EP3990729B1 - Opening device for a door or wing in or on a motor vehicle - Google Patents

Description

The invention relates to a device for opening a door or flap in or on a motor vehicle, with at least one transmission lever and with a spring that acts on the transmission lever. - As a rule, the transmission lever is deflected with the aid of a handle, a Bowden cable or by using another actuating means that can be actuated manually by an operator.

The handle mentioned as a component of the device described above can be either an external handle or an external door handle or an internal handle, in particular an internal door handle. As a rule, the handle is designed as an external handle or external door handle and is typically used for the so-called "electrical opening" of an associated motor vehicle lock and in particular a motor vehicle door lock. For this purpose, a sensor assigned to the handle is generally provided, which, depending on its load, controls a motor drive, which in turn generally ensures the previously described electrical opening of a locking mechanism consisting of a rotary latch and pawl as a component of the motor vehicle lock and in particular a motor vehicle door lock.

In the generic state of the art according to the EP 1 816 290 B1 In addition to the previously described electric opening drive and the handle, a transmission mechanism is provided. The overall design is such that only when the handle is pulled with a force that is equal to or greater than an emergency opening force is, a mechanical movement of the door handle is permitted and a transmission is made to the vehicle lock or vehicle door lock or a mechanical locking device there. During this emergency opening, the associated door or flap can also be opened as an alternative to electrical opening.

Such an emergency opening is typically carried out when the electronics or a power supply for the electronics have failed and the usual electrical opening is therefore not possible. During the emergency opening, the mechanical movement of the handle ensures that the associated door or flap can be opened mechanically.

The EP 1 816 290 B1 In this context, the door handle is referred to as quasi-fixed because the door handle is pre-tensioned against a stop with the help of a return spring, so that only a relatively large pulling force acting on the door handle can overcome the questionable return force of this spring. However, with normal actuating forces to open the door, the door handle is not moved or hardly moved, so that it is considered quasi-fixed. In this functional position, however, the sensor for electrical opening can still be activated.

In order to provide an operator with tactile feedback as to whether he has pulled the door handle hard enough to trigger the sensor, the known teaching works in such a way that when the handle is pulled with a force that is less than the emergency opening force but sufficient to generate an output signal from the sensor, a handle movement that can be perceived by the operator is generated with the help of the transmission mechanism. In order to constructively depict these various known scenarios, a relatively complicated structure is required. The transmission mechanism is equipped with, among other things, an elastically deformable bistable component that jerks from one position to the other when the handle is pulled. stable shape into another, with the jerky movement being transferred to the handle.

Another device of the same type is used in the EP 1 455 039 A2 presented. This also involves a device for the motorized operation of a lock for hatches or doors of vehicles in normal cases. In addition, an emergency device is provided for the manual operation of the same lock in an emergency. The normal device has a signal transmitter or sensor which acts on a motor used to control the lock.

The emergency device has a manually operated pulling or pushing means, which is connected on the one hand to the lock and on the other hand to an output link of a link chain. In this case too, a relatively complicated mechanical device for opening a door or flap is described, which, like the device previously discussed, is not free of defects in terms of functional reliability. In addition, the complex structure of the known devices leads to increased costs in their implementation, which is disadvantageous in view of the enormous cost pressure in the automotive sector. The invention aims to remedy this overall.

In the documents DE102017123258A1 and DE102016014773A1 A transmission lever is located directly on the outside door handle.

The invention is based on the technical problem of further developing such a device for opening a door or flap in or on a motor vehicle in such a way that, with increased functional reliability compared to the prior art, the design and manufacturing effort are reduced at the same time.

To solve this technical problem, the invention proposes, in a generic device for opening a door or flap in or on a motor vehicle, that the spring acting on the transmission lever has at least one of a first actuation path of the transmission lever spaced first region, so that the spring only acts on the transmission lever after the first actuating path has been completed.

According to the invention, a further second region adjoins the first region of the spring in the actuation direction of the transmission lever. This second region of the spring ensures that the transmission lever is subjected to a counterforce that is opposite to the actuation force during its associated second actuation path. In addition, the transmission lever is designed according to the invention as an external actuation lever or an internal actuation lever and is arranged in a motor vehicle door lock.

According to an advantageous embodiment, the spring then has a third region, with the second region of the spring then transitioning into the third region in the actuation direction of the transmission lever. In the third region of the spring, the spring ensures that the transmission lever is subjected to a restoring force during its associated third actuation path.

