The present invention relates to a buffer for a pole, in particular for a trekking pole, walking stick or Nordic walking pole, it being the case that the buffer, at its top end, has means for fastening on a pole shaft, in particular in the form of a recess, and, at its bottom end, has a rolling surface, and that the rolling surface is of essentially planar or only slightly convexly curved design in a transverse direction, as seen in relation to the rolling movement, but in a longitudinal direction, perpendicularly thereto, is curved convexly such that, as the user of the pole is moving, it forms a rolling surface as the pole is pushed off an underlying surface. The present invention also relates to a trekking pole, walking stick or Nordic walking pole having such a buffer, and to methods of producing such buffers or damping elements.
For health reasons, trekking, and equally mountaineering, is increasingly being done with the aid of at least one pole, and preferably even two poles. In particular so-called Nordic walking is even based on the use of two poles, which therefore allows dynamic movement which does not adversely affect the joints.
Both techniques are used on a wide variety of different terrains, in particular, on the one hand, on hard, sealed surfaces, for example tarred roadway and paths, but also, on the other hand, for example on soft surfaces such as country paths and fields or also on snow-covered or ice-covered surfaces.
For soft surfaces or for snow-covered or ice-covered surfaces, use can usually be made of the classic tip, as is known, for example from downhill skiing or cross-country skiing. Such a hard tip, however, is not suitable for hard, sealed surfaces since, on the one hand, the resulting impacts are harmful to the joints and, on the other hand, the level of adherence or friction for pushing the pole off the ground is too low and the level of sound/noise developed upon impact is too high. Correspondingly, buffers which are made of elastomeric material and can be pushed, for example, onto a conventional pole have already been proposed for such surfaces.
In order for it not to be necessary for the tip to be modified every time as the underlying surface changes, combined forms have already been proposed, these having, for example, a kind of classic tip passing through such a rubber buffer and thus, in respect of the pole being pushed off the ground, partially combining the advantages of both systems. Such a system is described, for example, in EP-A-0 978 298.
However, such a system still has the disadvantage, on the one hand, that the projecting tip still strikes harshly against hard surfaces and is thus problematic for the joints and, on the other hand, that an unpleasant level of sound/noise develops when the hard tip strikes against the underlying surface. In addition, at the moment when such a tip strikes as it rolls onto the underlying surface, the resistance or the friction is usually insufficient for pushing the pole off the ground.
Correspondingly, systems in which the tip, depending on requirements, can be recessed in the buffer or pushed out through the same have already been proposed. However, such systems are mechanically complex and correspondingly expensive; in addition, as a result of the moving parts, they usually attract dirt and, in particular, they also require manipulation by the user as the terrain changes, which is normally undesirable.
This is where the invention comes in. Accordingly, one object of the invention is to provide an improved buffer which can be used for a trekking pole, walking stick or Nordic walking pole and is suitable for a wide variety of different terrains. The task in particular is to provide a buffer for a pole, in particular for a trekking pole, walking stick or Nordic walking pole, it being the case that the buffer, at its top end, has a fastening element for fastening on a pole shaft, e.g. in the form of a recess, and, at its bottom end, has a rolling surface, and that preferably the rolling surface is of essentially planar or only slightly convexly curved design (if appropriate with hollow-like indents or depressions) in a transverse direction, as seen in relation to the rolling movement, but in a longitudinal direction, perpendicularly thereto, is curved convexly such that, as the user of the pole is moving, it forms a rolling surface as the pole is pushed off an underlying surface.
This object is preferably achieved in that the buffer consists of an elastomeric material, at least in the region of the rolling surface, and in that at least one elastically mounted, hard, essentially non-elastic retaining element is arranged in the elastomeric material.
One finding of the invention is thus, to a certain extent, for the function of a tip to be performed by at least one retaining element which is mounted elastically in the elastomeric material. This means that the hard, non-elastic retaining element, for example made of metal and/or ceramic material, can engage in soft terrains and thus, in a manner similar to a classic pole tip, and is suitable for such soft terrains. However, the fact that the retaining element is mounted elastically in the elastomeric material results in a surprising effect when the pole is used on a hard underlying surface, namely that, by virtue of being embedded elastically, the retaining element does not transmit any hard impacts to the pole handle, and thus does not have any adverse effects on the locomotor apparatus, and that, furthermore, embedding the retaining element elastically means that there is essentially no unpleasant impact noise, which is unavoidable with conventional tips. The effect is therefore similar to that of a spike as is known from use in winter tires.
