WO2007002971A1 - Wheel - Google Patents

Abstract

The invention relates to a wheel, especially for a sports gear, comprising a rim (1), a tire (6) that is retained on the rim (1), and resiliently embodied supporting elements (22, 23) for the tire (6), on which the tire (6) rests at least in part and by which the tire (6) is supported at least in some sections in the cross-sectional direction thereof. Furthermore, a first group of supporting elements (22) extend from a first bearing section (12) of the rim (1) to the opposite side while a second group of supporting elements (23) extend from a second bearing section (13) of the rim (1) to the opposite side, said second bearing section (13) facing the first bearing section (12).

Description

wheel

The present invention relates to a wheel, in particular for a sports device, according to the preamble of claim 1. In particular, the invention relates to a wheel with a rim, with a tire held on the rim and with resilient support elements for the tire on which rests the tire and of which the tire is at least partially supported in its cross-sectional profile.

There is an increasing demand for new types of sports equipment that allow for an expansion of the range of leisure activities. A form of sports equipment are those that allow a ski-related descent on snow-free slopes, so serve for so-called grass skiing. Such sports equipment is generally constructed similar to skis, i. they are elongated with a binding for attachment to a shoe, but have at least two rollers instead of the running surfaces of skis.

The actual grass skiing is done on meadows and thus requires a sufficiently smooth surface, which is largely free of obstacles. For the purposes of the present invention, however, the term grasshopper is also to be extended to activities in rougher terrain, i. for example, on descents on gravel forest roads and other subsoil. The sports equipment and in particular the wheel of such a sports equipment according to the invention should therefore have a largely off-road behavior, so that one is not bound to the use of meadows.

But even for driving largely smooth surfaces, such as paved roads or paths conventional wheels are not completely satisfactory. It has been found that conventional wheels of in-line skaters experience high-frequency vibrations that are transmitted to the user's legs and can lead to joint problems with prolonged use.

Another requirement that is made of a sports equipment, is that the mastery is as easy to learn and that the driving behavior pleasant and the movement is physiological as possible to avoid damage to the musculoskeletal system. A generally perceived as very pleasant movement that meets the above requirements, is itself during deep snow skiing with skis adjusting. It is therefore desirable to provide a sports equipment that comes as close as possible to a ski in its driving behavior, which is driven in deep snow. In particular, the behavior during turning and during load changes is intended to simulate deep snow driving.

An essential prerequisite for achieving the driving behavior described above is a corresponding design of the wheels of the sports equipment. These must on the one hand allow a certain off-road capability and on the other hand ensure by their elasticity a corresponding steering behavior to allow changes of direction as in skiing.

From WO 00/27490 a wheel is known which can be used for inline skaters. This wheel has an outer rim, which is resiliently mounted relative to an inner rim to cushion shocks. Furthermore, from WO 98/41295 a wheel is known, which is also intended for inline skaters. In order to achieve a predetermined braking behavior when crossing the skater, a toroidal tire is provided, which can rotate about its own axis and thus enables a correspondingly braked sideways movement of the wheel. Both previously known wheels described above are unable to simulate the behavior of a ski during deep snow skiing. In particular, with the known wheels, operation in rougher terrain can not be performed.

Even with wheels conventionally equipped with pneumatic tires, such as disclosed in US 5,535,800 A, the handling performance can not be adjusted according to the desired deep snow driving behavior.

From WO 2004/060506 a wheel is also known, which meets the above requirements as far as possible. However, the production of such a wheel is relatively complicated and there is a need to reduce the weight of the wheel without degrading the driving characteristics.

Object of the present invention is to develop a wheel of the type described above so that a simple and inexpensive production is possible and a reduction in weight can be achieved. Another essential task is to prevent the occurrence and transmission of vibrations as far as possible and thereby achieve a protection of the joints of the user.

The above objects are achieved by the features of claim 1. In the subsequent claims 2 to 10 are advantageous embodiments. In particular, these objects are achieved according to the invention in that a first group of supporting elements extends from a first bearing section of the rim, preferably beyond the median plane of the wheel, to the opposite side, and a second group of supporting elements extends from a second bearing section of the rim, which is the first Bearing portion opposite, extending to the opposite side.

