Lifting Tool for Motorbike Wheel

Abstract

The invention is directed to a lifting tool (10) for a vehicle wheel (4), comprising a scissor lifting mechanism (12) with scissor pivoting arms (14); wheels (20) mounted on a lower portion of the scissor lifting mechanism (12), for rolling on the floor; and two parallel bars (16) on a top portion of the scissor lifting mechanism 812), for supporting the vehicle wheel (4). The wheels (20) are mounted directly on the scissor pivoting arms (14).

Claims

1.-11. (canceled)

12. A lifting tool for a vehicle wheel, comprising: a scissor lifting mechanism with scissor pivoting arms; wheels mounted on a lower portion of the scissor lifting mechanism, for rolling on the floor; and two parallel bars on a top portion of the scissor lifting mechanism, for supporting the vehicle wheel; wherein the wheels are mounted directly on the scissor pivoting arms; and wherein the scissor lifting mechanism further comprises: two transverse arms each interconnecting the lower ends of two distant and parallel arms of the scissor pivoting arms, respectively.

13. The lifting tool according to claim 12, wherein the scissor lifting mechanism comprises: two distant and parallel pairs of the scissor pivoting arms; the wheels comprising: four wheels, each of said wheels being mounted on a lower end of one of the arms, respectively.

14. The lifting tool according to claim 13, wherein the two parallel bars are mounted directly on the scissor pivoting arms, two opposed ends of each of said bars being attached to top ends of two distant and parallel arms of said arms, respectively.

15. The lifting tool according to claim 12, wherein the scissor lifting mechanism comprises: a spindle assembly for varying the distance between lower ends of the scissor pivoting arms.

16. The lifting tool according to claim 15, wherein the spindle assembly comprises: a threaded spindle extending through the transverse arms, said threaded spindle abutting against a first one of said arms and engaging with a corresponding thread on the second of said arms.

17. The lifting tool according to claim 12, wherein the scissor lifting mechanism comprises: resilient means allowing an automatic lift movement of said mechanism until the two parallel bars reach the vehicle wheel lifted up from the floor.

18. The lifting tool according to claim 17, wherein the resilient means comprise: a least one traction spring with two ends anchored to the transverse arms or to the lower ends of one of each pair of scissor pivoting arms, respectively.

19. The lifting tool according to claim 17, wherein the spindle assembly is configured such that it slides freely through the first transverse arm during the automatic lift movement of the scissor lifting mechanism.

20. The lifting tool according to claim 12, wherein the scissor lifting mechanism is configured such that the scissor pivoting arms of each pair of said arms are aligned in a lower position.

21. The lifting tool according to claim 20, wherein one of the arms of each pair of scissor pivoting arms shows a recess for accommodating, in the lower position, the bar or a wheel axle on the other arm of said pair.

22. The lifting tool according to claim 12, wherein at least two of the wheels are swivel wheels.

23. The lifting tool according to claim 22, wherein the swivel wheels are at one longitudinal end of the scissor lifting mechanism.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] FIG. 1 is a perspective view of the rear wheel of a motorbike while being lifted by a lifting tool according to the invention.

[0025] FIGS. 2(a), 2(b) and 2(c) are views of successive steps of lifting a motorbike wheel with the lifting tool of FIG. 1, according to the invention.

[0026] FIG. 3 is a side view of the lifting tool of FIGS. 1 and 2;

[0027] FIG. 4 is a top view of the lifting tool of FIG. 3.

DESCRIPTION OF AN EMBODIMENT

[0028] FIG. 1 illustrates a motorbike where the rear wheel is lifted with a lifting tool according to the invention.

[0029] The motorbike 2 comprises a rear wheel 4 that is mounted on the rear swing arms 6. As is apparent in FIG. 1, the rear of the motorbike 2 is jacked up by means of the stand 8 that is as such well known to the skilled person. The stand 8 for instance comprises a frame with two upwards support ends engaging with the ends of the swing arms 6, rolls and a handle enabling a pivoting movement of the stander around the engagement of the support ends with the swing arms.

