DE102018221360A1 - Automatic roll-off protection - Google Patents

Abstract

The invention is directed to a device for securing vehicles from rolling on a vertically movable running rail. The device comprises a securing element 20 which can be moved into a first and a second position. In addition, a movable actuating element 50 is provided for actuating the securing element 20. The actuating element 50 is coupled to the securing element 20 by a lever mechanism, in such a way that the securing element 20 can be moved by the actuating element 50 under gravity.

Description

The present invention relates to an automatic roll-off protection for lifting platforms with travel rails and a method for a lifting platform and a lifting platform.

Rails are known from the prior art which are used on lifting platforms with which vehicles, such as, for example, motor vehicles, are brought into a raised position in order to be able to carry out maintenance and repair work on the vehicles. The raised vehicles are secured against rolling, for example by applying the handbrake on the vehicle.

To secure the vehicle against rolling off the rail, lifting platforms are known, on the rails of which ramps are mounted. These ramps are rotatably mounted and, as an extension of the travel rails, have an extended drive-up area in order to compensate for height differences between the travel rail and a floor surface. After a vehicle has run onto the travel rail, the lifting platform is raised, the drive-up ramps tilting in such a way that the shorter drive rails line up in the overlapping area of the drive-on ramps and thus form a rolling obstacle for the vehicle.

The DE 10 2017 206 351 A1 relates to roll-off protection for vehicles on rails. A flap is proposed which can be moved along a guideway. The flap unit is extended by expanding a gas spring. The guideway has at least a first section and a second section, the course of the guideway in the second section running in a different direction than in the first section.

It is an object of the present invention to provide an improved and simplified device for securing vehicles from rolling on rails. In addition, it is an object to provide an improved lifting platform and an improved method for a lifting platform for securing vehicles from rolling. In particular, it is an object to provide a simpler and more efficient, more maintenance-friendly and less expensive structure of a device for rolling protection of vehicles.

This object is solved by the features of the independent claims. The dependent claims relate to advantageous developments of the invention.

A device for securing vehicles from rolling on a vertically movable running rail can comprise a movable securing element. The movable securing element can be movable into at least a first position and into a second position. In addition, a movable actuating element can be provided for actuating the securing element. In particular, the actuating element can apply a force to actuate the securing element from the first position to the second position (along a single continuous guideway), this force being essentially the weight of the actuating element. The actuating element is therefore a so-called passive actuating element, which generates the actuating force only by the weight. The first position can be a rest position and the second position can be a safety position. The actuating element can be coupled to the securing element by a lever mechanism in such a way that the securing element can be moved by the actuating element under the force of gravity. For example, in the raised state of the travel rail, the actuating element can be deflected by the weight force in such a way that a force redirection takes place via the lever mechanism, which causes the securing element to be deflected. In a lowered state of the travel rail, in particular in the completely lowered state of the travel rail, the actuating element can be contacted with the floor in such a way that the actuating element is in a retracted state relative to the travel rail, so that the securing element is also drawn in by the lever mechanism, ie in the rest position. This advantageous embodiment makes it possible to provide a passive actuating element which, when actuated by gravity, activates the securing element for securing vehicles on the running rail. This embodiment is particularly efficient and advantageous in particular because no active additional activation elements are required for the device and only by lifting the travel rail a relative movement between the actuating element and the securing element, which are connected via the lever mechanism, is brought about. This structure is also very easy to maintain or maintenance-free. The weight of the actuating element therefore moves the levers of the lever mechanism in such a way that the securing element is moved from the first position into the second position, namely the securing position. In other words, a deflection of the actuating element relative to the travel rail is automatically effected when the travel rail is raised, so that the levers of the lever mechanism are moved in order to subsequently deflect the safety element and bring it into the safe position. When the rail is lowered, it will Contacted actuating element with the floor, in particular a workshop floor, so that a retracting movement of the actuating element is achieved in such a way that the securing element is also moved into the rest position via the lever mechanism.

The actuating element can move essentially opposite to the securing element. In other words, the actuating element moves downwards in the vertical direction in the event that the securing element moves upwards. Conversely, the actuating element moves upwards in the vertical direction, so the securing element moves downwards. The actuating element thus moves in the opposite direction to the securing element, preferably at least in the vertical direction. The movement of the actuating element is thus deflected by the lever mechanism, so that an opposite movement of the securing element is brought about.