The wheel of the invention has a very simple structure and is therefore easy to produce. At the same time with such a wheel excellent off-road capability is achieved, which offers the possibility to realize a driving behavior, which in combination with corresponding sports equipment has an experience that is largely similar to driving in deep snow. Up to a certain transverse force, which acts on the wheel transversely to the direction of travel, a stable directional stability is achieved. With larger transverse forces but still takes a deformation of the tire in the footprint, so that the wheel receives a component of movement transverse to the actual direction. Since the transverse force limit from which the transverse movement begins, depends on the load on the wheel and the size of the movement component decreases transversely to the direction with increasing inclination of the wheel relative to a vertical plane, a substantial match with the deep snow skiing is achieved. The support elements deform differently depending on the direction of the lateral force. The preferably tongue-shaped design of the support elements, it is possible to vary the bending stiffness as a function of the distance from the bearing section as desired by the width or the thickness of the support elements is varied accordingly. In this way, the deformation behavior and thus ultimately the handling of the wheel can be influenced as desired.

The above-mentioned advantages can be further enhanced by biasing the support members circumferentially against the tire. In addition thereto or independently thereof, it may be provided that the support elements are arc-shaped.

A particularly pleasant driving behavior of the wheel according to the invention results from the fact that the support elements support the tire at least approximately in its entire cross-sectional profile.

Production technology is particularly advantageous if the support elements are integrally formed on the rim. In this way, fasteners or other precautions for attachment of the support elements are not required. The connection of the support elements to the rim can be done in different ways. Thus, there is the possibility that a support element extends from the first bearing portion of the rim through to the second bearing portion of the rim. A particularly simple production and an equally simple assembly can be achieved in that the support elements are arranged cantilever-like on the rim. In this case, the support elements may be wedge-shaped towards their free end.

In a cantilever-like configuration of the support elements or in a cantilever-like connection of the support elements to the rim, there is still the possibility that the support elements are arranged on the first and the second bearing portion so that the free ends of the support elements of these two bearing portions are aligned diametrically opposite each other. In this case, the free ends of the support elements can touch. It is also possible that the free ends of the support elements have a distance from each other. Alternatively, it may also be provided that the support elements of the first bearing section are arranged offset in the circumferential direction to the support elements of the second bearing section, so that the free ends of the support elements of the first bearing section in the distance space between two consecutive support elements of the second bearing section have. Here, too, there is basically the possibility that the support elements of the first bearing section with their free ends touch the free ends of two consecutive support elements of the second bearing section. Likewise, also here the support elements can have a distance from each other both in the axial direction and in the circumferential direction.

In principle, there is the possibility that the support elements after manufacture of the rim are attached thereto by a suitable manufacturing step, such as gluing, ultrasonic welding and the like. A particularly simple production can be achieved, in particular with a cantilever-like configuration of the support elements on the first and the second bearing portion of the rim, by virtue of the fact that the support elements are integrally connected to the rim.

In order to enable a sufficient compression of the support elements, it is also advantageous if a compression cavity is provided below the support elements on the rim.

In principle, the support elements can be designed to be resiliently deflectable both in the circumferential direction and in the radial direction. Is particularly advantageous it, if the support member are at least approximately in the radial direction to the wheel axle to spring deflected. In principle, the deflection path of a supporting element can be designed to be undefined. In order to obtain a defined Auslenkweg a support element, it is also advantageous if the Auslenkweg a support element by a stop, in particular provided on the rim, preferably integrally molded projection is limited.

A further increase in stability can be achieved in that the support elements in the region of the bearing sections have recesses for receiving and guiding the tire.

It has also proven to be particularly favorable for the driving behavior if a narrow gap is provided between the individual support elements, in particular if the gap between the support elements has a uniform width.

Furthermore, it is advantageous if both groups of support elements each extend beyond the middle end of the wheel to the opposite side.

