This application claims priority under 35 U.S.C. §119 of French Patent Application No. 09 03107, filed on Jun. 26, 2009, the disclosure of which is hereby incorporated by reference thereto in its entirety.
1. Field of the Invention
The present invention relates to a damping arrangement for a gliding board, in particular for an alpine ski, as well as for gliding boards of other types, such as snowboards and Nordic skis, the latter including, e.g., cross-country skis. In the following description, unless specifically described otherwise, reference made to a ski is for the purpose of convenience and not for the purpose of limiting the scope of the invention from gliding boards as mentioned above. The invention relates more particularly to an improvement to a damping arrangement of the aforementioned type, as well as to a ski, or other gliding board, equipped with such a device or arrangement. The method is also directed to a method of manufacturing such a gliding board.
2. Description of Background and Other Information
It is known to make the body of a ski to have a more or less flexible structure.
Various types of skis are known, and there are numerous variations among them of skis. Such skis are comprised of an elongated beam, the front end of which is curved upward to constitute the shovel, the rear end also being curved upward more slightly to constitute the tail.
Currently available skis generally have a composite structure in which various materials are combined, so that each of them cooperates with the others in an optimal manner, particularly in terms of the distribution of mechanical stresses during use of the ski. Thus, the structure generally includes peripheral protective elements, internal reinforcement elements to resist flexion and torsion forces, as well as a core. These elements are assembled by gluing or by injection molding, the assembly being carried out generally under heat in a mold having the final shape of the ski, with a front portion sharply raised into a shovel, a rear portion slightly raised into a tail, and a cambered central portion.
In spite of their desire to make high quality skis, manufacturers have not, to date, produced a highly efficient ski that performs satisfactorily under all conditions of use.
Currently available skis have a number of disadvantages, particularly that of poor performance when oscillations are produced by vibrations or flexing of the ski. Indeed, persistent vibrations cause a loss of adherence of the ski to the snow or terrain and, therefore, result in poor steering of the ski, i.e., a lessened control of the ski. Therefore, it is very important to damp the vibrations; and some solutions have been proposed, such as those disclosed in patent documents DE 297 09 403, EP 0 521 272, EP 0 733 386, and U.S. Pat. No. 5,332,252, for example. However, the effects of these damping devices are in fact quite minor and imperceptible to the skier.
Document DE 297 09 403 discloses a gliding board with a damping arrangement comprised of a channel in which a friction piston slides freely. The friction piston can be comprised of parallelepipedic or cylindrical rods. In both cases, the friction piston has a certain thickness which is greater than a third of the total thickness of the ski. This substantial thickness of the friction elements in relation to the total thickness of the ski causes a substantial alteration in the characteristics of the ski, in particular the flexion and torsion characteristics. In addition, the excessive thickness of the damping arrangement in relation to the total thickness of the ski is such that the damping arrangement is close to the neutral plane of the ski. When the beam of the ski is subject to upward flexion, the upper portion of the beam is subject to compressive stresses, whereas the lower portion of the beam is subject to tensile stresses. The neutral plane of the beam corresponds to an imaginary surface comprised of all points of the beam which are subject neither to tension nor to compression. The damping arrangement of a gliding board is more efficient as it is farther from the neutral plane thereof. In the case of the ski disclosed in DE 297 09 403, this characteristic is far from extant.
The documents EP 0 521 272 and U.S. Pat. No. 5,332,252 disclose a ski having a damping arrangement comprised of a flexion blade connected to the ski via a friction device. Such a system has numerous disadvantages, in particular those relating to the damping arrangement being separate from the structure of the ski. The mounting of the damping arrangement on the ski is carried out mainly after the primary manufacturing stage of the ski, i.e., after the molding of the ski, such as by injection. In addition, the mounting on the outer surface of the ski considerably hinders the decoration thereof and especially limits possibilities for the design and external appearance of the ski.
The document EP 0 733 386 discloses a ski having a damping arrangement comprised of a plurality of blades positioned one on top of another. The damping arrangement is distinct from the remainder of the ski and is comprised of a closed box in which the blades and the friction layers form a stack, the box being inserted between the upper reinforcement and the top of the ski, i.e., the top of the ski being comprised of the protective and decorative layer. Here again is a damping arrangement which considerably modifies the mechanical characteristics of the ski, inasmuch as the damping device is heavy and thick.
