FR2845610A1 - Molded graphite or glass fiber tennis racket includes frame with bridge separated from frame arms by mechanical discontinuities in form of elastic joints that reduce vibration - Google Patents

Abstract

The tennis racket includes a molded graphite or glass fiber frame (11) with a handle connected to the frame by two arms (16,17). A bridge (15) is provided for completing the frame and extends between the two arms, with the connections (32,32') between the arms and bridge defining mechanical discontinuities. Each discontinuity maintains the tension of strings (12) crossing the bridge and frame while filtering vibrations of the strings.

Description

A tennis racket has a frame on which a string is stretched

  and which is extended by a handle intended to be held in the hand by a player. The problem of the transmission of vibrations, generated by the impact of the ball on the line, to the player's arm via the 5 racket handle is old. It will be noted that, at the level of the frame portion closest to the handle, which, so to speak, carries the two branches of the fork which connects the handle and the frame and which extends into the handle, is a center of vibrations. which is created, prejudicial,

  since it is near the handle.

  io Different solutions have already been proposed to reduce the drawbacks of these vibrations, which cause the famous epicondylitis.

  pain known as tennis-elbow.

  It has also been proposed to absorb the vibrations by an elastomer piece slipped between the strings parallel to the axis of the racket, between the last perpendicular string and the portion of frame mentioned above,

hereinafter referred to as "bridge".

  We also proposed to introduce at the end of the sleeve a

  resonant weight to combine its resonances with those created by the bullet on the handle and ultimately generate a compound resonance of lower frequency and therefore less harmful.

  The invention in fact relates to a racket with a separate bridge of the type which contributes to the shaping of the frame of the rackets.

metallic, aluminum.

  In these aluminum snowshoes, made with a rod (profiled rod 25) curved on itself, the bridge serves, of course to complete the frame, but above all to maintain the rod in its curved position. The bridge is screwed permanently to the rod, from which it is firmly attached. In an aluminum racket, the bridge is therefore also a vibratory bridge

  which transmits the vibrations of the string to the handle.

  However, the invention relates more particularly to a racket made from molded graphite or glass fibers (racket molded from fibers). In such a racket, the bridge does not perform any function of

  frame conformation, which is molded in one piece around the fibers.

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  To avoid the trauma mentioned above with a racket

  fibers, the applicant proposes the following solution.

  The invention relates to a tennis racket molded around fibers, comprising a frame, a string, a handle connected to the frame by two branches of a fork, and a bridge being provided to complete the frame between the two branches of the fork. of the handle, characterized in that the connections between the bridge and the legs of the fork have at least

mechanical discontinuity.

  Thus the bridge is not firmly fixed to the frame and is therefore not, or, in practice, as little as possible, a vibratory bridge between the rope

  and the handle that it mechanically insulates from each other.

  Preferably, a discontinuity is provided at each end of the bridge, as close as possible to the fork so as to isolate said vibration by vibration

  fork of the entire rope crossing the bridge.

  Mechanical discontinuities mechanically isolate the fork from the bridge, and therefore from all the central cords attached to it, and

  which are the main seat of the vibratory excitation of the handle.

  More preferably, each discontinuity is designed to

  preserve a tension continuity of the rope crossing the bridge and 20 crossing the frame.

  The rope tension is thus uniform over the entire

racket stringing.

  Preferably always, each discontinuity is designed to

  filter the vibrations of the rope.

  The belly of the racket's vibrations is thus reduced.

  Advantageously, the discontinuities are obtained by mechanical connections of axes substantially perpendicular to the branches of the fork or substantially perpendicular to an intermediate direction.

  between the direction of the branches and the perpendicular to the axis of the racket.

  The discontinuity is thus optimal to reduce the amplitude of the

transverse vibrations of the handle.

  Advantageously still, the connections between the bridge and the

  fork legs each support an elastic seal.

  The material of the seal can thus be chosen to filter the

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  vibrations as efficiently as possible.

  The invention will be better understood using the description

  following and the accompanying drawing in which: - Figure 1 is an overview of the racket of the invention; 5 - Figures 2A and 2B show perspective views of the bridge and the fork legs, in the fitted position (Figure 2A), and in the disconnected position (Figure 2B), according to a first embodiment of the racket of the invention and - FIGS. 3A and 3B represent perspective views of the bridge and of the arms of the fork of a second embodiment of the

  racket of the invention, similar to the views of Figures 2A and 2B.

  With reference to FIG. 1, the racket 1 comprises a frame 11 supporting a rope 12 passing through it in holes 19 distributed along the frame and stretched according to a calibrated tension, a handle 13 and a fork 14 15 connecting the handle to the frame by through its two branches 16 and 17, and between which is disposed a bridge 15 closing the frame 11 and participating in the support and in the tension of the rope, which crosses it in holes 18.

  The whole racket 1 accepts the axis 10 as the axis of symmetry.

