EP4291793A1

EP4291793A1 - Electromotive drive unit for motor vehicle applications

Info

Publication number: EP4291793A1
Application number: EP22708289.8A
Authority: EP
Inventors: Frank Kunst
Original assignee: Kiekert AG
Current assignee: Kiekert AG
Priority date: 2021-02-15
Filing date: 2022-01-26
Publication date: 2023-12-20
Also published as: WO2022171233A1; KR20230144043A; JP2024507175A; DE102021103444A1; CN117062995A

Abstract

The invention relates to an electromotive drive unit for motor vehicle applications, said drive unit being equipped with an electric motor (4) comprising an output shaft (5), which has a substantially circular cross-section, and a drive element (6), which is preferably made of plastic and is assembled on the output shaft (5). The output shaft (5) engages into a receiving bore (9) of the drive element (6), thereby defining at least one ventilation bore (10). According to the invention, one variant of the output shaft (5) has two mutually spaced webs (11) which extend axially in the manner of a chord at least in the engagement region (E) of the receiving bore (9). A protrusion (13) of the drive element (6) engages between the webs (11) in order to produce a rotary coupling. Each of the two webs (11) additionally describes a respective ventilation bore (10) on the outer edge.

Description

description

Electromotive drive unit for automotive engineering

applications

The invention relates to an electromotive drive unit for motor vehicle applications, with an electric motor with an output shaft that is essentially circular in cross section, and with a drive element mounted on the output shaft, preferably made of plastic, for example as part of a transmission, the output shaft being inserted into a receiving bore of the drive element by definition engages at least one vent hole.

Such electromotive drive units for motor vehicle-technical applications are used by way of example and not restrictively as actuators in or on motor vehicle locks, for adjusting motor vehicle seats, headlights, mirrors or in connection with window regulators. Consequently, the electric motor of the relevant electromotive drive unit is typically operated with a low direct current of 12 V, 24 V or also 48 V. However, in order to be able to realize and implement sometimes power-sapping positioning movements, rotary movements of the fast-running output shaft of the electric motor are translated using the usually provided and downstream gearbox, which usually includes the drive element. The drive element as such can be, for example, a worm which, together with a worm wheel, forms and defines the gear mechanism in question. Such worm gears are generally known in connection with motor vehicle applications, for which reference is only made to DE 10 2009 036 834 A1 or DE 103 60 419 A1 as an example.

Since relatively high forces are sometimes transmitted using the gear or the drive element, the constructive connection between the Output shaft and the mounting hole of the drive element (made of plastic) are of particular importance. In fact, output shafts that have a D-shape in cross section have proven beneficial here. Such a design is also known as a D-cut, as explained in DE 10 2013 010 461 A1, among others. In fact, at this point the output shaft is equipped with at least one recess in the form of a groove. The drive element in the form of a worm or a worm wheel with a projection engages in the groove, realizing a form-fitting connection.

The groove extends parallel to the axis of rotation of the output shaft. As a rule, there are even three parallel grooves in the output shaft. The worm wheel or the worm as a plastic drive element engages in the grooves in question with the help of three projections. In this way, higher forces can also be transmitted overall if the worm or the worm wheel is made of plastic. In addition, this is intended to prevent the output shaft from shifting into the drive element or worm wheel made of plastic during actuation.

In the generic prior art according to JP 2005-265169 A, the electromotive drive unit is used in connection with a CD player mounted inside a motor vehicle. In order not only to provide a perfect connection between the metal output shaft and the plastic worm at this point, but also to absorb temperature-related deformations of the worm or the worm wheel, a ventilation hole has also been implemented. In this way, any deformation of the drive element or the worm made of plastic in the engagement area can be reliably prevented. This has basically worked.

However, the state of the art allows for further improvements. The ventilation holes in the generic teaching are relatively small, so that deformations in the drive element or the worm are still and unchanged made of plastic are possible in operation. In addition, in the case of the known teaching, the coupling between the output shaft and the drive element is realized by a press fit. Under certain circumstances, such a press fit can shear off under high torque stresses or the output shaft can “peel” into the drive element in the engagement area, as already described in DE 102013010461 A1. This is where the invention aims to remedy the situation overall.