According to the invention, the spring acting on the transmission lever has at least a first region and a second region. The first actuation path of the transmission lever corresponds to the first region of the spring. In contrast, the second actuation path of the transmission lever, which follows the first actuation path, belongs to the second region of the spring.

Since the spring in the first area is spaced apart from the first actuation path of the transmission lever, there is no interaction between the transmission lever and the spring when completing this first actuation path of the transmission lever. Consequently, if the handle that acts on the transmission lever is actuated by an operator to open the door or flap, this happens during the first actuation path of the transmission lever without any resistance or with at most a slight frictional resistance, because the spring that normally acts on the transmission lever during the first During the actuation path of the transmission lever, the transmission lever is not subjected to pressure in its spaced-apart first area. Only when the transmission lever has completed its first actuation path does the spring ensure that the transmission lever is acted upon after completing this first actuation path. The second area adjacent to the first area of the spring corresponds to this. In this second area of the spring, the transmission lever is subjected to a counterforce that is opposite to its actuation force.

As a result, an operator pulling the handle, for example, can distinguish particularly easily and tactilely between the first actuation path of the transmission lever, which is virtually resistance-free, and the second actuation path of the transmission lever, which is subject to resistance caused by the spring and which must be completed against the counterforce built up by the spring in the second area.

Typically, the handle is assigned a sensor to detect its application. The sensor is actuated during the first and/or second actuation path of the transmission lever. In accordance with signals from the sensor, a motor vehicle lock and in particular a motor vehicle door lock is actuated using a motor drive, for example via an intermediate control unit. In this context, the motor drive can ensure that the motor vehicle lock and in particular a motor vehicle door lock in question is unlocked and/or opened, for example.

Beyond the second area of the spring or the second actuation path of the transmission lever, the sensor is generally no longer actuated. The subsequent third actuation path of the transmission lever is characterized by the associated third area of the spring applying a restoring force to the transmission lever. This means that During this third actuation path of the transmission lever, the transmission lever is not only subjected to a resistance created by the spring, but the spring also actively ensures that the transmission lever is subjected to a restoring force, resulting in a restoring torque acting on the transmission lever, which is usually mounted so that it can rotate. This also allows an operator to easily distinguish between the second actuation path and the third actuation path of the transmission lever by touch.

While the second actuation path of the transmission lever is characterized by a decelerated movement, during the third actuation path a restoring force is built up by the spring and an additional restoring moment or restoring torque acts on the transmission lever. The overall design is such that the transmission lever mechanically loads the motor vehicle lock or motor vehicle door lock directly or indirectly during this third actuation path. This means that, according to the invention, the motor vehicle lock or motor vehicle door lock is only and exclusively mechanically loaded during this third actuation path. In contrast, during the first or second actuation path of the transmission lever, the motor vehicle lock or motor vehicle door lock is continuously loaded by a motor or electric motor, for example in the sense of "electrically opening".

All of these scenarios and functional positions can be implemented in a particularly simple manner according to the invention and correspond to a strikingly simple construction. The spring is designed in detail as a leaf spring, i.e. as a spring made of a flat leaf-shaped strip, which is typically made of metal, but can also be made of plastic. The flat leaf-shaped strip in question can now be easily deformed in such a way that a contour leg and a Fastening legs are defined. The contour leg is located opposite an actuating pin on the transmission lever. The actuating pin is typically arranged at the opposite end to an axis of the transmission lever, about which the transmission lever is generally rotatably mounted in or on a housing, the door or flap.

The contour leg now has the first area and optionally the second and third areas of the spring. In contrast, the fastening leg ensures that the leaf spring can be anchored in a housing, for example. The housing can be a lock housing, a locking housing, etc. As a result, the leaf spring used according to the invention has a U-shaped to V-shaped cross-section with U-legs or V-legs of different lengths. The long U-leg or V-leg is designed as a contour leg and faces the actuating pin on the transmission lever. In contrast, the short U-leg or V-leg is the fastening leg for anchoring the leaf spring in the housing in question.

The spring or leaf spring itself can be fixed in the housing in question using an additional element, such as a screw or a pre-stamped disc. A locking connection or any other conceivable connection to the housing is also possible at this point. This means that the spring or leaf spring and, depending on the size and point of action of a force threshold provided by it, can be adapted to the respective requirements. All that is required is to adapt the spring very easily to the desired requirements in terms of its geometry, e.g. in terms of its material thickness, the angle between the legs, its shape, etc.

