LIFTING PLATFORM

Abstract

The invention relates to a lifting platform for lifting vehicles, with two base assembly halves (14) with in each case one lifting device (24) arranged on the base assembly half (14), which includes a load arm (25) and a guiding arm (27), which arms, by means of at least one drive, are pivotably transferable out of a starting position arranged on the floor into an operating position (32), and which comprises a carrier (31) in in each case one end region of the lifting device (24), which carrier is mounted pivotably to the load arm (25) via a pivot bolt (54) and is mounted pivotably to the guiding arm (27) via a bearing bolt (63), and each carrier (31) receives at least one support arm (34) arranged pivotably thereon, so that the support arms (34) opposite one another are pivotable in a working space (50) formed at least between the lifting devices (24), wherein an angle of inclination is adjustable between the at least one support arm (34) and the lifting device (24).

Claims

1. A lifting platform for lifting vehicles, with two base assembly halves, with in each case one lifting device arranged on the base assembly half, which, by means of at least one drive, are transferable out of a starting position arranged on the floor into an operating position and which comprises a carrier in in each case one end region of the lifting device, and each carrier receives at least one support arm (34) arranged pivotably thereon, so that the support arms opposite one another are pivotable in a working space formed at least between the lifting devices, wherein an angle of inclination is adjustable between the at least one support arm and the lifting device.

2. The lifting platform according to claim 1, wherein at least one adjustment device for adjusting the angle of inclination is provided between the carrier and the lifting device and/or between the carrier and the support arm.

3. The lifting platform according to claim 2, wherein, the carrier is adjustable, by means of the adjustment device, for orienting the at least one support arm, in the inclination to the pivot axis of the pivot bolt or to the bearing axis of the bearing bolt, or to both.

4. The lifting platform according to claim 2, wherein the adjustment device comprises a compensation plate with a borehole, which is placeable on an end of the pivot bolt or the bearing bolt and is fastenable on or in the carrier, through which the zero point position or inclination of the carrier to the pivot bolt or bearing bolt or both is adjustable.

5. The lifting platform according to claim 2, wherein the carrier includes at least two lateral walls distanced to one another, which walls respectively comprise a perforation for the pivot bolt and the bearing bolt and in that, in one of the lateral walls, at least one centering receptacle is provided, into which the compensation plate is insertable.

6. The lifting platform according to claim 5, wherein the centering receptacle, in the lateral wall, has a V- or trough-shaped contour, narrows in a load direction, and the compensation plate has a complementary external contour and rests form-fittingly in the contour of the centering receptacle.

7. The lifting device according to claim 2, wherein a retaining device is provided for fixating the compensation plate in the centering receptacle, which device is provided detachably on the lateral wall.

8. The lifting platform according to claim 7, wherein the retaining device is configured as a retaining plate which receives at least one detachable fastening element, through which the retaining device is fixated on the lateral wall.

9. The lifting platform according to claim 7, wherein the retaining device receives at least one retaining element for fixation of the compensation plate to the retaining device.

10. The lifting platform according to claim 7, wherein the retaining device receives least one fixation element for detachable fastening of the retaining device to the pivot bolt or the bearing bolt.

11. The lifting platform according to claim 7, wherein the retaining device configured as a retaining plate completely covers the centering receptacle in a position fastened to the lateral wall.

12. The lifting platform according to claim 2, wherein the adjustment device includes multiple compensation plates which deviate from one another in the distance between a reference surface provided on the compensation plate and a longitudinal axis of the borehole.

13. The lifting platform according to claim 2, wherein the pivot bolt and the bearing bolt are rotatably arranged, by means of a radial bearing, about a pivot axis and bearing axis stationary to the load arm and guiding arm.

14. The lifting platform according to claim 1, wherein a base assembly, stationary in the lifting of vehicles, is provided, which assembly includes two base assembly halves, which are arranged fixedly to one another via at least one connecting point, with a middle part.

15. The lifting platform according to claim 14, wherein two base assembly halves are arranged to one another via at least one detachable connection point with the middle part.

16. The lifting platform according to claim 1 wherein a lifting device is arranged on each base assembly half which, by means of at least one drive arranged on or in the at least one base assembly half, are transferable out of a starting position arranged on the floor into an operating position and which receives a carrier in each case one end region of the lifting device, which carrier is mounted pivotably to the load arm, via a pivot bolt and is mounted pivotably to the guiding arm, via a bearing bolt, and in that each carrier receives at least one support arm arranged pivotably thereon, so that the support arms opposite one another are pivotable into a working space formed at least between the lifting devices.

17. The lifting platform according to claim 16 wherein the lifting device is configured as a parallel guiding device, which includes a load arm and a guiding arm.

