This application is the U.S. National Phase of PCT Application No. PCT/EP2019/053679 filed on Feb. 14, 2019, the disclosure of which is hereby incorporated in its entirety by reference herein
The present disclosure relates to a door drive device for use in a motor vehicle.
A door drive device of this kind may include an adjustment member, a drive element operatively connected to the adjustment member such that the adjustment member is movable with respect to the drive element for moving the vehicle door relative to the vehicle body, a sensor device for measuring a measuring quantity indicative of a movement of the vehicle door to provide a sensor signal, and a control device for controlling operation of door device.
Such a vehicle door can, for example, be configured as a vehicle side door or as a tailgate or any other movable flap of a vehicle.
One or more objects of the present disclosure may be to provide a door drive device and a method for operating a door drive device which allow for a reliable operation of the door drive device in particular to counteract an unintentional movement of a vehicle door caused by gravity forces.
Accordingly, the control device is configured to compute, from the sensor signal obtained from the sensor device, an acceleration value indicative of an acceleration of the vehicle door, wherein the control device is further configured to evaluate the acceleration value to distinguish a moving of the vehicle door caused by a gravity force and a moving of the vehicle door caused by a user action.
Movement of a vehicle door caused by gravity and a movement caused by a user action are generally distinguishable. Generally, a gravity force acts onto a vehicle door generally by means of a constant acceleration, such that a movement of a vehicle door caused by gravity should generally exhibit a constant acceleration. In contrast, a movement caused by a user generally will exhibit an acceleration which differs from acceleration due to gravity and for example is not constant, such as if a user grabs on a vehicle door and intentionally moves the vehicle door in a guided fashion.
In addition, additional parameters may be taken into account, such as a speed signal and sensor readings of sensor devices such as an inclination sensor or the like providing information with respect to a parking position of a vehicle and a slope the vehicle may be parked on.
In one embodiment, the control device is configured to initiate a braking of a movement of the vehicle door in case a moving of the vehicle door caused by a gravity force is detected. Hence, if it is detected, from the evaluation the acceleration value indicative of an acceleration of the vehicle door, that the movement of the vehicle door likely is caused by gravity, such movement shall be counteracted. For this, for example a brake device is controlled such that the movement of the vehicle door is braked such that, beneficially, the movement is stopped, upon which the vehicle door may be locked in its current position. An uncontrolled movement caused by gravity hence is effectively prevented.
The braking of the vehicle door may be cause for example by a brake device acting onto a gearing element (e.g. the drive element), such that by means of the brake device a movement of the gear element may be braked. In this case a drive device may be permanently coupled to a drive train.
Alternatively, a brake device may serve as a coupling device to couple a drive element to a drive train, the brake device being switchable between a coupling state, a brake state and a free state. In the brake state a braking of the movement of the vehicle door may be caused.
Yet alternatively, an electromotive drive device may electrically be controlled to reduce a movement of the vehicle door, without requiring a brake device.
In one embodiment, the control device is configured to repeatedly compute the acceleration value over time or position. As an example, the control device may be configured to evaluate whether the acceleration value is substantially constant over a predetermined period of time or a predetermined period of position. If the control device concludes that the acceleration value is substantially constant over a predetermined period of time or a predetermined period of position, the control device issues a control signal to for example cause the brake device to brake a movement of the vehicle door with respect to the vehicle body, such that a movement caused by gravity is prevented.
Hence, by evaluating if the acceleration of the vehicle door is substantially constant, it is derived whether movement of the vehicle door is likely caused by gravity or not. It herein is concluded that the movement takes place at a substantially constant acceleration if over a predetermined period of time or a predetermined period of position no substantial change in acceleration occurs. Hence, over a predetermined time or a predetermined range of position it is observed whether and how acceleration changes. If acceleration does not substantially change, it is assumed that the acceleration is constant and thus may be due to gravity.
In one embodiment it may be concluded that the acceleration value is substantially constant if the acceleration value lies within a predefined range over the predetermined period of time or the predetermined period of position. If over a specified time range or a specified range of position the acceleration value does not substantially change, as it does not leave a predefined range bound by a lower acceleration threshold value and an upper acceleration threshold value, it is concluded that the movement takes place at substantially constant acceleration, such that the movement may be caused by gravity and is concluded to be caused by gravity for example if in addition the overall speed of movement of the vehicle door is small, as it lies below a predetermined speed threshold.
