WO2022043109A1 - Electric locking and unlocking device of a seat rail - Google Patents

Abstract

The invention relates to a locking and unlocking device for a rail (10, 20) of a rail system of a vehicle seat, which can be adjusted by means of an electric seat rail drive by actuating an actuation element paired with the vehicle seat. The locking and unlocking device of the rail (10, 20) comprises an electric unlocking drive which, by actuating the actuation element, unlocks the rail (10, 20) prior to an electric adjustment of the vehicle seat.

Description

description

Electrical locking and unlocking device for a seat rail

The invention relates to a locking and unlocking device for a rail of a rail system of a vehicle seat, which can be adjusted by means of an electric seat rail drive by actuating an actuating element assigned to the vehicle seat.

In the publications DE 36 13 832 A1, DE 198 15 542 C1, DE 102007 029 976 B4, DE 10 2017 117 534 A1 and DE 102018 110683 A1 locking and unlocking devices are disclosed in connection with a locking and unlocking of vehicle seats, wherein In some applications, magnets or electromagnets are also used, with reference being made in particular to the document DE 36 13 832 A1, in which the blocking elements of a rail guide system that can be locked and unlocked are selected in such a way that they are held in a permanent blocking position by springs and during seat adjustment be pulled over electromagnets and also by hand in the sense of releasing a brake in exemption.

In particular, rail guide systems for guiding vehicle seats with short and long rails are known. From a certain length, longer rails can no longer be driven with a spindle, since the spindle rod used in this case breaks off from a certain length in a crash scenario that has to be taken into account, with a corresponding force being applied to the spindle rod. The drive, in particular the motorized drive of long rails, therefore takes place, for example, via a gear/rack arrangement or frictionally with a drive wheel on a surface provided for this purpose.

The disadvantage of these drive solutions, however, is that no crash forces are transmitted in the direction of travel that coincides with the course of the rails of the rail guidance system, so that it is necessary to design a crash-safe locking mechanism that unlocks before the rails of the rail guidance system are adjusted and securely locks again after the adjustment will. Since a crash can also occur during an adjustment process, locking or relocking must be able to take place particularly quickly. The object of the invention thus relates to a locking and unlocking device for a rail of a rail system of a vehicle seat.

The object of the invention is to create a locking and unlocking device for a rail system of a vehicle seat, which ensures quick and safe locking and unlocking of the vehicle seat.

The starting point for the insertion is a locking and unlocking device for a rail of a rail system of a vehicle seat, which can be adjusted by means of an electric seat rail drive by actuating an actuating element assigned to the vehicle seat.

According to the invention, it is provided that the locking and unlocking device of the rail comprises an electrical unlocking drive which, by actuating the actuating element before the vehicle seat is electrically adjusted, causes the rail to be unlocked.

The invention thus relates to a vehicle seat having a locking and unlocking device according to the invention for a rail of a rail system of the vehicle seat, which can be adjusted by means of the electric seat rail drive by actuating an actuating element assigned to the vehicle seat, it being provided according to the invention that the locking and unlocking device the rail comprises the electric unlocking drive, which causes the rail to be unlocked by actuating the actuating element before the electric adjustment of the vehicle seat, the vehicle seat being set up to adjust the lengthwise seat stepwise by electric activation by means of a control unit in which a computer-readable program algorithm is stored of the unlocking drive and the seat rail drive.

Preferred configurations consist in the locking and unlocking device comprising a locking element on the seat rail side and an unlocking element which are mechanically connected to one another, the unlocking element being brought from a first position to a second position by an actuator of the unlocking drive when the actuating element is actuated is, whereby the locking element comes from a locking position with release of an upper rail relative to a lower rail of the seat rail in an unlocking position, wherein the unlocking element for adjusting the vehicle seat on the seat rail is held in the second position. In one embodiment, it is preferably provided that the unlocking element is held in the second position by the actuator for as long as the user desires a longitudinal adjustment of the seat by actuating the actuating element.

In another preferred embodiment, the locking and unlocking device also comprises an electromagnet as a holding element which, when energized, holds the unlocking element in the second position, which is fed to the holding element by the actuator of the unlocking drive. In this embodiment, the unlocking element is held in the second position by the electromagnet for as long as the user desires a longitudinal adjustment of the seat by actuating the actuating element.

