NL1029832C2 - Hand-driven snowboard. - Google Patents

Abstract

The invention relates to a transport board, such as a snowboard or a skateboard, comprising a substantially flat plate, which is adapted to carry a person standing with his/her feet on the plate, and at least a first handle which is connected to the plate and on the distal end of which a handgrip is arranged, wherein the handle is connected to the plate for rotation about a rotation axis extending transversely of the longitudinal axis of the plate substantially parallel to the plate, wherein the first handle is rotatable to both sides from the vertical position. As a result of this measure a greater measure of freedom is obtained, so that particularly an experienced user can derive more enjoyment.

Description

HANDGESTÜÜD SNOWBOARD

The invention relates to a device for controlling a sliding board, for example a snowboard. More specifically, the invention relates to the control of sliding board or snowboard with the use of hands. Such a device is known from US patent 2005087942 and Japanese 2001310008. It is characteristic of these devices that, unlike in conventional devices such as the French patent FR2626189, no use is made of a connection between the shoe on the one hand and the snowboard on the other hand. . As described, a handlebar is installed on the top of the snowboard with handles that can support the driver and enable steering of the snowboard. The feet are not connected to the snowboard 15 and can be placed next to the snowboard in case of loss of balance. Of course the feet are resting on the snowboard, but they are not connected to the sliding board for transferring forces outside the weight of the user and the frictional forces caused thereby.

The disadvantage of these devices is that the loads are distributed and transferred entirely differently on the snowboard than in the conventional shoe binding. While sliding down a slope, it is hardly possible, if at all, to place the snowboard on its side over its entire length, thereby applying sufficient pressure to both the front and the rear of the snowboard. Furthermore, due to the lack of foot bindings, the driver is unable to exert a torque on the snowboard with which the snowboard can be bent. As a result, the control of the snowboard does not function optimally.

The object of this invention is to enable manual control of a snowboard or similar sliding board, whereby the feet can be placed loosely on the board, without the maneuverability being lost or the load on the board substantially changing compared to a conventional shoe binding. . This discovery offers a solution especially for novice snowboarders, because the user can easily get off the snowboard in case of loss of balance. This makes learning to snowboard more fun, safer and less tiring.

1029832-2

According to the invention this object is achieved by a sliding board, comprising control means engaging on the sliding board at the location of the feet, the control means comprising at least one lever operable at the location of the feet connected to the sliding board by the user's hand.

These levers have the function of transferring forces to a snowboard or sliding board, which in the case of an 'ordinary' snowboard are transferred with your feet.

The invention will be explained in more detail below with reference to an exemplary embodiment of the construction shown in the figure.

FIG. 1 and shows a cross-section of an embodiment in which the levers are considered as separate structures and in which these levers are connected to a conventional snowboard. In this embodiment, the lever 1,2 is attached to the snowboard 3 in an instant-proof manner. The connection 4 between the lever and the snowboard preferably takes place by using the screw holes (4A) which are normally already present in the snowboard for placing the shoe bindings, or this can be achieved by gluing a bottom surface of the lever to the snowboard. In addition, use can be made of a construction that grips around the side of the snowboard. In this embodiment, the lever is attached to the snowboard by means of the formed locking. The point (5) where the forces exerted by the user on the lever are transferred to the snowboard are located at or close to where the shoe bindings are attached to the snowboard in a conventional snowboard.

The driver can independently actuate the levers with the hands so that a moment of force can be exerted on the snowboard. To this end, the user takes one lever in each hand, this is possible at the location of a handle (6, 7). By energizing the each lever in the same direction, perpendicular to the longitudinal axis of the snowboard, the snowboard is tilted partly or completely. The hollow curved shape of the snowboard creates the possibility of sliding the snowboard in a desired direction.

The user can also actuate the two levers in an opposite direction perpendicular to the longitudinal axis of the snowboard.

1029832-3

This creates a torsional force along the longitudinal axis of the snowboard. The distortion of the snowboard that follows from this also occurs when using a traditional snowboard. The invention therefore makes it possible, in addition to tilting the snowboard, to effect the twisting of the snowboard.

The user can also actuate the two levers by moving the two levers towards each other. This creates a bending moment on the snowboard that makes the snowboard bend. The distortion of the snowboard that follows from this also occurs when driving a conventional snowboard. The invention therefore makes it possible to effect a bending of the snowboard in addition to tilting the snowboard and twisting the snowboard. By these ways of deforming the snowboard or a combination of these forms of deformations, a good similarity arises between the use of the invention and the use of the conventional snowboard. Subsequently, the levers provide support for the user's upper body and the levers contribute to maintaining the user's balance.

