FR3083191A1 - MOTOR-REDUCER, WIPING SYSTEM AND CONTROL METHOD THEREOF - Google Patents

Abstract

The present invention relates to a gear motor (101), in particular for a wiping system of a motor vehicle, comprising: - an electric motor (103) comprising a rotor (103a) and a stator (103b), - a device (105) for determining the angular position of the rotor (103a) relative to the stator (103b) comprising a sensor (105b) associated with the stator (103b) and a control magnet (105a) coupled in rotation to the rotor (103a), a reduction mechanism (107) comprising a first gear element (107a) coupled in rotation to the rotor (103a), said first gear element (107a) comprising a first bearing (109) and a second bearing (111), - a protective casing (108) of the reduction mechanism (107) comprising a first housing (113) and a second housing (115) configured to receive the first bearing (109) and the second bearing (111) respectively, characterized in that the gear motor (101) also includes a removable hand element axial (117) associated with the first bearing (109) and coming against the protective casing (108) of the reduction mechanism (107) and in that the control magnet (105a) is disposed next to the second bearing (111) , on the side opposite the first bearing (109), the diameter of the control magnet (105a) being greater than the diameter of the second bearing (111) and covering the latter at least partially.

Description

MOTOR-REDUCER, WIPING SYSTEM AND CONTROL METHOD THEREOF

The present invention relates to a gear motor and in particular a gear motor for wiping systems of a motor vehicle.

The gearmotors are essentially composed of an electric motor coupled to a reduction mechanism responsible for increasing the speed to obtain a high rotational transmission torque.

The connection between the electric motor and the reduction mechanism is generally carried out by a first gear element, for example a worm, fixed on the shaft of the electric motor and configured to cooperate with a second gear element, by example a gear wheel. The respective diameters of the worm and the gear allow the desired reduction ratio to be obtained.

However, such a reduction mechanism requires that the worm screw be kept in position relative to the toothed wheel to ensure the correct functioning of the reduction mechanism.

FIG. 1 represents an exemplary embodiment of a geared motor 1 of the state of the art. The toothed wheel 3 is arranged in a protective casing 5 of the reduction mechanism while the electric motor 7 is fixed on the protective casing 5 via a fixing element 9, the fixing element 9 being rigidly fixed on the protective casing 5, for example by fixing screws. The worm 11 extends between a first bearing 13 held in position in a housing 15 of the first casing 5 and a second bearing 17 held in position in a housing 19 of the fixing element 9.

Such an embodiment requires a good alignment of the elements supporting the bearings, that is to say of the casing 5 and of the fixing element 9 which implies a low tolerance of the dimensions of manufacture of the casing 5 and of the fastening element 9 as well as careful assembly of the assembly which implies a high manufacturing cost.

In order to at least partially overcome these drawbacks of the state of the art, the present invention aims to provide a geared motor having a reduced production cost and a simplified assembly while being compact so as to limit the size of the motorcycle. reducer which is an additional constraint in the automotive field.

To this end, the present invention relates to a gear motor, in particular for a wiping system of a motor vehicle, comprising:

- an electric motor comprising a rotor and a stator,

a device for determining the angular position of the rotor relative to the stator comprising a sensor associated with the stator and a control magnet coupled in rotation to the rotor,

a reduction mechanism comprising a first gear element coupled in rotation to the rotor, said first gear element comprising a first bearing and a second bearing,

- a protective casing of the reduction mechanism comprising a first housing and a second housing configured to receive the first bearing and the second bearing respectively, characterized in that the gearmotor also comprises a removable axial holding element associated with the first bearing and coming against the protective casing of the reduction mechanism and in that the control magnet is arranged next to the second bearing, on the side opposite to the first bearing, the diameter of the control magnet being greater than the diameter of the second bearing and covering the latter at less partially.

According to another aspect of the present invention, the removable axial holding element is configured to be placed in the protective casing of the reduction mechanism.

According to a further aspect of the present invention, the gear motor also comprising a support of generally hollow cylindrical shape with a circular bottom, said circular bottom comprising a central opening coming to be positioned around the rotor outside the protective casing, said support carrying the control magnet so as to position this control magnet at least partially around the second housing.

According to another aspect of the present invention, the control magnet is disposed at a first distance from the axis of rotation of the rotor and the sensor of the angular position determination device is disposed at a second distance from the axis of rotor rotation less than the first distance.

According to another aspect of the present invention, the control magnet is disposed at a first distance from the axis of rotation of the rotor and the sensor of the angular position determination device is disposed at a second distance from the axis of rotor rotation greater than the first distance.

According to another aspect of the present invention, the sensor of the device for determining the angular position is a Hall effect sensor.

According to another aspect of the present invention, the sensor of the device for determining the angular position is arranged on the electronic circuit of the geared motor.

