DE9411810U1 - Snowboard - Google Patents

Description

USP Unique Sports Products 20.07.94

Marketing and Sales GmbH 13932

81377 Munich

Snowboard

The invention relates to a snowboard.

The base of snowboards today is generally made of polyethylene. Polyethylene has excellent sliding properties, and it is also inexpensive and easy to process.

The polyethylene surface is relatively soft, however. If the snowboarder rides over a sharp, hard obstacle, it penetrates the polyethylene surface. If the snowboarder rides diagonally, the obstacle digs outwards into the polyethylene surface, possibly up to the steel edge, which can then tear outwards. This problem is particularly serious with a snowboard compared to skiing because snowboards generally do not have a self-releasing binding that opens when an obstacle hits the steel edge with great force from the side, and snowboarding is more likely to be ridden sideways, especially since there is a trend in riding style towards more and more sideways movements.

The object of the invention is to provide a snowboard in which the risk of a steel edge tearing out is significantly reduced.

This is achieved according to the invention with the snowboard characterized in claim 1. Advantageous embodiments of the invention are set out in the subclaims.

·

According to the invention, a strip-shaped aluminum protective layer is provided on the running surface, preferably next to both steel edges. If a sharp, hard object has dug into the polyethylene or similar soft plastic covering, it will not hit the steel edge when traveling at an angle, but the aluminum strip arranged in front of the steel edge. Since aluminum is harder than polyethylene, the sharp, hard object cannot penetrate further towards the steel edge. This means that the aluminum strip and thus the steel edge slide over it.

According to the invention, "aluminum" is not only to be understood as pure aluminum, but also and above all as aluminum alloys. The aluminum alloy can be a hardenable or a non-hardenable, naturally hard aluminum alloy. An aluminum alloy commercially available under the name "Titanal" has proven to be particularly suitable.

It is surprising that, despite the two aluminum strips on the running surface of the snowboard according to the invention, which can each have a width of up to 4 cm, for example, and can extend from the front bend to the rear bend of the snowboard, i.e. over the entire contact surface of the snowboard, the snowboard according to the invention has just as good sliding properties as a snowboard without such aluminum strips, i.e. with a correspondingly wider polyethylene covering. This result is surprising because polyethylene has extremely good sliding properties and therefore even the change from polyethylene to another plastic, such as polytetrafluoroethylene, leads to a significant deterioration in the sliding properties, so that when part of the polyethylene running surface is replaced by a metal, such as

Aluminium, a greater impairment of the sliding properties is to be expected.

The plastic base of the snowboard according to the invention is normally made of polyethylene. An extruded polyethylene base is normally used; however, a sintered polyethylene base can also be used.

However, the covering can also be made of a plastic other than polyethylene, for example another polyolefin. The only thing that matters is that the plastic is soft, or at least softer than the aluminum strips.

Since the snowboard is exposed to the greatest stress in the binding area due to the weight of the snowboarder, i.e. sharp, hard objects dig particularly deeply there, the invention provides the aluminum strips at least in the binding area.

Preferably, however, the two aluminum strips on the steel edges extend from the front bend to the rear bend of the snowboard, i.e. beyond the contact surface of the snowboard at the front and back. To prevent delamination, the front and rear edges of the aluminum strips do not run transversely, i.e. perpendicular to the longitudinal axis of the snowboard, but the front edges preferably run diagonally from the outside to the back and the rear edges run diagonally from the outside to the front.

The aluminum strips are simply glued to the snowboard. To do this, the aluminum strips and the plastic base are backed with a laminate, which, after the snowboard has been pressed together and the laminate plastic has hardened, connects the aluminum strips and the plastic base to the core of the snowboard.

The laminate can be a fiber fabric or fleece that is impregnated with a curable plastic. Preferably, a fiberglass fabric or fleece impregnated with epoxy resin is used.

To ensure that a laminate of the same thickness can be used across the entire width of the snowboard and that the aluminum strips are flush with the steel edges and the plastic base, the aluminum strips have a thickness that corresponds to that of the plastic base.

While the aluminum strips are simply glued on, it is generally necessary to additionally anchor the steel edges. For this purpose, the steel edges are preferably provided with one or more projections that run along the side of the aluminum strip facing the core of the snowboard. The projections are preferably thin and flat so that they can extend between the laminate and the aluminum strip. For better anchoring, they are preferably angled, for example T-shaped.

