EP3254363A1 - Drive unit for a wiper system - Google Patents

Abstract

The invention relates to a drive unit (100) for a wiper system, comprising an electronically commutated drive motor (10) having a drive shaft (15), and a transmission (50) having an output shaft (60) that can be driven by the drive shaft (15). According to the invention, at least one angular position sensor (80) for determining a respective angular position of the output shaft (60) is assigned to the output shaft (60) of the transmission (50).

Description

 description

title

 Drive unit for a Wischersvstem prior art

The present invention relates to a drive unit for a wiper system, with an electronically commutated drive motor having a drive shaft, and with a transmission having an output shaft drivable by the drive shaft. Moreover, the present invention relates to a method for

Determining an angular position of a drive shaft of an electronically commutated drive motor of such a drive unit.

Such drive units for wiper systems are known from the prior art. For example, DE 10 2009 047 566 A1 describes a drive unit for a windshield wiper, in which a drive shaft is driven by an electric motor and connected via a worm gear with an output element, wherein the electric motor is pivotally mounted, so that a distance between the axis of the output element and the drive shaft is adjustable.

From DE 10 2009 055 396 A1 a drive unit for a wiper system is known in which a drive motor and a worm gear are arranged in a common housing. Furthermore, from DE 10 2009 055 396 A1 a sensor for detecting a rotational position of a rotor of the drive motor is known, which is arranged in the common housing in order to control the electrical control of the drive motor forming brushless DC motor. From DE 10 2010 064 151 A1 a wiper motor is also known, the one

Gearbox is assigned, in which a driven via a drive wheel output shaft is rotatably mounted. Here, on the drive wheel, a contact fastened, which is designed to short circuit of two arranged in the transmission housing shorting elements to allow for switched off wiper motor displacement of the wiper motor driven by wiper arms in an associated parking position.

A disadvantage of this prior art is that the respective drive units are relatively complex and expensive and therefore not very suitable for opening up new markets in the hitherto less industrially developed regions of the world, the so-called "emerging markets" are.

Disclosure of the invention

An object of the invention is therefore to provide a drive unit for a wiper system, which is inexpensive to produce and in particular can dispense with a drive shaft associated with an angular position sensor for controlling a corresponding, electronically commutated drive motor.

This problem is solved by a drive unit for a wiper system, with an electronically commutated drive motor having a drive shaft, and with a transmission having an output shaft driven by the drive shaft. In this case, the output shaft of the transmission is associated with at least one angular position sensor for determining a respective angular position of the output shaft.

This eliminates an additional angular position sensor on the drive shaft of the drive motor, which reduces the cost of the drive unit and simplifies the structure according to the invention.

According to an advantageous development it is provided that the drive motor is designed in the manner of a brushless DC motor.

A brushless DC motor is particularly easy and accurate to control and regulate, so that a particularly precise speed control even at low speeds, as they typically occur in drive units for wiper systems, is possible. According to a further advantageous embodiment, it is provided that the drive shaft of the drive motor and the output shaft of the transmission are arranged at a predetermined angle to each other, in particular at right angles. This makes it possible to realize a compact and space-saving design of the drive unit, whereby the transmission housing can be made compact and small, which saves weight and manufacturing costs. Thus, the goal of a relatively inexpensive drive unit is achieved. According to one embodiment it is provided that on the output shaft of the

Gear is arranged a driven by the drive shaft of the drive motor gear, which is designed in particular as a gear.

As a result, a safe and reliable power transmission between the drive shaft and output shaft can be realized, which increases the durability and robustness of the drive unit as a whole. Thus, a smooth and shock-free transmission of force and torque is achieved by the drive shaft to the output shaft.

It is particularly preferred if the at least one angular position sensor is arranged at least partially on the gear wheel.

This provides an easy way to detect the speed of the output shaft, since the output shaft and the gear are rotatably connected to each other and rotate at the same speed. Thus, no additional component for receiving the angular position sensor is necessary.