The retaining element here has a hardness which preferably, on Mohs' scale, is greater than 3, in particular preferably greater than 4 or 5, or even greater than 6 or 7. The hardness specified relates here to that region of the retaining element which comes into contact with the terrain or penetrates into the same. Those regions of the retaining element which do not come into contact with, or penetrate into, the terrain may readily have a lower level of hardness, and they can even consist of soft and partially elastic material, as long as it is ensured that they are secured to a sufficient extent in the material of the buffer.
According to a first embodiment, the at least one elastically mounted retaining element projects, at least in part, beyond the rolling surface, typically by in the region of half a millimeter to 2 or 3 mm or more. The depth to which the retaining element is anchored in the buffer here is typically greater than the height which projects beyond the rolling surface.
The rolling surface is preferably generally of asymmetrical design in that it is drawn upward at the front end (that is to say in the walking direction) and the rear end essentially forms a point. This results in ideal rolling behavior of the, for example, usually rather long poles used for Nordic walking.
According to a further embodiment, at least 2, preferably at least 4, at least 6 or at least 8 retaining elements are arranged on or in the rolling surface. The retaining elements are preferably spaced apart in the longitudinal direction, that is to say in the walking direction, it being possible for at least 2 or at least 3 or at least 4 retaining elements to be arranged in at least one row or to be offset in particular laterally in relation to one another in the longitudinal direction. This particular arrangement of the retaining elements proves to be extremely suitable in particular in conjunction with the specifically configured rolling surface, which is convex in the walking direction. This is because it is thus ensured that, throughout the movement sequence, there is always a retaining element in contact with the terrain.
A further embodiment is distinguished in that at least 4, preferably 6 or 8 retaining elements are provided, and in that the retaining elements are arranged in at least 2 transversely offset rows of correspondingly 2, 3 or 4 retaining elements. The fact that various rows are offset laterally gives the additional advantage that, if the pole is set down at an angle or if the terrain is uneven, there are always retaining elements in contact with the terrain.
Particularly good suitability for a wide variety of different underlying surfaces can be achieved if, according to a further embodiment, the rolling surface, in addition, has a profile. In this case, preferably the at least one retaining element is arranged on at least one top cleat surface of the profile. The profile may have at least one, preferably central longitudinal channel and at least 2, 3 or 4 transverse channels branching off symmetrically, in particular laterally, therefrom, and two rows of, for example, in each case four retaining elements running in the longitudinal direction may be arranged on the top cleat surfaces of the rolling surface, these cleat surfaces being formed by the channels.
The buffer preferably consists entirely of a single piece of elastomeric material, in particular preferably of a possibly vulcanized natural and/or synthetic rubber, in particular preferably with a hardness of 20 to 80 Shore A, preferably of 50-70 Shore A, e.g. 55-64 Shore A. Use may be made, for example, of typical tire materials.
According to another embodiment, the retaining element is designed in the form of a pin which has its first end embedded in the elastomeric material and has its second end projecting beyond the top of the rolling surface. Preferably the region which projects at the second end is delimited from, and/or supported in relation to, the rolling surface by an in particular preferably encircling flange or collar. The second end typically projects beyond the top of the rolling surface by way of a height in the region of 0.05-5 mm, in particular preferably in the region of 1-2 mm. The collar preferably has a circular-ring width of 0.5-1.5 mm.
The retaining element preferably has a particularly hard, in particular hardened, tip at its second end.
The retaining element may have a single-piece anchoring element which, apart from a flange or collar (the flange or collar may be formed integrally with the anchoring element or as an individual element), is embedded in the elastomeric material, it being the case that, on its side which is directed toward the rolling surface, the anchoring element preferably has a recess in which a tip element, for example in the form of a metal pin, is incorporated and fastened. The anchoring element may consist, for example, of plastic, iron, steel, in particular stainless steel, brass, aluminum or other nonferrous metals. The tip element may consist, for example, of ceramic material, hardened metal, in particular hardened steel, sintered hard metals or other wear-resistant materials. The tip element may also be coated, using appropriate methods, with a wear-minimizing surface (e.g. TiN, TiCN, etc.).
According to a further embodiment, in the region which is embedded in the elastomeric material, the anchoring element preferably has anchoring elements, in particular preferably in the form of anchoring lamellae. Preferably a plurality of encircling anchoring lamellae are provided, and these are of conical design in the direction away from the rolling surface and of stepped design in the direction toward the rolling surface. In the case of such a specific design, the anchoring element, or the retaining element as a whole, can be particularly straightforwardly introduced, or driven, into the buffer by the method described hereinbelow.
A particularly straightforward design is possible if a single, elastically mounted, hard, non-elastic retaining element is arranged in the elastomeric material, this retaining element preferably projecting, at least in part, downward beyond the rolling surface. The retaining element here has an anchoring element which, preferably apart from a flange, is embedded in the elastomeric material, it being the case that, in the region which is embedded in the elastomeric material, the retaining element has anchoring means, in particular preferably in the form of anchoring lamellae. On its side which is directed toward the rolling surface, the anchoring element may have a recess in which a tip element is incorporated and fastened, as has been explained above. Such a single retaining element is arranged centrally in particular preferably in the transverse direction.
