FR2785822A1 - Vibration absorber intended to be mounted on e.g. snowboard, comprises at least three components of which two are magnetic and the other is of metal - Google Patents

Abstract

The vibration absorber comprises at least three components (25,26,28) of which two (25,26) are magnetic and the other is of metal. These components can move relative to each other so that their relative movement produces induced currents generating energy dissipation. The first component is fixed to one of the surfaces (7) of the sports article and the second moves in a direction perpendicular to this surface. The second component is integral with a lever (10) itself fixed to the sports article.

Description

VIBRATION DAMPING DEVICE FOR BEING
MOUNTING ON A SPORTS ARTICLE, AND SLIDING BOARD.
GOLF CLUB, TENNIS RACQUET OR ROLLER SKATES EQUIPPED WITH SUCH A DEVICE
Technical area
The invention relates to the field of sports articles, and more specifically to devices intended to dampen the vibrations which are generated on the surface of such sport articles, in particular during contact with the external environment, shocks or impacts.

Previous techniques
As is known, during the practice of a sport requiring the striking of a ball by an object such as a racket or a golf club, the impact of the ball generates vibrations which propagate from the point of impact down to all areas of the sports article.

 These vibrations generate two main types of problems, namely on the one hand, a loss of precision due to the oscillation of the racket or the golf club, and on the other hand, the transmission of vibrations in the arm of the user, which disturb the sensations and can even cause pain.

 The same problem is encountered when skiing, or a sliding sport, when the board oscillates. The vibrations generated by these oscillations cause inaccuracies in the handling of the ski. In addition, by transmitting to the skier's feet, these vibrations generate additional fatigue.

The Applicant has already described, in particular in the document FR 2 740 349 corresponding to the document US 5 674 135, a vibration damping device transforming the mechanical energy producing the longitudinal deformations of a board, into heat by the use of magnetic materials
More specifically, the solution described in these documents has a particular structure constituted by the stacking of several plates, some of which are magnetized, to ensure on the one hand, a mechanical plating generating friction, and on the other hand, the formation of currents induced in the metal plates during the relative movement of sliding of the plates with respect to each other.

 These plates are divided into two sets attached to the sports article at two separate points. Thus, when the vibrations are generated on the surface of the sports article, the spacing of the two attachment points of the plates varies. It follows that the plates which are integral with them move relative to each other, in a movement parallel to the surface of the article on which they are fixed.

 It is easily demonstrated that the power dissipated by such a device is proportional to the square of the intensity of the magnetic field present inside the device, to the square of the frequency of the oscillations, but also to the square of the amplitude of the displacements of the different plates relative to each other. However, although giving satisfactory results, given the small amplitude of movement of the plates relative to each other, the power dissipated during the operation of the device described in the aforementioned document is relatively reduced. It follows that the damping effect is not always sufficient for optimal operation of the sports article.

 The problem which the invention therefore proposes to solve is that of optimizing the power dissipated with a device operating by creating induced currents, while remaining compatible with the geometry and the ergonomics of the various sporting articles.

 The invention therefore aims to define a damping device which can be incorporated into a large number of sports articles, and whose geometry allows the transformation of a large part of the kinetic energy of vibrations into electrical energy dissipated by the Joule effect. .

Statement of the invention
The invention therefore relates to a vibration damping device intended to be mounted on a sports article, comprising at least two elements, at least one of which is magnetic (that is to say carrying magnets or magnetized parts), said elements being movable relative to each other so that the relative displacement of the elements produces induced currents generating energy dissipation.

 This device is characterized in that the first of the two elements is intended to be mounted integral with one of the faces of the sports article, and in that the second of the two elements is able to move relative to the article of sport in a direction substantially perpendicular to said face of the sports article on which said device is mounted.

 In other words, the invention consists in using the deformations generated on the surface of the sporting article to generate the displacement of an armature or of an inductor perpendicular to the surface of the article to obtain an amplitude of much greater displacement than in known devices, and therefore greatly increase the power dissipable by such a damping device.

 Thus, in sliding sports, or more generally sports in which the article is in contact with the plane on which it moves, such as snow gliding board, skateboard, roller skate, bicycle, moped, hull boat ...., the movement of the movable part is substantially perpendicular to the displacement plane.