In one embodiment, the control device is configured to determine a rate of change of the acceleration value and to conclude for a potential movement due to gravity based on the rate of change. Generally, a vehicle door may initially be moved manually by a user acting onto the vehicle door, for example by pushing the moving the vehicle door in an impulse fashion or by continuously moving and holding onto the vehicle door. At some point the user may release the vehicle door, in case of which the vehicle door may continue to move, wherein the movement of the vehicle door now is influenced by gravity forces acting onto the vehicle door, such gravity forces potentially causing a deceleration or acceleration of the vehicle door, depending on the movement direction and the direction of the gravity forces.
For determining whether a movement is due substantially to gravity forces acting onto the vehicle door, the control device hence, beneficially, should be able to determine whether a user has released the vehicle door. This may take place by determining a rate of change of the acceleration of the vehicle door. If an abrupt change in the rate of change (derivative) of the acceleration of the vehicle door is detected, this may indicate that after this abrupt change now only gravity acts onto the vehicle door, which can subsequently be verified by detecting whether the acceleration remains substantially constant over a predetermined period of time or a predetermined period of position. If subsequently to the abrupt change the acceleration is substantially constant for a predetermined period of time or a predetermined period of position, it may be concluded for a movement due to gravity, and the control device may initiate a braking of the movement of the vehicle door.
In one embodiment, the control device is configured to compute, from the sensor signal obtained from the sensor device, a speed value indicative of a moving speed of the vehicle door, wherein the control device is configured to evaluate the speed value to distinguish a moving of the vehicle door caused by a gravity force and a moving of the vehicle door caused by a user action.
Generally, in addition to a substantially constant acceleration, a movement caused by gravity generally will occur at a rather slow speed, such that the evaluation of both the speed of the vehicle door and the acceleration of the vehicle door may allow for the determination whether a movement caused by gravity may be present. In contrast, a movement caused by a user generally will exhibit an acceleration which differs from acceleration due to gravity, and in addition a user will generally move a vehicle door at a rather fast speed, for example by pushing or by pulling on the vehicle door, such that a combined evaluation of speed and acceleration may reliably be used to distinguish a movement of the vehicle door caused by a user action and a movement of the vehicle door caused by gravity.
In one embodiment, the control device may be configured to initiate a braking of a movement of the vehicle door only if—in addition to for example a substantially constant acceleration value—the speed value derived from the sensor signal is smaller than a predefined speed threshold. Hence, in addition to the evaluation of the acceleration value the speed value is taken into account. Only if movement of the vehicle door takes place at a rather low speed, which is smaller than a predefined speed threshold, it is concluded that the movement of the vehicle door is due to gravity such that a braking action is initiated to prevent movement of the vehicle door.
In one embodiment the sensor device may be configured to sense position and/or angular speed of the vehicle door. For this, the sensor device may be configured to sense a rotation of a drive shaft to which the drive element is coupled. The sensor device herein may be configured to sense position in a relative manner or in an absolute manner by in a relative manner counting rotations of the drive shaft or by in an absolute manner detecting the absolute angular position of the drive shaft.
The sensor device may for example comprise one or multiple Hall sensors suitable for sensing position in a relative manner. Alternatively, the sensor device may comprise for example a magnetic disk attached to the drive shaft such that an absolute detection of position of the drive shaft is possible.
In an alternative embodiment, the sensor device may be implemented by a speed sensor for sensing the rotational speed (angular velocity) of the vehicle door or by an accelerometer for sensing acceleration on the vehicle door and may be placed on the vehicle door for a direct measurement on the vehicle door.
In addition to the sensor device for detecting a movement of the vehicle door (from which speed and acceleration can be derived) an inclination sensor may be placed on the vehicle body. The inclination sensor is configured to sense an inclination of the vehicle. From a reading of the inclination sensor it hence may be determined whether the vehicle is parked at an inclined position at a slope.
The inclination sensor may sense inclination in all three spatial directions and hence in three dimensions. From the reading of the inclination sensor it may be estimated what gravity forces act onto the vehicle door. As an example, if the vehicle is parked at an inclined position, gravity forces acting onto the vehicle door in an opened position may be substantially larger (or smaller) than in a situation in which the vehicle is parked in a flat, non-inclined position.