The invention is based on the technical problem of further developing such an electromotive drive unit for motor vehicle applications in such a way that a perfect non-rotatable coupling is provided without the risk of mechanical damage and at the same time any temperature effects that occur during operation are properly controlled.

In order to solve this technical problem, the invention proposes in a first variant of a generic electromotive drive unit for motor vehicle applications that the output shaft, at least in the engagement area of the receiving bore, has two spaced-apart webs that extend axially and run like a chord in cross section, between which a Projection of the drive element engages in the rotary coupling and the outer edge side each describe or limit a vent hole.

Within the scope of the invention, a special configuration of the output shaft is used, at least in the engagement area of the receiving bore of the drive element. The drive element is usually a worm or a worm wheel comparable to the embodiment described and illustrated in DE 10 2013 010 461 A1. Of course, other configurations of the drive element are also possible and are covered by the invention. The drive element is usually made of plastic, but can also be made of metal. First of all, however, the two spaced and axially extending webs of the output shaft, which are realized at least in the engagement area of the receiving bore, are decisive. This is because these webs run in the manner of a chord, ie along a chord of a circle of the output shaft which is essentially circular in cross section. As a result, the two webs running along a chord can be spaced apart from one another and form a receptacle between them, into which the projection of the drive element engages for rotary coupling. In principle, the two webs can run at an angle to one another. As a rule, however, a parallel course of the two webs to one another is observed.

In addition, it has proven useful in this connection if the two webs run in the axial direction at the same distance from the center point of the output shaft, which is designed to be essentially circular in cross section. The chord-like extension of the webs is also manifested in the fact that the webs end at the head end on a circumference of the output shaft, which is essentially circular in cross section. On the foot side, the two webs can be connected to one another by an arch. As a result, the two webs together with the arch form a composite U-web.

The projection on the drive element now engages in this U-web of the output shaft in the engagement area of the receiving bore. This is usually done with a force fit to implement the slewing ring and mostly even with a force fit and form fit. Accordingly, the projection has a shape complementary to the U-web or the receptacle formed in the interior, in the form of a U-shaped projection. In this way, a particularly secure rotary coupling is provided between the U-shaped projection on the drive element on the one hand and the U-shaped design of the output shaft in the receiving area on the other hand.

It also happens that on the outer edge side of the two webs or the U-legs of the U-web in this way and as it were inevitably a development ventilation hole is described. This venting bore appears practically automatically, namely starting from the outer edge of the respective web up to the inner edge of the receiving bore in the engagement area that accommodates the output shaft or the U-web running in the axial direction. These two ventilation bores formed on the outer edge of the webs are generally designed in the form of a segment of a circle in cross section. In addition, the two ventilation holes usually have the same size in cross section. In addition, the ventilation bores are regularly arranged mirror-symmetrically to an axis running through the center point of the output shaft, which is essentially circular in cross section.

Due to the fact that the ventilation bores each emanate from the edge of the U-web or its two U-legs, any temperature-related changes in the diameter of the receiving bore can be accommodated and compensated for without any problems. This also prevents possible cracks inside the plastic drive element. It also prevents the output shaft from shearing off and peeling into the mounting hole. As a result of this, long service lives of the electromotive drive unit according to the invention can be expected and perfect functionality over the entire service life, even under high loads.

Comparable vent holes are also observed in a further second variant of the invention. This provides that, in the case of a generic drive unit, the output shaft has a D-shaped extension, at least in the engagement area of the receiving bore, with ventilation bores on the outer wall in each case. The vent holes can be constructed in a similar way as before and offer similar advantages.

In fact, for example, for the realization of the drive element or the screw mostly used at this point, typically ther moplastics are used, such as PMMA (polymethyl methacrylate), PA (polyamide), PBT (polybutylene terephthalate), POM (polyoxymethylene) or also PC (polycarbonate). Such plastics are particularly easy to process and also have sufficient hardness for power transmission in connection with a gear constructed from them or when the worm, which is usually realized, engages in an associated worm wheel. The use of polyamide (PA) has proven to be particularly advantageous at this point, namely PA 66, ie a special homopolyamide.

The invention also relates to a motor vehicle lock and in particular a motor vehicle door lock which is advantageously equipped with an electromotive drive unit of the design described at the outset. In this context, the drive unit can be used to realize and implement individual functional positions such as "locked" or "anti-theft". In addition, such electromotive drive units can be used and used as closing devices in connection with motor vehicle locksmiths. They can also be used as locking drives in conjunction with locking actuators in electric charging devices for electric or hybrid vehicles and are used.