In addition, the leaf spring used according to the invention is also oriented in such a way that its narrow side is opposite the actuating pin on the transmission lever or in interaction with the actuating pin As a result, the leaf spring is actuated by the actuating pin, which is predominantly cylindrical in cross-section, in such a way that the actuating pin moves against the narrow side of the leaf spring in the second or third area and pivots or deforms the leaf spring in its longitudinal extension or along its broad side. The three areas of the leaf spring correspond not only to the contour leg of the leaf spring, but also to different geometries of the leaf spring, as will be explained in more detail below and with reference to the description of the figures.

As a result, a device for opening a door or flap in or on a motor vehicle is provided which is of simple construction and works properly. In fact, according to the invention, the one (single) spring ensures that the transmission lever completes the different actuation paths described during its actuation. Due to the interaction of the transmission lever with the spring or the lack of interaction during the first actuation path, a user who presses the handle can tactilely determine in which area of the actuation he is. This makes it easy to distinguish between the electrical opening that typically takes place during the first and/or second actuation path on the one hand and a type of emergency actuation or emergency opening during the third actuation path on the other. This is where the main advantages can be seen.

Fig. 1 bis 3

die erfindungsgemäße Vorrichtung zum Öffnen einer Tür oder Klappe in oder an einem Kraftfahrzeug in verschiedenen Funktionsstellungen.

In the following, the invention is explained in more detail with reference to a drawing which merely represents an exemplary embodiment; in the drawings:

Fig. 1 to 3

the device according to the invention for opening a door or flap in or on a motor vehicle in different functional positions.

The figures show a device for opening a door 1 or flap in or on a motor vehicle. For this purpose, the device has a handle 2, which in the exemplary embodiment is an outside door handle. A sensor 4 is assigned to the handle 2 or to a transmission lever 3 connected to the handle 2. The sensor 4 is, for example, a switch and in particular a microswitch. The transmission lever 3 is actuated by means of a spring 5. The basic structure also includes a control unit 6, which evaluates signals from the sensor 4 and, depending on this, acts on a motor drive 7 for a motor vehicle lock 8.

The motor vehicle lock 8 is a motor vehicle door lock 8 that locks the door 1 or motor vehicle door. The motor vehicle lock or motor vehicle door lock 8 essentially has a locking mechanism 9, 10 consisting of a rotary latch 10 and a pawl 9 that secures the rotary latch 10. With the help of the locking mechanism 9, 10 inside the door or motor vehicle door 1, a locking bolt 11 provided on the body side is caught and secured in a known manner as soon as the door or motor vehicle door 1 is in the closed state relative to the body.

With the help of the motor drive 7, the locking pawl 9 in the embodiment can now be pivoted in the indicated anti-clockwise direction so that it releases the rotary latch 10, which in turn then pivots open under spring action and releases the previously caught locking bolt 11. This allows the associated motor vehicle door 1 to be opened in the course of the described "electric opening".

In addition to this described "electrical opening" of the motor vehicle door lock 8 with the aid of the associated motor or electric motor drive 7, an emergency opening and/or emergency unlocking is also possible possible. In this case, the handle 2 ensures that the locking mechanism 9, 10 is unlocked or opened by applying pressure to the transmission lever 3. In addition, a mechanical connection 12 between the transmission lever 3 and the motor vehicle door lock 8 is realized or can be realized, which is or can be closed in particular for the emergency opening already mentioned. The functional position according to the Fig. 3 , as will be explained in more detail below. As a rule, however, the motor vehicle door lock 8 is opened exclusively electrically, in that an actuation of the handle 2 is sensed with the aid of the sensor 4 and then, via the control unit 6, results in an actuation of the motor or electric motor drive 7 for electrically opening the motor vehicle door lock 8.

As already explained, the transmission lever 3 is equipped with a spring 5 which acts on it. In the example, the spring 5 is a leaf spring which is made from a longitudinally extending narrow strip of metal. In principle, the spring or leaf spring 5 can also be made from plastic. The spring or leaf spring 5 interacts in detail with an actuating pin 3a on the transmission lever 3. For this purpose, the actuating pin 3a is designed to be largely cylindrical in cross-section. In addition, the actuating pin 3a is located at an end opposite an axis 3b of the transmission lever 3. In fact, the transmission lever 3 can be pivoted by pulling the handle 2, as indicated in the figures, about the axis 3b in question to open the motor vehicle door lock 8 in the counterclockwise direction, which is also indicated in the figures, so that starting from the position shown in the Fig.1 shown rest position the other functional positions according to the Figures 2 and 3 can be achieved one after the other in this way.