Based on an inclination of the vehicle, parameters used for determining whether a movement due to gravity is present may be adjusted. As an example, thresholds for the acceleration and/or the speed may be adjusted, and/or the length of the period of time over which the acceleration shall substantially be constant can be adapted. In this way it can be taken into account that at large gravity forces acting onto the vehicle door, for example, the speed by which the vehicle door is moved due to gravity is substantially larger than when only a small gravity forces act onto the vehicle door. This can be taken into account by suitably adjusting threshold values such that the determination whether a movement due to gravity is present can be adaptively modified dependent on a parking position of the vehicle.
In one embodiment, the door drive device may include a brake device operatively connected to the drive element for braking a movement of the vehicle door with respect to the vehicle body.
In one embodiment, the brake device is implemented by a coupling device which is transferable between different states. As an example, the brake device in a brake state provides for a braking action for braking a movement of the vehicle door with respect to the vehicle body. The brake device in this respect may for example act onto the drive shaft connected to the drive element such that in this way a movement of the drive element and thus a movement of the vehicle door with respect to the vehicle body is counteracted.
In addition, the brake device may assume a coupling state for establishing a force flow between the vehicle door and the vehicle body, wherein the brake device may be switchable to an uncoupling state for allowing a free pivoting of the vehicle door with respect to the vehicle body. In the coupling state, for example, an electric drive motor of the door drive device may be coupled to the drive element such that a driving force can be introduced into the drive element for electromotively moving the vehicle door with respect to the vehicle body. In the uncoupling state, in turn, the drive motor may be effectively decoupled from the drive element, such that a free pivoting movement of the vehicle door with respect to the vehicle body, for example by manual user action, is possible without loading the drive motor.
The brake device may for example have the shape of a drum brake device as described for example in WO 2018/002158 A1. The brake device may however also be designed in a different manner, for example as a lamella brake, a magnetic brake or the like.
The brake device herein may serve the function, in addition, of a coupling device, wherein it also is conceivable to implement a brake device and a coupling device by different functional units.
The object is also achieved by a method for operating a door drive device for adjusting and/or locking a vehicle door relative to a vehicle body, the method comprising: measuring, using a sensor device, a measuring quantity indicative of a movement of the vehicle door to provide a sensor signal; braking, using a brake device, a movement of the vehicle door with respect to the vehicle body, wherein the brake device is operatively connected to a drive element which is operatively coupled to an adjustment member such that the adjustment member is movable with respect to the drive element for moving the vehicle door relative to the vehicle body; and controlling, using a control device, operation of the door drive device. Herein, the method may include the further step of computing, using the control device, from the sensor signal obtained from the sensor device an acceleration value indicative of an acceleration of the vehicle door, and evaluating, using the control device, the acceleration value to distinguish a moving of the vehicle door caused by a gravity force and a moving of the vehicle door caused by a user action.
The advantages and advantageous embodiments described above for the door drive device equally apply also to the method, such that it shall be referred to the above.
The idea underlying the invention shall be explained in more detail below according to the embodiments of the figures. Herein:
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
A door drive device as disclosed for example in WO 2018/002158 A1 may include an adjustment member in the shape of a retaining strap coupled for example to the vehicle body and operatively connected to a drive element in the shape of a cable drum. The coupling of the adjustment member to the drive element is established by means of a coupling element in the shape of a pull cable, which is wound around the cable drum and by means of which the cable drum can be moved with respect to the adjustment member in order to cause a movement of the vehicle door with respect to the vehicle body. A drive device is coupled to the drive element by means of a gearing and a coupling device serving as a brake device, the coupling device being designed such that in a coupling state a coupling of the drive device to the drive element is established, in an uncoupling state however a free pivoting movement of the vehicle door with respect to the vehicle body is possible. In a brake state of the coupling device a movement of the drive element and in this way a movement of the vehicle door with respect to the vehicle body is braked, such that for example a manual movement of the vehicle door can be controlled.
The door drive device in principle may be configured as an adjusting and/or locking device and may be used to electromotively adjust the vehicle door or to mechanically lock the vehicle door in a currently assumed position. If the door drive device is configured as an electromotive adjusting device, it may include a drive device in the form of an electric drive motor by means of which the vehicle door can be electromotively moved. In contrast, the door drive device may substantially act as a mechanical locking device for providing for a mechanical locking of the vehicle door in an open position, such that the vehicle door is held in position so that the vehicle door cannot easily slam shut from the open position, at least not in an uncontrolled manner.