The device can comprise at least one rotatably mounted support element, which can preferably be fixedly connected to the securing element at a first end. The rotatably mounted support element can preferably be provided for absorbing forces in the horizontal direction. The forces absorbed are preferably absorbed via the bearing point of the rotatably mounted support element. The combination of the rotatably mounted support element, which is preferably fixedly connected to the securing element, and the lever mechanism, which moves the securing element, for example by the weight of the actuating element, make it possible to absorb loads on the securing element via the supporting element, in order thus to directly load the Avoid lever mechanism (at least in the horizontal direction). For example, the lever mechanism moves the securing element from the first position into the second position (which is the securing position) along a circular movement path. If the securing element is now loaded, for example, by a vehicle tire of the vehicle located on the rail, forces which preferably act in the horizontal direction can be absorbed by the rotatably mounted support element, so that the horizontal forces do not act on the lever mechanism. The device thus has two separate mechanisms, a first mechanism for direct movement of the securing element and a second mechanism for absorbing a load (in particular from the vehicle). The device therefore has, for example, two separate force absorption paths with corresponding bearing points, preferably a bearing point for absorbing the horizontal forces and a bearing point for absorbing the vertical forces which act on the securing element.

The lever mechanism can be set up in such a way that the securing element can be moved from the first position into the second position by the weight of the actuating element. The securing element is thus preferably movable from the first position into the second position solely by the weight of the actuating element. The actuating element can be retracted by contacting the floor, so that the securing element can be moved from the second position to the first position.

The at least one support element can advantageously be L-shaped. A pivot bearing point can be at a second end of the support element, so that the support element can be arranged rotatably about the pivot bearing point. With the first end of the securing element, a fixed contact with the support element can be provided. The L-shaped configuration of the support element makes it possible to absorb the forces which act essentially in the horizontal direction (via the pivot bearing point). The longer section of the L-shaped support element is connected to the pivot bearing point at the open end, and the short section of the L-shaped support element is connected to the securing element at the open end, preferably fixedly connected, for example welded or screwed. The length of the short section of the L-shaped support element advantageously determines the extension height of the securing element over the road surface of the rail.

Advantageously, two support elements can be provided, which are attached to bearing points at two opposite ends of the securing element. By fastening the support elements to opposite ends of the securing element, the securing element can be attached as stably as possible.

The lever mechanism may have at least an upper link and a lower link. The lever mechanism particularly preferably has a first and a second upper connecting element and a first and a second lower connecting element. The lower connecting link can preferably be rotatably connected to a first end of the upper connecting link at a first end and the upper connecting link can preferably have a roller for contacting the securing element at a second end. The lower connecting member can preferably be rotatably connected to the actuating element at a second end. The lever mechanism thus has at least one two-armed lever, which is mounted on a pivot point, the two-armed lever, for example, by the upper connecting member is formed. At one end of this lever, a roller can be provided for contacting the securing element (in particular for applying a vertical force, in particular a vertical compressive force in the vertical direction upwards on the securing element). At the opposite end, the lower connecting member can be provided, which is in particular provided rotatably and is connected to the actuating element, which is, for example, a counterweight. In a preferred development, the actuating element is provided directly on the two-armed lever. In other words, there is a roller on the power arm and a weight on the load arm, which is the counterweight. The connecting links are advantageous, for example, compression rods or cross struts or a tension / compression rod.

The lever mechanism is preferably designed as a scissor lifting mechanism, so that the connecting links can be arranged like scissors.

The at least one roller can be movable along a guide surface of the underside of the securing element, and preferably the guiding surface can be parallel to a longitudinal axis of the securing element. The roller can move along the guide surface and thereby exert a force in the vertical direction on the securing element, for example in order to press it from the first position into the second position. The securing element is thus essentially only subjected to vertical forces from the connecting element on which the roller is provided. A very simple and efficient structure for deflecting the securing element is thus possible. The rollers move parallel to the longitudinal axis of the securing element, which is, for example, orthogonal to the travel axis of the rails on which the vehicle is placed. The securing element can be movable along a circular path section from a first position to the second position and vice versa. The center point of the circular path section can preferably be the fulcrum of the rotatably mounted support element. Due to the corresponding configuration of the long section of the L-shaped support element and the resulting large radius of the circular path section, the securing element only moves on a slightly curved circular path and thus essentially only in the vertical direction. As mentioned, a load on the securing element can be absorbed in the horizontal direction, for example via the supporting element.