A preferred embodiment provides that the actuator of the unlocking drive is a member rotating about an axis, which pivots from an initial position to a first position in which the actuator comes into contact with the unlocking element, and then from the first position to a second position occurs in which the actuator holds the unlocking element in the second position (first embodiment) or transfers it to the electromagnet as a holding element in the second position and holds it in the second position (second embodiment), the actuator being designed in such a way that it can swing past the unlocking element as soon as it leaves the second position.

It is preferably provided that the unlocking drive with its actuator and the seat rail drive as well as the locking element on the seat rail side and the unlocking element are arranged on the upper rail of the seat rail.

The invention is explained in more detail below with reference to the associated drawings in two preferred embodiments, with the same reference numbers being used for the same components in both embodiments.

A first embodiment is shown in Figures 1A to 1C.

Show it:

FIG. 1A shows a section through a locking and unlocking device according to the first embodiment in a locking position; FIG. 1B shows the section through the locking and unlocking device according to the first embodiment in an unlocked position;

FIG. 1C shows the section through the locking and unlocking device according to the first embodiment in the restored locked position.

A second embodiment is shown in Figures 2A to 2C.

Show it:

FIG. 2A shows a section through a locking and unlocking device according to the second embodiment in a locking position;

FIG. 2B shows the section through the locking and unlocking device according to the second embodiment in an unlocking position;

FIG. 2C shows the section through the locking and unlocking device according to the second embodiment in the restored locked position.

A third embodiment is shown in Figures 3A and 3B.

FIG. 3A shows a section through a locking and unlocking device according to the third embodiment in an unlocking position;

FIG. 3B shows the section through the locking and unlocking device according to the second embodiment in a locking position;

First embodiment:

FIG. 1A shows a section through a locking and unlocking device according to a first embodiment.

A vehicle seat, not shown in detail, is connected to an upper rail 20 which is movably arranged with respect to a lower rail 10 fixed to the body. According to FIG. 1A, the upper rail 20 is locked in relation to the lower rail 10 by means of at least one locking element 30 . The top rail 20 includes a bearing or panel part 21 with an opening through which the at least one locking element 30 is guided to the top rail 20 and bottom rail 10 . The at least one locking element 30 is movably mounted in the bearing or panel part 21 transversely to the longitudinal extension of the seat rail in the horizontal installed state of the seat rail in the vertical direction.

The at least one locking element 30 is connected to an unlocking element 40, in particular an unlocking lever.

In FIG. 1A, the unlocking element 40 is arranged between a first position 40.1 and a second position 40.2, in which the locking element 30 locks the upper rail 20 in relation to the lower rail 10. The first position 40.1 of the unlocking element 40 is shown in FIG. 1C. The second position 40.2 of the unlocking element 40 is shown in FIG. 1B.

The unlocking element 40 is arranged pivotably on a bearing 50 such that a movement of the free end 41 of the unlocking element 40 leads to translational movement with an end 42 of the unlocking element 40 and thus of the locking element 30 connected to the locking element 30 . In the exemplary embodiment, the bearing 50 is fixedly arranged on the bearing or screen part 21 .

In other words, an actuation of the unlocking element 40 from the first position 40.1 shown in Figure 1A to a second position 40.2, which is shown in Figure 1B, leads to an unlocking of the locking element 30 into its unlocking position II. The at least one locking element 30 is 1A is always pressed by means of a spring element not shown in detail into the locking position I, so that the direction of movement of the locking element 30 according to the movement arrow P1 (upward) takes place against the force of the spring element.

The upper rail 20 can be moved electrically relative to the lower rail 10 by means of an electric drive, which is referred to below as the seat rail drive. The seat rail drive is not shown. The upper rail 20 is actuated in relation to the lower rail 10 by manual actuation of an actuation element which, by its actuation direction, causes an electrical longitudinal adjustment of the vehicle seat in one direction or the other, i.e. in the usual arrangement of the vehicle seat in a motor vehicle mostly forwards or backwards , causes.

According to the invention, the locking and unlocking device also includes a further electric drive, which is referred to below as the unlocking drive. The unlocking drive itself is also not shown. However, FIGS. 1A to 1C show an actuator 60 which is integrated into the unlocking drive and which acts on the free end 41 of the unlocking element 40 .

According to the invention, the unlocking drive is actuated with the same actuating element with which the seat rail drive is actuated. In other words, by actuating the actuating element, the unlocking drive and the seat rail drive are energized one after the other and the locking element 30 is unlocked step by step and the vehicle seat is then longitudinally adjusted by the movement of the upper rail 20 in relation to the lower rail 10, as follows will be explained further.

