FR2762220A1 - TENNIS RACKET EQUIPPED WITH OSCILLATING ELEMENTS FOR DAMPING VIBRATIONS - Google Patents

Abstract

The invention concerns a tennis racket comprising at least an oscillating element (11) mounted on said racket in a housing (15) so as to oscillate freely under the effect of vibrations caused by the impact of the ball. Each oscillating element (11) being of the mass/spring type with a component forming a spring integral with its housing (15) on one of the sides and integral with the component forming mass on the other side, the component forming a spring made of a material in soft gel state while the component forming the mass is a sheet made of a heavy material.

Description

TENNIS RACKET EQUIPPED WITH OSCILLATING ELEMENTS
FOR DAMPING VIBRATIONS
The present invention relates to a tennis racket equipped with special means intended to dampen the vibrations caused by the impact of the ball on the sieve of the racket. It relates more particularly to a tennis racket equipped with at least one oscillating element capable of oscillating freely under the effect of said vibrations.

 The practice of tennis, which also has particularly beneficial effects, can cause trauma to the elbow tendons of the player. These traumas can have several causes among which an excessive weight of the racket, a center of gravity of the racket too offset towards the sieve, bullet impacts too frequently far from the central area of the sieve representing the normal center of percussion and finally amplitudes of excessive racket vibration due to the impact of bullets.

 We have already sought to reduce the causes of these traumas by proposing tennis rackets equipped with means capable of damping the vibrations of the racket at the level of the grip, that is to say of the part of the handle of the racket which is in contact with the player's hand.

For example in document WO 92/00781, there are interposed between the handle itself of the racket and the grip of the longitudinal connecting elements which allow a certain rotation of the handle relative to the grip along the longitudinal axis of the latter. These elements, which are arranged in grooves made in the handle, consist of two separate components,
One being an elastomeric material, for example polyurethane, of very high hardness and the other a material, for example of synthetic rubber, of lower hardness. These longitudinal elements serve both as a connection between the grip and the handle of the racket and as dampers of longitudinal and torsional vibrations reaching the handle of the racket.

 According to the applicant, The impact of a ball on the sieve of a tennis racket causes not one but several types of vibration, which are cumulative.

For a given racket, each type of vibration has a range of natural frequencies. The first type of vibration, having the lowest frequency range, corresponds to bending vibrations in a direction perpendicular to the plane of the racket sieve, with two nodal zones located for one towards the end of the handle close to the sieve and for the other towards the opposite end of the frame. The second type of vibration having a range of frequencies greater than those of the first type, corresponds to vibrations in bending in a direction parallel to the plane of the screens, with two nodal zones located for one towards the end of the nearest handle of the sieve and for the other about two thirds of the sieve starting from the handle. The third type of vibration, which has an even higher frequency range, corresponds to torsional vibrations relative to the longitudinal axis of the handle.

 According to the applicant, it is the first two types of vibration, in flexion, which are the most dangerous with regard to trauma to the elbow tendons, when the amplitude of such vibrations is excessive.

 The aim of the applicant is to provide a tennis racket equipped with vibration damping means capable of reducing the amplitude of the vibrations, preferably of the first two types of vibration, in the above-mentioned flexion.

 This object is perfectly achieved by the tennis racket of the invention which is characterized in that it comprises at least one oscillating element mounted on said racket in a housing so as to be able to oscillate freely under the effect of vibrations due to the impact of the bullet.

 According to the concept of the invention each oscillating element is caused to vibrate at the same time as the part of the racket where it is mounted with a determined frequency. There is thus obtained a greater progressive loss of energy by dissipation so that a significant reduction in the amplitude of the vibrations is obtained.

 Preferably each oscillating element is of the mass / spring type with a spring component which is integral with its housing on one of its sides and which is integral with the mass component on the other side. The choice of components makes it possible to adjust the range of vibration frequencies of the oscillating element.

 Advantageously, the spring component is a block made of a material in the soft gel state while the mass component is a sheet of heavy material. The sheet of heavy material, for example lead, is glued to the upper face of the gel block, for example of polyurethane, while the opposite face of the gel block is secured to the opposite face of the housing.

