阅读说明：本技术 用于机动车的驻车锁止器 (Parking brake for a motor vehicle ) 是由 克里斯托夫·哈施克 克里斯托夫·蒂劳夫 马蒂亚斯·费尔巴哈 于 2019-11-25 设计创作，主要内容包括：本发明涉及一种用于机动车换挡变速器的驻车锁止器(1),所述驻车锁止器具有：锁止棘爪(4),所述锁止棘爪可围绕转动轴线(8)枢转并且具有用于接合到驻车锁止器轮(2)中的棘爪齿(5)；和操作单元(7),借助于所述操作单元,锁止棘爪(4)能够可逆地接合到驻车锁止器轮(2)中。根据本发明,锁止棘爪(4)形成用于操作单元(7)的止挡(9)。(The invention relates to a parking brake (1) for a motor vehicle transmission, comprising: a locking pawl (4) which is pivotable about a rotational axis (8) and has pawl teeth (5) for engaging into the parking brake wheel (2); and an operating unit (7) by means of which the locking pawl (4) can be reversibly engaged into the parking lock wheel (2). According to the invention, the locking pawl (4) forms a stop (9) for the operating unit (7).)

1. Parking lock (1) for a motor vehicle transmission, having: a locking pawl (4) which is pivotable about a rotational axis (8) and has pawl teeth (5) for engaging into the parking brake wheel (2); and an operating unit (7) by means of which the locking pawl (4) can be reversibly engaged into the parking lock wheel (2),

it is characterized in that the preparation method is characterized in that,

the locking pawl (4) has a stop (9) against which the operating unit (7) can be stopped when the parking brake is installed.

2. The parking lock according to claim 1,

it is characterized in that the preparation method is characterized in that,

the stop (9) is spaced apart from its mating stop surface (10) in the locked state of the parking brake (1).

3. Parking lock according to claim 1 or 2,

it is characterized in that the preparation method is characterized in that,

the stop (9) is formed integrally with the locking pawl (4).

4. The parking lock according to any one of claims 1 to 3,

it is characterized in that the preparation method is characterized in that,

the operation unit (7) has: a linearly movable slider (12) which contacts the locking pawl (4) on the rear side of the pawl tooth (5); and a spring (20), against the spring force of which the slide (12) can be pre-tensioned.

5. The parking lock according to claim 4,

it is characterized in that the preparation method is characterized in that,

the slide (12) is stopped by means of its slide head (26) against the stop (9) when the slide is stopped.

6. The parking lock according to claim 4 or 5,

it is characterized in that the preparation method is characterized in that,

the slide (12) holds a roller (13) which rolls on the locking pawl (4).

7. Parking lock according to one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

the stop surface (11) is formed spherically.

8. Parking lock according to one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

the stop (9) is designed as a cam having a steep edge forming the stop surface and a flatter edge (18) facing away from the stop surface.

9. Parking lock according to one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

the parking brake (1) has a damping mechanism which is arranged on the stop (9) or on the operating unit (7).

10. A locking pawl (4) of a parking lock (1) according to any of the preceding claims.

Technical Field

The invention relates to a parking brake for a motor vehicle transmission, comprising: a locking pawl pivotable about a rotational axis and having pawl teeth for engaging into a parking lock wheel; and an operating unit, by means of which the locking pawl can be reversibly engaged into the parking lock wheel, which operating unit has a linearly movable slide which contacts the locking pawl on the rear side of the pawl tooth and which operating unit has a spring, against the spring force of which the slide can be pretensioned.

Background

A parking lock of this type is known from DE 102010053857 a 1. DE 102011080498 a1 or JP H07-144616 a show similar solutions. In the last-mentioned solution, a planetary rolling gear is used as a mechanical transmission unit for transmitting the movement of the actuator to the locking pawl. It is thereby possible to achieve a relatively high transmission force.

When the vehicle is parked, for example, on a slope, the vehicle mass, in relation to the wheel diameter, the transmission gear ratio and the radius of the locking wheel (locking toothing), generates a force which acts on the closed pawl and, in turn, on the parking lock mechanism. This force must therefore be overcome when the parking lock is unlocked under load.

A parking lock of this type requires a relatively large force in order to disengage the locking pawl, i.e. in order to place it in the unlocked position. The force is derived from the geometry between the pawl tooth and the recess in the locking tooth by means of a corresponding reserve angle. High forces can also be obtained due to the coefficient of friction and the friction wedge achieved.

The forces must be supported reliably, and the parking lock and the transmission should on the other hand be designed to be as lightweight as possible. In particular, in the case of high forces and narrow installation spaces, the movable part of the parking brake can be stopped on a housing of the parking brake, which housing transmits structure-borne noise. If the operator tries to insert the parking brake beyond the push-open speed, slipping occurs and an undesirable shock propagates.

