DE2264627A1 - LINK EDGE FOR A SKI IN WHICH THE SPRING CONSTANT ALONG THE LINK EDGE CAN BE CHANGED - Google Patents

Description

"Link edge for a ski in which the spring constant is variable along the link edge"

Priority: January 29, 1971, V.St.A., no.Ho 9o9

The invention relates to a ski with interrupted "Steel edges" (metal edges or other comparable edges), their splitting or interruption, the flexibility of the edge compared to a continuous or uninterrupted edge of the same shape and made of the same material.

Modern skis are made from a large number of different components composed. A single ski can, for example, be components made of materials such as fiberglass, light metal alloys,

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Steel edges, wood and / or plastic core and the like. These different materials have different ones physical properties in their entirety and together determine the running characteristics of the ski with the shape of the ski.

Among the numerous physical characteristics that affect runnability is the modulus of elasticity or the Ε module of the various materials is most important. The modulus of elasticity of the components of a This is because the ski, together with the thickness of the ski, not only determines the stiffness of the ski in curves, but also in large measure Extent the vibration absorption capacity respectively. the damping. The higher the modulus of elasticity of the components of a ski is, the lower the damping of the ski. A wooden ski without metal or glass fiber reinforcement parts with a Body made of hickory or ash with a modulus of elasticity of approx. 1350 kp / mm has the best damping effect. A Light metal ski with glued-on, single-piece Steel edge in which the light metal alloy has a modulus of elasticity of 7000 kp / mm and the steel edge has a modulus of elasticity of approx. 22000 kp / mm is extremely susceptible to vibrations and poorly damped. Experience has shown that the period of oscillation in the After receiving a shock, the light metal ski is about 8 times as long as the oscillation period of the wooden ski same thrust ",

In order to improve the damping of modern skis made of several materials, attempts have already been made to use the the components of the ski, which have the high modulus of elasticity, transferred to the other parts of the ski To limit the effect of vibrations. Since the steel edge has the highest modulus of elasticity and the weakest damping property, all efforts have been made on this Focused component of the ski.

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A method of controlling the vibrations transmitted from the steel edges to the rest of the ski consisted in an attempt to isolate the steel edges by adding layers of rubber or other elastic layers between the steel edges and the other components of the ski. The rubber layers therefore serve to reduce the transfer of the longitudinal expansion of the ski body to the steel edge strips. Through this procedure the influence of vibrations of the steel edges is reduced, but not so for certain running conditions desired dimensions

There is a second, known, more satisfactory measure for reducing the influence of vibrations on the steel edge in dividing the steel edge strips into sections or split, which are connected to each other and thereby form a uniform edge, which is divided into sections is divided. By splitting the steel edge into sections, the lines of tension are broken, and it is a greater longitudinal expansion at the connection points of the sections without the usual high stress of a continuous strip stripping occurs. on split in this way into ν x-bound sections Steel edges are commonly referred to as "split edges". Various methods are known to divide the steel edge strips into small, interconnected sections by cutting and slitting. As a result, the interrupted edge shows the characteristics of a tension spring when there is a tensile load acting in the longitudinal direction. Consequently, the stress-strain ratio of an interrupted edge can be determined by the spring characteristic: c = -γ-f where P is the force acting on the edge and f is the length of the edge.

Experience has shown that the duration of the decay

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the oscillation "in skis with split steel edges is proportional to the spring stiffness of the split edge. The higher the spring stiffness of the split edge, the more longer is the decay time of the oscillation of the skis after they have been subjected to an impact. The hardness of the spring the interrupted edge is determined by the length of the individual sections of the edge and by the stiffness or the bending resistance of the connections between the individual sections of the edge. The longer the individual Sections are, the greater the spring stiffness of the steel edge and the greater the oscillation needs to be before it subsides «, The same effect can be achieved by looking at the stiffness or bending resistance of the connections increased, i.e. the greater the bending resistance of the connections, the greater the spring stiffness and the longer it takes time for the vibration of the steel edge to subside.