 In a preferred embodiment, the housing consists of a hollow portion of the handle in the bottom of which is (are) fixed (s) the element (s) oscillating (s) and whose depth is greater than the height maximum of the oscillating element so that the grip which envelops the handle is not in contact with the said (said) element (s). Thus, according to this particular arrangement, the oscillating element or elements are not directly accessible and therefore cannot be damaged.

 Advantageously, the racket of the invention comprises a plurality of oscillating elements which are arranged one next to the other on a support plate, and the housing corresponding to said plate is in the form of a groove arranged along the axis. longitudinal of the handle. The applicant has in fact found that the damping of the amplitude of the vibrations is largely a function of the number of oscillating elements. In a preferred embodiment, it was a support plate of twelve blocks of soft polyurethane gel topped with sheets of lead, each block having the configuration of a rectangular parallelepiped having a length of the order 8 mm, a width of 5 mm and a thickness of the order of 2 to 3 mm for a weight of 0.1 g, while the lead sheet had a thickness of 0.2 mm for a weight of 0, 1 g.

 In order to preferentially dampen the flexural vibrations of the first type, the racket has a groove provided with a plurality of oscillating elements formed in the horizontal plane, that is to say the general plane of the sieve. In order to preferentially dampen the flexural vibrations of the second type, the racket has a groove, provided with oscillating elements, formed in the vertical plane, that is to say the plane perpendicular to the sieve.

 In a preferred embodiment, the handle of the racket has an octagonal cross-section and has four grooves serving as housings with four plates provided with oscillating elements, two in the opposite faces of the octagon parallel to the horizontal plane of the screen. and two in the opposite faces of the octagon perpendicular to the horizontal plane of the sieve.

 The Applicant has found that the amplitudes of vibration have peaks as a function of certain frequencies. In order to optimize the reduction in the amplitude of these vibrations, the frequency specific to each oscillating element is determined to correspond to the frequency of one of these peaks.

 In the preferred version above, the oscillating elements located in a housing whose bottom is in a plane parallel to the plane of the screen have a natural frequency between 100 and 180 Hz while the oscillating elements arranged in a housing whose bottom is in a plane perpendicular to that of the sieve have a natural frequency between 120 and 200 Hz.

 The present invention will be better understood on reading the description which will be given of a preferred exemplary embodiment illustrated in which - FIG. 1 is a partial perspective representation of a tennis racket, - FIG. 2 is a representation schematic in section of the first type of bending vibrations, - Figure 3 is a schematic plan view of the second type of bending vibrations, - Figure 4 is a partial perspective representation of a support plate in which are arranged four elements oscillating, - Figure 5 is a schematic representation in longitudinal section of the handle of a racket equipped with a plate on which are arranged eight oscillating elements, - Figure 6 is a partial schematic representation in cross section of the handle of a racket equipped with plates arranged in perpendicular planes.

 A tennis racket 1 as illustrated in FIG. 1 comprises a frame 2 of oval shape in which strings are stretched 3 forming the sieve 4, a handle 5, covered with a grip 6 and, in the example illustrated an intermediate piece 7 in the form of a fork connecting the handle 5 to the frame 2. In practice the handle 5, the intermediate piece 7 and the frame 2 are produced from a single tubular element, according to a technique known elsewhere. The handle consists of the assembly of the two ends of this tubular element and covered by the grip 6.

 When the tennis ball strikes the sieve 4, the energy released by this impact is reflected in particular by the formation of vibrations throughout the racket 1. Figures 2 and 3 illustrate the two modes of vibration, in bending, of a racket under the effect of this impact.

 In the first mode of FIG. 2, the vibrations occur in a direction D1 perpendicular to the plane P1 of the sieve, the racket oscillating on either side of the horizontal plane, that is to say the plane P1 passing through the sieve 4, with two nodal zones 8, 9, that is to say zones which correspond to vibration nodes. In these zones 8, 9, there is strictly speaking no vibration.

As can be seen in FIG. 2, the first nodal zone 8 is located towards the front end 5a of the handle 5, that is to say the end which is located towards the screen 4. Thus it is towards the other end 5k of the handle 5 of the racket 1 that the vibrations of greater amplitude occur.