DE 10245951 a1 proposes to reduce structure-borne noise by: a spring is introduced into the force line. By means of the spring, the transmission element reaches the stop with a time delay. By means of the time delay, more time is provided for the force to collide when striking the end stop, so that the structure-borne sound is already impeded in its occurrence. No damping is caused by this arrangement. When pushing open, the transmission element is periodically pulsed onto the end stop if the parking lock is operated at too high a speed. Without damping, only insufficient energy is extracted from the system.

For decoupling from structure-borne sound, it is proposed in US 2014/0231213 a1 to arrange a plastic sleeve or a plastic layer as a damping mechanism between the housing and the transmission mechanism. In the parking brake, the occurrence of structure-borne noise is not impeded, but rather is prevented from further propagation by the introduction of a plastic layer. This requires, on the one hand, heat-resistant and oil-resistant plastics and a multiplicity of expenditure in the illustrated installation by screwing. DE 102017127211 a1 shows an alternative with two coupled spring plates.

Disclosure of Invention

The invention is based on the object of developing a parking lock of this type which is constructed compactly and overcomes the disadvantages described above.

This object is achieved by a parking lock according to claim 1. In the parking brake according to the invention, the stop for actuating the actuating element of the locking pawl is formed on the locking pawl itself. The actuating element is thus not directly stopped on the housing, so that it forms a resonant body, but rather is stopped on the housing via the supported latching pawl, so that vibrations occurring in the support in the stop are only partially transmitted. Furthermore, no additional components are required thereby. It is neither necessary to provide a stop surface on the inner wall of the housing, which allows a greater freedom in shaping the housing, nor is it necessary to mount a separate stop. In addition to the effect, the tolerance chain shortens. The stop and the locking pawl do not need to be positioned relative to one another, since their mutual distance is fixedly predetermined by being arranged on the same component.

In one embodiment of the invention, the stop is spaced apart from a mating stop surface thereof connected to the actuating element in the locked state of the parking brake. This ensures that the parking brake can be easily disengaged and engaged, since no friction occurs at the stop as long as the spring biasing the pawl is relaxed. Furthermore, the stop can be positioned such that the spring-preloaded actuating element does not stop each time the parking brake is engaged, but only when the spring is relaxed due to a particularly high pretensioning. Thereby, an overshoot of the maximum allowed axial position is avoided and the stop forms a final stop to ensure the maximum possible path of the operating unit.

In a development of the invention, the stop is formed integrally with the locking pawl, which enables particularly simple production. The locking pawl can be forged, for example.

Preferably, the stop is provided with a spherical stop surface aligned with the operating unit. The spherical stop surface ensures that, when the detent stops and rotates simultaneously, the stop surface and the mating stop surface can roll on each other, which reduces the load on the component. Furthermore, a suitable radius of the stop surface ensures that the stop allows the same axial displacement path for the actuating element at each rotational angle of the locking pawl.

The stop can be designed as a cam with a steep edge forming the stop face and a flatter edge facing away from the stop face. In one embodiment, the edges are formed asymmetrically. The stop force can be absorbed well if the projection has a substantially triangular shape in longitudinal section. The locking pawl is particularly of lightweight design in the case of a pawl which has recesses or through-recesses in its less loaded regions. The stop may also be provided with one or more such recesses or through-notches.

In a further embodiment, the operating unit has a linearly movable slide which contacts the latching pawl on the rear side of the pawl tooth, and a spring against which the slide can be pretensioned. The slider forms, by means of its end face, a mating stop element for a stop face of the stop. The slider can be arranged on the end face on the actuating element and can be prestressed by a spring. The slide can also have a roller in order to enable low-friction actuation and disengagement of the parking brake or to reduce the maximum force required, which is important for the power measurement of the actuator.

The parking lock may further have a damper mechanism that is provided on the stopper or on the operation unit and reduces a collision. Here, this is a spring pack. The spring pack ensures that, during operation, the movable part is less stopped against the housing of the parking brake. On the one hand, the force impact generated by the pushing-apart movement of the locking pawl is delayed by the spring packet. Thereby providing more time for the pulses to interact so that sound generation is avoided during the preparation phase. On the other hand, a spring pack can be realized in which the springs are deformed relative to one another and thus also rub against one another. By means of said friction, the spring additionally assumes a damping function. In the simplest embodiment, the spring pack is designed as a double spring plate. Since the spring package is first of all elastic and only a small part absorbs the shock, the damping effect of the spring package is increased by: the spring plates are coated with a friction material to increase internal friction when deformed.

