DE3712807A1 - Spring-board for a ski - Google Patents

Abstract

The spring-board shown in the main application, which is located in the middle region of a ski on the upper side thereof, is two-jointed and connected to a ski by angled articulation arms at the front and rear ends of the spring board in such a manner that the spring board, as a result of the rotation of the angled articulation arms about their axes of articulation, performs a vertical and horizontal movement relative to the ski surface, and all commercial ski bindings can be mounted on the spring board without additional measures. In the spring board described in Claim 2 of the main application, which is located in the middle region of the ski on the upper side thereof, the front end, with four angled articulation arms in rhomboidal form, is connected by four joints to an angled articulation plate arranged on the ski surface, the rear end of the spring board is connected by three joints, via two mutually connected angled articulation arms, to an angled articulation plate arranged on the ski surface, by three joints, a bar rigidly connecting the common joints of the angled articulation arms, which joints point towards the ski end, at the front and rear ends of the spring board and, in the event of a rotation of the two articulation arms about their axes of articulation, the spring board performing a vertical movement parallel to the ski surface. As a result, a safe equilibrium position of the skier is achieved. The resilient support of the spring board relative to the ski is achieved by pneumatic cushioning, which ... Original abstract incomplete.

Description

The invention relates to the main application on a springboard, which is in the middle of a Ski is located on the top and the front and H-shaped rear end of the spring board articulated arms over bearing elements with the ski top area is connected. The H-shaped hinge arms have the disadvantage that the spring board on the front End, or if there is a horizontal towards the ski end Movement describes at the back end, on both sides around the Length of the articulated arms and the width of the articulated legs is constricted. This results in the assembly of some commercially available ski bindings Difficulty because the holes for the attachment screw these ski bindings too large on the side Have distance and therefore additional measures for assembly is required. A disadvantage of this Embodiment is also that the H-shaped Articulated arms including the bearing elements heavy and are expensive to manufacture.  

Another disadvantage is with the main registration seen in the independent claim 2 that the front end of Springboards swivel with swivel raised point and the rear end stretched over an H-shaped th and H-shaped cranked articulated arm above bearing elements, which are arranged on the ski surface with the ski are connected.

This training is considered disadvantageous that the spring board is not parallel to the compression Ski surface runs, but the spring travel of the spring boards in the front area is smaller than in the rear area, whereby the equilibrium and thus the security of the skier especially in mogul slopes is influenced.

Furthermore, the main application appears as a disadvantage seen that the resilient support of the spring board opposite the skis, by a cone, torsion bar or Leaf spring takes place. These have mechanical spring types the disadvantage that the damping properties for example when driving over hard, bumpy, icy or humped Slopes are not satisfactory.

The task is, therefore, the springboard, which is in the middle area of a ski is located on the top of it, according to the main filing, while maintaining the good Leadership characteristics and directional stability even with short drawn Swings and on inclines on steeper slopes, to improve that all commercially available skis bindings can be mounted on the springboard and weight and manufacturing cost savings aims to be.  

Furthermore, it is the task of the spring board Claim 2 of the main application, while maintaining the to improve good swing initiation in that a secure balance of the skier also in Mogul slopes are reached.

Another object is according to claim 3 of the Main registration while maintaining the good tax bar keit in that the springboard bumps and blows that especially for hard, bumpy, icy and humped Slopes occur, dampens.

To solve the above problem are the following Measures provided.

One solution is that the front and rear End of the spring board over a cranked joint arm two-articulated with those on the ski surface arranged joint plates is connected. Are the crooked articulated arms of the same length on both ends of the spring board, this is how it moves around its joint when it is turned axis the spring board parallel to the ski surface. are the cranked articulated arms on the two spring board ends unequal length, the springboard faces the ski surface inclination to the ski tip or to the ski end on. With this training, the skier is able to a certain reserve or reserve to his driving style to fit. With the cranked design of the articulated arms maximum spring deflection is achieved. For reasons of cost and weight savings the cranked articulated arms and articulated plates for example stamped out of thin material and for improvement characterized by their torsional stiffness and knocked over pages should be formed.  

The spring travel of the spring board is when rebounding bounded by a band with one end on the Ski surface and with his other on the springboard underside is attached. By changing the length the band or changing the attachment point of the same on the ski surface or the underside of the springboard in the longitudinal axis of the ski is the spring travel of the spring board changeable and can adapt to the driving speed of the Skier, the type and nature of the slopes be adjusted.

A solution for the swiveling spring board with high set pivot point is that the front End of the spring board with four cranked articulated arms diamond-shaped with one arranged on the ski surface cranked joint plate is four-jointed where with two cranked articulated arms with their one End together with the joint on the spring board or with the joint of the ge arranged on the ski surface cranked joint plate and with its other end with are articulated to one another in pairs. The rear The end of the spring board is articulated with each other via two connected cranked articulated arms, three-jointed with the cranked joint arranged on the ski surface plate connected. Through a rigid connection, for example wise two poles, between the towards the end of the ski pointing joint joints of the cranked joint arms at the front and rear end of the spring board, be moves when the cranked articulated arms rotate the spring board vertically and parallel around its hinge axes to the ski surface. Due to the same length of travel on front and rear ends of the spring board, one secure balance of the skier especially in Mogul slopes reached.  