It is particularly advantageous if in the circumferential direction of the wheel between each two support elements of the first group, a support member of the second group is arranged, and vice versa, when in the circumferential direction of the wheel between each two support elements of the second group, a support member of the first group is arranged. In this way, the individual support elements of the first group, or of the second group, engage with each other in a tooth-like or comb-like manner, but without touching each other. In this way, a uniform deformation behavior is achieved over the circumference of the wheel.

Alternatively, it may be provided that in each case a support element of the first group rests on a support element of the second group. As a result, a particularly favorable spring behavior is achieved. The lateral symmetry is ensured in particular by the fact that in the circumferential direction alternately a support elements of the first group rests on a support element of the second group or a support elements of the second group on a support element of the first group. A limitation of the compression is achieved in that the support elements have stop projections. The spring rate of a single support element can be influenced in various ways. Thus, on the one hand there is the possibility that the spring rate of a support element is adjustable by the choice of material. Additionally or alternatively, it may further be provided that the spring rate of a support element is adjustable by the geometry of the support element.

Particularly favorable in this context, when the rim is made in two parts and consists of two halves, which are preferably connected in the region of the median plane of the wheel. Each rim half carries the support elements of a group, so that from the two rim halves and the tire already all the essential elements of the wheel can be assembled. Alternatively, it is possible that the rim is made in two parts and consists of two halves, one half of which has a hub portion for receiving rolling bearings or plain bearings. In this way, a particularly robust bearing of the wheel can be achieved, since all bearings are arranged in a single component.

For the material of the rim any suitable material can be selected. The rim can be produced particularly simply by being made of plastic. Here, the rim can be made of two-component injection molding, wherein the rim body made of a hard plastic and the support elements molded thereon are made of an elastic plastic.

An optimal handling of the wheel, especially for the grass can be achieved by the fact that the tire is constructed without pressure. In addition, it can be provided that the wheel is designed as a solid rubber tire.

Particular advantages result according to the invention in that the tire is constructed in three layers and consists of a tread, a soft-elastic inner layer and a support layer. The support layer is mechanically resistant to withstand the friction on the support elements. The tread has the optimum profile for the respective terrain and suitable wear resistance. The soft-elastic inner layer is elastic in the thickness direction and allows a fine spring behavior.

Another particularly favorable embodiment variant of the invention provides an engagement element on the rim next to the tire, which extends along the circumference of the rim. As a result, the engagement of the edges can be simulated, which only takes effect when driving in deep snow at a certain angle of inclination in the transverse direction. - / -

Further advantageous embodiments and some embodiments of the present invention will be explained below in conjunction with the accompanying drawings. Here is:

1 shows a first embodiment of the wheel according to the invention in a cross-sectional view.

FIG. 2 shows a second embodiment of the wheel according to the invention in a cross-sectional view; FIG.

3 shows a detail of the wheel according to the invention in a plan view;

4 shows a third embodiment in a cutaway exploded view; and

Fig. 5 shows a fourth embodiment in section.

An inventive wheel 1 is shown in Fig. 1 and consists of a rim 1 made of plastic, which is composed of two rim halves 2, 3, which are fastened along a the wheel axis at an angle of 90 ° intersecting center plane 4 of the wheel 1 to each other , The attachment can be either insoluble, for example, by gluing or releasably done for example by a snap or screw. The tire 6 may, as shown, be constructed in three layers and consists of an outer running surface 9, a soft elastic inner layer 10 and a support layer 11. Likewise, the Possibility that the tire 6 consists of only one layer.

The two rim halves 2, 3 enclose a substantially torus-shaped interior 7, which is not closed airtight, so that a non-pressure tire is realized. This toroidal interior 7 serves as a spring cavity in the manner described in more detail below.

