WO2011042472A1

WO2011042472A1 - Electric motorized actuator

Info

Publication number: WO2011042472A1
Application number: PCT/EP2010/064936
Authority: WO
Inventors: Volker Schulmayer; Julia Hilz
Original assignee: Zf Friedrichshafen Ag; Kett, Juergen
Priority date: 2009-10-09
Filing date: 2010-10-06
Publication date: 2011-04-14
Also published as: DE102009045505A1

Abstract

The invention relates to an electric motorized actuator (1), having an electric motor (2), sensors (3) for detecting the rotation of a rotor (5) of the electric motor (2), electronics (4) for controlling the electric motor (2) in an open- and/or closed-loop manner, and a mechanism (7) for transferring or converting a rotation of the rotor (5) of the electric motor into a translatory and/or rotary adjusting displacement of an adjusting element actuated by the actuator. According to the invention, the electric motor (2) is implemented as a brushless electric motor (2) positioned together with the sensors (3) and the electronics (4) in a common housing (8), wherein the sensors (3) comprise at least two digital Hall effect sensors (9).

Description

Electromotive actuator

The invention relates to an electromotive actuator according to the preamble of claim 1.

Electromotive actuators are used in a variety of different applications, such as in automated manual transmissions, active transfer gears, active suspensions, power steering systems or other applications, to provide a linear and / or rotational actuator movement for an actuator-actuated actuator using the electromotive actuators. Known from practice, electromotive actuators have an electric motor, a sensor for detecting the rotation of a rotor of the electric motor, an electronics for controlling and / or regulating the electric motor and a mechanism for implementing the rotation of the rotor of the electric motor in the translational and / or rotational adjustment movement of the actuator actuated actuator. Such electromotive actuators increasingly displace hydraulic or pneumatic actuators, wherein the actuators either fixedly attached to a housing or in a moving component, for example, in a shaft, can be integrated.

In electromotive actuators known from practice, at least the electric motor, the sensor system and the electronics are each designed as separate, functionally and spatially separate subsystems of the electromotive actuator. This makes it necessary to cabling the electric motor with the electronics and the sensors with the electronics each consuming. Such electromotive actuators on the one hand have a complex and therefore expensive construction, on the other hand, the same are susceptible to interference, since the wiring on the one hand between the electric motor and electronics and on the other hand between electronics and sensors in operation can unintentionally solve. From DE 10 2007 000 446 A1 a brushless electric motor with associated sensor is known, wherein a rotor-side rotor of the brushless electric motor via a shaft in two bearings, namely in an A-bearing and a B-bearing, is mounted, and wherein a Sensor for detecting the rotation of the rotor of the electric motor by a housing wall thereof extends, which is positioned adjacent to the B-bearing of the brushless electric motor.

On this basis, the present invention based on the problem of creating a novel electromotive actuator.

This problem is solved by an electromotive actuator according to claim 1. According to the invention, the electric motor is designed as a brushless electric motor which is positioned together with the sensor system and the electronics in a common housing, the sensor system comprising at least two digital Hall sensors.

With the present invention, an electric motor actuator is proposed for the first time, the electric motor is positioned together with the sensor and the electronics in a common housing, wherein the electric motor of the electromotive actuator is designed as a brushless electric motor, and wherein the sensor at least two digital Hall sensors for detecting the rotation and thus the position of the rotor of the electric motor comprises. Such an electromotive actuator requires no cumbersome wiring between the electric motor and electronics and between sensors and electronics. It is characterized by a simple and compact design and is particularly suitable for integration in moving or rotating systems. Thus, it is possible, for example, to integrate the electromotive actuator according to the invention in rotating at a high speed rotating shafts. Preferred embodiments of the invention will become apparent from the dependent claims and the description below. An embodiment of the invention will be described, without being limited thereto, with reference to the drawing. Showing:

1 is a schematic representation of an electromotive actuator according to a first embodiment of the invention; 2 is a schematic representation of an electromotive actuator according to a second embodiment of the invention; Fig. 3 shows a detail, namely a B-bearing plate, the electromotive

Actuator of Fig. 1; and

4 shows a further detail, namely a unit of sensor technology and electronics, of the electromotive actuator of FIG. 1 or 2.