 The invention can be used for sports articles of the ball striking type such as tennis racket or golf club; in this case the damping device is located in a zone of maximum deformation.

 It has been found that the displacement of the various elements generating induced currents was thirty times greater with the technique according to the invention than with the geometry which is the subject of document FR 2 740 349.

 In practice, in a first embodiment, the second element able to move is secured to a lever itself connected to the sports article in an area undergoing large deformations while the first element is secured to the sports item but in an area with little distortion. In this way, the displacement of the second element relative to the first is the result of the modification of the respective position of each of the attachment points. Thus, by choosing the length of this lever and the optimal position of its attachment point, a maximum displacement of the magnetic elements relative to one another is allowed.

 In a particular embodiment, the second element may be secured to two levers, themselves secured to the sports article at separate points.

 In this way, it is advantageously possible to provoke the operation of the damping device for vibrations present in multiple zones of the sports article.

 In addition, by making the movable part integral with a greater number of fixed points, this limits the degrees of freedom of movement of the second element to better control its relative movement relative to the first inducing or induced element. In other words, when the sports article stops vibrating, the inductor and the armature are stationary with respect to each other.

 In a particular embodiment, the levers are connected to the second element by an articulated connection, in order to limit the mechanical stresses at the level of these connections.

 In another embodiment, the second element is free and mounted floating relative to the first element. In this case, the second element is free to move relative to the first element when the sports article on which the first element is placed deforms under the effect of vibrations.

 In all of these embodiments, one of the elements can be made of a magnetic material or an assembly of parts containing magnetized parts while the second element has at least one generally metallic electrically conductive part, to be the seat. of currents induced by the displacement of the magnetic element.

 In a particular embodiment, the first element consists of two plates perpendicular to the face on which the damping device is mounted, the second element being a magnetic plate capable of moving between the two plates of the first element.

 In a more improved form, the two plates of the first element are associated with a piece of soft iron connecting them, capable of channeling the magnetic flux between the two plates.

 The invention finds multiple applications for equipping various sports articles such as in particular snow gliding boards (skiing, surfing ...). In this case, it may be advantageous in a particular form to locate the device so that the first element is located at a zone of maximum deformation of the board, that is to say for example in a vibration belly, while the lever at the end of which the second movable element is located is secured to the board at the level of a zone of minimal deformation, that is to say for example near a knot vibration.

 These embodiments of the invention can be used to equip other sports articles undergoing longitudinal deformations and vibrations maintained by the irregularities of the ground on which these articles move. Thus, the invention can be placed on a skateboard, a roller skate, a bicycle or a moped or even a boat hull.

 According to another embodiment geometry, the first element, integral with the sports article, follows a hollow cylindrical shape inside which is able to move the second element.

 In the case where the second element is free to move inside the first fixed element, the device can be equipped with stops to limit the displacement of the second element.

 In an alternative embodiment, when the movable element constitutes the inductor, it can be made up of several unitary magnets connected by metal plates.

 In an alternative embodiment, the first element comprises at each end a magnet in repulsion with the second element, to ensure a magnetic suspension of the counterweight.

 Advantageously, these magnets in repulsion with the second element are associated with a conductive part.

 This embodiment of the invention can equip golf clubs or tennis rackets.

 The means of the invention can then be placed either on the back of the striking face for golf clubs, or inside the core formed for attaching the handle to the sieve of a tennis racket so that the axis of the damping device is coincident with the starting axis of the ball.

 The manner of carrying out the invention as well as the advantages which result from it will emerge clearly from the description of the embodiments which follow, illustrating by way of example but not limitation the application of the invention to the field of alpine skiing, the transposition of the field skiing in other areas such as tennis, golf and roller skating are obvious to a person skilled in the art.

Brief description of the figures
These embodiments are described in support of the appended figures in which:
Figure 1 is a summary perspective view of a first embodiment of the invention.

 FIG. 2 is a summary perspective view of a variant of the solution illustrated in FIG. 1.

 FIG. 3 is a summary profile view of a ski equipped with a device produced on a second embodiment of the invention.

 Figure 4 is a summary profile view of a third embodiment of the invention.

 Figure 5 is a summary perspective view of an alternative embodiment of the above principle.

 Figure 6 is a longitudinal sectional view of a ski produced according to a fourth embodiment.