The documents EP 0 966 992 and U.S. Pat. No. 6,237,932 disclose a ski, the sides of which are provided with damping elements for damping only the specific unwanted vibrations that propagate between the running edges and the top of the ski. These damping elements are made of flexible or viscoelastic material and function by means of compression.
The present invention overcomes the various disadvantages mentioned above and proposes a particularly simple, efficient, and reliable solution to the problems related to damping vibrations.
The invention is directed to a gliding board equipped with a frictional damping arrangement, which is simple and inexpensive insofar as it can be integrated directly into the gliding board, during the injection phase during manufacture thereof.
To this end, the damping arrangement according to the invention is adapted to damp the vibrations of a gliding board having a length L, the gliding board comprising a primary core positioned between a lower sub-assembly and an upper sub-assembly, the upper sub-assembly and the lower sub-assembly comprising at least one first upper reinforcement and at least one first lower reinforcement, respectively, extending longitudinally over at least two thirds of the length of the gliding board. The included frictional damping arrangement includes a blade having a thickness of 2 millimeters (mm) or less than 2 mm, and a structure arranged to enable at least one of the ends of the blade to slide. The damping arrangement is positioned between the first lower reinforcement and the first upper reinforcement, and the distance separating the damping arrangement from the first upper reinforcement or from the first lower reinforcement, ranges from 0 mm and four times the thickness of the blade.
According to one or several other characteristics of the gliding board, taken alone or in combination:
The damping arrangement according to the invention is particularly efficient because it acts on a substantial portion of the length of the gliding board, and because it is positioned as far as possible from the neutral plane of the gliding board, whether it is positioned above or below the neutral plane. However, the weight added by the damping arrangement is minimal compared to the damping which it performs, and it can be substantially imperceptible, it only very slightly modifying the mechanical characteristics of the gliding board. Moreover, because it is positioned under the first upper reinforcement, or on the first lower reinforcement, the damping arrangement is completely integrated into the structure of the ski, and it has no effect on the external shape of the gliding board, i.e., whether the sliding board is a ski or a snowboard, for example.
Other characteristics and advantages of the invention will become apparent from the description which follows, with reference to the annexed drawings which are provided only by way of non-limiting examples, and in which:
The gliding board 1 shown in
The lower sub-assembly 5 includes a lowermost layer comprising the gliding sole 7, a layer comprising a first lower reinforcement 8, a layer comprising a second lower reinforcement 23, and two running edges 6 positioned on each side of the gliding sole 7. The upper sub-assembly 9 includes a protective layer 10, also referred to as the top of the ski, a layer comprising a first upper reinforcement 11 and a layer comprising a second upper reinforcement 12. A secondary core 15 is positioned between the first upper reinforcement 11 and the second upper reinforcement 12.
According to the invention, a frictional damping arrangement 16, or damping device or damping structure, is positioned inside the structure of the gliding board, in the vicinity of and below the first upper reinforcement 11. In other words, in the illustrated embodiment, e.g., the damping arrangement is positioned in the ski between the neutral plane and the first upper reinforcement 11. In the first embodiment of the invention, the damping arrangement 16 is positioned between the first upper reinforcement 11 and the second upper reinforcement 12. The frictional damping arrangement includes a blade 17 surrounded by a sleeve 18 and placed in contact with the first upper reinforcement 11.
The damping arrangement 16, over its entire length Lma, is completely embedded inside the structure of the ski. The complete integration of the damping arrangement within the structure of the ski renders it completely impervious to infiltration of any material (such as water, dust, etc.) which could be harmful to the operation or performance of the damping arrangement and, consequently, to that of the ski. The damping arrangement could be entirely hidden from the ski user's view, but it is possible to provide a transparent or translucent cover or other such structure in the area of the core 13 and/or in the area of the upper sub-assembly 9, and/or in the area of the lower sub-assembly 5, in order to provide one or more viewing windows. Such viewing windows enable all or certain portion(s) of the damping arrangement to be visible to the user.
Another means to render the damping arrangement visible comprises arranging it so that only a portion thereof is embedded inside the structure of the ski. In such a case, it is nevertheless necessary that a majority of the length Lma of the damping arrangement be embedded within the structure of the ski, and that a sealing arrangement be provided to prevent dust and water, and other unwanted material or debris, from penetrating inside the structure of the ski.
According to the invention, the portion of the blade that is fixed with respect to the ski, i.e., the anchoring zone 19, is positioned within a 600 mm longitudinal segment of the ski centered on the boot center MC. In an alternative embodiment, the longitudinal segment has a length of 200 mm, centered on the boot center.