In Figure 1A, the actuator 60 is already in a first position A, starting from an initial position A' shown in broken lines, in which the actuator 60 is already in mechanical operative connection with the free end 41 of the unlocking element 40, but the actuator 60 begins in this representation just to act on the free end 41 of the unlocking element 40, so that the unlocking element 40 is still arranged with its lower engagement end in the lower rail 10, but in the further course of the movement of the actuator 60 moves out of the lower rail 10, so that the unlocking element 40 finally the Leaves locking position I.

When the vehicle seat is actuated by means of the electric longitudinal seat adjustment, the person actuates the actuating element, as a result of which the unlocking drive 60 is actuated in a first step, so that the actuating element 60 moves from the first position 40.1 (Figure 1A) to a second position B (Figure 1B) is relocated.

In the exemplary embodiment, the actuator 60 rotates by one, starting from the initial position A'

axis of rotation by a definable angle in the first layer A, contacts that Unlocking element 40 and takes it with the free end 41 of the unlocking element 40, wherein the actuator 60 is shifted to the second position B (Figure 1B). After the second position B is reached, a control program of a control unit (not shown) for adjusting the vehicle seat fore and aft ensures that the unlocking drive is de-energized so that the unlocking element 40 is held in the second position 40.2.

Using the procedure described above, the unlocking element 40 pivots via the bearing 50 with its locking element-side end 42 in the direction of the arrow P1 upwards, as a result of which the unlocking position II of the locking element 30 is set and assumed.

Figure 1B shows the section through the locking and unlocking device according to the first embodiment, the unlocking position II of the locking element 30, in which the unlocking element 40 is located with its two ends 41, 42 in its second position 40.2, with the actuator 60 now being in the second layer B is located.

During the movement of the unlocking element 40, a spring element (not shown) is preferably tensioned, which ensures that after the unlocking element 40 has been released, the unlocking element 40 is returned to its first position 40.1 by the tensioned spring element.

After the unlocking drive 60 has been actuated and the unlocking position II (FIG. 1B) is present, the longitudinal adjustment of the vehicle seat takes place by means of the seat rail drive until the person interrupts the actuation of the actuating element.

On the control side, according to the invention it is ensured that the seat rail drive is likewise immediately de-energized when the person interrupts the actuation of the actuating element.

To lock the seat rail, at the moment when the person interrupts the actuation of the actuating element, the control program of the control unit for adjusting the longitudinal seat of the vehicle seat (not shown in detail) ensures that the unlocking drive is briefly energized again in a pulse-like manner, so that the actuator 60 leaves its second position B. As a result, the actuator 60 releases the second position 40.2 of the unlocking element 40, which, by the adjustment movement of the Unlocking element 40 from the first position to the second position 40.2 tensioned spring element is moved back to the first position 40.1.

As a result, the first end 41 is correspondingly shifted back into its position shown in FIG. 1A and the locking element 30 returns to its locking position I.

FIG. 1C shows the section through the locking and unlocking device according to the first embodiment in the locking position II of the locking element 30 after the locking element 30 according to FIG. 1B has been unlocked.

It is clear that the actuator 60 is in a third position C after the short-term pulse-like energization after the person has interrupted the actuation of the actuating element, which is characterized in that the actuator 60 from the second position B by a predetermined adjustment angle has further rotated (clockwise) to the third position C, whereby the free end 41 of the release lever 40 has been released. The actuator 60 and/or the unlocking element 40 are designed in such a way that the actuator 60 can run off the end of the unlocking element 40 .

According to the movement arrow P2, the unlocking element 40 pivots via the bearing 50 with its locking element-side end 42 downwards again in the direction of the arrow according to the movement arrow P2, as a result of which the locking position I of the locking element 30 is assumed again.

The locking movement of the locking element 30 is supported by the spring element, not shown in detail, which is associated with the at least one locking element 30 .

