EP1582240B1 - Snow gliding board in particular a snowboard - Google Patents

Abstract

The board has a glide board corpus having a running surface coating with steel edges on one bottom side. The steel edges form an edge area for an edge grip and are located on one long side of the glide board corpus where in a section, between ends of the glide board corpus, one of the steel edges is set back by an amount (x) in relation to one plane or level (N) of a running surface formed by a running surface coating to a top of the snow glide board. On both long sides of the glide board corpus, the respective steel edge and its edge area are set back from the level of the gliding surface in a direction toward the top of the glide board corpus.

Description

The invention relates to a snowboard according to the preamble of claim 1.

Snow gliding boards of this type are known in various designs. The object of the invention is to show a snowboard, which offers an extended range of driving pleasure.

A snowboard board is known ( US 5,871,224 ) having a sliding board body having on each longitudinal side two continuous steel edges at different levels, in such a way that an inner steel edge is provided at the same level with the tread and an outer steel edge opposite the tread by an amount toward the Gleitbrettoberseite out.

Also known sliding boards in the form of skis with differently shaped steel edges on the two longitudinal sides of a ski body ( US Pat. No. 6,062,585 ). All versions have in common that the steel edges each form a groove-like or undercut edge area by their design and arrangement. The steel edges are always provided at the same level with respect to the running surface of the ski body.

To solve this problem, a Snowbroard is designed according to claim 1. With the snowboard according to the invention is the usual snowboarding in the terrain also possible, as a so-called rail driving or grinding, i. a transverse slide on existing in the terrain rails, beams, edges, etc., and without obstruction by the necessary for the edge grip during normal boarding steel edges or their edge regions.

Fig. 1

in vereinfachter Darsetellung und in Draufsicht ein Snowboard gemäß der Erfindung;

Fig. 2 - 4

verschiedene Mögliche Ausführungsformen des erfindungsgemäßen Snowboards in perspektivischer Teildarstellung und im Schnitt, und zwar im mittieren Bereich des Snowboards und zwischen den beiden

Fig 5

Snowboard in Schnitt, nicht im Umfangsbereich der Erfindung.

Further developments of the invention are the subject of the dependent claims. The invention will be explained in more detail below with reference to the figures of exemplary embodiments. Show it:

Fig. 1

in simplified Darsetellung and in plan view of a snowboard according to the invention;

Fig. 2-4

Various possible embodiments of the snowboard according to the invention in a perspective partial representation and in section, in the mittierte area of the snowboard and between the two

Fig. 5

Snowboard in section, not in the scope of the invention.

In the figures, 1 is a snowboard, which has the usual shape in plan view, ie a Snowhoardkörper 2 with two waisted or a sidecut forming longitudinal sides 3. On top of the snowboard body are the two, in the FIG. 1 only schematically indicated bonds 4 and 5 are provided. As the Figures 2-4 Furthermore, the snowboard body 2 is manufactured using the usual materials, namely with a core 6, for example made of wood, with the core 6 on the circumference of the snowboard body 2 enclosing side walls made of plastic, eg ABS, with a the top of the core subsequent Upper belt 8 and a subsequent to the underside of the core lower belt 9 each made of a suitable material, such as fiber-reinforced plastic and / or metal (eg Titanal), with a top of the snowboard body 2 forming surface or decorative film and a lower , Bauflächenbauteil subsequent to the lower flange 9 consisting of the tread 11 and the necessary for the edge grip of the snowboard steel edges 12 which extend along each longitudinal side 3 and the side of the tread 11 formed by the tread of the snowboard with their webs 12.1 laterally. The steel edges 12 have the usual L-profile with the web 12.1 and the legs 12.2, which protrudes laterally with a large width over the web 12.1 and on which the respective side cheek 7 indirectly or directly supported, in each case over the entire width of Schenkel's 12.2. The steel edges 12 are further shaped or sharpened for the edge engagement so that they each have a preferably sharp edge region 12.3 on the web 12, ie an edge region 12.3, which is formed by the two, the leg 12.2 remote flat web surfaces, which enclose an angle of about 90 ° or slightly greater than 90 ° with each other.