According to an alternative to the first embodiment of the invention, the anchoring zone 19 is replaced with a mechanical anchoring carried out by means of a rivet, a screw, or a pin extending through the blade. In such an alternative, the blade 17 is entirely surrounded by a sleeve 18, which does not comprise any interruption in the central portion. However, the sleeve and the blade are bored in the area of the anchoring zone, and the boring cooperates with a mechanical anchoring mechanism fixing the blade to the remainder of the ski in the central zone of the ski.
According to the invention, the damping arrangement extends over a substantial length of the front portion and/or rear portion of the ski. In the first embodiment, the damping arrangement extends to the front and to the rear. If the rear tip of the ski is considered the starting point for the length measurements, the front end of the blade is in on the side of the front contact point Pca at the front of the ski, in a lengthwise range Ba equal to 20% of the length of the front contact Lca. The rear end of the blade is beyond the tail contact point Pct, in a lengthwise range Bt equal to 20% of the tail contact length Lct.
Under these conditions, the zone in which the energy generated by the vibrations of the ski is frictionally damped is concentrated at the front 27 of the ski, close to the front contact point Pca, without extending into the shovel. In particular, this is one of the reasons why a gliding board according to the invention achieves a good compromise between a good damping of vibrations and a behavior of the ski that is reactive, i.e., relatively stiff, or “nervous.” In other words, although the vibrations are damped, the gliding board of the invention does not have an amorphous behavior, i.e., it does not have a behavior that is ill-defined, nor characterized as suffering from a lack of response during use.
In the illustrated example of the first embodiment, the length of the ski is approximately 1700 mm, the boot center MC is positioned at 727 mm from the rear tip of the ski. The shovel has a length of 170 mm and the front contact point Pca is located at a distance of 1530 mm from the rear tip of the ski. Thus, the front contact length Lca is equal to 803 mm (1700-727-170), and the front end of the blade is positioned in the zone defined by the following dimensions: 1409 mm and 1530 mm.
With regard to the rear portion, the tail length Lt is equal to 70 mm; thus, the tail contact length Lct is 757 mm. The rear end of the blade is in the zone defined by the following dimensions: 70 mm to 168.5 mm.
Rather than a single blade extending along the entire length of the ski, the ski can have two blades, including one at the front and the other at the rear, each one surrounded by a sleeve and having their portions in the central zone of the ski extending outside of the sleeve, in order to be anchored against the first upper reinforcement.
In the first embodiment of the invention, the damping arrangement includes a single metallic blade made of a material such as steel or aluminum, the thickness of which ranges between 0.4 mm and 0.7 mm. In a particular example, the blade can be 0.5 mm thick and approximately 12 mm wide.
The sleeve 18 is comprised of a sheath made of braided polyester fiber coated on its outer surface with polyurethane resin. A sheath made of silicone-coated paper can also be used. The damping arrangement can be made with a blade that is coated over most of its length with a material preventing bonding and adhesion with the resin of the upper reinforcement. Like the sleeve, this material would have the function of preventing any portions of the blade, with the exception of the anchoring zone 19, from being affixed to the remainder of the ski.
The dimensions of the blade, i.e., the length and the width, are precisely defined by the desired friction properties. To this end, a test can be conducted to evaluate the sliding force necessary for a blade in a sheath, the sheath and the blade being placed beforehand in a testing device.
Once the stacking is completed, it is placed in a stratification press; the curing cycle is undertaken at a temperature and for a time that are determined as a function of the preimpregnated material selected; then, the testing device is allowed to stabilize for at least 24 hours. At the end of this period, four traction forces are applied, back and forth, to the blade in order to break in the system.
The testing phase itself is carried out on a traction machine, the testing device being fixed thereto. The blade is caused to slide so as to leave only 200 mm of it inside the testing device. Traction is then applied on the blade by measuring the force necessary to make it slide over 30 mm. The reading of the mean value provides an evaluation of the friction of the blade in the sheath.
To obtain a satisfactory damping under normal conditions of use of a gliding board, such as an alpine ski, the blade is sized so that the mean value of the force necessary to slide ranges between 20 N and 80 N. In a particular embodiment, the force range is between 40 N and 60 N.