On the first rim half 2 is located on the outer periphery of a first bearing or a first bearing portion 12, on the one hand, the tire 6 is supported and on the other hand integrally projecting integrally formed on the first bearing 12 integrally formed support members 22 of a first group to support the tire 6 arcuate. Analogously, the second rim half 3 has a bearing point or a bearing section 13, from which support elements 23 of a second group, which are likewise integrally formed on the second bearing section 13, protrude opposite to the support elements 22 of the first group. The Ausfϋhrungsvariante of Fig. 2 differs from that of Fig. 1, characterized in that below the bearings 12, 13 projections 14, 15 are provided, which serve to limit the compression of the support members 22, 23 in the spring cavity 7 and thus define. With broken lines, a support member 22 of the first group is shown in a compressed state. Furthermore, the embodiment of Fig. 2 differs from that of Fig. 1 in that the rim 1 is integrally formed.

Fig. 3 shows a portion of the rim 1 in a plan view. It can be seen that the support elements 22, 23 are formed tongue-shaped or Kragarmartig and that the gap 16 between the support members 22, 23 is narrow and uniformly wide. As can be seen in particular from FIG. 3, the support elements 22 or 23 of the first and second groups in the circumferential direction have an unspecified distance from one another. In the distance space two successive support members 22, 23 of a group engage the support members 23 or 22 of the second group like a comb. However, as already explained above, there is also the possibility that the support elements 22, 23 lie opposite one another and in this case touch the free ends or have a spacing through which the center plane 4 of the wheel 1 passes.

According to one embodiment, it is provided that the running surface 9 is formed integrally with the support elements 22, 23 and preferably consists of the same material.

4 shows a further embodiment, in which the rim halves 2, 3 are substantially disc-shaped. On the first rim half 2, a hub portion 2a is integrally formed, which receives two rolling bearings 24, 25. The other rim half 3 is seated on a groove 29 of the hub portion 2a.

In the region of the outer circumference of the rim halves 2, 3, in each case the support elements 22, 23 protrude cantilever-like in the axial direction. The support elements 22, 23 have in the region of the bearing portions 12, 13 on the outer side in each case a recess 18, 19 which form a total circumferential interrupted groove and which are intended to receive a bead 26, 27 of the wheel 6. The support elements 22, 23 carry under pretension the inner surface 28 of the tire 6. Overall, this structure results in a tense and compact assembly, since for example the tire 6 by the two beads 26, 27, the support members 22, 23 are held together. On the outer circumference of the Rim halves 2, 3 are shoulders 30, 31 are formed, which support the tire 6 and increase the stability.

The embodiment variant of FIG. 5 differs from the ones described above in that the individual support elements 22, 23 are not arranged in the circumferential direction with or without a spacing between the individual successive support elements 22, 23 but one above the other. The support element 22 of the first group shown in Fig. 5 is located below a support member 23 of the second group and supports this. In the adjacent pairs of support members 22, 23, which are not detailed here, it is vice versa, here supports a support member 23 of the second group, a support member 22 of the first group. In principle, all support elements 22 or 23 of the one group can also be arranged on or under the support elements 23 or 22 of the other group.

The support elements 22, 23 have abutment projections 20, 21 which delimit the inserts by forming a stop for the tip of the opposing support element 23, 22.

The embodiments of the wheel according to the invention explained in connection with FIGS. 4 and 5 can be manufactured by first producing the first rim half 2 and the second rim half 3 with the supporting elements 22, 23 integrally formed thereon by an injection molding process. Subsequently, the wheel 6 can be pushed onto the first or the second rim half 2, 3. Thereupon, the two rim halves 2 and 3 with the mutually facing support elements 22, 23 are plugged in such a way that the second rim half 3 dips into the circumferential groove 29 of the first rim half 2 and possibly simultaneously the support members 23 of the second rim half 3 in the Interspaces between two consecutive support elements 22 of the first rim half engage in a comb-like manner or, as shown in particular in FIG. Subsequently, the two rim halves 2, 3 are releasably connected to each other, for example by a screw connection.

The present invention makes it possible to manufacture a wheel with optimum driving characteristics in a simple manner and at the same time extremely easy to build. At the same time unwanted vibrations are largely suppressed.