According to one embodiment, the at least one angular position sensor has a signal transmitter and a signal receiver operatively connected to the signal receiver, wherein the signal transmitter is arranged on the gear wheel.

Although in principle a reverse arrangement with signal receiver on the gear is conceivable, it is easier, for example, due to the less expensive signal management when the signal receiver is stationary, for example, to allow electrical contacting of the signal receiver.

It is particularly preferred if the signal generator is designed as a magnet. Such a magnet can be easily and inexpensively integrated into the gear and requires no additional power supply, but permanently emits a signal in the form of its magnetic field. This signal is reliable, easy and inexpensive to detect with known signal receivers and sufficiently accurate for a determination of an angular position.

Alternatively, an embodiment is provided in which the signal generator is designed as an optical signal generator.

This can be done in a simple form by a marking, preferably in white or black, on the surface of the gear, wherein the mark should clearly settle on the color of a corresponding base material of the gear. Such a signal generator can then be easily detected by a signal receiver in the manner of a photocell. Such a solution is also relatively easy and inexpensive to implement.

According to a preferred embodiment, it is provided that the transmission has a gear housing, in which the drive shaft of the drive motor and the output shaft of the transmission are arranged at least in sections at the predetermined angle to each other.

Through the gear housing, the meshing teeth of the drive shaft and the output shaft are protected from contamination. In addition, a bearing of the drive shaft or the output shaft can be integrated in such a transmission housing, whereby the maintenance of the predetermined angle between the drive shaft and output shaft is facilitated and a bend, or a deflection of the respective shaft can be reduced.

An advantageous development is that the transmission housing has a cover, wherein in the cover an evaluation and / or a control unit are integrated.

Through the lid, the gear housing can be closed at least on one side, whereby the risk of contamination and damage is reduced. Integrating the controller and or transmitter in the lid offers several advantages. On the one hand, a short way and thus ne short signal line between evaluation and control unit can be realized, which protects the signal from interference. On the other hand, a receptacle for the control unit and / or the evaluation can be easily integrated into the lid, especially when the lid is designed as a plastic injection molded part. In addition, the control unit and transmitter are protected by the lid against contamination and damage, which in turn increases the longevity of the drive unit as a whole.

According to one embodiment, it is provided that the at least one angular position sensor is an absolute angle sensor.

As a result, no additional effort in determining the angular position of the output shaft is required.

According to a further advantageous embodiment, it is provided that the transmission is designed in the manner of a worm gear.

Worm gears are particularly suitable for high gear ratios at low speeds and are therefore preferred in the proposed drive unit for a wiper system.

The problem is also solved by a method for determining an angular position of a drive shaft of an electronically commutated drive motor of a drive unit for a wiper system, wherein the drive unit has a transmission with an output shaft driven by the drive shaft. In this case, a Abtnebswellenwinkellage the output shaft of the transmission is determined in a first step by means of at least one of the output shaft associated angular position sensor, and in a second step, a drive shaft angular position of the drive shaft of the drive motor is determined based on the determined Abtnebswellenwinkellage.

This eliminates an additional angular position sensor on the drive shaft of the drive motor, which significantly reduces the cost of the wiper drive.

An improvement of the proposed method is that based on the drive shaft angle position of the drive shaft, a commutation of the drive motor is controlled. Thus, the drive motor can be commutated at the optimum time, which reduces the energy requirement of the drive motor.

According to a further improvement, it is provided that the determination of the Abtnebswellenwinkellage the output shaft and / or the Antriebswellenwinkella- ge of the drive shaft by an associated evaluation electronics.

As a result, the signal of the signal receiver can easily be prepared electronically and transmitted to the control unit.

It is particularly preferred if the commutation of the drive motor is performed by an associated control unit.

The controller can be used to control the electronically commutated drive motor at the determined, respectively optimal times.