18. The lifting platform according to claim 16 wherein the lifting device is configured as a scissoring guide device.

19. The lifting platform according to claim 1, wherein the lifting platform is configured as a moveable lifting platform.

Description

[0020] The invention, as well as further advantageous embodiments and further developments of the same are described in further detail and explained in the following based on the examples illustrated in the drawings. The features to be taken from the description and the drawings can be applied according to the invention individually or multiply in any combination. Shown are in:

[0021] FIG. 1 a perspective view of the lifting platform according to the invention,

[0022] FIG. 2 a schematic front view onto the lifting platform according to FIG. 1,

[0023] FIG. 3 a schematic partial section along the line III-III in FIG. 1,

[0024] FIG. 4 a schematic view onto a mounting position of the adjustment device according to FIG. 3,

[0025] FIG. 5 a schematic side view onto an adjustment device on the carrier,

[0026] FIGS. 6a to 6c perspective views onto compensation plates of the adjustment device, different from one another, according to FIG. 4 and

[0027] FIG. 7 a perspective view of an alternative embodiment of the lifting platform to FIG. 1.

[0028] FIG. 1 shows a perspective view of a lifting platform 11 according to the invention. This lifting platform 11 includes a base assembly 12 which includes two base assembly halves 14 and a middle part 15 arranged therebetween. Through the middle part 15, the base assembly halves 14 are preferably distanced and oriented parallel to one another. By means of the base assembly halves 14 and the middle part 15, a U-shaped base assembly 12 is formed. The open region constitutes an entry region in a working space 50 for a vehicle, which enters for so long until this vehicle is positioned near the middle part 12. The entry direction is illustrated according to arrow 17 in the perspective view of the lifting platform 11 in FIG. 1. The entry direction lies in the region of a longitudinal center axis 18 of the lifting platform 11. The longitudinal center axis 18 extends parallel between the two base assembly halves 14 and is arranged centrally thereto. The working space 50 extends at least between the two base assembly halves 14.

[0029] Each base assembly half 14 includes a housing 21, inside of which a schematically illustrated drive 22 is provided. Moreover, each base assembly half 14 receives a lifting device 24 which is configured, in this exemplary embodiment, as a parallelogram guiding device. Alternatively, the lifting device 24 can be configured as a scissoring guide device, in particular half-scissor, full scissor or double scissor. The at least one drive 22 lifts and lowers the lifting device 24. This lifting device 24 includes a load arm 25, which is pivotable about a first pivot axis 26. Moreover, the lifting device 24 includes a guiding arm 27, which is pivotable about a second pivot axis 28, which axis is distanced to the first pivot axis 26. Both pivot axes 26, 28 are mounted on the housing.

[0030] The lifting device 24 comprises a carrier 31 on an end region remote to the housing 21, which carrier remains oriented horizontally through the lifting device 24 during the raising and lowering of the lifting device 24. In FIG. 1, the lifting devices 24 are provided in an operating position 32. Such an operating position 32 can correspond to an overhead height. In a non-operating position, the lifting devices 24 are positioned oriented near the floor or resting upon the floor.

[0031] Each carrier 31 receives at least one support arm 34. Preferably, two support arms 34 are respectively provided on the carrier 31. These support arms 34 are pivotably mounted about in each case one pivot axis 35, 36. The support arms 34 can be configured to have the same length. Alternatively, the rear support arm facing towards the entry region can be configured longer than the in particular front support arm 34 facing towards the middle part 15. The support arms 34 are preferably configured as telescoping support arms.

[0032] The lifting platform 11 is preferably configured as a moveable lifting platform 11. Each base assembly half 14 preferably comprises a running roller 38 at an end remote to the middle part 15, which roller is part of a chassis. Moreover, a drawbar not illustrated in further detail can be fastenable, in a middle region, to the middle part 15, so that after lifting the middle part, the lifting platform 11 bis supported on an impeller of the drawbar and the two running rollers 38. The lifting platform 11 is thereby mobile and can be moveable to the respective use site. After the removal of the drawbar, this lifting platform 11 is stationary and rests on the floor.

[0033] Alternatively to the lifting platform 11 illustrated in FIG. 1, this platform can also be configured as a stationary lifting platform 11. In this case, the running rollers 38 can be dispensed with. In a stationary lifting platform 11, it can also be provided that this platform consists of the two base assembly halves 14 oriented towards one another. A middle part 15 can be provided or also be dispensed with.

