FI13461Y1 - Snowboard - Google Patents

Abstract

A snowboard that includes a frame (1), which is made as a laminate structure, comprising a base laminate (7) with a glass fiber layer attached to it, a core (4) made of hardwood and a surface plate (3) attached to the surface of the core (4), characterized by the fact that the snowboard includes a stiffening part (2), which is placed on the top surface of the snowboard in the middle of the board and that the bottom laminate (7) of the board includes a heat-resistant edge piece (9) on both sides of the snowboard.

Description

SNOWBOARD

FIELD OF THE INVENTION

The object of the invention is a snowboard, which is intended especially for kite snowboarding in winter conditions on various surfaces, such as in open terrain covered with snow — and on the ice of waterways, in hard or soft snow and especially on smooth ice.

BACKGROUND OF THE INVENTION

Kite snowboarding uses flexible, symmetrical snowboards designed for skiing that can be driven in the direction of both ends. These are narrower in the middle, with the radius of curvature of the edge usually 7000-9000 mm. When skiing straight, you stand on the bottom of the entire snowboard. When cornering, the snowboard is tilted against the edge of the inside curve at its sharpest point, into the cutting curve according to the curvature and flexibility of the edge. In the other direction, we bend against the opposite edge. That is, when turning in skiing, both edges of the snowboard are used. It is equally possible to descend in the direction of both ends of the snowboard. In skiing and kitesurfing, you stand — on the snowboard, fastened crosswise with ties, in a crotch position of 500-650 mm.

In kiteboarding, even long distances are driven directly. When pulling the kite, always sideways to the front, the snowboard is driven on the edge of the heel side, steering the snowboard lightly to maintain balance. In contrast to downhill skiing, kitesurfing curves in both directions on the same edge. The edge of a snowboard works like a sailboat — a keel resisting sideslip. After turning back and forth, ride on the same edge in the direction of the other end of the snowboard. Snowboards intended for kitesurfing have also been developed, the radius of the edges of which has mostly been increased, so they work better on a snowy surface. Flexible snowboards for kiteboarding, suitable only for soft closed projects, have also been developed. For the ice surface alone, an attachment in the shape of a skate blade, made of steel, has been developed, which is attached to the edge of the snowboard.

The installation takes place with the help of screws in the holes drilled through the snowboard.

There are various problems associated with known snowboard structures and usability.

A snowboard intended for skiing tends to turn in the direction of the curvature of the edge when kitesurfing, especially on a harder snow surface. On smooth ice, the grip ends completely, because — only the ends of the snowboard on the slope touch the ice.

The shape of the large-radius edges developed for kiteboarding works on snow.

Even the steel edge of these snowboards does not bite into smooth ice effectively, due to the vague contact area of the steel edge of the flexible snowboard with the ice.

An attachment similar to a skate blade attached to the edge of the snowboard provides good grip, glide and maneuverability on the ice. Only the steel insert is in contact with the ice surface.

However, this structure is not suitable for use on a snowy surface.

PURPOSE OF THE INVENTION

The purpose of the invention is to create a very versatile snowboard especially intended for kitesurfing. With the help of the structural solutions according to the invention, you can get a functional snowboard for kitesurfing, whose maneuverability, slippage and edge grip are as good as possible on all surfaces covered with snow and ice.

SUMMARY OF THE INVENTION

The snowboard according to the invention is characterized by what is presented in the —characteristics part of the protection requirements.

The idea of the invention to build the middle part of the snowboard as stiff as possible in the part between the binding points, combined with the shape of the edge, is new and inventive. In addition, the heat-resistant edge parts of the snowboard base plate next to the steel edges are an improvement to prevent damage to the base plate.

The basic idea of the invention is to build a snowboard in the middle, in the part between the binding points, as unchanged as possible. A stiffener is placed above the snowboard between the binding points and below, which can be integrally laminated to the snowboard, or as more precisely in the application shown here = a separate stiffener made of carbon fiber. —When the edge of the snowboard is straight when viewed from above, or slightly curved outwards in the middle, the directional stability is neutral. The gentle curvature of the bottom in the middle enables the snowboard to turn easily in both directions on all platforms. The flexible and gentle tip parts and the sole, which is wide over the entire length of the snowboard, carry well in soft snow. The stiffening part of the snowboard, combined with the shape of the bottom and edges, forms a skate blade-shaped area on the edge of the snowboard in the area between the binding points, so that the sharp steel edge bites into smooth ice very well, maintaining maneuverability. In soft, thick snow, the snowboard can also be used without the stiffening part. The snowboard according to the structure of the invention works well for closed-loop skiing with the stiffener part or with the stiffener part removed.