It goes without saying that when the locking and unlocking device is actuated again, the actuator 60 does not have to be moved further by 180° in the direction of rotation from the third position C, since the actuator 60 is designed to be axially symmetrical with respect to its geometric shape in relation to the axis of rotation, see above that the third position C of the actuator 60 corresponds to the starting position A' according to FIG. 1A. In other words, the opposite ends of the actuator 60 alternately act on the unlocking member 40 after rotating through 180° in the successive operations for seat adjustment of the vehicle seat. The procedure described above also advantageously ensures that the seat rail, that is to say the upper rail 20 relative to the lower rail 10, is locked in the event of a crash. In such a case, the person's manual actuation of the actuation element for longitudinally adjusting the vehicle seat is interrupted because of the crash, since the respective person will let go of the actuation element in the event of a crash. In this case, as explained, the power supply of the seat rail drive is interrupted and only the unlocking drive is briefly energized again via the control program of the control unit, not shown in detail, whereby the actuator 60 leaves the second position B and preferably into the third position C, which corresponds to the initial position A', thereby ensuring that the locking position I of the at least one locking element 30 is resumed since the unlocking element 40 returns to the first position 40.1 shown in Figure 1C.

Second embodiment:

The second embodiment differs from the first embodiment in particular in that the locking and unlocking device also has a holding element in the form of an electromagnet 70, which changes the procedure or mode of operation of the locking and unlocking device, as can be seen by comparing the following description with that of Description of the first embodiment becomes clear.

FIG. 2A shows a section through a locking and unlocking device according to a second embodiment.

The vehicle seat, which is not shown in detail, is connected to the upper rail 20, which is arranged such that it can move with respect to the lower rail 10 fixed to the body.

According to FIG. 2A, the upper rail 20 is locked in relation to the lower rail 10 by means of the at least one locking element 30 . The top rail 20 includes the bearing or panel part 21 with the opening through which the at least one locking element 30 is guided to the top rail 20 and bottom rail 10 . The at least one locking element 30 is movably mounted in the bearing or panel part 21 transversely to the longitudinal extension of the seat rail in the horizontal installed state of the seat rail in the vertical direction. The at least one locking element 30 is connected to the unlocking element 40, in particular an unlocking lever.

The unlocking element 40 is arranged in FIG. 2A in a first position in which the locking element 30 locks the upper rail 20 in relation to the lower rail 10 .

The unlocking element 40 is arranged pivotably on the bearing 50 such that a movement of the free end 41 of the unlocking element 40 leads to the translational movement of the end 42 of the unlocking element 40 connected to the locking element 30 and thus of the locking element 30 . The bearing 50 is fixed to the bearing or screen part 21 .

In other words, an actuation of the unlocking element 40 from the first position shown in Figure 2A to a second position, which is shown in Figure 2B, leads to an unlocking of the locking element 30 into its unlocking position II Spring element shown in more detail is always pressed into the locking position I shown in FIG. 2A, so that the movement of the locking element 30 according to the movement arrow P1 (upward) takes place against the force of the spring element.

The upper rail 20 can be moved electrically relative to the lower rail 10 by means of the electric drive, which is referred to below as the seat rail drive. The seat rail drive is not shown.

The upper rail 20 is actuated in relation to the lower rail 10 by manual actuation of the actuating element, which, due to its actuating direction, causes an electrical longitudinal adjustment of the vehicle seat in one direction or the other, i.e. in the usual arrangement of the vehicle seat in a motor vehicle mostly forwards or backwards , causes.

According to the invention, the locking and unlocking device also includes the additional electric drive, which is referred to below as the unlocking drive. The unlocking drive itself is also not shown. However, the actuator 60 which is integrated into the unlocking drive and which acts on the free end 41 of the unlocking element 40 is shown in FIGS. 2A to 2C. According to the invention, the unlocking drive is actuated with the same actuating element with which the seat rail drive is actuated. In other words, by actuating the actuating element, the unlocking drive and the seat rail drive are energized one after the other and the locking element 30 is unlocked and the vehicle seat is longitudinally adjusted by the movement of the upper rail 20 relative to the lower rail 10, as will be explained further below .

A comparison of FIGS. 1A to 1C with FIGS. 2A to 2C makes it clear that in the second embodiment, a holding magnet that can be energized is additionally arranged on the bearing and screen element 21, which is only shown symbolically.

The holding magnet is therefore an electromagnet whose electromagnetic holding force (attractive force) is only effective when energized.

In Figure 2A, actuator 60 is in its home position A'.

When the vehicle seat is actuated by means of the electric longitudinal seat adjustment, the person actuates the actuating element, as a result of which the unlocking drive is actuated in a first step, so that the actuator 60 is shifted from the initial position A' to the first position A (Figure 2B).

In the first position A according to FIG. 2B, in which the actuator 60 is mechanically operatively connected to the free end 41 of the unlocking element 40, the unlocking element 40 begins to move out of the lower rail 10 with its lower engagement end in order to produce the unlocking position II of the seat rail.