The flat trained upper belt 8 rests with its edge on the top of the respective side cheek 7 and is there connected to the side wall 7. The likewise flat decorative sheet 10 covers the upper belt 8 also in the region of its edge connected to the upper side of the side wall 7.

Allen in the Figures 2-4 described embodiments is also common that the two steel edges 12 are provided on the two longitudinal sides 3 so or have such a course that they in a middle section 3.1 each longitudinal side, ie between the two bonds 4 and 5 there, where the distance the two longitudinal sides 3 is reduced by the sidecut in the direction perpendicular to the plane of the tread from the level N of this tread in the direction of the top of the snowboard body 2 formed by the film 10 by an amount x back, while outside of this range 3.1, ie in particular at the front and rear sections 3.2 of the longitudinal sides, the steel edges 12 and their edges 12.3 are at the level N of the underside of the snowboard body or the tread. This is without interference by the steel edges 12 a rail-driving or grinding, ie a lateral slide with the snowboard 1 on a terrain bridge or a terrain edge or the like. Possible.

In the in the FIG. 2 and 3 illustrated embodiment of 1a snowboards this reset the steel edges 12 and the edge portion 12.3 is achieved in that at the beginning of each section 3.1, the steel edges 12 and their edge portions 12.3 first from the level N in the direction of the snowboard body top, then over a length parallel or substantially parallel to the top of the snowboard and at the end of section 3.1 again back to the level N. The tread surface 11 is then chamfered in the area 3.1 at the edge at 11.1, in such a way that the tread surface also extends in the section 3.1 with the chamfer 11.1 to the leg 12.1 side facing the web 12.1 and the leg 12.2 to the bottom covering the snowboard body 2a.

Over the entire length of the snowboard body 2a in this embodiment, the lower flange 9 is arranged with its edges between the steel edges 12 and the underside of the side wall 7 and connected to these elements in a suitable manner, for example by gluing etc. Furthermore, in this embodiment, the side cheeks 7 have a height that varies according to the course of the steel edges 12.

As a result of the described construction, the steel edges 12 or their edge regions 12.3 in sections 3.1 are opposite the lower one in the snowboard 1a Tread of the snowboard shifted upwards, so that a Grinding or rail driving, ie a transverse slide without obstruction by the steel edges 12 is possible.

The FIG. 4 shows as a further embodiment, a snowboard 1 b, in which the resetting of the steel edges 12 and the edge portions 12.3 in the sections 3.1 is achieved in that the tread surface protrudes in these sections on the underside of the snowboard body 8b facing side of the webs 12.1 and thus below the steel edges 12 at the level N of the tread in the respective section 3.1 forms another, rounded edge portion 11.2. This is offset from the adjacent edge region 12.3 in the direction of the width of the snowboard body 2b, ie in an axial direction perpendicular to the longitudinal extent of the snowboard 1b and parallel to the lower tread by an amount y to the center of the snowboard body 2b, where y is approximately equal to the width of the Bridge 12.1 in this axial direction is.

In this embodiment, the lower flange 9 is located with its edge regions on the edge regions of the tread 11. Outside the two sections 3.1, the lower flange 9 and the tread covering 11 are then received in the angular region of the steel edges 12 formed by the web 12.1 and the legs 12.2, i. Both the lower flange 9 and the tread covering 11 extend with their edges in each case up to the side of the web 12.1 facing the leg 12.2.

In sections 3.2, the steel edges 12 with their legs 12.2 lie directly on the edges of the lower flange 9. In sections 3.1, an additional material 13 is introduced between the leg 12.2 and the adjacent edge of the lower flange 9, so that the running surface covering 11 then protrudes downward in the described manner over the steel edges 12 and forms the additional rounded edge region 11.2. The core 6 is also adapted in its thickness, so that the tread surface 11 also forms a flat or substantially flat running surface between the sections 3.1.

The FIG. 5 shows a snowboard 1c, the snowboard body 2c in sections 3.1 an additional steel edge 14 which in turn has the usual L-profile consisting of the web 14.1 and the leg 14.2, the edge portion 14.3 but is rounded.