Fig. 1 shows a highly schematic representation of an inventive electromotive actuator 1 according to a first embodiment of the invention.

The electromotive actuator 1 of FIG. 1 has an electric motor 2, a sensor 3 and an electronics 4, with the aid of the sensor 3, the rotation of a rotor 5 of the electric motor 2 relative to a stator 6 thereof can be detected, and wherein the electronics 4 of Control and / or regulation of the electric motor 2 is used.

Further, the electromotive actuator 1 has a mechanism, in the illustrated embodiment via a shaft 7, by means of which the rotation of the rotor 5 of the electric motor 2 can be converted or implemented in an actuating movement of an actuator actuated by the actuator 1 according to the invention. The electric motor 2, the sensors 3 and the electronics 4 of the electromotive actuator 1 according to the invention are positioned in a common housing 8 as shown in FIG. The electric motor 2 according to the invention is a brushless electric motor, preferably a brushless DC motor, which is also referred to as an electrically commutating motor or power converter motor. The sensor system 3, by means of which the rotation of the rotor 5 of the electric motor 2 can be detected, comprises at least two digital Hall sensors, namely three digital Hall sensors 9 in the exemplary embodiment shown.

In the embodiment of FIG. 1, the rotor 5 of the brushless electric motor 3, namely the brushless DC motor, is mounted in the common housing 8 via an A-bearing 10 and a B-bearing 11. When A-bearing 10 is the output side bearing, the B-bearing 1 1 to the output side bearing opposite bearing. The A-bearing 10 is accommodated in a so-called A-bearing plate 12, the B-bearing in a so-called B-bearing plate 13. As the schematic representation of FIG. 1 can be seen, the Hall sensors 9 of the sensor 3 are positioned directly at the B-bearing plate 13. The digital Hall sensors 9 are preferably positioned between the B-end shield 13 and the electronics 4.

Then, when, as shown in the embodiment of Fig. 1, the B-end shield 13 covers a detected by the digital Hall sensors 9 magnetic field of the rotor 5 of the brushless DC motor 2, the rotor 5 of the electric motor 2, a Magnetgeberrad 14 is assigned. The Magnetgeberrad 14 rotates together with the rotor 5 of the brushless DC motor 2, so then the digital Hall sensors 9 detect the magnetic field of the Magnetgeberrads 14 so as to determine the position of the rotor 5 of the electric motor 2 indirectly. The Magnetgeberrad 14 is preferably positioned between the digital Hall sensors 9 of the sensor 3 and the B-bearing 1 1. In contrast to the exemplary embodiment shown in FIG. 1, it is possible that the B-end shield 13 does not obscure a magnetic field of the rotor 5 of the brushless DC motor 2 to be detected by the digital Hall sensors 9. In this case can be dispensed with the Magnetgeberrad 14, in which case the Hall sensors 9 detect the magnetic field of the rotor 5 directly, so as to determine its position directly.

Fig. 2 shows a second embodiment of an electromotive actuator 15 according to the invention, the rotor 5 of the brushless DC motor 2 is mounted exclusively via an A-bearing 10 with associated A-bearing plate 12 in the common housing 8. Thus, in the embodiment of FIG. 2 no B-bearing and thus no B-bearing plate available. In this case, can then be dispensed with a Magnetgeberrad, in which case the digital Hall sensors 9 of the sensor 3 can detect the magnetic field of the rotor 5 directly, so as to determine its location again directly. The Hall sensors 9 are then positioned immediately adjacent to an end remote from the A-end shield 12 of the rotor 5 of the electric motor 2, in such a way that they are arranged between this end of the rotor 5 of the electric motor 2 and the electronics 4.

Then, when, as shown in the embodiment of Fig. 1, a B-bearing plate 13 is present, which serves to receive the B-bearing 1 1, the same may, for example, as shown in Fig. 3, executed. Such a B-end shield is typically made of a magnetically ineffective material, for example made of aluminum or plastic.

According to Fig. 3, which shows a view of a front side 16 in a variant of a B-bearing plate 13, the B-bearing plate 13 has at this front side 1 6 via a pin 17, which serves to receive the B-bearing 1 1. The front side 1 6 of the B-bearing plate 13, which has the pin 17 is in the assembled state, the electric motor 2, namely the brushless DC motor, the electromotive actuator 1 faces.