The parking brake can be incorporated into different types of transmissions. For example, the parking brake is suitable for motor vehicles with manual transmissions, with automated or automatic transmissions, or for transmissions of electric vehicles.

The parking lock may have its own housing as a parking lock housing. The parking brake housing then forms a common overall housing together with the transmission housing, or the parking brake housing is arranged within the transmission housing. Alternatively, the parking brake may not have its own housing, so that the housing for the parking brake is the transmission housing itself.

In one embodiment, the assistance force of the locking pawl, which is generated by the locking torque and the angle of engagement of the pawl tooth of the locking pawl with the gear tooth of the parking brake, is conducted out into the housing via the roller group.

To reduce friction, the two housing-side rollers can be needle-roller-mounted. The rollers constitute supporting rollers. The third roller that rolls on the locking pawl is a solid roller, which is subjected to its radial bearing by two supporting rollers located thereon.

The rollers are optionally integrated in a slide which serves as a guide housing. In one embodiment, the slider has two elongate lateral sections, which are preferably produced as sheet metal stampings. The two lateral portions are connected at the end sides by two transverse portions. The transverse portion is also preferably manufactured as a sheet metal stamping. The lateral portion and the transverse portion may be riveted to each other.

Drawings

Embodiments of the invention are illustrated in the drawings. The figures show:

figure 1 shows a longitudinal section through the main components of the parking lock according to the invention,

fig. 2 shows a perspective sub-view of the locking pawl according to fig. 1.

Detailed Description

Fig. 1 to 4 show a parking lock 1. The essential features of the invention, which are based on the basic design of the parking lock, are described in the following text, as explained in detail in the above-mentioned DE 102010053857 a1 and DE 102011080498 a1 of the applicant. In this connection, reference is made in detail to the above-described solution in order to avoid duplication of the basic functional principle with respect to the parking brake.

In general, the parking lock 1 includes a parking lock wheel 2 having a locking tooth with a plurality of recesses 3 on its circumference. The parking brake 1 has a locking pawl 4, which is pivotably arranged about a rotational axis 8. The locking pawl 4 is visible in a downwardly oriented unlocking position (in the direction of the locking toothing 2), in which the pawl tooth 5 of the locking pawl 4 is arranged above the parking lock wheel 2.

The parking lock 1 is locked or unlocked via an actuator 6, which is shown here as a shaft.

The transmission of the movement of the actuator 6 to the locking pawl 4 takes place by means of the actuating mechanism 7. As in the above-described solution, the operating mechanism 7 comprises a linearly movable slide 12 in which two rollers 13 and 14 are supported. The roller 13 is in contact with a ramp 17, which is formed on the rear side of the locking pawl 4. Therefore, when the slider 12 moves linearly, the locking pawl 4 pivots. When the roller 13 rolls on the locking pawl 4, the roller 14 rolls on the cover 15. The cover 15 is formed as a flat, hard steel plate and contacts the housing 21 of the parking lock 1 on the rear side. The rollers 13, 14 are integrated in a slide 12, which for this purpose has two elongate lateral sections, of which only one lateral section 22 is shown, wherein the lateral sections are preferably produced as sheet metal stampings. The two lateral parts are connected at the end by two transverse parts 24, 25, which are likewise preferably produced as sheet metal stampings. The lateral and transverse portions 24, 25 may be riveted to each other. The transverse portion 24 now forms a slider head 26, which stops against the stop 9.

The operating mechanism 7 comprises a slide 12 guided along a rod 16. The lever 16 is surrounded by a spring 20, which is designed as a helical compression spring and which pretensions the locking pawl 4 and holds it in the locked position.

The locking pawl 4, which is shown in detail and enlarged in fig. 2, is formed as a one-piece component and has a pawl tooth 5 aligned with the parking brake wheel 2. On its rear side, a ramp 17 is provided, on which the roller 13 rolls. The end face of the transverse portion 24 serves as a mating stop face 10 for the stop face 11 of the stop 9, wherein the stop face 11 is formed spherically.

The stop 9 has a convex shape, wherein the stop surface 11 forms a steeper edge than the edge 18 facing away from the stop surface 11. To reduce mass, the locking pawl 4 also has a bearing eyelet 19 and a through-opening as a pawl recess 23.

List of reference numerals:

1 parking lock

2 parking lock ware wheel

3 concave part

4 locking pawl

5 pawl tooth

6 actuator

7 operating element

8 axis of rotation

9 stop

10 mating stop surfaces

11 stop surface

12 sliding block

13 roller

14 roller

15 guard board

16-bar

17 slope

18 edge facing away from

19 support button hole

20 spring

21 casing

22 lateral part

23 pawl recess

24 transverse part

25 transverse section

26 slider head