With the known split or interrupted edges it has become possible to reduce the spring stiffness <3 «γ steel edge compared to a continuous steel edge; but the known interrupted edges have a constant spring rate, albeit a lower one, over the entire length of the edge. As a result, a ski with well-known split edges is evenly dampened over its entire length. Modern skiing techniques, especially ski races by professional skiers and internationally known amateurs with highly specialized skiing techniques on specially prepared slopes have shown that a ski does not give its utmost capabilities when it overruns evenly along its entire length. ^; ^ .pft is.

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The main task of the invention is to create a ski that risher mentioned type to create interrupted metal edges with having different spring stiffness along its length.

It is a special object of the invention to provide a ski with different damping properties along its length create an extremely short oscillation decay time at the Gchaufelenrie des Skis and at the rear of the ski a measured higher one Has shing cooldown.

To solve this problem, the invention provides an interrupted edge and a ski with an interrupted edge, the is attenuated to varying degrees at different points along its length. The decay time for vibrations of each Areas along the length of the ski according to the invention are therefore different. This is achieved by the spring stiffness the interrupted edge is chosen differently at different points along the length of the ski. This change in hardness is achieved in that individual sections of different lengths are formed along the length of the edge with the aid of connecting elements are created that have a different bending Euidcrstand along the length of the edge. The preferred spring stiffness on skis according to the invention runs in a curve whose lowest value in the shovel area of the ski and the all-

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It rises gradually until it reaches its maximum value in the area of the bond and reached behind it. It should be noted, however, that in For the purposes of the general task, other changes to the Spring stiffness in the scope of the invention are possible, depending on for which particular type of skiing the ski is intended for. üienn animal So ski is designed according to the preferred spring rate curve, the shovel or tip area is heavily damped and has a short decay time for vibrations, while the rear end of the Skis have less damping and a longer decay time for the oscillation, which is particularly important for gliding on skis is desirable. The preferred ski according to the invention is consequently superior for a good skier or racer Quality because of its strong cushioning and, as a result, extreme calm and trace security at the front end of the ski and Simultaneously measured or controlled oscillation in the rear area of the ski, resulting in a good gliding effect and lightness There are no possibilities.

The invention and advantageous details of the invention are explained in more detail below with reference to schematic drawings of several exemplary embodiments.

Fig. 1 is a top plan view of a preferred embodiment an interrupted edge according to the invention;

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Fig. 2 is a perspective view of a broken one Hants of the type shown in Fig.l; '.

Fig. 3 is a vertical section through a ski and shows the type of attachment of the interrupted edges according to FIGS. 1 and 2 on a ski according to the invention;

Fig. U is a side view of a ski according to the invention showing the preferred ranges of different damping along the length of the S! <5η;

Fig. 5 i st a graphical representation of the spring hardness of a broken steel edge according ner invention, which varies along the length of the ski, and z & irjt also a comparison with both. an interrupted ice bul ... · ..., a continuous flat edge according to the prior art;

Fig. 6 is a plan view of another embodiment an interrupted handle according to the invention;

Fig. 7 is a plan view of a third embodiment of an interrupted hand according to the invention.

In Figs. 1 and 2, a preferred embodiment leg game is one interrupted or split handle according to the invention shown. The hand is of a longitudinal

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elongated, generally L-shaped, a total of 2 be ~ drawn limb formed. The edge member 2 has a depending portion 4 which is the actual running edge of the edge member 2 forms, as well as a lateral web area 6, which formed the connecting part of the edge member 2. The connecting part 6 of the edge has a plurality uniform connecting elements 8, which are generally square or rectangular and in each of which has an opening 10. Multiple interruptions, Gaps or cuts 12 extend laterally and completely through the barrel portion 4 of the edge member 2. These incisions 12 open into the openings 10 in the connecting elements 8.

The distance between adjacent incisions 12 is along the length of the edge member 2 different. In FIGS. 1 and 2, for example, the incisions 12 are in the left-hand area of the edge member 2 arranged close to one another and open into openings 10 adjacent to one another. The left section of the running part 4 of the edge member 2 is thus of the incisions in a large number of small sections or segments H of divided into equal length. In the middle of the in Pig. 1 and 2 of the edge member shown are the incisions 12 further apart, so that the barrel part 4 is divided into segments 16 which have the same length and twice as long as segments 14 ", at the right end in Pig. 1 and 2, the incisions 12 are arranged even further apart, so that segments 18 are formed which are even longer than segments 16 and three times as long like the segments 14 The area of the edge link containing the segments 14 has a lower peder hardness, a stronger damping property and consequently a shorter one Period of oscillation, since the segments H are shorter than the area of the edge member which contains the segments 16.