On an opposite rear side of the B-bearing plate 13 has the same recesses 18, which are shown in dashed lines in the illustration of FIG. 3, since the same of the representation of FIG. 3 are covered by the front wall 1 6 of the B-bearing plate 13. In the recesses 18 find in the mounted state of the electromotive actuator 1, the Hall sensors 9 of the sensor 3 recording.

In the area of the recesses 18, therefore, the B-bearing plate 13 has a reduced wall thickness. Optionally, the wall thickness of the B-bearing plate 13 in the recesses 18 is so small that the Hall sensors 9 through the B-bearing plate 13 through the magnetic field of the rotor 5 of the electric motor 2 can detect directly, in which case optionally on the Magnetgeberrad 14th can be waived. Due to the closed front side 1 6 of the B-end shield 13, however, the Hall sensors 9 are protected from damage and / or contamination.

According to FIG. 4, the sensors 3 and the electronics 4 of the electromotive actuator 1 according to the invention are formed as a unit. This unit of electronics 4 and sensor 3 is, as already stated, positioned together with the brushless DC motor 2 of the actuator 1 according to the invention in the housing 8, wherein the relative position of the unit of electronics 4 and sensor 3 in the housing 8 via slots 1 9 defined is, in which in the assembled state of the actuator 1 according to the invention webs of the housing 8 engage.

The bearing plate 13, which in the assembled state of the electromotive actuator 1 according to the invention between the unit of electronics 4th and sensor 3 and the electric motor 2 is positioned as shown in FIG. 3 has a plurality of slots 20 which are distributed over the circumference of the B-bearing plate 13. Via these slots 20, it is possible in a simple manner to contact the electronics 4 with the electric motor 2, namely windings of the stator 6 of the electric motor 2. This contacting of the electronics 4 with the windings of the stator 6 via Kontaktierungsstifte 21, which extend through the slots 20 in the B-end shield 13 in the assembled state of the actuator 1. There are two pairs of Kontaktierungsstiften 21 for contacting the electronics 4 with the three phases of the brushless DC motor 2.

By way of further contacting pins 22, it is possible, for example, to contact a temperature sensor, which is installed in the electric motor 2, with the electronics 4. These Kontaktierungsstifte 22 extend in the mounted state of the actuator 1 through the slots 20 in the B-end shield 13th

The B-bearing plate 13 shown in Fig. 3 therefore has a pin 17 for receiving the actual B-bearing 1 1, via recesses 18 for receiving the digital Hall sensors 9 of the sensor 3 and via slots 20 through which for contacting the electronics. 4 with the windings of the stator 6 of the electric motor 2 and for contacting a temperature sensor with the electronics 4 Kontaktierungsstifte 21 and 22 extend.

The B-bearing plate 13 is made of a magnetically inactive material, wherein if the material thickness or wall thickness in the region of the recesses 18 is low enough, if necessary, directly through the B-bearing plate 13, a magnetic field of the rotor 5 of the electric motor 2 are detected can, in which case can be dispensed with a Magnetgeberrad 14. As already stated, the electronics 4 and the sensors 3 together form one unit. The electronics 4 can be designed as a thick-film hybrid circuit, in which case the electronics 4 is inserted into the B-end shield and after contacting the windings of the stator 6 of the electric motor 2 is shed with these. In this case, then form electronics 4, sensor 3, B-bearing plate 13 and the windings of the stator 6 of the electric motor 2 is a unit.

The electronics 4 can also be designed as a board with the interior of the same introduced active components, in which case the electronics forms a so-called active multilayer electronics. The electronics may in this case have a metallized surface to press the same directly into the B-end shield.

Furthermore, the electronics 4 can also be designed as a populated FR4 board. In this case, in turn, after contacting the electronics 4 with the windings of the stator 6 of the electric motor 2, electronics 4 with the end shield 13 can be cast into one unit.

Electromotive actuators according to the invention are particularly suitable for integration in moving assemblies, for example in a shaft rotating at high speed. For example, it is possible to integrate the electromotive actuator 1 or 15 according to the invention into a rotating shaft of an automated manual transmission. It is also possible to integrate the actuators according to the invention in other moving systems, such as in an active chassis.