The actuator can be a counterweight with a weight greater than 3 kg. The actuating element can be movable in a retracted state and in an extended state. The lever mechanism can be designed such that when the actuating element is retracted, the securing element is in the rest position and when the actuating element is extended, the securing element is in the securing position, for securing a vehicle from rolling. As mentioned, the actuating element thus moves in the opposite direction to the securing element. A movement of the actuating element from the retracted state into the extended state takes place due to gravity, by the weight of the actuating element or by the lifting of the travel rail, which causes the actuating element to exert a force on the lever mechanism in order to thereby actuate the securing element. As soon as the securing element has reached the securing position, and thus further movement of the lever mechanism is restricted, the actuating element is also lifted off the floor. When the travel rail is raised, the securing element is held in the securing position by the weight of the actuating element. Automatic roll-off protection can thus be provided effectively.

In a raised state of the travel rail, the actuating element can be in the extended state and in a lowered state of the travel rail, the actuating element can be in the retracted state.

The securing element can have a longitudinal axis, which can be arranged transversely to the direction of travel of the rails.

A lifting platform with at least one vertically movable travel rail can comprise a device for securing vehicles from rolling. In a lowered state of the travel rail, the actuating element and the securing element can each be present in the retracted state and in the raised state of the travel rail, the actuating element and the securing element can each be present in the extended state.

A method for a lifting platform can include the step of lifting the travel rail of the lifting platform so that the actuating element is moved from the retracted state to the extended state and the securing element is thereby moved from the first position to the second position by transferring the weight of the actuating element by means of a lever mechanism .

The method can advantageously also comprise the step of lowering the travel rail of the lifting platform, so that the actuating element is contacted with the floor and the actuating element is retracted into the retracted state, at the same time using the Lever mechanism, the securing element is moved from the second position to the first position.

The device can thus comprise a securing element, which is moved exclusively by gravity from the first position to the second position, the weight of the counterweight being at least greater than the weight of the securing element and the supporting elements firmly connected to it. A movement of the securing element from the second position into the first position is also effected by gravity, namely by the weight of the securing element and the connected supporting elements. The counterweight is preferably arranged on one side (the running rail), which lies opposite the side on which the securing element is arranged. The securing element can advantageously be designed as a support plate. The counterweight can advantageously consist of at least two elongated bars which are arranged transversely to the direction of travel of the rails. The counterweights can preferably be arranged parallel to the longitudinal axis of the securing element.

The lever mechanism advantageously has a first and a second upper connecting link, each of which is rotatably attached to a front plate at its own bearing point. The front plate is firmly connected to the running rail. In addition, a first and a second lower connecting link are provided. Each of the lower connecting links has a contact point with the one upper connecting link and a contact point with a bearing point on the counterweight. The lower connecting links are rotatably supported, the axis of rotation preferably being parallel to the direction of travel of the rails. The upper connecting links are advantageously arranged in one plane with the lower connecting links (in the same plane of movement). This plane is particularly advantageously a vertical plane which is orthogonal to the direction of travel of the rails. More preferably, the pivot bearing point of the support element lies outside of this plane. The L-shaped support element can advantageously be arranged such that the longer section of the L-shaped support element is arranged essentially horizontally and the short section of the L-shaped support element is arranged essentially vertically. Further advantageously, the short section of the L-shaped support element can lie essentially in the plane in which the lever mechanism is arranged, that is to say the corresponding vertical plane which is orthogonal to the direction of travel of the guide rails.

Advantageously, the securing element can be moved from the first position into the second position exclusively by gravity.

In the rest position, the securing element can advantageously be flush with a plane of the top of the travel rail.

The securing element can advantageously be rotatable from the rest position to the securing position and vice versa.

The actuating element and the securing element can each be held in an articulated manner and coupled together via the lever mechanism.

Advantageous refinements and further details of the present invention are described below with reference to the schematic figures. Explained in more detail in the schematic drawings.

Figure list

• 1 : shows a first view of an automatic roll-off protection with the securing element actuated;
• 2nd : shows another view of the automatic roll-off protection;
• 3rd : shows a view of the structure of the roll-off protection in a substantially retracted state;
• 4th : shows the internal structure of the roll-off protection in an essentially extended state.

According to the prior art, vehicles such as passenger cars are brought to a raised position on lifting platforms with travel rails in order to carry out maintenance and repair work. To prevent vehicles from rolling, swivel-mounted flaps or ramps are attached to the front of the rails. The flaps / ramps overlap the travel rail and thus shorten the usable length. When the lift is lifted, the flaps or ramps tip over their longer side, so that the overlapping length rises above the running rail and thus functions as a rolling obstacle. Further designs of a roll-off protection are, for example, a locking plate which translates to the travel rail. The locking plate must be brought into the extended state by an active actuating element. Automatic roll-off protections are mainly designed for lifts up to 4.2 t.