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The peder hardness of the area comprising the segments 16 is in turn lower than that of the area containing the segments 18 Area. In this way, the peder hardness of the edges and thus the damping characteristics of the ski can be practical can be varied indefinitely along the length of the edge and the ski. With a square or rectangular design of the Connecting elements 8 has shown that it is possible to arrange the incisions 12 only about 9 mm apart without that the strength of the edge member would be affected. The edge member 2 is preferably made of steel, but can be made from another metal of acceptable strength within the scope of the invention be. The edge member 2 is preferably designed to be L-shaped in cross section, but within the scope of the invention other cross-sectional shapes can also be used.

Pig. 3 is a somewhat schematic representation of one Cross-section through a ski and shows how the edge links 2 are attached to the ski. The ski includes a core 20, made of foam, wood, fiberglass, a layered metal structure or other known materials or combinations can be made of materials. The sides 22 of the ski can be made of a phenolic resin layer or the like be educated. Upper side edges 24 made of aluminum, steel or another metal can be provided in such a way that that they extend over most of the length of the ski. These upper edges 24 can be glued to the ski body or otherwise attached. A fiberglass layer 26 can extend over the top of the core 20 between the opposing surfaces of the upper edges 24 extend, and a top layer 28 of phenolic resin or another decorative surface may be applied over the fiberglass layer 26 and the top edges 24 so that it forms the top of the ski «> The broken edges 2 are on the lower lateral areas of the core 20

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attached by gluing, screwing or similar, and underneath the underside of the core 20 For example, a fiberglass layer 30 may be provided that extends between the opposing surfaces of the web or connecting part 6 of the interrupted edges extends. A tread 32 made of P-Tex or the like Plastic extends across the underside of the ski between the opposing side surfaces of the sectioned running part 4 of the interrupted edges. The running part divided into sections 4 of the split edges thus form part of the side surface of the ski and also part of the running surface of the ski i

Fig. 4 is a side view of one in longitudinal zones or areas with different damping properties divided ski $ what by changing the spring stiffness of the split Edges is achieved which have the same overall shape as shown in FIGS. Zone A in the The shovel area of the ski can be approx. 180 mm long and in 20 Segments be divided, each of which is 9 mm long. The zone B adjoining the blade area can approx. 180 mm long and divided into 10 segments, each 18 m long be. Zone C can be 189 mm long and divided into 7 segments, each of which is 27 mm long. Zone D can be 180 mm long and divided into 5 segments, each 36 mm long. Zone E can be 180 mm long and be divided into 4 segments, each 45 mm long. Zone F extends the remainder of the length of the ski and is preferably a continuous segment ", the boot or binding area of the ski is preferably 34, i.e. «, im foremost part of zone F.

Fig. 5 is a graphical representation of the values of the spring hardness of the edge along the bar of one according to the invention

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Skis produced in the k in Fig. Ueise shown. The side view of the ski is shown above the curve in FIG. 5, sd that the spring stiffness for the Kantoj in any part of the ski can be seen from the curve. The abscissa of the curve shows the length of the skiing surface in centimeters, while the ordinate E indicates the spring rate of the interrupted edge in kilopond per millimeter. The dashed line 3G represents the spring stiffness of a continuous steel edge over the entire length of the running surface of the ski, while the dash-dotted line 38 shows the spring stiffness είπετ known split steel edge over the length of the running surface of the ski. It should be noted that, on the other hand, the stiffness of the spring is the same for both continuous and known broken edges over the entire length of the ski. The solid line 4o represents the average spring stiffness of a variably burned edge according to the invention. From the curve it can be seen that. '', in spring stiffnessB is very low in the shovel area of the ski and that it increases gradually over the length of the ski until the binding area of the ski is reached; at this point the stiffness of the spring becomes constant, since the edge is continuous from here sn. It is therefore obvious that the shovel area of the ski is strongly damped and that the damping pressure decreases towards the rear in the longitudinal direction of the ski.