 FIG. 7 is a summary perspective view of the damping device shown in FIG. 6.

 Figure 8 is a sectional view of a damping device produced according to an alternative embodiment.

Way of realizing the invention
As already said, the invention relates to a vibration damping device intended to be mounted on a sports article.

 In the following description, the invention will be illustrated in its application to the field of alpine skiing, but the transposition to other sporting articles would be done without difficulty for a person skilled in the art.

 According to the principle of the invention, the damping device comprises two elements, one of which is able to move relative to the other, perpendicular to the plane of the ski.

 In other words, one of the elements is movable relative to the other in a direction perpendicular to the plane of the ski. The displacement of one of the two elements of the damping device can be generated either by the connection of this mobile element to one or more points distant from the ski, or even by inertia in the case where this second element is mounted to slide freely in the first element attached to the ski.

First example
In the example illustrated in FIG. 1, the damping device (1) according to the invention consists of a block (2) located in the vicinity of the front contact line (3) of the ski. This block (2) consists of two plates (5,6) mounted perpendicular to the upper face (7) of the ski and in the longitudinal direction of the ski. These two plates (5,6) are slightly separated and receive between them a third plate (8) which is able to move vertically. This plate (8) is mounted at the end (9) of a rod (10) oriented towards the front and the other end (11) of which is fixed to the tip (12) of the ski by a yoke (13 ).

 In this embodiment, the two plates (5,6) mounted integral on the ski are made of a conductive metallic material while the central plate (8) integral with the tip (12) is made of a magnetic material.

 Of course, the opposite provision could be adopted. Thus in the variant of Figure 2, the plates (25,26) connected to the spatula are made of magnetic material while the plate (28) integral with the ski has at least one conductive part.

In this embodiment, the two plates (25,26) are made of soft magnetic materials and constitute the yokes for closing the magnetic flux created by the magnets (21,22,23,24). The magnetization directions (M21, M22, M23, M24) of these magnets make it possible to generate a strong magnetic field in the area where the central plate (28) is located. Using Neodymium-Iron-Boron magnets, with a typical magnetization of 1.25 Tesla, we can create a magnetic induction of the order of 1 Tesla in the magnetic air gap where the plate is located. The flux created by the magnet (23) mainly closes in the magnet (21) and that created by the magnet (22) in the magnet (24). This generates an alternating magnetic field in the area where the conductive plate (28) is located.
In the systems presented in FIGS. 1 and 2, the conductive part is linked to the upper surface of the ski, and the part which carries the magnets is linked to the tip of this ski, and the system works by relative displacement (D1, D2 ) of both parties with respect to each other. The reverse configuration can be adopted, that is to say that the conductive part can be fixed on the tip, and the magnetized part fixed on the upper surface of the ski.

 The operation of the device is as follows.

 When the ski is the seat of vibrations generated along its length, the tip (12) undergoes an oscillating movement relative to the area of the ski where the device (1) is located, namely the front contact line (3).

 The beating of the spatula results in an oscillation of the rod (10) according to the arrows shown D1, D2, consequently of the intermediate plate (8) constituting the second element of the damping device which moves between the two plates (5, 6) of the first element.

 In cases where the movable plates are magnetized as illustrated in FIG. 2, the conductive plate (28) sees the magnetic induction passing through it vary. It follows that induced currents are generated inside this metal plate (28).

 These currents close in loops which have a resistance which is a function in particular of the resistivity of the metal, and which therefore cause the dissipation of energy by the Joule effect.

 It follows that part of the kinetic energy of vibrations of the spatula is absorbed and dissipated in the form of heat, which greatly reduces the amplitude of the vibrations of the spatula.

 Given the materials used, that is to say the resistivity of metals as well as the intensity of the magnetic field, the power dissipated by such a device is of the order of a few tens of Watts.

 Advantageously, as illustrated in FIGS. 1 and 2, the two metal plates (5,6; 25,26) are connected by a third plate (15; 29) which is perpendicular to them and which closes the magnetic circuit between the two plates ( 5.6; 25.26).

 In this way, the intensity of the field present on the metal plates (5,6; 25,26) is increased when a single set of magnets (21,23) is used, which increases the efficiency in terms of energy absorption.