In all of these cases, functional operation is provided and temperature-related effects can be controlled particularly well. As a result, large forces can also be transmitted. This is where the main advantages can be seen.

The invention is explained in more detail below with reference to a drawing that merely represents an exemplary embodiment; show it:

Fig. 1 an electric motor drive unit for automotive engineering

Applications according to the invention schematically and by way of example, 2 shows the drive element designed as a worm in a perspective view,

3 shows a section through the object according to FIG. 2,

Fig. 4 is an alternative output shaft of the electric motor in perspective and

Fig. 5 shows a section through the object according to Fig. 4.

In the figures, an electric motor drive unit for motor vehicle technical applications is shown. In fact, within the scope of the exemplary embodiment, the electromotive drive unit is used in connection with a motor vehicle lock and in particular a motor vehicle door lock. In fact, within the scope of the exemplary embodiment according to FIG. 1 and not restrictively, the electromotive drive unit is designed as an opening drive for a locking mechanism 1 , 2 made up of rotary latch 1 and pawl 2 , shown schematically there. For this purpose, the electromotive drive unit works on a release lever 3. To open the locking mechanism 1, 2, the release lever 3 is applied using the electromotive drive unit in such a way that the release lever 3 pivots clockwise about its axis.

The clockwise movement of the release lever 3 results in the release lever 3 pivoting the pawl 2, which is in engagement with the rotary latch 1 in the closed position of the locking mechanism 1, 2, about its axis counterclockwise. As a result, the rotary latch 1 is released and can in turn pivot clockwise about its axis and release a previously caught and not expressly shown locking bolt. The same applies to a motor vehicle door that carries the locking bolt and is not expressly shown.

For this purpose, the electromotive drive unit according to the invention has an electric motor 4 and, in cross section, an essentially circular output shaft 5, which is provided on the output side of the electric motor 4 and is set with its help in high-speed rotations. A drive element 6 is mounted on the output shaft 5 .

The drive element 6 made of plastic is, according to the exemplary embodiment, a snail 6, as shown in detail in the perspective view of FIGS. The worm 6 or the drive element 6 made of plastic meshes with a worm wheel 7 also made of plastic. The worm wheel 7 has an actuating pin 8 . In this way, a transmission 6, 7, 8 connected to the electric motor 4 is realized.

1 shows that a counterclockwise movement of the worm wheel 7 causes the actuating pin 8 to act on the release lever 3 in the sense that the release lever 3 performs the previously described clockwise movement about its axis. As a result, the pawl 2 is lifted from its engagement with the rotary latch 1 and the motor vehicle door is finally released. Of course, the electromotive drive unit to be described in detail below can also be used for other purposes and applications, as have already been described in the introduction.

It is clear from FIGS. 2 to 5 that the drive element or the worm 6 made of plastic is not just a part of the transmission 6 , 7 , 8 . Instead, the drive element or the worm 6 is also mounted on the output shaft 5, according to the exemplary embodiment slipped onto the output shaft 5 and optionally additionally secured axially thereon. This can be done, for example, by additionally applying adhesive or in some other way.

For this purpose, the output shaft 5 engages in a receiving bore 9 inside the drive element or the worm 6 . The mounting hole 9 is arranged according to the embodiment in the center of the cylindrical worm formed from 6 and extends in the axial direction.

The schematic representation in FIGS. 2 and 4 shows that the output shaft 5 engages in the worm 6 over a certain axial length, namely with the definition of an engagement area E. In addition, when the output shaft 5 engages in the receiving bore 9 of the worm 6 ventilation holes 10 on both sides are defined, which can best be understood from the illustration in FIGS.

In fact, according to the invention, the design of the output shaft 5, which is essentially circular in cross section, in the engagement area E of the receiving bore 9 of the worm 6 is essentially designed and pronounced in such a way that at this point there are two axially extending webs 11 with a chord-like cross section in the first variant according to 2 and 3 are realized. This becomes particularly clear based on the sectional view according to FIG. 3 . In this sectional view, a center M of the output shaft 5, which is essentially circular in cross section, can be seen.