[0030] A lifting tool 10 is positioned under the rear wheel 4 and lifted up to contact said wheel so as to facilitate its dismounting from, and remounting on, the motorbike. Indeed, once the rear wheel is slightly lifted up, the wheel axle can be extracted out of the swing arms and the wheel without having to exert high efforts since the weight of the wheel does not act anymore on said axle.

[0031] The lifting tool 10 comprises a scissor lifting mechanism 12 with scissor pivoting arms 14. For instance, the scissor lifting mechanism 12 comprises two pairs of scissor pivoting arms, said pairs of arms being distant and parallel so as to be on each lateral side of the wheel when the lifting tool is in position under the wheel. Supporting bars 16 are attached to the upper ends of the scissor pivoting arms 14, said bars being for contacting the running surface of the wheel tire. The scissor lifting mechanism 12 comprises also a threaded spindle assembly 18 that cooperates with the lower ends of the scissor pivoting arms 14. Wheels 20 are mounted on the lower ends of the scissor pivoting arms 14.

[0032] FIGS. 2(a) to 2(c) illustrate different successive steps of use of the lifting tool of FIG. 1.

[0033] In FIG. 2(a), the wheel 4 is jacked up at a usual height, e.g. between 50 and 100 mm, and the lifting tool 10, in a lower and nearly flat configuration, is rolled longitudinally under the wheel 4. In that configuration, the arms of each pair of scissor pivoting arms are essentially in, or at least close to alignment. The lifting tool is configured to show a total height in its lower configuration that is advantageously less than 50 mm.

[0034] In FIG. 2(b), the lifting tool 10 is manipulated so as to free it from a state where resilient means tending to lift the tool are retained. This can be achieved by slightly manually lifting the tool so as to misalign the arms of each pair of scissor pivoting arms, leading to a de-neutralization of the resilient means, allowing them to act and lift up the tool up to a contact between the bars 16 and the wheel 4. The threaded spindle assembly 18 is configured not to hinder the lift up movement of the tool by virtue of the resilient means. For example, the spindle assembly 18 can be configured to allow a free sliding of a thrust portion of the spindle while the tool lifts up. The exceeding portion of the spindle resulting of the above sliding further to the lift up movement is visible at the right of the lifting tool in FIG. 2(b).

[0035] In FIG. 2(c), the wheel 4 can be slightly lifted so at to support its weight via the bars 16 and thereby unload the wheel axle. To that end, the threaded spindle assembly 18 is operated so as to catch up the exceeding portion of the spindle of the above described rapid lift up movement, and then further operated for unloading the wheel axle by rotation of the spindle. Depending on the dimensioning of the spindle assembly and more generally the lifting tool, the torque can be applied to the spindle manually by means of a knob (not represented), preferably an ergonomic knob of a sufficient diameter to provide a proper and stable gripping by the hand, or mechanically by a drill driver, preferably a cordless drill driver 22.

[0036] It goes without saying that what has been presented in relation with FIGS. 2(a) to 2(c) applies also in the reverse order to remounting a wheel 4 on the vehicle 2.

[0037] FIGS. 3 and 4 are more detailed views of the lifting tool of FIGS. 1 and 2. FIG. 3 is a side view whereas FIG. 4 is a top view.

[0038] Each of the scissor pivoting arms 14 of the scissor lifting mechanism 12 comprises a top end 14.1 and a lower end 14.2. These end are at top and end positions when the scissor lifting mechanism 12 is in a lifted configuration, as illustrated in FIGS. 3 and 4, i.e. not as illustrated in FIG. 2(a). The top ends 14.1 of each of the arms 14, on each side, are interconnected by one of the bars 16. Each of the two bars 16 is preferably with a round cross-section, being however understood that other configurations can be considered. The lower ends 14.2 of each of the arms carries a wheel 20. Each wheel is mounted on a lower end of an arm so as to be free to rotate about its axis. The wheels 20 can have an outer diameter greater than 30 mm and/or less than 50 mm. The wheels 20 can be made of metal, plastic or a combination thereof. At least two of the wheels 20 can be pivoting or swivel wheels, i.e. able to freely rotate also about a vertical axis. For instance, the two wheels provided at one end of the lifting tool 10, relative to the longitudinal axis corresponding to the spindle 18, can be swivel wheels, thereby facilitating the positioning of the tool.