The present device ensures that a vehicle rolls off rails, the lifting lever automatically moving into the secured position when the lifting platform is raised.

In the retracted state of the lift, according to an exemplary aspect of the invention, a counterweight rests on the floor. The counterweight is detachably connected to the support plate via connecting struts. The support plate (securing element) only rests on rollers. The levers, which are mounted in the travel rail plate in the direction of travel, are screwed to the support plate. The levers are attached to the running rail plate in a pivoted manner. If the rail is raised, the counterweight moves downwards in relation to the rail. The cantilever movement moves the rollers upwards in relation to the running rail. The support plate is moved upwards in relation to the travel rail by the lever movement and the weight of the counterweight. This configuration makes it possible to ensure use for lifting platforms with travel rails of up to 5.5 t according to the currently applicable standard.

In the uppermost position, the connecting struts (connecting links) are in a toggle lever position, which prevents the support plate from being pressed in by an adjacent wheel. When the lift is lowered, the counterweight rests on the ground and swivels in the connecting struts as the rails continue to move downwards.

The present invention makes it easy to retrofit the roll-off protection in existing lifting platforms. In addition, a design for lifts up to 5.5 t is possible. The securing position ensures protection against rolling even with a large tire diameter. In addition, a particularly simple and maintenance-friendly construction of the roll-off protection can be provided.

In 1 a first non-limiting example of the invention is shown. The securing element 20th , which is for example a support plate, lies transversely to the longitudinal axis of the rails 70 or the direction of travel of the rails 70 . The securing element 20th is movable in the vertical direction and thus extendable to secure a vehicle that is (at least partially) on the running rail. A tire of a vehicle, which is located on the running rail, can be extended with the securing element 20th be contacted so that further rolling can be blocked by the extended security element.

For moving the securing element 20th a lever mechanism is provided. By way of example, this lever mechanism comprises a first upper connecting link 13 (Connecting strut) and an upper second connecting link 14 to contact with the fuse element 20th . The upper links 13 , 14 , are about the first depository 61 or the second depository 62 rotatably mounted, on the front panel 60 . The front panel 60 is, for example, firmly connected to the running rail 70 . The upper links 13 , 14 are each with lower links 11 , 12 rotatably connected. The first lower link 11 is rotatable with the first upper link 13 connected and the second lower link 12 is rotatable with the upper second link 14 connected.

On a bottom of the lower links 11 , 12 , is the actuator 50 intended. The actuator is a passive actuator 50 designed and for example a simple counterweight with a corresponding mass to generate a corresponding weight. The lower links 11 , 12 , are at a first counterweight bearing point 53 and a second counterweight bearing point 54 with the actuator 50 connected. Between the first counterweight bearing 53 and second counterweight bearing point 54 can be an intermediate plate 55 be provided, which can also be designed, for example, as a movement limiter. The actuating element is preferably present 50 at least from a front counterweight 51 and a rear counterweight 52 .

The front counterweight 51 is, for example, via a screw connection through the first counterweight bearing point 53 with the rear counterweight 52 connected, being between the front counterweight 51 and the rear counterweight 52 one end of the first lower link 11 is arranged. The first lower connecting link is advantageously rotatably mounted on the first counterweight bearing point 53 . The second lower link is analogous 12 at the second counterweight bearing point 54 stored.

The weight of the front and rear counterweights 51 , 52 , is, for example, about the respective counterweight bearing 53 , 54 into the respective lower link 11 , 12 initiated. The power transmission takes place via the lower connecting links to the upper connecting links 13 , 14 , so that, for example, a vertical force (upwards) on the securing element 20th through the upper links 13 , 14 can be applied.

There is also a first support element 30th and a second support element 33 intended. The first support element 30th is at one end of the securing element 20th provided or preferably fixed with the securing element 20th connected, for example by a screw connection. At the opposite end (of the securing element 20th ) is the second support element 33 provided and with the support member 20th firmly connected. The first support element 30th is rotatable at a first pivot point 31 mounted so that a rotational movement of the first support element 30th around the pivot point 31 is made possible. Through this rotational movement of the first support element 30th can extend or retract a vertical portion of the first support member 30th be made possible. Advantageously disappears when the securing element is retracted 20th the vertical section of the first support element 30th in the track 70 so that the securing element 20th flush with the surface of the running rail 70 completes. This makes it easy to run over the securing element without any problems 20th can be reached in the retracted state. The retracted condition of the fuse element 20th corresponds to the rest position of the securing element. In the extended state of the vertical section of the first support element 30th is the securing element 20th in the so-called safety position, so that a rolling movement or a horizontal movement of a vehicle tire, which is on the rail 70 located, can be blocked, at least in one direction.