According to another aspect of the present invention, the gear motor also comprises an elastic element disposed between the second bearing and the support and configured to serve as a spacer between the support and the second bearing.

According to another aspect of the present invention, the first and second bearings are substantially identical.

The present invention also relates to a wiping system, in particular for a motor vehicle comprising a geared motor as described above.

The present invention also relates to a method for mounting a gear motor for wiping systems, the gear motor comprising:

- an electric motor comprising a rotor and a stator,

a device for determining the angular position of the rotor relative to the stator comprising a sensor associated with the stator and a control magnet coupled in rotation to the rotor,

a reduction mechanism comprising a first gear element coupled in rotation to the rotor, said first gear element comprising a first bearing and a second bearing, and a second gear element intended to cooperate with the first gear element,

a protective casing of the reduction mechanism comprising first and second housings configured to receive the first and second bearings respectively,

- a removable axial holding element associated with the first bearing,

a support configured to be positioned around the rotor outside the protective casing, said support carrying the control magnet, the method comprising the following steps:

- the first gear element is mounted in the protective housing of the reducing mechanism by translation so that the first bearing is in the first housing of the protective housing of the reducing mechanism and that the second bearing is in the second housing of the housing protection of the reduction mechanism,

- the second gear element is mounted in the protective casing of the reduction mechanism,

- the removable axial holding element is mounted at the level of the first housing bearing against the protective housing of the reduction mechanism,

- Mount the support with the control magnet on the rotor so that the control magnet is positioned at least partially around the second housing (115).

Other characteristics and advantages of the invention will emerge from the following description, given by way of example and without limitation, with reference to the appended drawings in which:

Figure 1 shows a diagram of a gear motor according to the state of the art, Figure 2 shows a diagram of a gear motor according to a first embodiment of the present invention Figure 3 shows a diagram of a motor-reducer according to a second embodiment of the present invention, FIG. 4 represents a flow diagram of the steps of the method of mounting the motor-reducer.

In all the figures, identical elements have the same reference numbers.

The following embodiments are examples. Although the description refers to one or more embodiments, this does not necessarily mean that each reference relates to the same embodiment or that the characteristics apply only to a single embodiment. Simple features of different embodiments can also be combined or interchanged to provide other embodiments.

FIG. 2 represents an example of a geared motor 101 intended to equip a motor vehicle wiping system.

The gear motor 101 comprises an electric motor 103 comprising a rotor 103a and a stator 103b as well as a device 105 for determining the angular position of the rotor 103a relative to the stator 103b comprising a sensor 105b associated with the stator 103b and a magnet control 105a (for example an alternating ring of north and south poles) coupled in rotation to the rotor 103a. The sensor 105b is for example a Hall effect sensor disposed on an electronic circuit of the geared motor 101, in particular a printed circuit.

As will be described in more detail below, the control magnet 105a is disposed next to the second bearing 111, on the side opposite to the first bearing 109, the diameter of the control magnet 105a being greater than the diameter of the second bearing 111 and covering the latter at least partially to reduce the size of the geared motor 101, in particular in the axial direction of the rotor 103a.

The gear motor 101 also includes a reduction mechanism 107 comprising a first gear element 107a coupled in rotation to the rotor 103a of the electric motor 103, for example a worm, and a second gear element 107b, for example a wheel toothed, intended to cooperate with the first gear element 107a to provide a reduction ratio at the output of the reduction mechanism 107. The output of the reduction mechanism 107 corresponds for example to an output shaft fixed on the axis of rotation of the gear 107b. The gear motor 101 also includes a protective casing 108 of the reducing mechanism 107 in which the said reducing mechanism 107 is positioned. The protective casing 108 is for example formed by a shell and a cover fixed one to the other. other, for example by fixing screws.

In order to ensure correct positioning of the endless screw 107a and therefore proper functioning of the reduction mechanism 107, the endless screw 107a comprises a first guide bearing 109 and a second guide bearing 111 to allow it to pivot along the axis of the rotor 103a while ensuring its maintenance in the radial directions. The first bearing 109 is configured to be placed in a first housing 113 of the protective casing 108. The first housing 113 is for example a blind housing of cylindrical shape. The second guide bearing 111 is configured to come to be placed in a second housing 115 of the protective casing 108. The second housing 115 is for example a through housing of cylindrical shape allowing the passage of the worm screw 107a in the protective casing 108. The first guide bearing 109 and the second guide bearing 111 can be identical so as to reduce the reference number and thus facilitate manufacturing and reduce associated costs.

The gear motor 101 also includes a removable axial retaining element 117 configured to be positioned against the protective casing 108 of the reduction mechanism 107 at the level of the first housing 113 for example in a slot extending perpendicular to the axis of the cylinder. of the first housing 113. Thus, the removable axial holding element 117 is configured to ensure the axial holding of the first guide bearing 109.