 In the second mode of vibration, in bending, illustrated in FIG. 3, the vibrations occur in a direction D2 parallel to the plane of the screen, the racket oscillating on either side of the median plane P2 passing through the handle 5 and which is perpendicular to the sieve 4 with a first nodal zone 10 which is also located towards the front end 5a of the handle 5 and a second nodal zone 10 'which is located towards the end of the sieve, substantially two-thirds of the sieve starting from the handle .

 In both Figures 2 and 3 there is shown in solid lines the normal position of the racket and in dotted lines an extreme position adopted by the racket during the corresponding vibrations. These representations are of course very amplified compared to reality.

 In accordance with the object of the invention, the racket 1 is equipped with oscillating elements 1 1 which are placed in housings formed in said racket so as to be able to oscillate freely under the effect of the vibrations caused by the impact of the ball on the screen 4. Each oscillating element 1 1 will contribute to damping, by natural dissipation of energy, the vibrations which reach it. Of course for this it is necessary that the oscillating element 1 1 can vibrate freely and without constraint and in particular that there is no contact with other parts which may disturb its proper functioning.

 In FIG. 4, four oscillating elements 11 have been illustrated, arranged one next to the other on a support plate 12.

 Each oscillating element 1 1 consists of a first component 13 which is a soft polyurethane gel and a second component 14 which is a lead sheet. The block 13 of polyurethane gel is secured to the support plate 12 while the lead sheet 14 is located on the free upper face of the block 13. There is thus an oscillating element 1 1 of the mass / spring type. The vibrations which are communicated to the oscillating element 1 1 by the support plate 12 causes the soft gel block 13 to vibrate, in the direction of the arrows F, at a frequency which is a function of the stiffness of said gel and of mass of the lead sheet 14.

 Such a support plate 12, equipped with these oscillating elements 11, is placed in a groove 15 which is formed in the handle 5 of the racket 1. This groove 15 is then closed by the positioning of the grip 16, that is to say -to say of the covering which covers the handle 5 and which is directly in contact with the hand of the player. So that the oscillating elements 11 can oscillate freely, it is important that the height H of the groove is greater than the maximum height h taken by the support plate 12 and by each oscillating element 11 at its maximum amplitude of vibration.

 In a specific embodiment, a support plate 12, supported 12 oscillating elements 11, having a length L of the order of 8 mm, a width! of the order of 5 mm and a thickness e of the order of 2 to 3 mm. The weight of each oscillating element 11 was of the order of 0.2 g distributed approximately equally between the polyurethane gel 13 and the lead sheet 14, the said lead sheet 14 having a thickness of the order of 0.2 mm.

 To preferentially dampen the vibrations according to the first mode, in bending, illustrated in FIG. 2, the oscillating elements 11 are placed in a groove 15 which is formed in a face 17 of the handle 5 which is parallel to the horizontal plane P1 that is that is to say in the plane of the screen 4. The oscillating elements 11, of the type described above, are determined so as to vibrate at a frequency which corresponds substantially to the natural frequency of the racket 1 according to the first mode of vibration in bending relative to the horizontal plane P1, with the two nodal zones 8 and 9. The frequency in question is of the order of 100 to 180 Hz, depending on the structure and the constituent elements of the racket 1.

 To preferentially dampen the vibrations according to the second mode, illustrated in FIG. 3, the oscillating elements 11 'are placed in a groove 15' which is formed in one of the faces 18 of the handle 5 which is in a plane perpendicular to the plane of the screen 4 Each element 11 ′ is determined so as to have a vibration frequency which corresponds to the natural frequency of vibrations of the racket 1 according to the second mode of vibration in bending with respect to the plane P2 with the two nodal zones 10 and 10 ′. . The frequency in question is of the order of 120 to 200 Hz.

