The invention relates to a motor vehicle door closure which is equipped with a closing/opening device containing a drive, a transmission element and a locking mechanism, with the drive acting on the locking mechanism with the aid of the transmission element in order to close or open it.
A variety of designs are known for motor vehicle door closures. DE 101 40 385 A1 discloses a servo latch holder for a motor vehicle door closure in which a locking bolt of the motor vehicle door closure is mounted on an adjustable actuation rocker arm. A drive for the actuation rocker arm is also provided. The drive moves the actuation rocker arm with the locking bolt and a catch surrounding the locking bolt and thus an associated door, out of a preliminary closed position into a fully closed position with the aid of a motor. An additional blocking lever ensures that the actuation rocker arm is held in this position when the door is manually moved from the preliminary closed position to the fully closed position.
Such servo latch holders are generally used in all doors of a motor vehicle. In this way, not only side doors but also boot lids and tailgate flaps or even bonnets can be acted upon and are covered by the invention. By means of the closing aid provided in this way or the servo latch holder, the respective door or vehicle door can be moved from said preliminary closed position into a fully closed position against the resistance of, for instance, a door seal. As a result, the door can be closed with little noise and with little force.
Another design of a closing device is disclosed in DE 198 28 040 B4, describing a power-assisted closing device for doors, flaps, hoods or roofs of vehicles and, in particular, cars in which a pivotable fixing element is arranged on a catch. The pawl interacting with the catch also has a pivotable fixing element. The two fixing elements cooperate with a control disk during the opening and closing process. The control disk is part of an actuating drive with the aid of which an opening and closing operation can be carried out.
The described drives and the associated elements are often relatively large so that the drive is generally positioned remotely from the locking mechanism and thus from an associated motor vehicle door or is installed in the car body. Movements of the electric drive are in this case transmitted to the locking mechanism by means of the transmission element. The transmission element is typically a Bowden cable, although also rods, pulleys, etc. can be advantageously used at this point.
According to the generic state of the art disclosed in DE 20 2008 015 789 U1, a transmission lever is provided that is positioned on the same axis as that of a catch of the locking mechanism. A drive pawl is also mounted on a transmission element. The drive pawl is connected to the drive by means of a Bowden cable or another connection means.
The known closing/opening devices of motor vehicle doors are generally used successfully but are, however, often limited in practical application and require improvement. This is mainly due to the fact that the force transmitted from the drive onto the locking mechanism via the transmission element during closing of the respective door, is not even along the drive travel. Or in other words, the motor vehicle door opposes the drive with different forces along the drive travel during closing.
This is, in particular, due to the fact that a seal closing the motor vehicle door must be increasingly compressed towards the end of the drive travel or of the closing travel. This means that the closing force exerted by the drive onto the locking mechanism via the transmission element increases or decreases depending on the drive travel. This means that in practical application relatively large, heavy and expensive drives are used in order to ensure that the closing movement can be implemented. Such a design is disadvantageous for weight and cost reasons. This is remedied by the invention.
The invention is based on the technical problem of further developing such a motor vehicle door closure in such a way that an optimized drive is provided that is lower in weight and cost but provides the same functionality.
In order to solve this technical problem, a generic motor vehicle door closure of the invention is characterized by the drive being designed to have a variable torque and act on the transmission element with a torque depending on the drive travel and thus a force depending on this drive travel.
According to an advantageous embodiment, the drive contains a torque converter. This torque converter is generally designed in such a way that with an increasing drive travel a progressively rising torque is provided on the output side. Alternatively, the torque converter can, however, also provide a degressively decreasing torque or a degressively decreasing force on the output side as the drive travel increases. The invention can also operate with a linearly increasing torque as the drive travel increases and a respectively linearly increasing force on the output side.
The torque on the output side or the respective force is in any case used to act on the transmission element. The said different designs (progressive, degressive, linear) can be advantageously achieved by the torque converter being interchangeable.