The sliding test makes it possible to choose the dimensions of the blade or blades, so as to obtain an optimal damping of the gliding board under the conditions of use. For a blade with a thickness ranging between 0.4 mm and 1 mm, a blade with a width ranging between 6 mm and 30 mm is selected. In the case in which several blades are positioned side-by-side, the thickness of the blade is reduced accordingly so that the sum of their width ranges between 6 mm and 30 mm.
The blade 17 is fixed via its central portion to the first upper reinforcement 11 while the ski is being stratified. Indeed, the first upper reinforcement 11 is made of resin-preimpregnated fiber glass fabric. During stratification, the upper surface of the blade that is not covered by the sleeve is glued to the first upper reinforcement 11 due to the resin. If the upper reinforcement is a metallic reinforcement, for example made of aluminum, a film of adhesive can be provided to ensure the adhesion of the blade to the upper reinforcement. In the case in which, as described below, the damping arrangement is not in direct in contact with the upper reinforcement, but only near it, means for anchoring the blade to the core can be provided.
In the first embodiment of the invention, the damping arrangement is above the neutral plane. Consequently, during upward flexing of the front and rear tips of the ski, the ends of the blade tend to come close to, or move toward, the tips of the ski. In order for this to occur, expansion spaces are provided to receive the ends of the blade.
In
Each of the caps 22 is comprised of a parallelepiped having a slightly larger cross section than the cross section of the sleeve 18. The cap is split to facilitate the penetration of the blade 17. In an alternative embodiment of the invention, the caps are made of a transparent or translucent material; and a window is provided in the first upper reinforcement in order to render the ends of the blade visible from the outside of the ski. It is then possible to show the movement of the ends of the blade during flexing of the ski. During normal use, the ends of the blade have a travel ranging between 1 mm and 3 mm. The ends of the blade are cut along an oblique line in relation to the longitudinal axis in order to make their movement more visible.
The damping arrangement constitutes an addition of weight of less than 100 g for a ski 1700 mm long, which represents a very small weight considering its efficiency, in particular because it acts on a major proportion of the length of the ski.
As in the preceding embodiment, the damping arrangement is positioned between the first upper reinforcement 11 and the second upper reinforcement 12. Conversely, unlike the preceding embodiment, the two upper reinforcements are positioned on one another, leaving therebetween only a space that is sufficient for positioning the damping arrangement 16. This damping arrangement is comprised of a blade 17 affixed to the upper reinforcements in the central zone of the ski and is capable of sliding in a sleeve 18.
The sleeve 18 is obtained by the wrapping of the blade in a silicone-coated paper. This is a sheet of paper coated with silicone in a proportion of 80 g/m2. The sleeve covers the blade over a major portion of its length, leaving exposed only the central portion thereof. The central portion of the blade is affixed between the second upper reinforcement 12, which is an aluminum plate, e.g., and the first upper reinforcement 11, which is comprised of a resin-impregnated fiber fabric cloth.
Right and left blades can be chosen that are strictly identical, or they can be chosen to have different characteristics. The latter possibility provides for the ability to manufacture nonsymmetrical pairs of skis, i.e., where the left ski is different from the right ski.
The damping arrangement is anchored to the ski during the hardening of the core due to the material of the core which confines it. In particular, the blade, in the area of its central portion, is anchored to the core due to the material which has penetrated in the bore arranged therein.
Examples of methods of manufacturing gliding boards, or skis, such as by means of injection molding are disclosed in U.S. Pat. No. 5,183,618 and in U.S. Pat. No. 5,449,425, the disclosures of which are hereby incorporated by reference thereto in their entireties.
The core 13 is made of wood. A channel capable of receiving the damping arrangement 16 is made in the lower portion of the core. The damping arrangement 16 is placed in contact with the first lower reinforcement 8. As in the first embodiment, the damping arrangement includes a blade 17 extending over a major portion of the length of the ski and a sleeve 18 comprising a front sheath and a rear sheath. The two sheaths are disjoined so as to leave, in the center, an exposed blade portion that is fixed to the structure of the ski by gluing during polymerization of the resin of the first lower reinforcement 8.
In the fifth embodiment, the damping arrangement is above the first lower reinforcement and below the neutral plane, and in particular as far from the neutral plane as possible, in order to guarantee its maximum efficiency.
The invention is not limited to the several embodiments described here by way of examples, and it includes any equivalent embodiment.
Also, this invention illustratively disclosed herein, suitably may be practiced in the absence of any element which is not specifically disclosed herein.
Number | Date | Country | Kind |
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09 03107 | Jun 2009 | FR | national |