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6 shows another embodiment of an interrupted edge according to the invention. The edge is formed VDn an elongated, generally L-shaped member, which is designated as a whole with Io2. The hand member Io2 comprises a running part Id ^ and a transverse web part 1q6, which comprises a series of essentially square or rectangular connecting elements designated as a whole by loO. The barrel part Io4 is subdivided into a series of segments Hd of uniform length by incisions 112 lying at a distance from one another. Each incision 112 extends completely through the barrel part Io2 and opens into an opening HU which is provided in each connecting element Io8. The connecting elements Io8 thus form a resilient connection between adjacent segments Ho of the running part Ιοί *. It should be noted

that openings 114 in Pig. 6, viewed from left to right, are grouped in pairs of the same size, the size of a pair of openings 114 being smaller than the size of the pair preceding to the left. The connecting elements 108 are therefore provided in pairs which, viewed from left to right in FIG. 6, become increasingly stronger. It is obvious that the greater the strength of the connecting elements 108, their bending resistance becomes greater, so that the connecting elements 108 in Pig. 6, seen on the left, can be bent more easily than the connecting elements that lie further to the right in the longitudinal direction. In this way, the left area of the interrupted edge as seen in Pig, 6 has a lower peder hardness than the intermediate area, which in turn has a lower peder hardness than the right area. By increasing the thickening or reinforcement of the connecting elements 108, an interrupted edge with a Peder hardness that differs along the length of the edge can be achieved. 409827/0183

Pig. 7 shows a modification of the embodiment shown in FIG. 1, in which the connecting elements 8 ^{1 have} a curved profile instead of being square or rectangular. By using a connecting element 8 ^f with a curved profile, the stress on the connecting element is evenly distributed over the entire connecting element. It should also be pointed out that the incisions 12 or 12 'can run either inclined or at right angles with respect to the axis of the edge, preference being given to the incisions inclined with respect to the axis of the edge.

From the above description it is readily apparent that the invention is the production of skis with outstanding Vibration damping properties allowed the longitudinal the length of the skis are different and exactly the damping requirements of the respective area of the skis correspond over their length. The varying spring hardness the steel edge of the SkiE *, which causes the different damping of the ski, can be achieved by that the length of the individual segments is chosen differently along the length of the interrupted edge that the Bending resistance of the individual connecting elements that unite adjacent segments, designed differently or that a combination of these two possibilities is chosen. This allows a very precise and achieve a gradual change in the spring stiffness of the interrupted edge over the length of the edge. So can Skis are manufactured whose properties in tracking, maneuverability and gliding ability of every single known ski are far superior.

Although only lower edges produced according to the invention have been described here, it is obvious that that top edges can also be made according to the invention,

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Claims (7)

Claims (1.J link edge for a ski, where the links are connected by connecting brackets are interconnected and in which the spring rate is variable along the link edge, thereby characterized in that the bending resistance of the connecting bracket (108) is variable along the link edge. 2. link edge according to claim 1, characterized in that the Bending resistance of the connecting bracket (I08) in a first end area the link edge is smaller than in a second end region of the link edge. 3. link edge according to claim 1 or 2, characterized in that the bending resistance of the connecting bracket (IO8) from the first End area of the link edge gradually increases up to the middle area. 4. link edge according to claim J, characterized in that that the bending resistance of the connecting bracket (108) from the central area is constant up to the second end region of the link edge. 5. link edge according to claim h, characterized in that the link edge between the central region and the second end region is a continuous edge. 6. link edge according to one of claims 1 to J5i, characterized in that that the train-spring constant of the link edge of the 409827/0183 first end region gradually increases to the second end region. 7. link edge according to one of claims 1 to 6, characterized in that that they have several longitudinally adjoining sections (A, B, C, D, E) each with several has links (14, 16, 18) of equal length, the individual sections with connecting brackets (108) of different bending resistance are provided. 409827/0183