It can be seen that the spring or leaf spring 5 is opposite the transmission lever 3 with its narrow side. The leaf spring 5 also has a contour leg 5a and a fastening leg 5b. The contour leg 5a interacts with the transmission lever 3 or the actuating pin 3a on the transmission lever 3. In contrast, the fastening leg 5b ensures that the leaf spring 5 in the embodiment is or can be anchored in a housing not shown in detail.

The contour leg 5a of the leaf spring 5 is divided into three different areas 5a ₁ , 5a ₂ and 5a ₃ . The first area 5a ₁ of the spring 5 corresponds to a first actuation path B ₁ of the transmission lever 3. The second area of the spring 5a ₂ belongs to a second actuation path B ₂ that follows the first actuation path B ₁ . A third actuation path B ₃ that follows the actuation path B ₂ of the transmission lever 3 finally corresponds to the third area 5a ₃ of the spring or leaf spring 5.

Based on a comparative analysis of the Figures 1 and 2 one can see that the first area 5a ₁ is spaced apart from the first actuation path B ₁ of the transmission lever 3. As a result, the spring or leaf spring 5 cannot act on the transmission lever 3 within this first actuation path B _1. This can be seen in the Fig.1 .

As soon as the transmission lever 3 is pivoted further anti-clockwise around its axis 3b with the aid of the handle 2 along the actuation direction shown by an arrow, the transmission lever 3 or its actuation pin 3a reaches the second area 5a ₂ of the spring 5 after completing the first actuation path B ₁ . This includes the second actuation path B ₂ . This is associated with a force threshold that can be tactilely detected by an operator acting on the handle 2. The second area 5a ₂ of the spring 5 now ensures that the transmission lever 3 is acted upon by a counterforce G directed opposite to an actuation force F, which is in the associated Fig. 2 when the previously mentioned force threshold is reached by the spring 5. The force F and the counterforce G enclose an obtuse angle according to the embodiment, so that the counterforce G has at least one force component directed opposite to the actuating force F, which overall ensures that the transmission lever 3 is braked, as it were, and an operator can tactilely detect this force threshold when acting on the handle 2.

The second region 5a ₂ of the spring 5 merges into the third region 5a ₃ already mentioned, which, when the transmission lever 3 is continuously actuated in the indicated counterclockwise direction with respect to the axis 3b during the third actuation path B _3, presses the transmission lever 3 with a force in the Fig.3 The restoring force R generated by the spring or leaf spring 5 corresponds to a restoring force R shown in the Fig.3 drawn force vector, which is oriented at a distance from the axis 3b of the transmission lever 3. In fact, one can see from the illustration in the Fig.3 that an extension of the force vector of the restoring force R according to the embodiment points into a region below the axis 3b, so that as a result the restoring force R corresponds to a restoring moment which acts on the transmission lever 3 against its normal actuating direction in the counterclockwise direction in relation to the axis 3b and consequently for a resetting of the transmission lever 3 in the direction of its in the Fig.1 shown rest position.

As a result, the transition of the transmission lever 3 from the second actuation path B ₂ to the third actuation path B ₃ is also tactilely detected by a user pulling on the handle 2. This third actuation path B ₃ of the transmission lever 3 corresponds according to the embodiment and not restrictively to the fact that the force threshold according to the Fig.2 As a result, the mechanical connection 12 from the transmission lever 3 to the motor vehicle door lock 8 is closed and the motor vehicle door lock 8 can be mechanically unlocked and/or opened as described.

The functionality is as follows. In the Fig.1 the rest position of the device Z according to the invention for opening the door 1 is shown. If, starting from this rest position, the user pulls on the handle 2, the transmission lever 3 is pivoted anti-clockwise about its axis 3b during the first actuation path B ₁ with practically no resistance. At the same time, this pivoting movement of the transmission lever 3 in the anti-clockwise direction ensures that the sensor 4 is actuated. The actuation of the sensor 4 is registered by the control unit 6 and ensures that the motor drive 7 is actuated to open the locking mechanism 9, 10 according to the exemplary embodiment. This means that, in accordance with signals from the sensor 4, the motor vehicle lock or motor vehicle door lock 8 is actuated, for example unlocked and/or opened, with the aid of the motor drive 7.