Short description of the drawing

The invention is explained in more detail in the following description with reference to an embodiment shown in the drawing. It shows:

Fig. 1 is an exploded view of a drive unit according to the invention for a wiper system.

Description of the embodiment

1 shows an exemplary embodiment of a drive unit 100 according to the invention for a wiper system. The drive unit 100 preferably has an electronically commutated drive motor 10, which is preferably designed as a brushless DC motor 1 1 in the illustrated embodiment and for the invention. This drive motor 10 illustratively has a rotor 20 which is non-rotatably connected to a drive shaft 15 and drives this drive shaft 15. The drive motor 10 also has a housing 25 and at least one bearing 29, wherein the drive shaft 15 of the drive motor 10 or the rotor 20 is preferably mounted rotatably in the housing 25 via the bearing 29. The drive unit 100 further has a gear 50 with an output shaft 60 which can be driven by the drive shaft 15. The drive shaft 15 of the drive motor 10 and the output shaft 60 of the transmission 50 are preferably arranged at a predetermined angle to each other, preferably as shown in the embodiment perpendicular to each other.

The output shaft 60 of the transmission 50 is assigned at least one angular position sensor 80, preferably exactly one angular position sensor 80, for determining a respective angular position of the output shaft 60. The angular position sensor 80 is preferably designed as an absolute angle sensor.

The transmission 50 preferably has a gear housing 55, in which the drive shaft 15 of the drive motor 10 and the output shaft 60 of the transmission 50 are at least partially arranged at the predetermined angle to each other, wherein in the embodiment, the preferred rectangular arrangement of drive shaft 15 and output shaft 60 shown is. In an opening of the transmission housing 55, a bearing bush 51 is preferably introduced, in which the output shaft 60 is rotatably mounted, wherein the bearing bush 51 is preferably fixed with a snap ring 53 in the gear housing 55.

On the output shaft 60 of the transmission 50 is a drivable by the drive shaft 60 of the drive motor 10 gear 70, in particular a gear arranged. In this case, the angular position sensor 80 is at least partially disposed on the gear 70.

The angular position sensor 80 preferably has a signal transmitter 72 and a signal receiver 52 operatively connected to the signal receiver 52, wherein the signal transmitter 72 is arranged on the gear 70. In this case, the signal generator 72 is formed as a magnet 73, which is preferably arranged approximately centrally in the middle of the gear 70. The position shown in FIG. 1 serves only to illustrate the possible use of a magnetic signal transmitter 73, but not to determine a specific position on the gear 70, which is preferably centric as described above. Alternatively, the signal generator 72 may be formed, for example, as an optical signal generator 74. The with this signal generator 72 in operative connection standing signal receiver 52 is arranged for example in the transmission housing 55.

The transmission housing 55 preferably has a cover 90 into which an evaluation electronics 92 and a control unit 94 are integrated. Alternatively, only the transmitter 92 or only the controller 94 may be integrated into the lid 90. Furthermore, it is possible to arrange the signal receiver 52 in the cover 90 of the transmission housing 55. In the illustrated embodiment, the drive shaft 15 and the output shaft 60 are connected to each other via a worm gear, wherein the drive shaft 15 is formed by way of example as a worm shaft which engages in the example designed as a gear gear 70 of the output shaft 60. Alternatively, however, other forms of transmission are also conceivable, although a worm gear is preferred due to a possible speed ratio and current production costs.

During operation of the drive unit 100, the electronically commutated drive motor 10 is energized and thus brings the drive shaft 15 to rotate. About trained in the manner of a worm gear 50, the rotation of the drive shaft 15 is transmitted to the output shaft 60. In this case, in an initial step, an angular position of the output shaft 15 can be determined by the angular position sensor 80 via the signal generator 72 and the signal receiver 52, which generate a signal for the control unit 94 by the evaluation electronics 92. Depending on the angular position of the output shaft 60, a drive shaft angle position of the drive shaft 15 of the drive motor 10 can be determined in a second step. About the thus determined drive shaft angle position of the drive shaft 15, a commutation of the drive motor 10 can be controlled by the controller 94.