In this embodiment, the actuator 60 rotates starting from the starting position A' about its axis of rotation by a predeterminable angle into the first position A, contacts the unlocking element 40 and takes the free end 41 of the unlocking element 40 with it, with the actuator 60 subsequently moving further into the second position B (see FIG. 2C) is shifted, in which the unlocking element 40 is attracted and held by the electromagnet 70 with its first end 41. For this purpose, the electromagnet 70 and the unlocking drive are energized via the controller essentially at the same time. In this second embodiment, the actuator 60 thus pivots, starting from the starting position A' (Figure 2A), by 180 degrees into the third position C (Figure 2C) and in the process transfers the first end 41 of the unlocking element 40 to the energized electromagnet 70. The actuator 60 and/or the unlocking element 40 are designed in such a way that the actuator 60 can run off at the end of the unlocking element 40—over the second layer B—(compare FIG. 2C).

After the third position C has been reached, it is initially no longer necessary to supply the unlocking drive with additional current. In other words, after the third position C of the actuator has been reached, the control program of the control unit (not shown) for adjusting the seat longitudinally of the vehicle seat ensures that the unlocking drive is in the de-energized state.

In this second embodiment, the unlocking element 40 is held independently of the actuator 60 by the electromagnet 70 according to FIG. 2C in the second position, in which the unlocking position II of the locking element 30 is brought about.

About the bearing 50, the unlocking element 40 is pivoted with its locking element-side end 42 in the direction of the arrow according to the movement arrow P1 upwards (compare Figures 2B and 2C), whereby the unlocking position II of the locking element 30 is reached.

2B shows the section through the locking and unlocking device according to the second embodiment, still in the locking position I of the locking element 30, in which the unlocking element 40 is not yet in its second position with its two ends 41, 42, since the actuator 60 is still in the first position A.

During the movement of the unlocking element 40, the spring element (not shown) is preferably tensioned, which ensures that after the release of the unlocking element 40 according to the second embodiment, the release from the electromagnet 70, the unlocking element 40 is returned to its first position 40.1 by the tensioned spring element .

After the unlocking drive has been actuated and the unlocking position II (FIG. 2C) is present, the longitudinal adjustment of the vehicle seat takes place by means of the seat rail drive until the person interrupts the actuation of the actuating element. According to the second embodiment of the invention, the control side ensures that the seat rail drive and the electromagnet 70 are immediately de-energized.

This achieves the effect that the electromagnet 70 releases the first end 41 of the unlocking element 40, which is suddenly moved back to the first position 40.1 by the spring element tensioned during the adjustment movement of the unlocking element 40 from the first position to the second position 40.2 .

As a result, the first end 41 is correspondingly shifted back into its position shown in FIG. 2A and the locking element 30 returns to its original secure locking position I.

FIG. 2C shows the section through the locking and unlocking device according to the second embodiment in the unlocking position I of the locking element 30 after the locking element 30 has been unlocked in accordance with the preceding description.

It is clear that the actuator 60 is already in a third position C after energizing the unlocking drive to unlock the seat rail, which is characterized in that the actuator 60 from the starting position A '(Figure 2A) by 180 ° moved further to the third position C.

Analogously to the first embodiment, the actuator 60 is axially symmetrical with respect to its geometric shape in relation to the axis of rotation, so that the third position C of the actuator 60 also corresponds to the starting position A' according to FIG. 1A in this second embodiment. In other words, the opposite ends of the actuator 60 alternately act on the unlocking member 40 after rotating through 180° in the successive operations for seat longitudinal adjustment of the vehicle seat.

In this second embodiment, the unlocking element 40 is only released when the electromagnet 70 is no longer energized. As a result, the unlocking element 40 pivots from the second position (FIG. 2C) back into the first position 40.1 (FIG. 2A) with the aid of a spring. Starting from FIG. 2C, the unlocking element 40 pivots downward via the bearing 50 with its locking element-side end 42, as a result of which the locking position I of the locking element 30 according to FIG. 2A is assumed again.

The locking movement of the locking element 30 is supported by the spring element, not shown in detail, which is associated with the at least one locking element 30 .

When the locking and unlocking device is actuated again, the actuator 60 in the third position C according to FIG 2A corresponds.