Claims

PATENT APPLICATIONS 1. wheel, in particular for a sports equipment, with a rim (1), with a rim (1) held on the tire (6) and with resilient support elements (22, 23) for the tire (6) on which the tire (6) at least partially rests and of which the tire (6) is at least partially supported in its cross-sectional profile, characterized in that a first group of support elements (22) from a first bearing portion (12) of the rim (1) to the opposite side extends and that a second group of support members (23) from a second bearing portion (13) of the rim (1) which is opposite to the first bearing portion (12), extends to the opposite side. 2. Wheel according to claim 1, characterized in that the support elements (22, 23) are biased in the circumferential direction against the tire (6). 3. Wheel according to claim 1 or 2, characterized in that the supporting elements (22, 23) are arcuate. 4. Wheel according to one of claims 1 to 3, characterized in that the support elements (22, 23) support the tire (6) at least approximately in its entire cross-sectional profile. 5. Wheel according to one of claims 1 to 4, characterized in that the supporting elements (22, 23) on the rim (1) are integrally formed. 6. Wheel according to one of claims 1 to 5, characterized in that the supporting elements (22, 23) cantilever-like manner to the rim (1) are arranged. 7. Wheel according to claim 5, characterized in that the support elements (22, 23) are wedge-shaped towards its free end. 8. Wheel according to claim 6 or 7, characterized in that the free ends of the support elements (22, 23) to each other at a distance in the direction parallel to the wheel axle. 9. Wheel according to one of claims 1 to 8, characterized in that the supporting elements (22, 23) are integrally connected to the rim (1). 10. Wheel according to one of claims 1 to 9, characterized in that on the rim a Einfederhohlraum (7) below the support elements (22, 23) is provided. 11. Wheel according to one of claims 1 to 10, characterized in that the support elements (22, 23) are at least approximately deflectable in the radial direction to the wheel axle to spring. 12. Wheel according to claim 11, characterized in that the Auslenkweg a support element (22, 23) by a stop, in particular one on the rim (1) provided, preferably integrally formed projection (14, 15) is limited. 13. Wheel according to one of claims 1 to 12, characterized in that the support elements (22, 23) in the region of the bearing portions (12, 13) recesses (18, 19) for receiving and guiding the tire (6). 14. Wheel according to one of claims 1 to 13, characterized in that between the individual support elements (22, 23) is provided a narrow gap (16). 15. Wheel according to claim 14, characterized in that the gap (16) between the support elements (22, 23) has a uniform width. 16. Wheel according to claim 1 to 15, characterized in that both groups of support members (22, 23) extend beyond the median plane (4) of the wheel also to the opposite side. 17. Wheel according to claim 1 to 16, characterized in that in each case a support element (22) of the first group rests on a support element (23) of the second group. 18. Wheel according to claim 17, characterized in that the support elements (22, 23) stop projections (20, 21). 19. Wheel according to claim 1 to 18, characterized in that in the circumferential direction of the wheel between each two support elements (23) of the second group, a support element (22) of the first group is arranged. 20. Wheel according to one of claims 1 to 19, characterized in that the spring rate of a support member is adjustable by the material selection. 21. Wheel according to one of claims 1 to 20, characterized in that the spring rate of a support element (22, 23) is adjustable by the geometry of the support element. 22. Wheel according to one of claims 1 to 21, characterized in that the rim (1) is made in two parts and consists of two halves (2, 3), preferably in the region of the wheel axis at least approximately perpendicularly intersecting center plane (4) of Rades are connected. 23. Wheel according to one of claims 1 to 22, characterized in that the rim (1) is made in two parts and consists of two halves (2, 3), of which one half (2) has a hub portion (2a) for receiving rolling bearings (24, 25) or sliding bearings. 24. Wheel according to one of claims 1 to 23, characterized in that the rim (1) is made of plastic. 25. Wheel according to claim 24, characterized in that the rim (1) is made of two-component injection molding, wherein the rim body made of a hard plastic and the support elements integrally formed thereon (22, 23) consist of an elastic plastic. 26. Wheel according to one of claims 1 to 25, characterized in that the wheel is formed without pressure. 27. Wheel according to claim 26, characterized in that the wheel is designed as a solid rubber tire.