In the event that a closing device is provided, the drive travel corresponds to a closing travel. This closing travel generally starts in a preliminary closed position of the locking mechanism. The reaching of this preliminary closed position generally corresponds to the drive of the closing device being started and ensuring that the locking mechanism is moved from its preliminary closed position into its fully closed position. Consequently, the increasing closing travel is also part of the transition from the preliminary closed position into the fully closed position in the described example.—A potential alternative opening device will operate the other way around
As part of the drive, the torque converter will ensure in any case that as the drive travel or the closing travel increases in a closing device and thus during the transition from the preliminary closed position to the fully closed position, as in the described above example, the torque provided by the torque converter and thus the force or closing force increases progressively. As a result, the locking mechanism is also pulled closed as the force increases, so that any increasing counter forces produced by a compression of the door rubber seal, can be overcome.
This is achieved at this point with a relatively small and low-cost drive or a respectively designed electric motor, saving both weight and cost. The torque converter used by the invention is actually able to provide a power transmission of up to 4:1. This means that the power provided by the electric motor on the output side can be progressively increased by up to a factor of four along the drive travel or closing travel by the described torque conversion. These are the main advantages.
A torque converter can in general consist of any conceivable gear arrangement and can be implemented according to the invention, such as a planetary or helical gear. It is, however, particularly advantageous for the torque converter to be a cam disc connected to the drive. Such a cam disk offers the advantage of a low weight and a simple design, resulting in significantly reduced costs and weight despite of the additional torque converter. Such a cam disk can also be easily replaced, ensuring that the torque converter as a whole is interchangeable. In this case, the drive as a whole is designed in a manner of a drive kit, i.e. the cam discs connected to the drive can be selected and used depending on the desired torque curve.
The respective cam disc is typically driven with the aid of a screw connected to the drive shaft of the motor. As part of this process, the screw engages with a gear on the circumference of the cam disc. The cam disc advantageously contains a spiral control contour. The radius of the control contour increasing due to the spiral shape is designed in such a way that it increases from the centre of the cam disc in the direction of the circumference of the disc.
One end of the transmission element is in turn connected to the cam disc or the control contour. The other end of the transmission element acts, on the other hand, on the locking mechanism. This arrangement can be particularly advantageously and simply used where the transmission element is a Bowden cable.
Such a Bowden cable typically consists of a central core and a sleeve surrounding the core. Both ends of the sleeve are generally supported by the respective bearings. As a result, the core can transfer forces compared to the sleeve. According to the invention, the core is connected to the cam disc or is connected to the control contour formed on the cam disc. As the control contour contains a spiral radius increasing from the centre point, a torque increasing with the radius of the spiral control contour is exerted on the end of the transmission element connected to the cam disc or the core of the Bowden cable during a rotation of the cam disc. This increasing torque on the input side of the transmission element or of the Bowden cable corresponds on the output side to a respective progressively increasing force or closing force, with the aid of which the catch is, for instance, moved from its preliminary closed position into the fully closed position.
For this purpose, the end of the transmission element connected to the locking mechanism or the Bowden cable can act on a transmission lever, which in turn acts on the catch in a closing sense via a drive pawl, similarly as disclosed in the aforementioned DE 20 2008 015 789 U1. Alternatively, also the locking mechanism end of the transmission element or of the Bowden cable can act directly on the catch in order to close it in the described manner, i.e. to move it in the example from the preliminary closed position into the fully closed position.
In a particularly preferred embodiment, the torque converter is interchangeable. If it is the already discussed cam disc with the control contour, the design is such that the control contour is connected to the cam disc via a plug-in connection or a similar detachable connection. As a result the control contour can be easily adapted to the actual conditions in the respective motor vehicle door closure, depending on the design and the required force.
Also significant is the fact that the drive contains or can contain a spring mechanism. This spring mechanism can, for instance, be used to assist the closing movement. This is made possible by the fact that the drive charges the spring mechanism energetically during a reset movement and that the energy from the spring mechanism stored in this way is then also available during a working movement and supports the effect of the torque converter. The spring mechanism is advantageously a simple and cost effective leg spring, although this is not mandatory.