The procedure described above also advantageously ensures that the seat rail, ie the upper rail 20 relative to the lower rail 10, is locked in the event of a crash. In such a case, the manual actuation of the actuation element for the longitudinal adjustment of the vehicle seat is interrupted, since the respective person will let go of the actuation element in the event of a crash. In this case, as explained, the power supply to the seat rail drive of the longitudinal seat adjustment and the power supply to the electromagnet 70 are abruptly interrupted at the same time, whereby the longitudinal seat adjustment is interrupted and the locking position I (Figure 2A) of the at least one locking element 30 is resumed, since the unlocking element 40 lying in the second position, is no longer held by the de-energized electromagnet 70 and is thus released, after which the unlocking element 40 returns to its first position 40.1 (compare FIG. 2A) and thus the locking element 30, which is mechanically operatively connected, also returns to its locking position I is relocated back.

Third embodiment:

The third embodiment differs from the first embodiment in particular in that the locking and unlocking device does not, as previously explained, act on the locking element 30 starting from the actuator 60 indirectly via the unlocking element 40, but rather that the actuator 60 acts directly on the locking element 30 ie without an interposed unlocking element 40) unlocking the seat rail 10, 20 causes. In other words, the locking and unlocking device comprises at least one locking element 30 on the seat rail side, which is brought directly from the locking position I of the locking element 30 into the unlocking position II of the locking element 30 by the actuator 60 of the unlocking drive when the actuating element is actuated. whereby the locking element 30 releases the upper rail 20 in relation to the lower rail 10 in the unlocked position II.

It is provided that the locking element 30 for adjusting the vehicle seat via the seat rail 10, 20 is held in the unlocked position II by the actuator 60.

This idea according to the invention is shown in FIGS. 3A and 3B, with FIG. 3A showing unlocking position II and FIG. 3B showing locking position I. Analogous to the previous figures, the bottom rail 10 and the top rail 20 are shown, which are in the unlocked state in FIG.

This unlocking position II is brought about by the actuator being brought from the initial position A' about the axis of rotation of the actuator 60 into the second position B of the actuator 60, that is to say rotated.

As in the other embodiments, the end of the actuator 60 causes the locking element 30 to move within the upper rail 20 relative to the upper and lower rails, so that the locking element 30 disengages from the upper rail 20 .

In this third embodiment, the adjustment movement for unlocking the locking element 30 is therefore not in the vertical upward direction as before, but in this embodiment the unlocking movement takes place in the vertical downward direction according to the movement arrow P3.

The unlocked state of the seat rail 10, 20 can be maintained in that the actuator maintains the second position B, so that the seat rail can then be adjusted longitudinally by means of the seat rail drive. Analogously to the other embodiments, FIG. 3B shows the actuator 60 in the third position C, which has run off the locking element 30 in order to produce the unlocked position I.

Figure 3B makes it clear that the spring element 31 shown in Figure 3A has been tensioned accordingly during the unlocking movement, when the locking element 30 assumes locking position I, its spring force ensures that the locking element returns to the locked starting position after the actuator 60 has expired accordingly from the locking element 30.

It is also understood here that the actuator 60 and the locking element 30 are matched to one another in such a way that the actuator 60 can run off the locking element 30 .

In position C according to FIG. 3B, the actuator 60 is available for renewed actuation, it again being the case that the third position of the actuator C according to FIG. 3B corresponds to the initial position A' of the actuator 60 in FIG. 3A.

A pivoting movement of the actuator 60 by 180° around the axis of rotation is therefore necessary for actuation.

A further aspect of the invention is explained below, which consists in the fact that the actuator 60 rotates further in the clockwise direction from the respective position at the moment when the respective person releases the actuating element in normal operation and in the event of a crash and that Locking element 30 abruptly releases acting on the locking element 30 in an indirect manner via the unlocking element 40 or in a direct manner.

In this aspect of the invention, a procedure is proposed that during normal actuation, i.e. in a normal case of actuation, there is no abrupt release of the unlocking element 40 and the locking element 30 (in an indirect manner) or of the locking element 30 (in a direct manner) by the actuator he follows.

In the procedure presented within the description of the third embodiment, the locking element 30 is reset from the unlocking position II to the locking position I by the control unit and the control unit stored application program is ensured in the normal actuation case that the actuator 60 does not move further in the clockwise direction, but is brought back to the starting position A '.

In other words, in all embodiments, the actuator is caused to assume position B by releasing the seat track. Compare Figures 1B, 2C and 3A. If the actuation action is normally interrupted by releasing the actuation element, the actuator 60 is rotated in the opposite direction of movement, so that the locking element 30 previously adjusted in the unlocking direction B1, B2 slowly returns to its locking position I.