A solution for the spring support boards opposite the skis is that between the underside of the springboard and the ski surface or several or more connected to each other volume and / or shape variable with air or gas Filled hollow bodies are arranged, the volume at Compression of the spring board is compressed. Through the pneumatic suspension are the damping properties when driving over hard, bumpy, icy and humped Slopes improved. The hollow body or bodies are with provide a valve with the help of which the air or Gas pressure in the hollow body or bodies is changeable. With this training, the spring force is on the weight of the skier, his skiing speed, the Slope type and slope quality adaptable. Farther weight savings are achieved that control the Make skiing easier.

Embodiments of the invention are in the following description with reference to drawings explained. It shows

Fig. 1 in a side view a spring board with a broken from skis and sectional view of the hollow body in the unloaded state,

Fig. 2, the spring board with broken ski of Fig. 1, without a sectional view of the hollow body in the spring-loaded state.

Fig. 3 in the plan view of the spring board with a broken ski of FIG. 2.

Fig. 4 shows a further embodiment of the spring board in the side view and sectional view of the hollow body in the unloaded state.

Fig. 5, the spring board of Fig. 4, without a sectional view of the hollow body in the compressed state.

Fig. 6 in the plan view of the spring board of Fig. 5.

In the drawing Fig. 1, 2 and 3, the front and rear ends of the spring board 2 , with crank arms 20, 21 of equal length, are connected in two joints to the joint plates 22, 23 arranged on the ski surface, the spring board 2 being one when it is deflected vertical and horizontal movement towards the tip of the ski. The cranked articulated arms 20, 21 can also be arranged so that the spring board 2 has a vertical movement towards the ski surface and a horizontal movement towards the end of the ski when deflected. For resilient support of the spring board 2 with respect to the ski 1 , a volume and shape-variable hollow body 24 filled with air is provided with a valve 25 arranged laterally on the spring board 2 . The volume and shape variable with air filled hollow body 24 is attached to the underside of the spring board with a Velcro fastener 26 , but it can also be integrated with the spring board 2 , with a recess provided on the underside of the spring board for receiving the air-filled hollow body 24 in the spring-loaded state of the Spring board 2 is used. The embodiment is not shown in the drawing. A band 27 which is attached with one end to the ski surface and with its other to the underside of the springboard limits the travel.

In the embodiment shown in FIGS . 4, 5 and 6, the front end of the spring board 12 is connected with four diamond-shaped cranked articulated arms 28 to a cranked articulated plate 29 fastened to the ski surface. In each case two cranked articulated arms 28 are articulated at their one end together with the articulation of the cranked articulated plate 29 attached to the ski surface and at their other ends in pairs. The rear end of the spring board 12 is connected via two articulated cranked articulated arms 30 , three articulated to a cranked articulated plate 31 fastened to the ski surface. Rods 32 connect the common joints of the cranked articulated arms 28, 30 pointing towards the end of the ski at the front and rear ends of the spring board 12 . The volume and shape variable air-filled hollow body 24 , with valve 25 provided laterally on the spring board 12 in a passage, is attached to the underside of the spring board with a releasable adhesive. The strap 27 is attached at one end to the ski surface and at the other end to the underside of the springboard.

Claims (3)

1. Spring board, which is located in the central region of a ski on its top, the front and rear ends of the spring board by articulated arms which are connected to the skis in such a way that by rotating the articulated arms about their articulated axes the spring board makes a vertical and horizontal movement describes the ski surface and the spring board is resiliently supported against the ski at least at one point between the articulated connections of the front and rear ends, characterized in that the spring board ( 2 ) has a cranked articulated arm ( 20, 21 ) is connected in two articulations to the articulated plates ( 22, 23 ) arranged on the ski surface. 2. spring board, which is located in the central region of a ski on its upper side and is supported at least at one point between the articulated connections of the front and rear ends of the spring board with respect to the ski, characterized in that the front end of the spring board ( 12 ) with four cranked articulated arms ( 28 ) diamond-shaped with a cranked joint plate ( 29 ) arranged on the ski surface, connected in four joints, the rear end of the spring board ( 12 ) via two jointed crank arms ( 30 ), three-jointed with one on the ski surface arranged cranked articulated plate ( 31 ) is connected and rods ( 32 ) which in the direction of the ski end pointing common joints of the cranked joint arms ( 28, 30 ) at the front and rear end of the spring board ( 12 ) rigidly connects, whereby when the two articulated arms ( 28, 30 ) rotate about their articulation axes, the spring board ( 12 ) makes a vertical parallel movement to the ski surface. 3. Spring board according to claim 1 or 2, characterized in that between the spring board underside and the ski surface one or more or more interconnected volume and / or shape-variable air or gas filled hollow bodies ( 24 ) with valve ( 25 ) are arranged .