The door drive device allows for a movement of the vehicle door by manual user action. As an example, if a coupling device (for example implemented by the brake device) is in an uncoupling state and hence a force flow in between the vehicle door and the vehicle body is disrupted, a user may act onto the vehicle door and may freely pivot the vehicle door with respect to the vehicle body in order to move the vehicle door between a closed position and a fully opened position.
In case a free movement of the vehicle door is possible, for example because a coupling device is in its uncoupling state, a movement of the vehicle door may also be caused by other forces, for example by gravity in case a vehicle is parked on a slope. Such movement may be unintentional and hence if possible should be avoided in order to prevent an uncontrolled movement of the vehicle door towards the fully opened position or towards the fully closed position, which may otherwise cause harm to a user or may damage the vehicle door or an object in the path of the vehicle door.
The vehicle door 11 can, for example, be a vehicle side door or a tailgate. In a closed position, the vehicle door 11 conceals a vehicle opening 100 in the vehicle body 10, for example a side door opening or a tailgate opening.
The vehicle door 11 can electromotively be moved from its closed position to an open position via a door drive device 2 arranged in a door interior 110. The door drive device 2, as schematically illustrated in
In the embodiments of the door drive device 2 shown in
The coupling element 24 is connected to the adjustment member 20 via a first end 240 in the vicinity of the end 200 of the adjustment member 20 and via a second end 241 in the vicinity of a second end 201 of the adjustment member 20, and is wound around the drive element 23 in the shape of the cable drum. When the drive element 23, driven by the drive motor 22, is rotated, the coupling element 24 in the shape of the traction element (traction cable) moves relative to the drive element 23 so that the drive element 23 is moved relative to the adjustment member 20, resulting in displacement of the vehicle door 11 relative to the vehicle body 10.
It should be noted at this point that other types of power transmission arrangements are conceivable. For example, the drive motor 22 can also drive a pinion which is in meshing engagement with a tooth rack forming the adjustment member 20. Alternatively, the door drive device may be configured as a spindle drive comprising, for example, a rotatable spindle that engages with a spindle nut.
The brake device 21, in the noted embodiments, serves as a coupling device to couple the drive motor 22 with the drive element 23 or to uncouple it from the drive element 23. In a coupling state, the brake device 21 establishes a flux of force between the drive motor 22 and the drive member 23 such that a rotational movement of a motor shaft 220 of the drive motor 20 is transmitted to the drive member 23 and, consequently, the drive member 23 is set into a rotational movement so as to thereby introduce an adjusting force into the adjustment member 20. In an uncoupling state, in contrast, the drive motor 22 is uncoupled from the drive element 23, so that the drive motor 22 can be moved independently of the drive element 23 and, conversely, the drive element 23 can be moved independently of the drive motor 22. In this uncoupling state, the vehicle door 11 may be manually moved with respect to the vehicle body 10 without applying a load to the drive motor 22.
The brake device 21 can in addition assume a third state, corresponding to a brake state, in which coupling elements are in contact with each other in a braking manner. A first coupling element herein is operatively connected to a motor shaft of the drive motor 22, while a second coupling element is operatively connected to the drive element 23. In this brake state the brake device 21 provides a braking force during manual movement of the vehicle door 11, caused by a sliding, frictional contact of the coupling elements.
In the example shown in
The door drive device 2 may include a sensor device 27 arranged at an end of the shaft 26 opposite the drive element 23 and configured to determine, during operation, the absolute rotational position of the shaft 26. The sensor device 27 may for example comprise a magnetic disk coupled to the shaft 26 and a magnetic sensor for detecting a position of the magnetic disk.
The brake device 21, which can be electrically actuated via an actuator 210, in its coupling state establishes a force flow between the gear 25 and the shaft 26, so that in the coupling state of the brake device 21 an adjusting force can be transmitted from the drive motor 22 to the shaft 26 and in this way to the adjustment member 20. In its uncoupling state, on the other hand, the brake device 21 disrupts the force flow between the drive motor 22 and the shaft 26, so that the adjustment member 20 can be adjusted relative to the drive motor 22 without applying a force to the drive motor 22.