  Ordinarily, if the racket is a metal racket, for example aluminum, the frame and the fork are one and the same rod shaped by elasticity according to the desired shape of the racket and maintained as shaped by the bridge, by means of screws, and by collage. The end of the fork on the handle side is fitted there, which completes the rigidity of the assembly. Here, the racket is made of molded material (carbon fibers, glass,), and the bridge does not participate in maintaining the desired shape of the racket, but participates in the support and in the tension of the line 12 near 30 of the axis 10 of the racket, string passing through the holes 18. The high tension of the string, of the order of 25 kg, being high, requires a

  good mechanical strength of the frame as a whole, therefore of the deck 15.

  Here, despite this constraint, and the relative ease of molding a one-piece racket, the bridge has been separated from the rest of the frame, and the bridge and

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  the frame are assembled by two mechanical connections 32 and 32 'located as close as possible to the branches 16 and 17 so that the bridge supports as many frames of the rope as possible on either side of the axis 10.

  - The mechanical connections 32 and 32 'are designed to both withstand the tension and absorb the vibrations of the rope. Thus, with reference to FIG. 2, in a first form of

  embodiment, the bridge 15 comprises at each of its ends bores 22, 22 'calibrated to be fitted on two axes 21, 21' integral with the branches 16 and 17 of the fork, in extension of the frame 1 1. Here the bridge io 15 is a slightly curvilinear tube.

  According to a second embodiment, with reference to FIG. 3, it is the legs of the fork or the frame which have the bores 22, 22 ′, the bridge coming therefrom by the two axes 21, 21 ′ formed

at its ends.

  In this second embodiment, we have made sure that the axes 21 and 21 'are fitted in a direction 25, 25' substantially perpendicular to the direction 26, 26 'of the branch 16, 17, while in the first form of embodiment, this direction 25, 25 ′ is substantially perpendicular to a direction intermediate between the directions 26, 26 ′ and perpendicular to the axis 10 of the racket. In this second embodiment, the bridge is generally a curved cylinder, extended by the two axes 21, 21 ', here inclined about 450 outwards. Elastic seals 30, 30 'and 31, 31', inserted between the bridge and the 25 branches, can complete the mechanical connections, and operate a mechanical filtering of the resonant frequencies of the racket at the level of the

  neck, especially bending frequencies, around 100 Hz.

  These seals are designed to completely cover the surfaces of

  contact between the bridge 15 and the branches 16 and 17 so as to isolate them 30 completely.

  In FIG. 3B, the axes 21 and 21 'being cylindrical, the joints

  31 and 31 'have substantially the shape of a flange sleeve.

  In FIG. 2B, the seals 30, 30 ′ are rings which can

be flattened or toroidal.

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  The mechanical connections 32, 32 ′ preserve the continuity of the mechanical behavior of the entire frame and the bridge relatively

to the tension rope support.

  On the other hand, during the impact of a tennis ball on the string, if the bridge is flexed, but thanks to the mechanical connections 32, 32 ′, these stresses on the central part of the string are filtered and / where are

  that very partially transmitted to the branches of the fork.

  In particular, due to the direction of the axes of the bridge, perpendicular to the branches of the fork, the deformations in vibration io of the bridge translate only partially into an excitation in bending of the

  fork and handle branches.

  In addition, the insertion of the joints in the mechanical connections makes it possible to filter any type of excitation of the branches having for origin

the central part of the rope.

Claims (7)

  1 - Tennis racket molded in fibers, comprising a frame (11), a string (12), a handle (13) connected to the frame by two branches (16, 5 17) of a fork (14), and a bridge (15) being provided to complete the frame between the two branches (16, 17) of the handle fork, characterized in that the connections (32, 32 ') between the bridge (15) and the branches (16, 17 ) of the   fork (14) have at least one mechanical discontinuity.   2 - Snowshoe according to claim 1, wherein there is provided a discontinuity at each end of the bridge (15), as close as possible to the fork (14).   3 - Racket according to one of claims 1 and 2, wherein each discontinuity is designed to preserve a tension continuity of the   rope (12) crossing (18) the bridge (15) and crossing (19) the frame (l 1).   4 - Snowshoe according to one of claims 1 and 3, wherein   each discontinuity is designed to filter the vibrations of the rope (12).   - Racket according to one of claims 1 and 4, in which   the discontinuities are obtained by mechanical connections (32, 32 ') of axes substantially perpendicular to the legs (16, 17) of the fork 25 or substantially perpendicular to a direction intermediate between the   branch direction and perpendicular to the axis (10) of the racket.   6 - Snowshoe according to claim 5, wherein the links   between the bridge and the fork legs each support an elastic joint 30 (30, 30 '; 31, 31').   7 - Racket according to one of claims 1 and 6, wherein   the bridge (15) is a curvilinear tube receiving axes (21, 21 ') integral with the   branches (16, 17) of the fork (14).   8 - Racket according to one of claims 1 and 6, wherein   the bridge (15) is a curved cylinder extended by two axes (21, 21 ') fitted into bores (22, 22') formed in the branches (16, 17) of the fork (14).