The aluminum strips are preferably cut from an aluminum sheet of the appropriate thickness. Only the outside of the aluminum strips is adapted to the tapered shape of a snowboard by removing material. This means that the opposite inner edges of the aluminum strips on the running surface run parallel to each other.

An embodiment of the snowboard according to the invention is explained in more detail below with reference to the drawing. In it:

Fig. 1 a view of the running surface of a snowboard,-

Fig. 2 is a partial section through the snowboard along the line II-II in Fig. 1.

According to Fig. 1, a snowboard 1 is bent upwards at the front and rear ends 2, 3. This means that the contact surface of the snowboard 1 on a flat surface is limited to the front and rear by the lines 4, 5.

The running surface of the snowboard 1 consists of a plastic covering 6, preferably made of polyethylene. Aluminum strips 7 extend along the two side edges, from front to back beyond the lines 4, 5. The front narrow sides or edges 8 of the aluminum strips 7 run diagonally from the outside to the back and the rear narrow sides or edges 9 run diagonally from the outside to the front with an angle α or β of, for example, 100 to 160° relative to the inner edges 10.

The inner edges 10 of the two aluminum strips 7 run parallel to each other. At their outer edges, the aluminum strips 7 are tapered in accordance with the snowboard 1, i.e. they have a smaller width at the center of the snowboard indicated by the line 11 than at the ends. The width of the aluminum strips in the area 11 can be, for example, 0.5 to 4, preferably about 1 to 3 cm.

According to Fig. 2, the snowboard 1 consists of a core 12 with a rectangular cross-section, for example made of wood or plastic foam. A top laminate 13 is arranged on the core 12 and a surface layer 14, for example made of ABS, is arranged on top of this.

The long sides of the core 12 are provided with a plastic layer 15 tapering towards the top, for example made of ABS or similar impact-resistant, rubber-elastic material

coated. The lateral support 15 is flush with the underside and the top of the core 12.

The underside of the core 12, including the supports 15 on both sides of the snowboard 1, is covered with a lower laminate 16 which, like the upper laminate 13, can be a fiber composite material made of glass fiber reinforcement fibers in an epoxy resin matrix. The steel edge 17 is arranged under the support 15, to which the strip-shaped aluminum layer 7 is connected. Anchoring tongues 18 extend from the steel edge 17 between the aluminum strips 7 and the lower laminate 16. The aluminum strip 7 has the same thickness as the polyethylene covering 6. When the snowboard is pressed and the plastic of the lower laminate 16 subsequently hardens, the polyethylene covering 6, the aluminum strips 7 and the steel edges 16 are glued to the core 12 or the side supports 15.

Claims (9)

U.S.P. Unique Sports Products 20.07.94 Marketing and Sales GmbH 13932 81377 Munich Snowboard Protection Claims 1. Snowboard with a running surface made of plastic, characterized in that an aluminum strip (7) is provided on the running surface between the steel edge (17) and the plastic running surface (6). 2. Snowboard according to claim 1, characterized in that the aluminum strip (7) is arranged at least in the area of the binding of the snowboard (I). 3. Snowboard according to claim 1 or 2, characterized in that the aluminum strip (7) extends into the front and/or rear bend (2, 3) of the snowboard (I). 4. Snowboard according to one of the preceding claims, characterized in that the front and/or rear edge (8, 9) of the aluminum strip (7) runs obliquely from the outside to the rear or to the front. 5. Snowboard according to one of the preceding claims, characterized in that an aluminum strip (7) is provided on both steel edges (17) of the snowboard (1). 6. Snowboard according to claim 5, characterized in that the opposite inner edges (10) of the two Aluminium strips (7) of the snowboard (1) run parallel to each other. 7. Snowboard according to one of the preceding claims, characterized in that the aluminum strip (7) is glued to the core (12) of the snowboard (I). 8. Snowboard according to claim 7, characterized in that the bonding of the aluminum strip (7) is carried out by the laminate (16) with which the plastic covering (6) is bonded to the core (12). 9. Snowboard according to one of the preceding claims, characterized in that the steel edge (17) is provided with a projection (18) which is arranged on the side of the aluminum strip (7) facing the core (12).