[0039] As is apparent in FIGS. 3 and 4, one of the arms of each pair of scissor pivoting arms comprises a notch or recess 14.3 that receives one of the bars 16 when the scissor lifting mechanism 12 is in a lower and aligned configuration. As it appears more precisely in FIG. 4 but still visible in FIG. 3, this is the arm, of each pair, that is located on the inner side that shows such a recess 14.3, so that the corresponding bar 16 that extends above said inner arms can be accommodated in said recesses 14.3.

[0040] It is to be mentioned that in alternative to the above recesses 14.3, the outer arms 14 of the two pairs of scissor pivoting arms could be designed longer so that their top ends 14.1 would end beyond the lower ends 14.2 of the inner arms 14 (on the right side in FIGS. 3 and 4, but not represented), and the corresponding bar 16 would be located beyond the lower ends 14.2 of the inner arms 14. In that case the wheel 20 would need to be more offset relative to the inner arms 14 and the outer arms extending above the axles of said wheels would then show recesses opened downwardly for accommodating the axels when in the lower position.

[0041] As this is apparent in FIG. 4, the lifting tool 10 comprises two transverse arms 26 interconnecting the lower ends 14.2 of the four arms, respectively. The threaded spindle 18 extends longitudinal and centrally through each of the two transverse arms 26. More specifically, the spindle 18 comprises a threaded portion 18.1 that engages with a corresponding female thread (not visible) on the corresponding transverse arm 26. The spindle 18 comprises also a head 18.2 that forms an abutting surface against the corresponding transverse arm 26 and also an end portion that can be rotatably engaged with a driving tool such as a screwdriver or a cordless drill driver. With reference to the above discussion in relation with FIG. 2(c), a gripping knob or hand-wheel can also be mounted on the end 18.2 of the spindle.

[0042] It shall be noticed that the engagement between the spindle 18 and the arms 14, for instance via the transverse arms 26, can show means that compensate the change of relative orientation between the arms 14 and the spindle 18. Indeed, in the lower configuration, the main directions of the arms and the spindle are essentially in the same plane, or at least parallel, whereas in the lifted configuration the arms are inclined relative to the horizontal plane comprising the axis of the spindle. Such compensating means can be means that allow a relative pivoting between the surfaces in contact with the spindle and the arms. For example, the transverse arms 26 could be pivotably mounted on the lower ends 14.2 of the arms. Alternatively, the transverse arms 26 could comprise pivotably mounted elements engaging with the spindle. Other mechanical compensation means, as such well known to the skilled person, can be considered.

[0043] The resilient means 24 comprise for instance two traction helical springs 24 anchored at both ends, each, at the transverse arms 26, so as to exert a resilient traction force between these two arms 26, tending to move these arms closer to each other. When the arms of each pair of scissor pivoting arms 14 are aligned, the lifting force normally produced by the resilient means 24 is absent or at least close to zero. Once the scissor lifting mechanism is manually lifted, the arms 14 of each pair of scissor pivoting arms are not aligned anymore and the attraction force of the resilient means 24 is converted into a lifting movement of the scissor lifting mechanism.

[0044] It goes without saying that the resilient means could take other forms, e.g.

[0045] the spring(s) could be anchored to the arms 14 directly, or even torsion springs could be provided at the pivots between each pair of scissor pivoting arms. In such a case, an arresting mechanism could be provided between the arms for retaining them in the lower configuration against the resilient force of the resilient means. The release of that mechanism would then free the pivoting movement between these arms and allow the lifting tool to lift up towards the wheel.

[0046] The different arms and bars constituting the above lifting tool can be made of metal, like steel or aluminium, and/or of plastic material. They could also be made of wood. The connection between the different elements can therefore be achieved by several methods, like screwing, welding (when made of metal) and/or gluing.

[0047] The above lifting tool is particularly interesting in that it can show a reduced height in a lower configuration, enabling it to be rolled under a jacked-up wheel of a motorbike while being of a simple construction and particularly adapted for supporting a motorbike wheel.