Outside the sections 3.1, the snowboard body 2c is designed so that the lower flange 9 and the tread surface 11 extend with their edges to the leg 12.1 side facing the web 12.1 of the sharpened edge portion 12.3 having steel edges 12, the side cheeks 7 then immediately rest on top of the steel edges 12.

In sections 3.1 then only the lower flange 9 reaches with its edge regions up to the respective leg 12.2 facing side of the webs 12.1 of the steel edges 12, while at the edge regions of the tread 11 each additional steel edge 14 is provided, in such a way that the Rims of the tread covering 11 in these sections 3.1 to reach the side 14.1 facing the respective leg 14.2. In this embodiment too, the edge regions 12.3 in the sections 3.1 are again set back by the amount x in the direction perpendicular to the plane of the running surface with respect to the level N. At the same time, each rounded edge region 14.3 in the transverse direction of the snowboard 1c is offset relative to the adjacent edge region 12.3 towards the snowboard center by the amount y.

In this embodiment, the additional steel edges 14 are supported on the adjacent steel edge 12, so that y is smaller than the width of the web 12.1. In principle, however, it is also possible to arrange the additional steel edges 14 in such a way that they are not supported directly on the steel edges 12 but, for example, indirectly via edge regions of the bottom flange or via additionally introduced materials, etc.

It is understood that in the presentation of the FIGS. 2 to 5 existing, not occupied by materials described cavities are completely filled by a material used in the production of the respective snowboard, for example, synthetic resin or the like. In all described embodiments, the dimension x is approximately equal to or greater than the height of the steel edges in the axial direction perpendicular to the tread and the dimension y is approximately equal to the width of the web 12.1.

The invention has been described above by means of exemplary embodiments. It is understood that changes and modifications are possible without thereby departing from the inventive idea underlying the invention.

LIST OF REFERENCE NUMBERS

1, 1a, 1b, 1c

snowboard

2, 2a, 2b, 2c

snowboard body

3

Long side of the snowboard

3.1, 3.2

Section of the long side

4, 5

binding

6

core

7

side cheek

8th

upper chord

9

lower chord

10

Decorative foil

11

Running surface

11.1

sloping surface

11.2

edge region

12

steel edge

12.1

web

12.2

leg

12.3

sharpened edge area

13

additional material

14

additional steel edge

14.1

web

14.2

leg

14.3

rounded edge area

L

Snowboard longitudinal axis

Q

Snowboard cross axis

Claims (3)

1. Snowboard with a snowboard body (2, 2a, 2b, 2c) which has on the underneath a track face covering (11) with steel edges (12) which form an edge zone (12.3) for edge engagement and which are each disposed along a long side (3) of the sliding board body (2, 2a, 2b,2c), with two bindings (4, 5) on the top side (10) of the snowboard body (2, 2a, 2b, 2c) wherein the long sides (3) each form an inwardly lying longitudinal side section (3.1) which extends between the bindings (4, 5), as well as two externally lying longitudinal side sections (3.2) which extend between one binding (4, 5) and an adjoining edge of the snowboard body (2, 2a, 2b, 2c), characterised in that the course of the steel edge (12) and its edge zone (12.3) on at least one longitudinal side (3) of the sliding board body is developed such that this steel edge (12) and its edge zone (12.1) in the inwardly lying longitudinal side section (3.1) are set back by an amount (x) from the plane of the track face covering towards the top side (10) of the snowboard body (2, 2a, 2b, 2c) and are arranged on the externally lying longitudinal side areas (3.2) in the plane of the track face (N).
2. Snowboard according to claim 1 characterised in that the amount (x) by which the edge zone (12.3) of the steel edge (12) is set back on the at least one longitudinal side of the snowboard body (2, 2a, 2b, 2c) in the direction of the top side (10) of the snowboard body, is equal to or greater than half the height which the steel edge (12) or a web (12.1) of this steel edge has in an axial direction perpendicular to the track face (11).
3. Snowboard according to claim 1 or 2 characterised in that the track face covering (11) is inclined in the area of the inner longitudinal side section (3.1) at the transition (11.1) to the edge zone (12.3).

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