 In practice, since the tennis racket handles generally have an octagonal external shape, the racket 1 has four grooves equipped with oscillating elements, two grooves 15 in the upper and lower faces parallel to the sieve and two grooves 15 'in the faces lateral 18 perpendicular to the sieve. The support plates 12, 12 'are glued in the bottom of each groove 15, 15' so that the vibrations communicated to the handle 5 are reflected in all the oscillating elements 11, 11 '. The applicant has carried out tests with a view to analyzing the reduction in the amplitude of the vibrations due to the installation of the oscillating elements in accordance with the invention. These tests were carried out with a racket in the free position, that is to say with a racket not held fixedly by the handle, which according to the applicant best simulates what is happening in practice. In a specific test, the applicant has placed two plates of twelve elements 1 1 in two grooves 15 formed in the two upper and lower faces 17 of the handle 5 of a racket 1, parallel to the screen 4. Curves have been drawn with ordered the amplitudes of vibrations and on the abscissa the frequencies of vibrations. The comparative curves between the results obtained with a racket equipped according to the invention and the same racket not equipped show that at the same frequency between 140 and 150 Hz, there is a peak amplitude which is divided by two for the racket equipped with oscillating elements according to the invention.

 The present invention is not limited to the embodiment which has just been described by way of non-exhaustive example. In particular, other components can be used to constitute an oscillating element of the mass / spring type as described. We can also think of other types of oscillating elements.

 Furthermore, the positioning of the oscillating element (s) in grooves formed in the external faces of the handle and protected by the grip is not exclusive of the invention, even if this solution is undoubtedly the easiest in terms of the manufacture of the racket itself. The oscillating element or elements can be placed at other locations, for example inside the handle 5, and not on a face facing outwards. The oscillating element or elements can also be located in other locations than the handle 5. From a theoretical point of view, they can be arranged, according to the invention, anywhere on the racket where vibrations are produced, that is to say that is to say with the exception of the nodal zones. Admittedly, it is the practical implementation which will be a limiting factor for having the oscillating elements at the level of the frame 2 or of the intermediate piece 7. However, this possibility cannot be excluded in the concept of the present invention.

Claims (10)

1. Tennis racket characterized in that it comprises at least one oscillating element (11) mounted on said racket (1) in a housing (15) so as to be able to oscillate freely under the effect of vibrations due to the bullet impact. 2. Racket according to claim 1 characterized in that each oscillating element (11) is of the mass / spring type with a component (13) forming a spring which is integral with its housing (15) on one of the sides and which is integral of the component (14) forming a mass on the other side. 3. Racket according to claim 2 characterized in that the spring component is a block (13) made of a material in the soft gel state while the mass component is a sheet (14) of a heavy material . 4. Racket according to claim 3 characterized in that the sheet of heavy material is a lead sheet secured to the upper face of a block of soft polyurethane gel. 5. Racket according to one of claims 1 to 4 characterized in that the housing consists of a recessed portion of the handle (5) in the bottom of which is (are) fixed (s) the (s) oscillating element (s) (s) (11) and whose depth (H) is greater than the maximum height (h) of the oscillating element so that the grip (16) which envelops the handle (5) is not in contact with the said (the said) elements. 6. Racket according to claim 5 characterized in that it comprises a plurality of oscillating elements (11) which are arranged one beside the other on a support plate (12), and the housing corresponding to said plate being presented in the form of a groove (15) arranged along the longitudinal axis of the handle. 7. Racket according to claim 6 characterized in that it comprises a support plate of twelve blocks of soft polyurethane gel topped with lead sheets, each block (13) being in the configuration of a rectangular parallelepiped having a length ( L) of the order of 8 mm, a width (i of 5 mm and a thickness (e) of the order of 2 to 3 mm for a weight of 0.1 g, while the lead sheet (14) has a thickness of 0.2 mm for a weight of 0.1 g. 8. Racket according to one of claims 1 to 7 characterized in that it comprises at least two oscillating elements, one in a housing formed in a horizontal plane, parallel to the plane of the sieve and the other in a vertical plane , perpendicular to the plane of the sieve. 9. Racket according to claim 8 characterized in that the handle of the racket having in cross section an octagonal shape, it has four grooves serving as housings with four pads provided with oscillating elements, two, in the opposite faces of the octagon parallel to the horizontal plane of the sieve and two in the opposite faces of the octagon perpendicular to the horizontal plane of the sieve. 10. Racket according to one of claims 8 or 9 characterized in that the oscillating elements being in a housing formed in a plane parallel to the plane of the sieve have a natural frequency between 100 and 180 Hz while the oscillating elements arranged in a housing formed in a plane perpendicular to that of the screen have a natural frequency between 120 and 200 Hz.