Analogous to the first support element 30th is also the second support element 33 at a pivot bearing point, namely the second pivot bearing point 34 , rotatably mounted. In 1 is also the opening 71 shown, which is a section of the rail 70 forms. The second support element 30th is over the second bearing point 35 with the securing element 20th firmly connected. The movement of the upper links 13 , 14 is through the first stop 63 and the second stop 64 limited accordingly.

In 1 is the securing element 20th in an essentially extended position, ie in the securing position S2 .

2nd shows the securing element 20th in a retracted position, namely in the rest position S1 . As in 2nd can be seen when the securing element is retracted 20th also the actuator 50 when retracted. This corresponds, for example, to a lowered state of the travel rail of the lifting platform. In such a lowered state, the counterweights contact the floor and thus become the first bearing points 61 and second depository 62 pressed, so that the vertical deflection of the upper connecting links via the lever mechanism 13 , 14 is minimal and the securing element 20th thereby in the rest position. The securing element can be advantageous 20th in the rest position on the surface of the running rail 70 rest on or advantageously flush with the surface of the rail 70 to lock. The upper links 13 , 14 bring only a vertical force upwards on the securing element 20th on, when retracting the securing element 20th from the safety position to the rest position S1 , the securing element 20th by the weight or the weight of the support elements 30th , 33 to the rest position S1 is moved. The securing element 20th is therefore only on the links 13 and 14 on (or on the rollers of the connecting links).

As in 2nd shown is in the rest position S1 of the securing element 20th the distance between the securing element 20th and the first depository 61 and second depository 62 minimal. Also the distance between the first counterweight bearing point 53 to the first depository 61 is minimal in this position. So are also the front counterweight 51 and the rear counterweight 52 at a minimal distance from the first deposit 61 and second depository 62 arranged. At rest S1 of the securing element 20th there is also the first support element 30th and the second support element 33 in a lower position or in a downward position along a circular path section (continuous guideway) around the respective pivot bearing point 31 , 34 .

3rd shows the internal structure of the roll-off protection, the securing element 20th in the rest position S1 is present, as shown in 2nd for example. As in 3rd can be seen, the first lower link 11 and the first upper link 13 present in the deflected state, so that there is a minimal distance between the first counterweight bearing point 53 and the first depository 61 is achieved. The upper links 13 , 14 , each have a roller at one end. The first upper link 13 has a first roller 36b on. The first roller 36b is along a surface at the bottom of the fuse element 20th movable along the longitudinal axis of the securing element. The horizontal component resulting from movement of the first upper link 13 results in a movement of the first roller 36b implemented, wherein the vertical component of the first upper link 13 leads to a vertical force which the securing element 20th moves or pushes in the vertical direction. Therefore the first roller presses 36b at the transition from the resting position S1 in the safety position S2 the securing element 20th in the vertical direction upwards. The upper second connecting link is analogous 14 with the second roller 36a designed.

In 4th a further illustration is shown in which the securing element 20th in the secured position S2 is present. When the actuator moves 50 to move the Securing element from the rest position to the securing position is a force introduction, the weight of the counterweights, via the lower connecting links 11 , 12 , in one end of each upper link 13 , 14 . This introduction of force into the upper connecting element causes the upper connecting element to rotate about the respective bearing point 61 , 62 causes so that the opposite end of the link rotates along a circular path around the bearing point 61 respectively. 62 . The movement of the opposite end of the connecting member along this circular path results in a vertical movement of the securing element 20th causes, so that the securing element from the rest position S1 in the safety position S2 can be moved. The horizontal component of the movement of the upper links 13 , 14 , leads to the movement of the first roller 36b or second roller 36a . In other words, by moving the opposite end of the first upper link 13 or second upper link 14 along the respective circular path (around the first bearing 61 or the second depository 62 ) a vertical force component in the securing element 20th initiated so that a vertical movement of the securing element results, the horizontal component merely leading to a movement of the rollers 36a , 36 leads. By lifting the securing element 20th through the described process, the support elements are also shown 30th , 33 raised so that preferably in the safety position S2 the longer portion of the L-shaped support member is in a substantially horizontal position. Like for example in 4th shown, the longitudinal axis of the L-shaped support element is thus essentially parallel to the longitudinal axis of the travel rail 70 . The shorter section of the L-shaped support element 30th , 33 is essentially in a vertical position, which is, for example, orthogonal to the contact surface of the running rail 70 is present. The contact area is an area for contacting the wheel of the vehicle. In the top position, for example in the safety position S2 , the connecting links are in a toggle lever position, which prevents the securing element 20th is pressed in by an adjacent wheel.