For this purpose, in the case of the production of the drive unit 100 in the control unit 94, for example, a respective optimal commutation time is programmed for the respective electronically commutated drive motor 10 and a position of the rotor 20 relative to a respective absolute angle on the output shaft 60 is specified. In the control unit 94, the current position of the absolute angle sensor 80 is determined on the gear 70 and stored and made a reference to the optimal commutation of the drive motor 10. About the control advises 94 and the software implemented therein calculates the controller 94 all other Kommutierungszeitpunkte based on the ratio of the transmission 50 between the drive shaft 15 and output shaft 60, and a Polpaarzahl the electronically commutated DC motor 10th

Claims

claims 1 . Drive unit (100) for a wiper system, comprising an electronically commutated drive motor (10) having a drive shaft (15) and a transmission (50) having an output shaft (60) drivable by the drive shaft (15), characterized in that the output shaft (60) of the transmission (50) is associated with at least one angular position sensor (80) for determining a respective angular position of the output shaft (60). 2. Drive unit according to claim 1, characterized in that the drive motor (10) leads out in the manner of a brushless DC motor (1 1). 3. Drive unit according to claim 1 or 2, characterized in that the drive shaft (15) of the drive motor (10) and the output shaft (60) of the transmission (50) are arranged at a predetermined angle to each other, in particular at right angles. 4. Drive unit according to claim 3, characterized in that on the output shaft (60) of the transmission (50) one of the drive shaft (15) of the drive motor (10) drivable gear (70) is arranged, in particular a gear. 5. Drive unit according to claim 4, characterized in that the Minim least one angular position sensor (80) at least partially on the gear (70) is arranged. 6. Drive unit according to claim 4 or 5, characterized in that the at least one angular position sensor (80) has a signal generator (72) and one with the signal generator (72) in operative connection signal receiver (52), wherein the signal generator (72) on the gear wheel (70) is arranged. 7. Drive unit according to claim 6, characterized in that the signal generator (72) is designed as a magnet (73). 8. Drive unit according to claim 6, characterized in that the signal generator (72) is designed as an optical signal transmitter (74). 9. Drive unit according to one of claims 3 to 8, characterized in that the transmission (50) has a gear housing (55), in which the drive shaft (15) of the drive motor (10) and the output shaft (60) of the gear ( 50) are arranged at least partially in the predetermined angle to each other. 10. Drive unit according to claim 9, characterized in that the gear housing (55) has a cover (90), wherein in the lid (90) an evaluation (92) and / or a control unit (94) is integrated. 1 1. Drive unit according to one of the preceding claims, characterized in that the at least one angular position sensor (80) is an absolute angle sensor. 12. Drive unit according to one of the preceding claims, characterized in that the transmission (50) is designed in the manner of a worm gear. 13. A method for determining an angular position of a drive shaft (15) of an electronically commutated drive motor (10) of a drive unit (100) for a wiper system, wherein the drive unit (100) comprises a transmission (50) with one of the drive shaft (15) drivable output shaft (15). 60), characterized in that in a first step by means of at least one of the output shaft (60) associated angular position sensor (80) a Abtnebswellenwinkellage the output shaft (60) of the transmission (50) is determined, and in a second step on the basis of the determined Abtweebswellenwinkellage a drive shaft angular position of the drive shaft (15) of the drive motor (10) is determined. 14. The method according to claim 13, characterized in that based on the drive shaft angle position of the drive shaft (15) a commutation of the drive motor (10) is controlled. 15. The method according to claim 13 or 14, characterized in that the determination of the output shaft angle position of the output shaft (60) and / or the Antnebswellenwinkellage the drive shaft (15) by an associated evaluation electronics (92). 16. The method according to claim 14, characterized in that the commutation of the drive motor (10) by an associated control unit (94).