As schematically shown in
The door drive device 2, as explained by reference to
It is desirable to enable a user to easily adjust the vehicle door 11. For this it is to be detected when a user interacts with the vehicle door 11 in order, for example, to close the vehicle door 11 from the open position or to open it further in the opening direction O. If a user applies a force to the vehicle door 11, for example by pushing or pulling on the vehicle door 11, this shall be recognized as an adjustment request in order to initiate an electromotive adjustment of the vehicle door 11 or to permit a manual adjustment of the vehicle door 11 by the user.
If an adjustment request of a user is detected, the control device 28 may be configured in different ways to initiate an adjustment of the vehicle door 11 in an electromotive manner or to allow a manual adjustment of the vehicle door 11.
If the vehicle door 11 is to be adjusted by an electric motor when an adjustment request is detected, the control unit 28 controls the drive motor 22 to electromotively adjust the vehicle door 11 once an adjustment request is detected. In this case, the brake device 21 remains in its closed (coupling) state.
If, in contrast, a manual movement of the vehicle door 11 shall be enabled when an adjustment request is detected, the control device 28 controls the brake device 21, once an adjustment request is detected, to transfer the brake device 21 into its free (uncoupling) state so that the force flow between the vehicle door 11 and the vehicle body 10 is disrupted and the vehicle door 11 can freely be moved manually.
If the brake device 21 is in its free, uncoupling state, a free pivoting of the vehicle door 11 with respect to the vehicle body 10 is possible. If, for example, the brake device 21 is switched to its free, uncoupling state in case for example erroneously a request for movement is detected or in case the vehicle door 11 is not (yet) locked in a currently assumed position by switching the brake device 21 to its coupling state, a free pivoting movement of the vehicle door 11 may be caused both by a user action and by other forces acting onto the vehicle door 11, for example gravity forces in case a vehicle is parked on a slope and hence at an inclined position of the vehicle door 11, causing gravity to act onto the vehicle door 11 towards the fully opened position or towards the closed position.
Hence, if gravity forces act along the opening direction O onto the vehicle door 11 and in case the brake device 21 is in its free, uncoupling state, a movement of the vehicle door 11 caused by gravity is possible, such movement potentially being undesired. Such movement therefore shall be avoided.
In
Generally, a movement caused by gravity will take place at (approximately) a constant acceleration, as visible from the acceleration signal G in
Hence, a movement caused by gravity can be characterized by a substantially constant acceleration over time or position (
A movement caused by a user action, for example by a user manually grabbing a vehicle door to move the vehicle door 11 in a guided fashion or by applying a pushing or pulling impulse action onto the vehicle door 11, will in general differ from a movement caused by gravity, as for a user action acceleration may not be constant and/or the speed of movement of the vehicle door 11 will be substantially larger.
In
Movement M1 herein relates to a type of movement in which a user pushes or pulls, by applying a force impulse, on the vehicle door 11, such that the vehicle door 11 is caused to move, after termination of the impulse, due to the force applied by the impulse. After termination of the impulse, no further acceleration caused by the user acts onto the vehicle door 11, but gravity may act onto the vehicle door 11, such that the acceleration of signal M1 (
Movement M2 in contrast relates to a movement during which a user continuously acts onto the vehicle door 11 and moves the vehicle door 11 in a guided fashion by for example grabbing a handle of the vehicle door 11. In this case, after an initial impulse, the vehicle door 11 may be moved at constant speed (
From this it can be concluded that a manual movement M1, M2 can be distinguished from a movement G caused by gravity by observing speed and acceleration. As an example, if it can be concluded that acceleration over a predetermined period of time T (or, alternatively, over a predetermined period of position) is substantially constant and if at the same time the speed of the movement of the vehicle door 11 is rather low, the movement of the vehicle door 11 may likely be caused by gravity.
The control device 28 hence is configured to evaluate, from for example a sensor signal obtained from the sensor 27 monitoring movement of the drive shaft 26, whether the vehicle door 11 is moved at substantially constant acceleration and at a low speed.
If it is found that within a predetermined period of time T (or alternatively within a predetermined period of position) acceleration is substantially constant (as illustrated in
The control device 28 may for example be configured to conclude that a substantially constant acceleration is present if the acceleration, within a predetermined period of time T (or alternatively within a predetermined period of position) lies within a range bound by a lower acceleration threshold value a1 and an upper acceleration threshold value a2, as illustrated in
The sensor signal herein may be averaged (by for example applying a running averaging filter) in order to compensate for outliers.