[0034] A controller 41 is provided for the actuation of the lifting platform 11 out of a non-operating position into an operating position 32, which controller is for example arranged on one of the two base assembly halves 14. This controller 41 can output a control signal to the respective drive(s) 22. The drive 22 can be a hydraulic cylinder which is electrically actuatable. Preferably, a drive 22 is provided in each housing 21 of the base assembly half 14. The controller 41 includes monitoring sensors to for the synchronization of the lifting and lowering movement of the respective lifting device 24. Control lines can, on the one hand, be guided into the directly assigned base assembly half 14 by the controller 41. On the other hand, control lines can be guided inside the middle part 15 to the opposite base assembly half 14.

[0035] FIG. 2 illustrates a schematic front view onto the lifting platform 11 according to FIG. 1, in the operating position 32. The force acting on the support arms 34 is symbolized through the force F1, which force acts in a vehicle lifted in the operating position 32. To increase the operational safety, it is required that the at least two support arms 34 opposite one another are oriented nearly or in a common horizontal. A skewed positioning of the vehicle in the operating position 32 can thereby be prevented.

[0036] Due to dimensional tolerances of the first and second base assembly half 14, the case can arise that the support arm(s) 34 of the first base assembly half 14 and/or the support arm(s) 34 of the second base assembly half 14 are not oriented towards one another and/or lie outside of the horizontal. Here, the free ends of the support arms can be oriented above or below the horizontal.

[0037] At least one adjustment device 51 is provided on each base assembly half 14, through which device the inclination of the least one support arm 34 of the lifting device 24 is adjustable. Preferably, an angle of 90 is provided between the at least one support arm 34 and the lifting device 24. Insofar as the lifting device 24 is oriented in an elevated position outside of the vertical, however, the setting of the inclination of the at least one support arm 34 is required, so that this arm, in turn, is oriented in the horizontal.

[0038] According to a preferred embodiment, the adjustment device 51 is provided between the carrier 31 and the lifting device 24. The adjustment device 51 is preferably provided on an external side of the carrier 31. This device can also be provided on an internal side of the carrier 31.

[0039] FIG. 3 illustrates a schematic sectional view along the Line III-III in FIG. 1. This schematic partial section extends through an upper end region of the lifting device 24, as well as a part of the carrier 31.

[0040] A bearing bush 52 is provided in the upper end region of the load arm 25, which bush receives a radial bearing 53, through which a pivot bolt 54 is pivotably mounted about a pivot axis 55, with respect to the load arm 25. The carrier 31 comprises at least a first lateral wall 56 and a second lateral wall 57, which are preferably distanced parallel to one another. The first lateral wall 56 forms an external side of the carrier 31. The second lateral wall 57 forms an internal side of the carrier 31. A support arm bracket 58 is provided on this second lateral wall 57, which bracket pivotably receives the support arm 34 about a bearing axis 35, 36. The two lateral walls 56, 57 are kept at a distance to one another by means of a head plate 61.

[0041] The carrier 31 is connected with the guiding arm 27, remote to the pivot bolt 54, by means of a bearing bolt 63. The guiding arm 27 is thereby pivotably mounted about the one bearing axis 64 of the bearing bolt 63. By means of receiving of the carrier 31, via the pivot bolt 54 and bearing bolt 63, the carrier 31 can be oriented horizontally during the lifting and lowering of the lifting device 24.

[0042] The adjustment device 51 acts, according to the preferred embodiment, between the pivot bolt 54 and the carrier 31. Alternatively, the adjustment device 51 can also be provided on the bearing bolt 63. Likewise, the adjustment device 51 can be provided on the pivot bolt 54, as well as on the bearing bolt 53. The structure of the adjustment device remains the same in the alternative embodiments.

[0043] The adjustment device 51 includes a compensation plate 66 which is positioned in a centering receptacle 67 in the lateral wall 56. This is illustrated in FIG. 4 in a side view. The centering receptacle 67 in the lateral wall 56 has a V- or trough-shaped contour 71 which tapers in a force direction according to Force F1. The centering receptacle 67 can be configured in a trapezoidal. A lower lateral edge 72 of the trapezoidal centering receptacle 67 is shorter than the opposite or upper lateral edge 73. The compensation plate 66 preferably has a complementary external contour. In a load acting on the support arms 34, the V- or trough-shaped region of the centering receptacle 67 is supported on the complementary region of the compensation plate 66, which region in turn transfers the force onto the pivot bolt 55.

[0044] The compensation plate 66 includes a borehole 75, into which an end of the pivot bolt 54 engages, insofar as compensation plate 66 is positioned in the centering receptacle 67.

[0045] The pivot bolt 54 comprises at least one borehole 77 on its end face. The compensation plate 66 likewise comprises at least one borehole 78. Outside of the compensation plate 76, at least one further borehole 79 is provided in the lateral wall 56.