 Obviously, the closure of this magnetic circuit can be carried out by a plate made of a material different from the fixed vertical plates, and this plate can be located at any suitable location, and for example, be an integral part of the casing, not shown, which covers the device according to the invention.

Second example
In the embodiment illustrated in FIG. 3, the damping device also comprises two plates (30, 31) situated in a maximum zone of deformation of the ski. The plate (33) movable between the two fixed plates (30, 31) is mounted at the end (35) of a lever (34) itself fixed by its other end (36) to the ski board in a zone of least deformation.

 Due to the relatively high rigidity of the lever (34), when the ski progresses, either flat on uneven ground, or on the edge during a turn, vibrations put the front of the ski in oscillation (D1, D2) which causes a relatively large displacement of the conductive plates (30,31) relative to the magnetized plate (33).

Third example
The embodiment illustrated in FIG. 4 works on the analogous principle, with the difference that the magnetic plate (40) is mobile (D3, D4), therefore able to move between the two plates (41,42) linked to the ski (7), therefore according to the deformations thereof (Dl, D2).

 A first lever (45) connects the magnetic plate (40) to the spatula (12), like the embodiment illustrated in FIG. 1, while a second lever (44) arranged at the rear, connects the magnetized plate (40) to a zone of the ski substantially situated at the level of the stop of the binding.

 To limit the mechanical stresses at the connection between the magnetized plate (40) and the levers (44,45), these are mounted with a certain capacity for articulation relative to the plate.

 In this case, the relative displacement of the magnetized plate with respect to the magnetic plates is maximum when the device is at a belly of vibrations, that is to say an area in which the oscillatory displacement is maximum.

 In an alternative embodiment, the two levers (44,45) are the parts of the same flexible blade fixed at two points distant from the ski. The movable element of the damping device is fixed on this plate and moves vertically relative to the fixed element, by buckling effect of the support blade.

 In a variant illustrated in FIG. 5, the blade (56) which is fixed by at least one of its ends to the gliding board, has an opening (57) through which passes the first magnetized element (58) integral with the board. In this case, the conductive blade (56) sees the magnetic flux generated by the first element (58) vary when the vibrations cause the blade (56) to move (Dl, D2) around the magnet (58). The blade (56) serves both as a lever arm and as an energy dissipating member. Of course, the invention is not limited to the illustrated geometry. Furthermore, the blade may be completely metallic, or else include only certain electrically conductive zones, for example produced in layers.

Fourth example
The damping device illustrated in FIGS. 6 to 8 consists of a first element (50), advantageously cylindrical and metallic, fixed to the ski, substantially at the level of the front contact line (3) or near the tip (12). or the ski heel.

 This first cylindrical element (50) has an axis (51) perpendicular to the upper face (7) of the ski. This cylindrical element (50) internally receives a second cylindrical element which is magnetized (54) and capable of sliding freely inside the housing (43) forming the interior of the cylinder (50).

 This second element (54), forming a counterweight, is magnetized, and may, in accordance with the variant illustrated in FIG. 7, be constituted by a stack of cylindrical magnets (61,63) and iron discs (60,62,64) . This system creates successive north and south poles with very high induction. Indeed, these iron discs play the role of pole pieces which concentrate the flux created by the magnets. The movement of the counterweight (54) is limited by the stops (68) so that it remains in its housing. These stops can be fitted with rubber parts to reduce shock.

 Given the materials used, it is possible to obtain a peak induction of the order of 1.5 Tesla. Thus, it has been calculated and measured that for a feeder diameter of the order of 10 mm, and for a peak induction of the order of 1 Tesla, for an active height of the device of the order of 1 cm, with a vertical displacement of the order of 6 mm in amplitude, using aluminum or copper as the metallic material, and at a frequency of oscillations of the order of 100 Hertz, we obtain a dissipated power of the order about ten Watts.

 This result can therefore be obtained with an additional mass for skiing of the order of 10 grams, breaking down into 6 grams, as regards the magnetic counterweight (54) and 4 grams as regards the conductive cylinder. (50).

