sleeve 30 has two stop tabs 38 which can rest on the stop 22 of the constriction 20 when the plug-in sleeve 30 is pushed onto the corresponding contact blade 16.

Both the detent springs 36 and the stop tabs 38 are bent out of the material of the receptacle 30 by suitably stamping and then deforming a one-piece blank. Ensure the detent springs 36 together with the stop tabs 38 that the socket 30, if it is pushed far enough on the corresponding contact blade 16, mechanically locked within the plug-in chamber 14, but also can not be pushed overly far. The brush holder housing 12 also serves to receive a printed circuit board 40, which serves a motor sensor for detecting the rotational speed and / or the angular position of the rotor of the electric motor. The motor sensor is not visible here, since it is arranged on the side facing the electric motor side of the printed circuit board 40.

The printed circuit board 40 covers the back of the brush holder housing 12 almost completely, as can be seen in FIG. Only the access to the plug-in chambers 14 remains free and a central recess 42 which is concentric with the motor shaft. Through the recess 42 through the motor shaft can be supported, for example, to be able to press a pinion on the output side. The circuit board 40 carries a connector 44 into which a complementary connector can be plugged to electrically connect the motor sensor to a controller.

The circuit board 40 is mechanically secured to the brush carrier housing 12 by having two retaining pins 46 integral with the brush support housing 12 extending through corresponding holes in the circuit board 40 and plastically deformed on the outside, for example, by hot forming.

The brush carrier housing 12 also has a torque support 48 which is here formed in the form of two axially extending pins. The pins can engage in complementary recesses of a module housing or other receptacle for the electric motor 10, so that the motor housing can not rotate in the circumferential direction. This prevents that the connection cables of the electric motor are damaged by the fact that the electric motor rotates about its own axis, when acting on a particularly high reaction torque.

Since the plug-in chambers 14 are aligned in the axial direction, the plug-in sleeves 30 are attached in the axial direction. This is assembly technology advantageous. In addition, results in the insertion of the sockets 30 a haptic feedback when the detent springs 36 engage behind the constriction 20. The locking springs 36 ensure that the receptacle 30 remains reliable on the contact blade 16. To remove the receptacle 30, the detent springs 36 must be bent so much that the receptacle is unusable.

Claims

claims

1 . Interface for connecting an electric motor (10) to a wiring harness, with a motor-side housing (12) in which two plug-in chambers (14) are provided, wherein in each plug-in chamber (14) extends a contact blade (16) of the electric motor (10) hineinerstreckt wherein each plug-in chamber (14) is provided with a stop (22) for a plug-in sleeve (30) and a latching element (24) for the plug-in sleeve (30).

2. Interface according to claim 1, characterized in that the stop (22) and the latching element (24) by opposite end faces of a constriction (20) of the plug-in chamber (14) are formed.

3. Interface according to claim 2, characterized in that the constriction (20) is arranged approximately at the level of the free end of the contact blade (16).

4. Interface according to one of the preceding claims, characterized in that the plug-in chamber (14) has an insertion bevel (26) for the

Socket (30).

5. Electric motor (10) with an interface according to one of the preceding claims.

6. Electric motor according to claim 5, characterized in that the housing is a brush holder housing (12) of the electric motor (10).

7. Electric motor according to claim 6, characterized in that the brush holder housing (12) receives a printed circuit board (40) on which a motor sensor is arranged.

8. Electric motor according to claim 7, characterized in that the circuit board (40) has a recess (42) concentric with the

Motor shaft is arranged.

9. Electric motor according to one of claims 7 and 8, characterized in that the circuit board (40) on the housing (12) by at least one plastically deformed retaining pin (46) is attached.

10. Electric motor according to one of claims 7 to 9, characterized in that on the circuit board (40) has a connector (44) is provided for connecting the motor sensor.

1 1. Electric motor according to one of claims 5 to 10, characterized in that the plug-in chambers (14) extend in the axial direction.

12. Electric motor according to one of claims 5 to 1 1, characterized in that the housing (12) with a torque support (48) is provided, with which a torque of the electric motor (10) can be supported.