On hard ice, friction causes heat generation in the steel edge, so the edge parts of the bottom plate and — the steel edge in the area between the bond points are made of heat-resistant materials.

PICTURE LIST

In the following, the invention is explained in detail with reference to the accompanying drawings:

Figure 1 shows the structure of the snowboard according to the invention, viewed from the side.

Figure 2 shows the structure of the snowboard according to the invention, viewed from above.

Figure 3 shows the structure of the snowboard according to the invention, viewed from below.

Figure 4 shows a cross-sectional view of the structure of the snowboard according to the invention, with the body and stiffener part combined.

DETAILED DESCRIPTION OF THE INVENTION

Figures 1-4 show a snowboard according to the invention, which includes a flexible body 1, and a stiffening part 2 that can be connected between the binding places 8 and under the bindings with binding screws. The ends of the stiffening part have flat areas 8 prepared on the upper surface for attaching the bindings. The stiffener part 2 attached to the snowboard is made as a fixed part of the snowboard or as a separate structure.

The sectional view in Figure 4 shows a snowboard according to the invention, where the structure of the frame 1 comprises a surface plate 3, a fiberglass-reinforced hardwood core 4, a steel edge 5 that goes around the frame — equipped with fastening ribs and an ABS plastic edge strip 6, as well as a base plate 7 and a heat-resistant base plate edge piece 9 attached to the edge of the base plate.

The sides of the frame 1 are chamfered above the steel edge 5 at the edge strip 6.

Figure 1 shows the shape of the frame 1 of the snowboard according to the invention as seen from the side, the frame 1 and the stiffener part 2 combined. The length of the frame 1 is preferably 1630 mm. The thickness of the body 1 — is about 9 mm in the area of the central part, becoming thinner after the connection points 8, being about 5 mm at the ends of the body 1. The bottom of the frame 1 is straight in the transverse direction, and curved upwards from the middle towards the ends between points B1-B2, the radius RI being 18000-24000 mm.

From points B1-B2 to the ends of frame 1, the curvature R2 is 400-500 mm, the length of the area being 250 mm.

Figure 2 shows the shape of the body 1 from above. The width of the body 1 in the middle is 300 mm, narrowing between the points C1-C2 according to the radius of curvature R3 76000 mm. The rounding of the corners of the ends of frame 1 R4 is 90 mm. The rounding of the ends from the center according to R5 is 300 mm. At the binding points 8 of the frame 1 of the snowboard, several counters for the binding screws can be installed, embedded inside the frame 1 for fixing and adjusting the bindings. Alternatively, a rail is installed for rail-mounted ties, or both, — in which case you can use several models of ties.

Figure 3 shows the frame 1 from below, showing the bottom laminate 7 covering the bottom of the frame 1, which functions as a sliding surface, and the steel edge 5 that goes around the frame.

The edge pieces 9 of the base plate 7 are made of heat-resistant polytetrafluoroethylene (IUPAC abbreviation PTFE) polymer, the other side of which is sintered to improve adhesiveness. the width of the edge pieces 9 is 20 mm and the length is 900 mm. The edge pieces 9 are attached to the steel edge 5, and a heat-resistant two-component epoxy glue is used for gluing to the fixing ribs.

Figures 1, 2 and 4 show the shape and structure of the stiffening part 2 of the snowboard according to the invention. The width of the stiffener part 2 is the same as the upper surface of the frame 1. Tie points 8 thin — the area remains under the ties at the adjustment points, so the length of stiffener part 2 becomes 850 mm.

The corners of the stiffener part 2 are rounded according to the radius R6, which is 100 mm. When the distance between the ties is at its smallest, an area of 350 mm remains between the tie points for the thickness 16 of the stiffener part 2. The bottom of the stiffener part 2 is straight in the transverse direction, and curves upwards from the middle towards the ends with a radius R7, which is 12000 mm. — Figure 4 shows Stiffener part 2, which is made as a composite structure, where the lowest layer is —glass fiber gauze 10 to improve wear resistance. — Next, two layers of € carbon fiber fabric 11 are placed on top of the glass fiber gauze.