This has the advantage or the effect that during normal actuation an abrupt movement of the unlocking element 40 (in the case of an indirect procedure) or of the locking element 30 (in the case of a direct procedure) takes place without the interposition of the unlocking element 40 .

In the event of an imaginary crash, however, as described above, very rapid actuation of the locking element 30 from the unlocking position II to the locking position I is required, so that in the event of a crash, as explained above, the actuator 60 is moved further in the clockwise direction in order to achieve the desired to produce a rapid locking effect. The rapid movement of the actuator 60 at the end from the unlocking element 40 (in the case of an indirect procedure) and thus from the locking element 30 or from the locking element 30 (in the case of a direct procedure) without the interposition of the unlocking element 40 causes a rapid reaction in each case, which means that a high safety standard for the seat rail 10,20 equipped with the locking and unlocking device according to the invention is reached.

It goes without saying that in this aspect of the invention, a distinction must be made between a normal actuation case and a crash case via the control unit for activating the locking and unlocking device.

For this purpose, in the aspect of the invention explained last, the control unit is connected to at least one crash sensor on the vehicle seat and/or at least one crash sensor on the vehicle, so that the corresponding crash sensor is ultimately structurally related to the locking and unlocking unit or structurally related to the locking and unlocking unit belongs if it fulfills other functions outside of the locking and unlocking device.

This means that the control unit ultimately decides whether the actuator, as explained above, ensures a somewhat slower locking of the locking element 30 for a normal actuation case or ensures a particularly fast locking of the locking element 30 in the event of a crash as soon as a crash sensor signals a crash Has.

The invention thus ensures the possibility of bringing about different adjustment speeds for the locking of locking element 30 by ultimately deciding whether actuator 60, according to the embodiment as a rotary element, based on its direction of rotation when unlocking locking element 30 for locking locking element 30 subsequently - In the normal case, that is, in a normal actuation action - opposite to its previous direction, or then - is further actuated rotating in its previous direction - in the event of a crash.

Reference List

10 bottom rail

20 top rail

21 bearing and screen element

30 locking element

31 spring element

I locking position of the locking element 30

11 Unlocking position of the locking element 30

40 unlocking element

40.1 Unlocking element in the first position

40.2. Release element in the second position

41 first end

42 second end

50 camp

60 actuator

A' Initial position of the actuator

A first position of the actuator

B second position of the actuator

C third position of the actuator

70 holding member, electromagnet (first and second embodiment)

P1 movement arrow

P2 movement arrow

P3 movement arrow

Claims

patent claims

1. Locking and unlocking device for a rail (10, 20) of a rail system of a vehicle seat, which can be adjusted by means of an electric seat rail drive by actuating an actuating element assigned to the vehicle seat, characterized in that the locking and unlocking device of the rail (10, 20) comprises an electrical unlocking drive which causes the rail (10, 20) to be unlocked by actuating the actuating element before the vehicle seat is electrically adjusted.

2. Locking and unlocking device according to Claim 1, characterized in that the locking and unlocking device comprises at least one locking element (30) on the seat rail side and one unlocking element (40) which are mechanically connected to one another, the unlocking element (40) during actuation of the actuating element is brought from a first position (40.1) into a second position (40.2) by an actuator (60) of the unlocking drive, as a result of which the locking element (30) is moved by the actuator (60) indirectly via the unlocking element (40) from one Locking position (I) when an upper rail (20) is released relative to a lower rail (10) of the seat rail (10, 20) into an unlocking position (II), the unlocking element (40) being held in the second position for adjusting the vehicle seat via the seat rail will.

3. Locking and unlocking device according to claim 2, characterized in that the unlocking element (40) is held in the second position (40.2) by the actuator (60).

4. Locking and unlocking device according to claim 2, characterized in that the locking and unlocking device also comprises an electromagnet as a holding element (70) which holds the unlocking element (40) in the second position (40.2) in its energized state, which is supplied to the holding element (70) by the actuator (60) of the unlocking drive.

5. Locking and unlocking device according to claim 2, characterized in that the actuator (60) of the unlocking drive is a member rotating about an axis, which pivots from an initial position (A') to a first position (A) in which the actuator (60) comes into contact with the unlocking element (40) and subsequently comes from the first position (A) to a second position (B). , in which the actuator (60) holds the unlocking element (40) in the second position (40.2) or in the second position (40.2) transfers it to the electromagnet as a holding element (70), holding the unlocking element (40) in the second position, wherein the actuator (60) is designed in such a way that it can pivot past the unlocking element (40) as soon as it leaves the second position (B).