In relation to this center point M, the two webs 11 run along a chord. The two webs 11 each end at the head end on the circumference of the output shaft 5 in question and are connected to one another at the foot end by an arc 12 . As a result, the two webs 11 in conjunction with the arch 12 describe a composite U-web 11, 12.

In addition, according to the exemplary embodiment, the two webs 11 run parallel to one another and are arranged at the same distance from the center M in question. A projection 13 of the drive element 6 engages between the two webs 11 . As a result, a rotary coupling or rotary connection between the output shaft 5 and the drive element 6 is realized and implemented. In addition, the two webs 11 each have a ventilation hole 10 on the outer edge Webs 11 as a delimitation of the respective ventilation bore 10 together with an inner wall of the receiving bore 9.

The projection 13 generally engages in the U-web 11 , 12 in a non-positive and positive manner. In fact, the projection 13 is designed to be complementary to the U-web 11 , 12 and is consequently designed as a U-shaped projection 13 . The ventilation bores 10 are designed in the form of a segment of a circle in cross section. In addition, according to the exemplary embodiment, the two ventilation bores 10 have the same cross section and are otherwise arranged mirror-symmetrically with respect to an axis A running through the center point M of the output shaft 5 .

The drive element or the worm 6 (and also the worm wheel 7) is generally made of a thermoplastic material. Plastics such as polyamide and in particular homopolyamide have proven to be particularly favorable here. In contrast, the output shaft 5 of the electric motor 4 is generally made of metal. To combine the worm 6 with the output shaft 5, the latter is pushed onto the output shaft 5 in such a way that there is a positive connection in the direction of rotation of the output shaft 5. The two webs 11 or the U-web 11, 12 in the engagement area E of the receiving bore 9 of the worm 6 is produced on the output shaft 5, as a rule, by reshaping the output shaft 5.

Comparable advantages and effects are also observed for the second variant according to FIGS. 4 and 5. Here the output shaft 5 engages in the engagement area E with a D-shaped extension 14 in the receiving bore 9. This again achieves a non-rotatable coupling to the worm 6. The ventilation holes 10 implemented on the outer edge of the D-shaped extension 14 in turn ensure any cooling.

reference list

Claims

patent claims

1. Electromotive drive unit for motor vehicle applications, with an electric motor (4) with an output shaft (5) that is essentially circular in cross section, and with a drive element (6) mounted on the output shaft (5), preferably made of plastic, the output shaft ( 5) engages in a receiving bore (9) of the drive element (6) while defining at least one ventilation bore (10), d a d u r c h e k e n n n n e t z i c h n e t that the output shaft (5) at least in the engagement area (E) of the receiving bore (9) has two spaced apart and axially extending as well as in the Webs (11) running in the form of a chord in cross section, between which a projection (13) of the drive element (6) engages for rotary coupling and which each describe a ventilation bore (10) on the outer edge.

2. Drive unit according to claim 1, characterized in that the webs (11) run parallel to one another.

3. Drive unit according to Claim 1 or 2, characterized in that the webs (11) run in the axial direction at the same distance from the center point (M) of the output shaft (5) which is essentially circular in cross-section.

4. Drive unit according to one of claims 1 to 3, characterized in that the webs (11) end at the head end on a circumference of the output shaft (5).

5. Drive unit according to one of claims 1 to 4, characterized in that the webs (11) are connected to one another on the foot side by an arc (12) to form a composite U-web (11, 12).

6. Drive unit according to one of claims 1 to 5, characterized in that the projection (13) positively and non-positively in the U-web (11, 12) engages.

7. Drive unit according to the preamble of claim 1, characterized in that the output shaft (5) at least in the engagement area (E) of the receiving bore (9) has a D-shaped extension (14) with each outer edge ventilation bores (10).

8. Drive unit according to one of claims 1 to 7, characterized in that the ventilation bores (10) are formed in cross-section like a segment of a circle.

9. Drive unit according to one of claims 1 to 8, characterized in that the ventilation bores (10) are of the same size in cross section.

10. Drive unit according to one of claims 1 to 9, characterized in that the ventilation bores (10) are arranged mirror-symmetrically to an axis (A) running through the center (M) of the cross-section essentially circular output shaft (5).

11. Motor vehicle lock, in particular motor vehicle door lock, with a drive unit according to one of claims 1 to 10.