The gear motor 101 also includes a support 119 rotatably coupled to the rotor 103a and carrying the control magnet 105a. The support 119 has in the present embodiment in a generally hollow cylindrical shape with a bottom of circular shape having a central opening traversed by and positioned around the rotor 103a. The support 119 can be locked in translation relative to the rotor 103a in the axial direction, for example by a force fitting or a mounting in a groove or using a retaining ring or pin or any other known means of the skilled in the art. The support 119 is disposed outside the protective casing 108 and is positioned near the protective casing 108 of the reduction mechanism 107 around the second housing 115. An elastic element 121, such as an elastic ring or a spring, can be disposed between the support 119 and the second guide bearing 111. The elastic element 121 is then configured to form a spacer between the support 119 and the second housing 115.

In addition, the support 119 carries the control magnet 105a of the device 105. The support 119 therefore comprises a central part in the form of a disc configured to extend radially around the axis of the rotor 103a and a cylindrical peripheral part which s 'extends axially from the central part. The control magnet 105a is for example disposed at the peripheral part and at least partially surrounds the second housing 115, which makes it possible to reduce the overall dimensions of the geared motor 101.

According to a first embodiment shown in FIG. 2, the peripheral part of the support 119 is configured to be located at a first distance from the axis of the rotor 103a and the control magnet 105a is disposed on the external side of said part peripheral. The sensor 105b of the device 105 is then configured to be disposed at a second distance from the axis of the rotor 103a, greater than the first distance and facing the control magnet 105a.

According to a second embodiment shown in FIG. 3, the peripheral part of the support 119 is configured to be located at a third distance from the axis of the rotor 103a and the control magnet 105a is disposed on the internal side of said part peripheral. The sensor 105b of the device 105 is then configured to be placed at a fourth distance from the axis of the rotor 103a, less than the third distance and facing the control magnet 105a.

In both embodiments, the sensor 105b can be placed on a printed circuit fixed to the protective casing 108.

The electric motor 103 can be fixed to the protective casing 108 of the reduction mechanism 107 by a connecting piece 123 intended to be fixed to the protective casing 108, for example by fixing screws and to receive the electric motor 103. The motor electric 103 is for example force-fitted into a housing of the fixing piece 123 or is fixed by fixing screws to the said fixing piece. Other fixing means known to a person skilled in the art can be used for fixing the electric motor 103 to the fixing piece 123 or for fixing the fixing piece 123 to the protective casing 108 of the reduction mechanism 107.

Thus, the use of a removable axial retaining element 117 configured to be fixed on the protective casing 108 of the reduction mechanism 107 allows easy mounting of the geared motor 101 and allows the use of two identical bearings 109, 111 which which reduces costs. Furthermore, the use of a support 119 of generally hollow cylindrical shape coupled in rotation to the rotor 103a and comprising the control magnet 105a of the device 105 for determining the angular position of the rotor 103a makes it possible to reduce the size of the gearmotor. 101.

The present invention also relates to a wiping system, in particular for a motor vehicle, comprising a geared motor 101 as described above.

The different stages of the assembly process will now be described from the flow diagram in FIG. 4.

The first step 201 relates to the mounting of the first gear element 107a of the reduction mechanism 107 in the protective casing 108 of the reduction mechanism 107. This mounting is for example carried out by a translation along the axis of the rotor 103a in order to pass through. the opening located at the second housing 115. Thus, the first gear element 107a is threaded through its first bearing 109 through this opening. The translation is carried out until the first bearing 109 is in the first housing 113 of the protective casing 108 of the reducing mechanism 107 and the second bearing 111 is in the second housing 115 of the protective casing 108 of the reducing mechanism 107.

The second step 202 relates to the mounting of the second gear element 107b in the protective casing 108 of the reduction mechanism 107. The second gear element is arranged so as to come to mesh with the first gear element 107a. The second gear element 107b is for example mounted on the protective casing 108 via a bearing.

The third step 203 relates to the mounting of the removable axial retaining element 117 at the level of the first housing 113. The removable axial retaining element 117 is for example configured to be positioned in a slot formed in the protective casing 108 and oriented at least partially perpendicular to the axis of the first gear element 107a. Thus, the removable axial retaining element 117 bears against the protective casing 108 of the reduction mechanism 107.

The fourth step 204 relates to the mounting of the support 119 on the rotor 103a outside the protective casing 108 and at the level of the second housing 115. The support 119 is for example force-fitted around the rotor 103a then slide to come close of the protective casing 108 of the reduction mechanism 107 on the side of the second bearing 111 which is opposite to the first bearing 109, and at least partially surround the second housing 115. Alternatively, the support 119 can be retained axially on the rotor 103a by a pin or a retaining screw.