 In an alternative embodiment illustrated in Figure 8, the stops (78, 79) located at the ends of the cylinder (50) each consist of a magnet (80,81) and a conductive part (82,83). The magnetization of the magnets (80,81) is oriented in such a way that the magnet (84) forming the counterweight is in repulsion with the two magnets (80,81). In this way, the magnet (84) is suspended magnetically inside the cylinder (50). The preferably metallic conductive parts (82, 83) see the magnetic flux passing through them vary when the counterweight (84) moves under the effect of vibrations. Induced currents therefore arise in these rooms (82,83) which produces energy dissipation. In this case, the part forming the cylinder can also be conductive to increase the damping capacities.

 For all of the variants described, a mechanical study of the system shows that the vibrations are particularly damped when the device oscillates at high frequencies.

 Beyond a certain frequency, the dissipated power increases with the square of the frequency. More precisely, for the aforementioned numerical values, the cut-off frequency beyond which the damping device dissipates an energy capable of disturbing and damping the vibratory movement, is situated around 50 to 70 Hertz.

 It emerges from the foregoing that the device according to the invention makes it possible to greatly dampen the vibrations of which a gliding board, or more generally numerous sports articles are the seat.

 In addition, the use of magnetic phenomena avoids any contact or friction, which on the one hand, limits wear, and on the other hand, allows operation at low temperatures, in the presence of snow.

Claims (19)

 CLAIMS 1 / Vibration damping device (1), intended to be mounted on a sports article, comprising at least two elements (5,6,8; 25,26,28) including at least one (8; 25, 26) is magnetic and another is metallic, said elements being movable relative to each other so that the relative displacement of the elements produces induced currents generating energy dissipation, characterized in that the first ( 5,6; 28) of the two elements is intended to be mounted integral with one of the faces (7) of the sports article, and in that the second (8; 25,26) of the two elements is able to move with respect to the sports article in a direction substantially perpendicular to said face (7) of the sport article on which said device (1) is mounted. 2 / A vibration damper device according to claim 1, characterized in that the second element is integral with a lever (10,34,56) itself integral with the sports article. 3 / A vibration damper device according to claim 1, characterized in that the second element is integral with two levers (44,45) themselves integral with the sports article at two separate points. 4 / A vibration damping device according to claim 3, characterized in that the levers (44,45) are connected to the second element by an articulated connection. 5 / A vibration damping device according to claim 1, characterized in that the second element (54-84) is mounted freely floating relative to the first element (50). 6 / A vibration damping device according to claim 1, characterized in that one of the two elements (8; 21,22,23,24; 33; 40; 58; 61; 63; 84)) contains a magnetic material and in that the other element (5,6; 28; 30,31; 41,42; 56; 50) has at least one electrically conductive part. 7 / A vibration damping device according to claims 1 to 6, characterized in that the other of the two elements is composed of two plates (5,6; 25,26) perpendicular to the face (7) of the article on which is mounted said device, and in that the other element is a plate (8; 28) interposed between the two plates (5,6; 25,26) of the first element. 8 / vibration damping device according to claims 6 and 7, characterized in that the two plates (5,6) of said one of the two elements are associated with a part (15) connecting them capable of channeling the magnetic flux between said two plates (5.6). 9 / A vibration damping device according to one of claims 1 to 6, characterized in that the first element (50) follows a hollow cylindrical shape, inside which is able to move the second element (54; 84 ). 10 / A vibration damping device according to claim 9, characterized in that the first element is conductive and in that the second element contains a magnetic material.  11 / A vibration damping device according to claims 9 and 5, characterized in that the first element is equipped with stops (68) to limit the movement of the second element (54). 12 / A vibration damping device according to claim 10, characterized in that the second element (54) consists of several unit magnets (61,63). 13 / A vibration damping device according to claim 10, characterized in that the first element comprises at each end a magnet (80,81) in repulsion with the second element (84).  14 / Apparatus according to claim 13, characterized in that the magnets in repulsion with the second element are associated with a conductive part (82,83)  15 / Gliding board characterized in that it is equipped with a vibration damping device according to claims 1 to 14. 16 / Gliding board, comprising a front contact line and a spatula, characterized in that it is equipped with a device according to claim 2, in which the first element is located at the level of the front contact line (3 ) and the lever (10,45) is secured to the board on the spatula (12). 17 / Golf club characterized in that it is equipped with a vibration damping device according to claims 9 to 14. 18 / Tennis racket characterized in that it is equipped with a vibration damping device according to claims 9 to 14.  19 / Roller skate characterized in that it is equipped with a vibration damping device according to claims 1 to 14.