The device furthermore offers space for both shoes of the user. The placement of the shoe is at or close to the location where in a conventional snowboard the shoe bindings are attached to the snowboard. This location can be pre-determined in the design, but could also be determined by the user during use. The contact surface between shoe and device 25 can be the base plate with which the device is attached to the snowboard, but also, for example, the upper surface of the snowboard. Studs can be provided on this contact surface, by screws or glues, to ensure sufficient friction. It is also possible to mount a rubber mat with protrusions below the base surface which protrude through recesses in the base plate. Another possibility is that the base plate consists of raised points that are set, for example, or injection molded. The device can also be provided with a raised edge around the shoe or a provision at the front of the user's shoe to prevent slipping.

Different embodiments of levers are conceivable, the features of these embodiments are described below.

iiQ29832-35 Λ 4

The levers can be attached to the snowboard as two separate elements, but can also be physically connected to each other in a somewhat flexible manner in a special embodiment.

The two levers can be entirely identical, but can also have a shape in which the first lever has the mirrored shape of the second lever. In addition, the two levers can have a completely different shape.

In addition, an embodiment is possible in which each lever can be rotated separately about an axis perpendicular to the plane of the snowboard (17). This rotation allows the user to adjust the position of the lever to an ergonomic position that is optimal for the user. The axis for the rotation is located in the center or close to the center of the place for the foot. The rotation can for instance take place by using slotted holes in the attachment with the snowboard (16), the angle rotation being limited here. Another possibility is by means of a loose ring that clamps the base plate against the snowboard. This makes the maximum angular rotation 360 degrees.

The levers can both be of equal length, but can also differ in length. However, an embodiment is also conceivable in which the length of the lever is adjustable so that each user can assume an ergonomic position. For this purpose, the levers are designed, for example, as one or more elements which slide in and out of each other and which can be fixed in a desired length. This fixation can be based on a form lock or clamping, which can arise after, for example, turning a handle or by using a locking spring.

The levers may be releasable. This disconnection can concern a segment of the lever, but also the total lever. The connection between the releasable part and the rest of the device can be created by means of a pinhole connection or, for example, by clamping, a form lock between the two parts is also conceivable.

The power supplied by the driver could be transferred with somewhat flexible levers. The levers 35 can be flexible in its entirety or only partially. The flexibility may also be adjustable, so that the control and response of the snowboard to the power supplied can be adjusted during use.

f029032-5

In addition, an embodiment is possible in which the levers can pivot and can therefore be collapsed in order to reduce the dimensions of the sliding board during transport or to adjust the position of the handles to the ergonomics of the user. This can be done by means of a pivot point 8 which is located between the connection to the snowboard and the handle, around which the lever or a part of the lever can rotate. The lever can be fixed in various positions around this pivot point with a simple operation, for example by clamping on the pivot axis 9 or with a form lock between the rotating parts.

In addition, a special embodiment of the levers is possible, wherein the lever consists of the tubes or shafts 10 and 11 which are attached to each other in the longitudinal axis of the lever by means of a hinge 12. These tubes or shafts can be made of aluminum, steel or plastic. A bend (13) is arranged at the bottom of the pipe or shaft, after which the pipe or shaft continues to run for a few decimeters. The lever is detachable from the sliding board. In the situation that the lever is not attached to the sliding board, the tubes can be turned towards each other, after which they form a compact and flat whole. If the tubes are twisted apart, a construction is created that is suitable as a moment for fixed mounting of the lever on the sliding board. As soon as the two tubes are fixed in the screw holes of the sliding board by means of two or more bolts (14), the hinged tubes are fixed relative to each other, and the lever moment is fixedly attached to the sliding board.

In addition, a provision may be provided near the surface where the feet are located, which prevents the feet of the user from coming loose from the top of the sliding board or the surface arranged in front of the feet. One can think of a construction that falls over the nose or instep of the shoe (15). The size of this construction has a fixed size and geometry, or this construction can be adjusted to the dimensions of the user's shoe. The construction can be made of a hard material, but is preferably also provided with a material with a considerably lower hardness in order to limit the forces on the foot, with which the comfort during use is increased. This facility can easily be taken out of use or put into use by the user. This can take place by means of removal or unilateral loosening or very wide adjustment of the provision of the foot.

5 I029832-

Claims (4)

4 1. Sliding board / comprising control means engaging the sliding board at the location of the feet, characterized in that the control means comprise at least one lever operable at the place of the feet connected to the sliding board by the user's hand. 2. Sliding board according to claim 1, characterized in that the control means comprise two levers which are each connected to the sliding board at the location of one of the feet. Sliding board according to claim 1 or 2, characterized in that the at least one lever is connected to the sliding board by a releasable connection. 4. Sliding board as claimed in claim 3, characterized in that the releasable connection is arranged for engaging means for shoe binding on the side of the sliding board. 1 0 2 9 8