In addition, the control device 28 may be configured to conclude that the speed is low if for example the speed of movement lies below an upper velocity threshold value v2 and, optionally, in addition above a lower velocity threshold value v1, as illustrated in
If both conditions are fulfilled, it is concluded for a movement caused by gravity, such that the brake device 21 is caused to apply a braking action to the drive element 23.
The movements M1, M2 in this way are distinguished from the movement of G caused by gravity, such that the movements M1, M2 are not falsely recognized as a movement caused by gravity. As an example, for movement M1 the movement of the vehicle door 11 takes place at a high speed, as visible from
The bounds a1, a2, v1, v2 may for example be user configurable. In addition, the period of time T (or alternatively a period of position) may be user configurable, such that the control device 28 may be programmed and adapted for example to different vehicles and different vehicle doors.
Whereas
As an example, within the algorithm of
Namely, first it is determined whether the acceleration a falls below a (negative) acceleration threshold a3, which in the example of
Subsequent to the determination that the acceleration a has fallen below the threshold a3 (i.e., the negative acceleration a exceeds the threshold a3) at time point A1, it is determined whether the acceleration a changes abruptly in its derivative. For this, a rate of change of the acceleration a may be determined, and from the rate of change it may be concluded for an abrupt change. This in the example of
If in the interval between time points A2 and A3 the acceleration a remains within bounds a1, a2, it is assumed that the acceleration a is sufficiently constant, and it hence is concluded that the movement is due to gravity. Once the velocity v at time A4 falls below a velocity threshold v3, the movement of the vehicle door 11 thus is braked and hence stopped, such that the vehicle door 11 is hold fixed in its opened position.
Whereas
Whereas
The threshold v3, v4 in
The algorithm may in addition take into account an opening angle of the vehicle door 11. For example, in case of small opening angles the algorithm may be switched off.
In
In case a vehicle 1 is parked at a flat parking position (
Dependent on the inclination of the vehicle 1, hence, parameters used for determining whether gravity forces act onto the vehicle door 11 may be adjusted. As an example, the threshold v1, v2 and a1, a2 of the embodiment of
By adjusting the parameters it can be made sure that also in a situation as in
The idea underlying the invention is not limited to the embodiments described above, but can also be implemented in a completely different way.
As an example, a door drive may comprise a mechanical adjustment mechanism other than a cable drive, for example a pinion gear for coupling a drive motor to an adjustment member. Alternatively, the door drive can be configured as a spindle drive, in which, for example, a rotatable spindle engages with a spindle nut such that the spindle nut may be moved along the spindle by rotary movement of the spindle.
In the case of a mechanical locking device, a drive motor possibly is not present in the door drive device.
The following is a list of reference numbers shown in the Figures. However, it should be understood that the use of these terms is for illustrative purposes only with respect to one embodiment. And, use of reference numbers correlating a certain term that is both illustrated in the Figures and present in the claims is not intended to limit the claims to only cover the illustrated embodiment.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/053679 | 2/14/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/164712 | 8/20/2020 | WO | A |
Number | Name | Date | Kind |
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8104822 | Kriese | Jan 2012 | B2 |
20090217596 | Neundorf | Sep 2009 | A1 |
20100287837 | Wuerstlein | Nov 2010 | A1 |
20130097940 | Brown | Apr 2013 | A1 |
20140083011 | Sumiya | Mar 2014 | A1 |
20160010379 | Sauerwein | Jan 2016 | A1 |
20160060942 | Hansen | Mar 2016 | A1 |
20170138099 | Wittorf | May 2017 | A1 |
20170247926 | Elie | Aug 2017 | A1 |
20180023334 | Kwak | Jan 2018 | A1 |
20190128041 | Haberberger | May 2019 | A1 |
20220268074 | Leonard | Aug 2022 | A1 |
Number | Date | Country |
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102009001668 | Sep 2010 | DE |
102016223667 | Nov 2016 | DE |
102018205138 | Oct 2019 | DE |
3299561 | Mar 2018 | EP |
2018002158 | Jan 2018 | WO |
Number | Date | Country | |
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20220145684 A1 | May 2022 | US |