As soon as the transmission lever 3 has completed the first actuation path B ₁ during the pulling movement of the handle 2, the user is then guided to the second actuation path B ₂ by the spring 5 as shown in the Fig.2 generated force threshold. This leads to a further difficult movement of the handle 2, which is easily perceptible by touch. During this second actuation path B ₂ , the sensor 4 can still be acted upon or it is also possible that no further actuation of the sensor 4 takes place. In any case, the counterforce G generated by the spring 5 when completing the second actuation path B ₂ ensures that the operator's actuation of the handle 2 is made more difficult and this is registered by touch as a force threshold.

In normal operation and usually, the handle 2 is only pulled by a user so far that the transmission lever 3 first actuation path B ₁ and reaches the maximum force threshold associated with the second actuation path B _2. This is because the force threshold can be detected tactilely and usually leads to a user generally letting go of the handle 2. The already-occurring action on the sensor 4 has in the meantime led to the motor vehicle door lock 8 being unlocked and/or opened.

Only for the purpose of emergency opening, the force threshold is set according to the Fig.2 exceeded in a certain way. This happens when completing the third actuation path B ₃ of the transmission lever 3 as shown in the Fig.3 This results in the mechanical connection 12 being closed by the transmission lever 3 and the motor vehicle door lock 8 being mechanically unlocked and/or opened, which is expressly neither provided for nor intended in normal operation.

The illustrated transmission lever 3 is an external operating lever in the exemplary embodiment. As a result, the handle 2 is designed as an outside door handle. Of course, the transmission lever 3 can also be designed as an inside operating lever. In this case, the handle 2 is an inside door handle. According to the invention, the transmission lever 3 is arranged in the motor vehicle door lock 8.

List of reference symbols:

• Door or vehicle door 1
• Handle 2
• Transmission lever 3
• Actuating pin 3a
• Axis 3b
• Sensors 4
• Spring or leaf spring 5
• Contour leg 5a
• Mounting leg 5b
• Areas 5a ₁ , 5a ₂ and 5a ₃
• Control unit 6
• motor drive 7
• Motor vehicle lock 8
• Pawl 9
• Rotary latch 10
• Lock 9, 10
• Locking bolt 11
• mechanical connection 12
• Actuation paths B ₁ , B ₂ , B ₃
• Actuating force F
• Counterforce G
• Restoring force R
• Device Z

Claims (9)

1. Device for opening a door (1) or flap in or on a motor vehicle, having at least one transmission lever (3), and having a spring (5) which acts on the transmission lever (3), wherein the spring (5) has at least one first region (5a₁) which is spaced apart from a first actuating path (B₁) of the transmission lever (3), so that the spring (5) acts on the transmission lever (3) only after the first actuating path (B₁) has been completed, wherein a second region (5a₂) adjoins the first region (5a₁) of the spring (5) in the actuating direction of the transmission lever (3), which second region applies a counterforce (G) opposite to the actuating force (F) to the transmission lever (3) during its second actuating path (B₂), wherein the transmission lever (3) is designed as an external actuating lever or internal actuating lever and is arranged in a motor vehicle door lock (8).
2. Device according to claim 1, wherein the second region (5a₂) of the spring (5) merges into a third region (5as), which applies a restoring force (R) to the transmission lever (3) during its third actuating path (B₃).
3. Device according to one of claims 1 or 2, wherein the transmission lever (3) is designed as a pivot lever rotatable about an axis (3b).
4. Device according to any of claims 1 to 3, wherein the restoring force (R) generated by the spring (5) corresponds to a force vector which is oriented at a distance from the axis (3b) of the transmission lever (3).
5. Device according to any of claims 1 to 4, wherein the spring (5) is designed as a leaf spring, which with its contour leg (5a) lies opposite an actuating pin (3a) on the transmission lever (3) and with its fastening leg (5b) is anchored in a housing, for example.
6. Device according to any of claims 1 to 5, wherein the transmission lever (3) or a handle (2) is assigned a sensor (4) for detecting the force application of the transmission lever or handle.
7. Device according to claim 6, wherein the sensor (4) is acted on during the first actuating path (B₁) and/or the second actuating path (B₂) of the transmission lever (3).
8. Device according to any of claims 6 to 7, wherein a motor vehicle lock (8) is acted on, for example unlocked and/or opened, by means of a motor drive (7) in accordance with signals from the sensor (4).
9. Device according to any of claims 1 to 8, wherein, during its third actuating path (B₃), the transmission lever (3) directly or indirectly mechanically acts on the motor vehicle lock (8).

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