A 5 mm thick PVC foam sheet 12 has been placed on top of the carbon fiber fabrics in the stiffener area for a distance of 850 mm. The PVC foam sheet 12 is shaped on all sides 8 mm smaller than — stiffener part 2. The edges of the PVC foam sheet 12 are beveled from the top to a 45 degree angle. A layer of carbon fiber fabric 13 is placed on top of the PVC sheet 12. A stiffener 14 shaped from a 20-30 mm thick PVC foam board is attached to the stiffener area at the tie points 8. The sides of the stiffener 14 are beveled at an angle of 20 degrees and the top corner is rounded according to the radius R8. The width of the PVC foam board 14 is the same as the width and length of the upper surface of the PVC foam board 12. In the center of the stiffener piece 14, there is a longitudinally shaped stiffener profile 16, curved from the upper surface, about 360 mm long. Two layers of carbon fiber fabric 15 are attached to the upper surface of the composite structure. All fiber layers are placed over the entire area of the stiffener part 2. All layers of stiffener part 2 are laminated 5 — into a uniform structure with epoxy resin. 6 mm holes are made in the area of tie points 8 for all the corresponding tie adjustment points of frame 1 or, in the rail-mounted model, grooves at the rails.

The invention is not limited only to the above example. However, it is clear - that different structural solutions are possible for the production of a snowboard according to the invention, while staying within the framework of the inventive idea defined by the protection requirements. For example, the bracing part can be built using different materials. Snowboard frame 1 and stiffener part 2 can also be built as a solid unit. — It is possible to manufacture the stiffener part as a cellular structure, which — enables a light and rigid structure through material choices.

Claims (5)

PROTECTION REQUIREMENTS 1. Snowboard, which includes a frame (1), which is made as a laminate structure, comprising a base laminate (7) with a glass fiber layer attached to it, a core (4) made of hardwood and a surface plate (3) attached to the surface of the core (4), characterized by the fact that the snowboard includes a stiffening part (2 ), which is placed on the top surface of the snowboard in the middle of the board, and that the bottom laminate (7) of the board includes a heat-resistant edge piece (9) on both sides of the snowboard. 2. A snowboard according to protection claim 1, characterized by the fact that the stiffener part (2) attached to the snowboard is made as an integral part of the snowboard or as a separate structure and is attached to the upper surface of the snowboard by mechanical fastening, preferably with screws, which are also the binding screws and that the stiffener part (2) is used to make the snowboard between B:-B2 curved upwards from the bottom surface according to the radius R1, whose value of the radius RI is preferably 18000-24000 mm and the tip and the base of the snowboard are bent upwards according to the radius R2 = 400-500 mm. 3. A snowboard according to protection requirements 1 and 2, characterized by the fact that the stiffening part (2) of the snowboard is made into a composite structure, which includes the lowest layer of fiberglass gauze (10), on the surface of which two carbon fiber fabrics (11) are attached, 5-10 mm is attached on top of the carbon fiber fabrics (11) thick PVC foam board (12), a carbon fiber fabric (13) is fixed on top of the stiffening board (12), and that the stiffening still includes a stiffening piece (14) made of foamed PVC plastic, the upper surface of which is approximately 20-30 mm high and 340-380 mm long stiffener profile (16) curved in the upper surface in the longitudinal direction of the snowboard, two layers of carbon fiber fabric (15) are attached to the surface of the stiffener part, the composite layers of the stiffener part (2) are attached to each other using epoxy resin, the stiffener part (2) is made 600 — 900 mm long and the stiffener part (2) the ends have flat areas (8) made on the upper surface for attaching ties. 4. A snowboard according to one of the protection requirements 1-3, characterized by the fact that the sides of the snowboard are curved outwards between C1-C> according to the radius R3 and that the value of the radius R3 is 76000 mm. 5. A snowboard according to one of the protection requirements 1-4, characterized in that the heat-resistant edge strips (9) belonging to the bottom laminate (7) of the snowboard are polytetrafluoroethylene (PTFE abbreviation IUPAC) polymer, one side of which is sintered to improve adhesiveness, and that the edge strips 9 are attached with heat with durable glue.