6. Locking and unlocking device according to claim 2, characterized in that the unlocking drive with its actuator (60) and the seat rail drive as well as the locking element (30) on the seat rail and the unlocking element (40) on the upper rail (20) of the seat rail are arranged.

7. Locking and unlocking device according to Claim 1, characterized in that the locking and unlocking device comprises the at least one locking element (30) on the seat rail side, which when the actuating element is actuated directly by the actuator (60) of the unlocking drive from the locking position ( I) of the locking element (30), is brought into the unlocking position (II) of the locking element (30), whereby the locking element (30) in the unlocking position (II) releases the upper rail (20) relative to the lower rail (10), the locking element (30) for adjusting the vehicle seat via the seat rail (10, 20) in the unlocked position (II) is held by the actuator (60).

8. Vehicle seat, having a locking and unlocking device according to at least one of claims 1 to 7, for a rail (10, 20) of a rail system of the vehicle seat, which can be adjusted by means of the electric seat rail drive by actuating an actuating element assigned to the vehicle seat, characterized characterized in that the locking and unlocking device of the rail (10, 20) comprises the electric unlocking drive, which causes unlocking of the rail (10, 20) by actuating the actuating element before the electric adjustment of the vehicle seat, the vehicle seat being set up, by means of a control unit, in which a computer-readable program algorithm is stored, to carry out the longitudinal adjustment of the seat step by step by electrically actuating the unlocking drive and the seat rail drive.

9. The vehicle seat according to claim 8, characterized in that the vehicle seat is assigned a crash sensor on the vehicle seat or on the vehicle.

10. Method for operating a locking and unlocking device of a rail (10, 20) of a rail system of a vehicle seat, which can be adjusted by means of an electric seat rail drive by actuating an actuating element assigned to the vehicle seat, characterized in that the locking and unlocking device of the rail (10, 20) is unlocked and locked by means of an electric unlocking drive, with a single actuation of the actuating element first unlocking the rail (10, 20) and then electrical adjustment of the electric seat rail drive of the vehicle seat of the unlocked rail (10 , 20) is carried out as long as the actuating element is actuated, after which the rail (10, 20) is locked again.

11. The method according to claim 10, characterized in that the unlocking drive is pivoted by means of a rotating actuator (60) from its initial position (A') into a first position (A), in which the actuator (60) with the unlocking element (40), wherein the unlocking element (40) is indirectly operatively connected to the locking element (30) or comes into direct contact with the locking element (30), and then from the first position (A) to a second position (B) further in is pivoted in the same direction of rotation in which the actuator (60) holds the unlocking element (40) in the second position (40.2) or in the second position (40.2) transfers it to an electromagnet as a holding element (70), the unlocking element (40) likewise holds in the second position, so that the locking element (30) is in its unlocking position (II), in which an electrical adjustment of the electric seat rail drive from the company vehicle seat of the unlocked rail (10, 20) is carried out as long as the actuating element is actuated, after which the rail (10, 20) is locked again.

12. The method according to claim 11, characterized in that the locking of the seat rail (10, 20) takes place during a normal actuation action of the actuating element by releasing the actuating element, as a result of which the actuator (60), designed as a rotary element, of the unlocking drive moves from its second position ( B) back to its original position (A ') thus in the opposite direction of rotation to the Unlocking movement of the actuator (60) of the unlocking drive is pivoted back. Method according to Claim 11, characterized in that the locking of the seat rail (10, 20) takes place when the actuating element is actuated and a crash is detected at the same time by means of a crash sensor by locking the locking element (30), for which purpose the actuator (60) designed as a rotary element of the unlocking drive from its second position (B) with the same direction of rotation, compared to the direction of rotation of the previous unlocking movement of the actuator (60) of the unlocking drive, further out of the second position (B) and at least into the third position (C ) or the starting position (A') is pivoted. Method according to Claims 12 and 13, characterized in that the locking of the locking element (30) of the seat rail (10, 20) during normal actuation of the actuating element by releasing the actuating element takes place more slowly than the locking of the locking element (30) of the seat rail (10 , 20) when a crash is detected by means of the crash sensor, the fast reaction speed of the locking and unlocking device after a crash signal detected by a crash sensor is detected is caused by the direction of movement, in particular the direction of rotation of the actuator (60) of the unlocking drive will be changed.