The fifth step 205 relates to the closing of the protective cover 108. A cover of the protective casing 108 is for example fixed on the shell in which the first and second housings 113, 115 are formed.

The sixth step 206 relates to the fixing of the electric motor 103 to the protective casing 108 of the reduction mechanism 107, for example via a fixing piece 123 and fixing screws or any other fixing means.

Claims (11)

1. Gear motor (101), in particular for a wiping system of a motor vehicle, comprising: - an electric motor (103) comprising a rotor (103a) and a stator (103b), a device (105) for determining the angular position of the rotor (103a) relative to the stator (103b) comprising a sensor (105b) associated with the stator (103b) and a control magnet (105a) coupled in rotation to the rotor ( 103a), a reduction mechanism (107) comprising a first gear element (107a) coupled in rotation to the rotor (103a), said first gear element (107a) comprising a first bearing (109) and a second bearing (111), - a protective casing (108) of the reduction mechanism (107) comprising a first housing (113) and a second housing (115) configured to receive the first bearing (109) and the second bearing (111) respectively, characterized in that the gearmotor (101) also includes a removable axial holding element (117) associated with the first bearing (109) and coming against the protective casing (108) of the reduction mechanism (107) and in that the control magnet (105a ) is arranged next to the second bearing (111), on the side opposite to the first bearing (109), the diameter of the control magnet (105a) being greater than the diameter of the second bearing (111) and covering the latter at least partially .. 2. Geared motor (101) according to claim 1 wherein the removable axial holding element (117) is configured to be disposed in the protective casing (108) of the reducing mechanism (107). 3. Gear motor (101) according to claim 1 or 2 also comprising a support (119) of generally hollow cylindrical shape with a circular bottom, said circular bottom comprising a central opening coming to be positioned around the rotor (103a) at the outside of the protective casing (108), said support (119) carrying the control magnet (105a) so as to position this control magnet (105a) at least partially around the second housing (115). 4. Geared motor (101) according to one of the preceding claims wherein the control magnet (105a) is disposed at a first distance from the axis of rotation of the rotor (103a) and the sensor (105b) of the device (105) for determining the angular position is arranged at a second distance from the axis of rotation of the rotor (103a) less than the first distance. 5. Gear motor (101) according to claim 1 or 2 wherein the control magnet (105a) is disposed at a first distance from the axis of rotation of the rotor (103a) and the sensor (105b) of the device ( 105) for determining the angular position is arranged at a second distance from the axis of rotation of the rotor (103a) greater than the first distance. 6. Geared motor (101) according to one of the preceding claims wherein the sensor (105b) of the device (105) for determining the angular position is a Hall effect sensor. 7. Gear motor (101) according to one of the preceding claims in which the sensor (105b) of the device (105) for determining the angular position is arranged on the electronic circuit of the gear motor (101). 8. Gear motor (101) according to one of the preceding claims in combination with claim 3 also comprising an elastic element (121) disposed between the second bearing (111) and the support (119) and configured to serve as a spacer between the support (119) and the second bearing (111). 9. Gear motor (101) according to one of the preceding claims in which the first and second bearings (109, 111) are substantially identical. 10. Wiping system, in particular for a motor vehicle comprising a geared motor (101) according to one of the preceding claims. 11. Method for mounting a geared motor (101) for wiping systems, the geared motor (101) comprising: - an electric motor (103) comprising a rotor (103a) and a stator (103b), a device (105) for determining the angular position of the rotor (103a) relative to the stator (103b) comprising a sensor (105b) associated with the stator (103b) and a control magnet (105a) coupled in rotation to the rotor ( 103a), a reduction mechanism (107) comprising a first gear element (107a) coupled in rotation to the rotor (103a), said first gear element (107a) comprising a first bearing (109) and a second bearing (111), and a second gear element (107b) intended to cooperate with the first gear element (107a), - a protective casing (108) of the reduction mechanism (107) comprising a first (113) and a second (115) housings configured to receive the first (109) and the second (111) bearings respectively, - a removable axial holding element (117) associated with the first bearing (109) - A support (119) configured to be positioned around the rotor (103a) outside the protective casing (108), said support (119) carrying the control magnet (105a), the method comprising the following steps : - the first gear element (107a) is mounted in the protective casing (108) of the reduction mechanism (107) by translation so that the first bearing (109) is in the first housing (113) of the protective casing ( 108) of the reduction mechanism (107) and that the second bearing (111) is in the second housing (115) of the protective casing (108) of the reduction mechanism (107), (201) - the second gear element (107b) is mounted in the protective casing (108) of the reduction mechanism (107), (202) the removable axial retention element (117) is mounted at the level of the first housing (113) bearing against the protective casing (108) of the reduction mechanism (107), - Mount the support (119) with the control magnet (105a) on the rotor (103a) so that the control magnet (105a) is positioned at least partially around the second housing (115).