[0046] FIG. 3 shows a retaining device 81 of the adjustment device 51 in a sectional view, which device in represented in an enlarged side view in FIG. 5. This retaining device 81 is configured as a retaining plate, which is fixedly connected with the lateral wall 56 by means of at least one detachable fastening element 82, in particular a screw, in that the at least one fastening element 82 engages into the borehole 79. Moreover, it is preferably provided that at least one detachable retaining element 83, in particular a screw, is provided for fixation of the compensation plate 66 to the retaining device 81, which screw engages into the at least one borehole 78. Advantageously, at least one detachable fixation element 84, in particular a screw, is provided, which engages into at least one borehole 77 of the pivot bolt 55. It is thereby made possible that the adjustment device 51 allows for a firm connection between the carrier 31 and the lifting device 24.

[0047] The adjustment device 51 illustrated in the FIGS. 3 to 5 allows for adjusting the carrier 31, to the lifting device 24, in a zero point position. The lateral walls 56, 57 are oriented perpendicular to the pivot axis 55. The pivot bolt 54 and bearing bolt 63 are respectively mounted in a perforation 62 in the lateral wall 56, 57, insofar as no adjustment device 51 is provided. The borehole 75 in the compensation plate 66 is arranged inside the compensation plate 66 in such a manner that the distance X according to FIG. 3 can be assumed. The distance X corresponds to a distance which is defined by the reference surface 86 of the compensation plate 66 and a longitudinal axis 87 of the borehole 75, as can be taken from FIG. 6a.

[0048] Insofar as the support arm 34 now inclines in direction onto the floor and lies below the horizontal, in the use of a compensation plate 66 for a zero position, the compensation plate 66 can be exchanged according to FIG. 4a and be employed by means of a compensation plate 66 according to FIG. 6b. In this compensation plate 66, a distance A is provided between the reference surface 86 and the longitudinal axis 87 of the borehole 75, which is smaller in distance than the distance X. The carrier 31 is thereby pivoted in a direction according to arrow N, wherein the lateral wall 57, to the pivot bolt 54, forms a kind of rotary bearing, in order to effect the pivoting movement of the carrier 31 to the pivot bolt 55.

[0049] The exchange of the compensation plate 66 occurs to the effect that the fastening elements 82, retaining elements 83 and fixation elements 84 provided on the retaining device 81 are detached, as well as the retaining plate being removed. Subsequent thereto, the compensation plate 66 is taken out of the centering receptacle 67 and the desired new compensation plate 66, in turn, is placed upon the pivot bolt 54 and inserted into the centering receptacle 67. The retaining device 81 is, in turn, affixed with the at least one fastening element 82, retaining element 83 and fixation element 84. The new orientation of the support arm 34 is fixed.

[0050] Insofar as the end of the support arm 34 lies above a horizontal, originating from the adjustment device 51, with a zero position, it is necessary to lower the free end of the support arm 34. In such a case, a compensation plate 66 can be used according to FIG. 6c, in which the distance B between the reference surface 86 and the longitudinal axis 86 of the borehole 75 is greater than the distance X. Thereafter, the carrier 31 is inclined in the direction of arrow O and the free end of the support arm 34 is lowered.

[0051] The adjustment device 51 is preferably provided with multiple compensation plates 66, which have different distances between the reference surface 86 and the longitudinal axis 87, in order to make an individual adjusting and adapting of the support arms 34 possible.

[0052] The compensation plates 66 can comprise markings 90, through which these plates can be differentiated from one another. For example, these can be indentations, as these are illustrated in FIGS. 6b and 6c. Likewise, numbers or other symbols can be applied. Colored markings are also possible.

[0053] FIG. 7 illustrates an alternative configuration of the lifting platform 11 with respect to FIG. 1. This lifting platform 11 is different to the embodiment in FIG. 1 with respect to the configuration of the lifting device 24. In FIG. 1, the lifting device 24 is configured as a parallelogram guiding device. In the embodiment in FIG. 7, the lifting device 24 is configured as a half scissor. This half scissor comprises a strut 95 which, on the one hand, is pivotably mounted on the load arm 25 and, on the other hand, is pivotably mounted on the housing 21 of the base assembly half 14. The carrier 31 is guided oriented horizontally in this half scissor through the load arm 25 and the guiding arm 27. An opposite end of the load arm 25 and of the guiding arm 27 is pivotably mounted in a moveable carriage 96. This moveable carriage 96 is illustrated in a dashed-line manner. This moveable carriage 96 is guided horizontally movably through the housing 21 of the base assembly half 14.