The buffer may additionally be provided with a specific flexibility, in particular when, as has been explained above, it consists entirely of a single piece of elastomeric material. This specific flexibility is possible by recesses being provided in the regions which may be of a softer structure. A particularly preferred region of this type is the front edge of the buffer. It is also advantageous, according to a further preferred embodiment of the invention, if, on its front edge, the buffer has a crosspiece formed by two laterally provided recesses, this crosspiece extending preferably over at least 10%, in particular preferably over in the region of 20-40%, of the overall length of the front edge. Analogous measures may be taken in respect of the rear edge.
In order to increase the grip of the buffer, in particular in soft material into which the buffer penetrates to a considerable extent, it is additionally possible to provide a profile laterally as well, rather than just in the downward direction on the rolling surface. According to a further preferred embodiment, it is thus possible to design the buffer with an asymmetric rolling surface in that it is drawn upward at the front end and the rear end essentially forms a point, and additionally to provide lateral protrusions which project laterally beyond the outer contour of the buffer and, correspondingly, allow better engagement in the material of the ground. In this case, preferably at least two, in particular preferably at least three, such lateral protrusions are provided on each side of the buffer.
The present invention also relates to a trekking or Nordic walking pole having a buffer as has been described above.
The present invention additionally relates to a method of producing a buffer as has been described above. The method is characterized, in particular, in that the at least one retaining element is driven into the rolling surface, essentially perpendicular to the rolling surface, at the appropriate locations, for example onto the cleats of a profile, appropriate blind holes possibly having been formed beforehand by drilling, melting or burning or even having been molded in during the process for producing the preform.
An alternative to this method consists in that the at least one retaining element is pushed into the rolling surface, essentially perpendicularly to the rolling surface, at the appropriate locations, in the process being pushed into, and adhesively bonded in, blind holes which are correspondingly formed by drilling or even during the process for producing the preform.
Further embodiments of the invention are described in the dependent claims.
The invention will be explained in more detail hereinbelow, with reference to exemplary embodiments, in conjunction with the drawings, in which:
a) shows a lateral view according to
The figures, which should be used as an illustration of the invention and not for limiting the scope of protection as formulated in the patent claims, will now be used hereinbelow to describe exemplary embodiments.
In the region of the bottom end, a buffer 2 is fastened on this pole shaft 1a. For this purpose, the buffer 2 is provided, at its top end 4, with a blind hole or a recess 10 (see
The buffer 2 has a rolling surface 5 at its bottom end. This rolling surface 5 has a front end 6 and a rear end 7, front and rear relating to the walking direction.
In other words, the illustration in
The shape is optimized for movement insofar as a certain triangular structure, as seen from the side, is predetermined, of which the long leg, which is directed toward the rear, is formed essentially along the axis of the pole, the bottom point of this long leg being formed by the rear end 7, and of which the bottom, short leg is formed convexly, in the direction of the ground, as the rolling surface, in which case the point which is directed toward the front is formed by the front end 6 of the rolling surface 5.
Incorporated on the rolling surface 5, or in this rolling surface 5, are retaining elements 9 which project some way beyond the rolling surface in the direction of the ground. As can be seen from
The buffer 2 is produced from an elastomeric plastic material, for example from materials which are conventional in tire production, that is to say examples of suitable materials are vulcanized synthetic rubbers. Such a buffer 2 may be produced by molding.
It is also possible to produce the buffer from different materials, for example for it to be produced, in the region which is directed toward the top end, from a first, possibly even non-elastic, plastic material and, in the region of the rolling surface, for example with a height from 2 to 10 mm, from an elastomeric plastic material. Such a buffer may be produced either by coextrusion, or two-component injection molding, or, for example, by virtue of the different materials being adhesively bonded. The essential factor is for the buffer always to consist of an elastomeric material in the region of the rolling surface since, otherwise, it is not possible for the retaining elements 9 to be mounted elastomerically according to the invention.
In addition, the buffer 2 preferably has a profile 8 on the rolling surface 5. This is easiest to see from
In conjunction with the typical movement sequence, it proves to be advantageous to provide a profile with a central longitudinal channel 12, from which transverse channels 11 branch off laterally. This results in the formation of two rows of cleats which run parallel in the longitudinal direction and on the top surfaces of which the retaining elements 9 may be arranged in likewise two rows. In order to prevent wear in the peripheral region at the front end 6 and/or the rear end 7, this region being subjected to particular loading, and or to prevent cleats from dropping out, it proves to be advantageous to allow the longitudinal channel 12 to run just over the central section, in which case the final cleats, as it were, are connected to one another at the ends 6, 7.