For moving the actuating element 50 For example, the runway of the lift can be raised or lowered. The travel rail can be raised, for example, in such a way that the actuating element 50 is moved from the retracted state to the extended state and thereby the securing element by force transmission, namely by the weight of the actuating element, the lever mechanism 20th from the resting position S1 in the safety position S2 emotional. By means of a corresponding method, an advantageous and simple actuation of the lifting platform can thus be achieved.

Present features and components or specific details can be exchanged and / or combined to create further embodiments, depending on the required purpose. Any modifications that are within the knowledge of the person skilled in the art are implicitly disclosed in the present description.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102017206351 A1 [0004]

Claims (16)

Device in particular for securing vehicles from rolling on a vertically movable running rail, with a securing element (20) which can be moved at least into a first position and into a second position; a movable operating element (50) for operating the securing element (20); wherein the first position is a rest position (S1) and the second position is a safety position (S2); the device being characterized in that the actuating element (50) is coupled to the securing element (20) by a lever mechanism in such a way that the securing element (20) can be moved by gravity actuated by the actuating element (50). Device after Claim 1 , wherein the actuating element (50) moves essentially opposite to the securing element (20). Device according to at least one of the preceding claims, wherein the lever mechanism is set up in such a way that the securing element (20) can be moved from the first position (S1) to the second position (S2) by the weight of the actuating element (50). Device according to at least one of the preceding claims, with at least one rotatably mounted support element (30, 33) which is fixedly connected to the securing element (20) at a first end and which is provided for absorbing forces in the horizontal direction. Device according to the preceding claim, wherein the at least one support element (30, 33) is L-shaped and a rotary bearing point (31, 34) is provided at a second end of the support element (30, 33) so that the support element (30, 33 ) is arranged rotatably about the pivot bearing point (31, 34). Device according to at least one of the preceding claims, wherein two support elements (30, 33) are provided and support points (32, 35) for coupling to the two support elements (30, 33) are provided on two opposite ends of the securing element (20). The device of at least one of the preceding claims, wherein the lever mechanism comprises at least an upper link (13, 14) and a lower link (11, 12) and the lower link (11, 12) at a first end with a first end of the upper link (13, 14) and the upper connecting member (13, 14) preferably has a roller (36a, 36b) at a second end for contacting the securing element (20). Device according to the preceding claim, wherein in the securing position (S2) of the securing element (20), the connecting links are at least partially in a toggle lever position, for securing the securing element (20). Device according to at least one of the preceding Claims 7 or 8th , wherein the at least one roller (36a, 36b) is movable along a guide surface of the underside of the securing element (20) and preferably the guide surface is parallel to a longitudinal axis of the securing element (20). Device according to at least one of the preceding claims, wherein the securing element (20) can be moved along a circular section from the first position to the second position and vice versa, and preferably the center of the circular path section is the fulcrum of the rotatably mounted support element (30). Device according to at least one of the preceding claims, wherein the actuating element (50) can be moved into a retracted state and an extended state and wherein the lever mechanism is designed such that in the retracted state of the actuating element (50) the securing element (20) in the rest position ( S1) and in the extended state of the actuating element (50) the securing element (20) is in the securing position (S2), for securing a vehicle from rolling. Device according to one of the preceding claims, wherein the securing element (20) is moved along a single guideway, which is preferably a circular path section. Device according to one of the preceding claims, wherein the securing element (20) can only be rotated from the rest position to the securing position and vice versa. Device according to one of the preceding claims, wherein the securing element (20) can be moved exclusively from the first position into the second position by the actuating element (50). Lifting platform with at least one vertically movable travel rail and a device according to at least one of the preceding claims, wherein in a lowered state of the travel rail the actuating element (50) is present in the retracted state and in the raised state the The operating element (50) in the extended state. A method for a lifting platform with a device according to at least one of the preceding claims, comprising the step of lifting the travel rail of the lifting platform so that the actuating element (50) moves from the retracted state to the extended state and thereby the securing element (20) by the lever mechanism of the first position is moved to the second position.

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