The electromotive actuator according to the invention can be connected to a data bus via a bus interface (not shown in the drawing). Thus, for example, it is possible, depending on the application in which the electromotive actuator is installed, that it is connected via a bus interface to a CAN bus or a fieldbus system, such as a Profibus.

The electromotive actuator 1 or 15 can be supplied with voltage or current, for example with direct current or direct current, via a further, not-shown interface, wherein the voltage supply or current supply can have any voltage level or current level which depends on the voltage level Application is in which the electromotive actuator 1 or 15 is installed. In the electronics 4, a rectification of the supply voltage can be integrated, so that the actuator 1, 15 can be supplied with AC voltage of any frequency.

REFERENCE CHARACTERS

actuator

electric motor

sensors

electronics

runner

stand

mechanics

casing

Hall sensors

A-bearing

B-bearing

A-end shield

B-end shield

Magnetgeberrad

actuator

front

spigot

recess

slot

contacting pin

Claims

claims

1 . Electromotive actuator, with an electric motor, a sensor for detecting the rotation of a rotor of the electric motor, electronics for controlling and / or regulating the electric motor and a mechanism for transmitting or implementing a rotation of the rotor of the electric motor in a translational and / or rotational adjustment movement an actuatable by the actuator actuator, characterized in that the electric motor (2) as a brushless electric motor (2) is formed, which is positioned together with the sensor (3) and the electronics (4) in a common housing (8), wherein the Sensor (3) comprises at least two digital Hall sensors (9).

2. Electromotive actuator according to claim 1, characterized in that the rotor (5) of the brushless electric motor (2) in the common housing (8) via an A-end shield (12) and a B-end shield (13) is mounted.

3. Electromotive actuator according to claim 2, characterized in that the sensor (3) is positioned immediately adjacent to the B-end shield (13), such that the digital Hall sensors (9) between the B-end shield (13) and the electronics ( 4) are positioned.

4. Electromotive actuator according to claim 2 or 3, characterized in that when the B-end shield (13) covers one of the digital Hall sensors (9) to be detected magnetic field of the rotor (5) of the brushless electric motor (2), the rotor (5) a Magnetgeberrad (14) is assigned, which is positioned between the B-bearing (1 1) and the Hall sensors (9), in which case the Hall sensors (9) detect the magnetic field of the Magnetgeberrads (14) to the position of the Runner (5) to determine indirectly.

5. Electromotive actuator according to claim 2 or 3, characterized in that when the B-end shield (13) of the digital Hall sensors (9) to be detected magnetic field of the rotor (5) of the brushless electric motor (2) does not obscure the Hall sensors (9) detect the magnetic field of the rotor (5) to determine its location immediately.

6. Electromotive actuator according to one of claims 2 to 5, characterized in that the B-end shield (13) on a side facing the electric motor has a pin (17) which receives the B-bearing (1 1) of the rotor of the electric motor ,

7. Electromotive actuator according to one of claims 2 to 6, characterized in that the B-bearing plate (13) on a side facing away from the electric motor recesses (18) for receiving the Hall sensors (9), wherein in the region of the recesses (18) a wall thickness of the B-end shield (13) is reduced.

8. Electromotive actuator according to one of claims 2 to 7, characterized in that the B-bearing plate (13) distributed over the circumference of a plurality of slots (20) via which the electronics (4) with windings of a stator (6) of the electric motor (2) is contacted.

9. Electromotive actuator according to claim 1, characterized in that the rotor (5) of the brushless electric motor (2) is mounted in the common housing (8) exclusively via an A-end shield (12).

10. Electromotive actuator according to claim 9, characterized in that the sensor (3) is positioned immediately adjacent to the A-end shield (12) facing away from the end of the rotor (5), such that the digital Hall sensors (9), the magnetic field of the Runner (5) capture to detect its location immediately.

1 1. Electromotive actuator according to one of Claims 1 to 10, characterized in that the sensor system (3) and the electronics (4) form a unit.

12. Electromotive actuator according to one of claims 1 to 1 1, characterized in that the brushless electric motor (2) is a brushless DC motor.

13. Electromotive actuator according to one of claims 1 to 12, characterized in that in the electronics (4) a rectification of a supply voltage is integrated.