The operation of embedding or fastening the retaining elements 9 in the buffer 2 will be explained in detail with the aid of
A possible retaining element 9 is illustrated in detail in
The anchoring element 16 serves essentially to fasten the tip element 15 in the elastomeric material of the buffer 2. It is of cylindrical design for this purpose and, on its side which is directed toward the buffer, it has a slightly conically tapering tip 20, which makes it easier for such an element 9 to be introduced or driven in.
Also provided are anchoring lamellae 17, which are intended to prevent the retaining element 9 from being “worked out” of the buffer under mechanical loading. In this respect, anchoring in elastomeric material is known to be problematic, and it has been found that barb-like lamellae 17 are particularly suitable for lasting fastening in such an environment.
At its end which is directed toward the rolling surface 5, the anchoring element 16 has a recess 19 in the form of a, for example, conically tapering blind hole, into which the tip element 15 can be introduced and fastened. Fastening here can take place via force fitting, form fitting (e.g. screw connection), pressing or adhesive bonding or the like.
In addition, the anchoring element 16 has a collar or flange 18 at its outermost end. This collar serves for preventing the retaining element 9 from sinking all the way into the elastomeric material under loading. The anchoring element 16 has a diameter d in the region of 1-3 mm. The collar has a thickness a in the region of 0.2-1.5 millimeters and an annular-ring width b in the region of 0.5-2 mm. Furthermore, the anchoring element 16 has an anchoring depth t in the region of 1-15 mm or above, preferably of 2-7 mm or 5-10 mm.
The anchoring element may be produced from metal, for example steel, iron, stainless steel, brass, aluminum or other nonferrous metals, in which case it may be produced by casting or machining. It is likewise possible to use plastic materials (more lightweight), for example polyethylene, polycarbonate, polypropylene, PVC, polyamide, etc., it also being possible for such materials to be fiber-reinforced. Anchoring elements made of such plastic materials may be produced, for example, by injection molding.
The tip element 15 may be formed integrally with the anchoring element 16, in which case it is then recommended to subject the tip element 15 to a special hardening process or coating process.
However, as is illustrated in
The tip element may be, for example, a pin made of a preferably hardened material, e.g. of metal such as hardened steel, sintered hard metals or other wear-resistant materials. The tip element may also be coated, using appropriate methods, with a wear-minimizing surface (e.g. TiN, TiCN, etc.). It is also possible, however, to provide tips made of ceramic material. Such a tip element 15 normally has a diameter D in the region of 1-2.5 mm.
A further exemplary embodiment of a buffer 2 is illustrated in
The buffer according to
A further special feature of the embodiment according to
In addition, it is also possible, although this is not illustrated in the figures, to provide just a single retaining element 9, as described in detail above, that is to say with one flange and one tip element 15 incorporated, in the rolling surface of such an asymmetric buffer, in particular along the central axis of the buffer, as seen in the walking direction. Such a design is particularly straightforward and, nevertheless, has the advantages according to the invention. Such a retaining element 9 can also be driven retrospectively into an existing buffer.
It can also be seen from
Number | Date | Country | Kind |
---|---|---|---|
0942/05 | Jun 2005 | CH | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/CH2006/000268 | 5/22/2006 | WO | 00 | 11/27/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2006/128312 | 12/7/2006 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3177884 | Thro | Apr 1965 | A |
4493334 | Semanchik et al. | Jan 1985 | A |
4899771 | Wilkinson | Feb 1990 | A |
5032135 | Jacobson | Jul 1991 | A |
5088513 | Ostermeyer | Feb 1992 | A |
5301704 | Brown | Apr 1994 | A |
5331989 | Stephens | Jul 1994 | A |
5409029 | Davis | Apr 1995 | A |
5778605 | Ellena et al. | Jul 1998 | A |
5826606 | Davenport | Oct 1998 | A |
5829463 | Galan | Nov 1998 | A |
5954075 | Gilmour | Sep 1999 | A |
7360547 | Carlson | Apr 2008 | B2 |
20040226593 | Robitaille et al. | Nov 2004 | A1 |
Number | Date | Country |
---|---|---|
20 58 863 | May 1972 | DE |
203 18 553 | Apr 2004 | DE |
203 18 682 | Apr 2005 | DE |
0 518 539 | Dec 1992 | EP |
0 978 298 | Feb 2000 | EP |
1 246 463 | Nov 1960 | FR |
Number | Date | Country | |
---|---|---|---|
20080196753 A1 | Aug 2008 | US |