The object of the invention is also to provide a method for closing and opening a locking mechanism of a motor vehicle door latch, as explained in detail in claim 10. Below, the invention is explained in detail with reference to a drawing showing only one embodiment, in which:
The figures show a motor vehicle door latch containing a usual locking mechanism 1, 2 comprising a catch 1 and a pawl 2. The locking mechanism 1, 2 is only shown in
As soon as a closing force F acts on the Bowden cable 5, 6 or its core 5 in comparison to the sleeve 6 in a left direction in
The preliminary closed position shown
In order to be able to implement the closing movements described in
For this purpose, a sensor regularly checks whether the locking mechanism 1, 2 is in the preliminary closed position. As soon as the locking mechanisms 1, 2 has entered the preliminary closed position as a result of a respective motor vehicle door being closed, an electric motor 9 is energized as part of the drive 9, 10, 11.
The electric motor 9 acts on a torque converter 10, 11, which in turn acts on the transmission element 5, 6 for closing the locking mechanism 1, 2. In principle, the arrangement could also contain a reverse-acting opening device at this point, which is, however, not shown.
The drive 9, 10, 11 as such is designed for a variable torque. In this way the drive 9, 10, 11 acts on the transmission element 5, 6 with a torque depending on the drive travel s. As a result, the force or closing force F acting on the transmission element 5, 6 changes depending on the drive travel s. The drive travel s is indicated in the figures by a main arrow and is designed to have the same direction as the force or closing force F acting on the locking mechanism 1, 2.
In the example, the start of the drive travel s corresponds to the locking mechanism 1, 2 assuming the preliminary closed position shown in
As part of this invention, a torque depending on drive travel s, acts on the transmission element 5, 6. For this purpose, the drive 9, 10, 11 contains the already mentioned torque converter 10, 11. As the drive travel s increases, the torque converter 10, 11 provides a progressively increasing torque, as apparent when comparing
This increasing torque manifests itself in the circumstance that the end 5′ of the transmission element 5, 6 connected to the torque converter 10, 11 or of the core 5 of the Bowden cable 5, 6 forms a (small) radius R1 with an axis or a rotation axis 12 of a cam disc 10 at the start of the drive travel or of the closing travel s, as shown in
In contrast, the end of the drive travel or of the closing travel s contains a radius R2, as apparent from
The torque converter 10, 11 comprises the aforementioned cam disc 10 and a spiral control contour 11. The cam disc 10 is rotated by the electric motor 9. A counterclockwise movement of the cam disc 10 corresponds to the closing operation, i.e. a working movement of the drive 9, 10, 11. If the electric motor 9 does, however, act on the cam disc 10 in clockwise direction, this corresponds to a resetting movement of the drive 9, 10, 11.
The spiral control contour 11 contains a radius R increasing from the centre of the cam disc 10 or from the axis of rotation 12 towards the circumference of the cam disc 10, as shown in the figures, from an actual value R1 to R2. As a result of this spiral design of the control contour 11 the aforementioned different radii R1 to R2 are produced, depending on the position of the control contour 11 in relation to the end 5′ of the transmission element 5, 6. This results in the different torques along the drive travel or closing travel s and the respective forces F1, F2.
In order to be able to work with different torque converters 10, 11 in this way, the torque converter 10, 11 is interchangeable. The control contour 11 can contain a plug-in connection—not shown—or a comparable detachable connection with the cam disc 10. In general, the cam disc 10 can, however, also be designed to be interchangeable. As a result, not only the described torque progressions but also a torque linearly increasing with the closing travel s, can be achieved. Also a degressive or decreasing torque can be provided with an increasing closing travel s.
In the option shown in
In the option shown in
Number | Date | Country | Kind |
---|---|---|---|
10 2013 102 063.1 | Mar 2013 | DE | national |
10 2013 106 672.0 | Jun 2013 | DE | national |
This application is the U.S. national stage application of International Patent Application No. PCT/DE2014/000079, filed Feb. 27, 2014, which claims priority of German Application No. 10 2013 102 063.1, filed Mar. 1, 2013; and German Application No. 10 2013 106 672.0, filed Jun. 26, 2013, which are hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/DE2014/000079 | 2/27/2014 | WO | 00 |