FR2789320A1 - Vibration damper for tennis racquet has flexible plate fixed to cords and having projection which rotates to dampen vibration - Google Patents

Abstract

The vibration damper for a tennis racquet has a flexible plate (1) fixed to the cords (3,4) of a racquet and having a rigid bar (5) with a projection (6). Following an impact by the ball, the projection rotates and pivots the fixed section which is braked by the deformation of the elastomer plate.

Description

ANTI-VIBRATION WITH ROTARY MECHANISM FOR ANY TENNIS RACKET

  The present invention relates to an anti-vibration device for any tennis or ball racket made of thermoplastic or thermosetting material which is flexible and more rigid and which fits into the strings of the sieve of a ball racket. This device is used to absorb the vibrations of the sieve strings following a bullet impact. The state of the prior art is detailed here in order to clearly understand the technological advance of the present invention. It is well known that an elastomeric element or

  made of thermoplastic placed on the strings of a sieve absorbs the vibrations of the latter.

  Filed in 1964, the French Lacoste patent N 1,308,833 presents an antivibration in flexible material and in the shape of a torus, provided with slots fixing in a mesh of the sieve of the racket. Then, other systems came to perfect the Lacoste patent, such as the German patent DE 34 43 009 A1 filed in 1984 and DE 35 04 137 A1 filed in February 1985. These two patents present elastomer devices, also having the shape of a torus like the device presented in the lacoste patent, and provided with a metallic mass causing an oscillation perpendicular to the plane of the sieve when the elastore of the torus is flexible. Depending on the hardness of their elastomer part and the spacing of the strings constituting the sieve, these devices oscillate at very different frequencies. Indeed, if the strings of the snowshoes are spread, the central part of the elastomer receiving the metallic mass is more flexible. This results in mass oscillations at lower frequencies. If the spacing of the strings is more reduced, it is the opposite effect, that is to say that the mass oscillates at higher frequencies. As these are the proper oscillations of the metal mass in phase with the vibrations of the racket which determine the effectiveness of the anti-vibration device, these devices are not universal. US Pat. No. 651,545, modeled on the German patents above mentioned, proposes to change the metallic masses as a function of the frequencies to be obtained. French patent N 2,585,257 filed in July 1985 still presents a torus-shaped device provided with a

  counterweight associated with a membrane system supposed to transmit vibrations to it.

  However, in addition to the fact that the displacement of the counterweight is necessarily reduced, the membrane connecting the said counterweight to the elastomeric toroid is more or less compressed depending on the spacing of the strings, and makes the device incapable of effectively absorbing vibrations on all types of snowshoes. All the devices known to date consisting of a flexible element and a metallic mass, oscillate in a very limited way because the oscillation is always made perpendicular to the plane of the sieve of the racket. They are therefore of limited effectiveness and really absorb vibrations only on a single type of racket with a specific spacing of the strings. None of these devices is

  2 intrinsically adjustable to oscillate in phase with the vibrations to dampen the racket.

  The present invention overcomes these drawbacks. In a preferred embodiment, the device according to the invention consists of at least two elements. The first element, of compact shape and in flexible material is inserted between the strings of a racket in the manner of the Lacoste patent 1.398 833 cited above, the other element in more rigid material, is inserted inside or fixed outside the flexible element, perpendicular to two strings of the racket. This second element comprises a perpendicular protrusion positioned between the two strings and directed along the longitudinal axis of said strings. Following a bullet impact on the sieve, the resulting vibrations induce a perpendicular protrusion movement which rotates the whole of the second element in order to dissipate the vibrations. The elastic pressure of the first elastomer element on the second more rigid element is always constant whatever the spacing of the strings. The frequency of the setting in motion of the rotary part is identical that that is the spacing of the cords because its semi-rigid articulation is decoupled from the oscillations of the flexible element which are they, perpendicular to the sieve. The rotating mobile part rotates around its central axis inserted in the flexible element. In order to prevent the device from inadvertently being extracted from the sieve, the more rigid element has, at each of its ends, prominences one upper, and the other lower lower, between which the strings are positioned. If the rotation of the rigid part is a little limited, on the other hand the displacement of the end of the prominence of the rigid part is always very important, and the device is perfectly locked to the rope. To accentuate the rotation effect of the rigid element, the prominence of this element contains an added metallic mass

  inserted inside or outside of its part furthest from its center of rotation.

  To further accentuate the rotation of the movable part, the prominence consists of a metal part comprising a passage where the more rigid part is inserted, interposed between the strings. An adjustment of the semi-rigid articulation in torsion makes it possible to adjust the frequency of oscillation in rotation of the mobile element with the frequency of the vibrations to be damped. For this, the movable part comprises on its upper or lower face, in the vicinity of its center of rotation, the addition of a tongue made of semi-rigid material itself articulated in rotation in the axis of the plane of the sieve, and overlapping the flexible elastomer adjacent to the first element. Thus, when the tongue is positioned along the axis of the movable element, the flexural strength of the latter, provided by the flexible compact element inserted between the strings, remains unchanged. But, if the human positions, by rotation of the tongue, the said tongue perpendicular to the 3 movable part, that is to say overlapping on the sides the first flexible element, this causes an increase in stiffness of the semi-articulation. rigid of the moving part. Thus, depending on the positioning of the tongue, the frequency of rotation of the movable part is different and makes it possible to adapt more finely to the vibration frequency of the racket, for better attenuation of the vibrations.

  The drawing presents several figures of a preferred materialization according to the invention.

  Figure 1 shows a front view of the device fixed between between two strings of the sieve

a tennis racket.

  FIG. 2 shows the same device seen in profile along the longitudinal axis of the strings.

  The strings have been removed here so as not to weigh down the design.

  Figure 3 shows a following section (B.B.) of Figure 1 Figure 4 shows the same device of Figure 1 side view along the transverse axis

some ropes.

  Figure 5 shows a following section (A.A.) of Figure 1

  Figure 6 shows a following section (C. C.) of Figure 2.

  Figures 7 and 8 each show a following section (B'.B '.) Of the device according to the figure

  1, but with the mobile part off-center following a bullet impact on the sieve.

  Figures 9 and 10 each shows a following section (B '. B') of a device similar to

  that of Figure 1, but with the tongue (2) oriented differently.

  With reference to FIG. 1, the device of compact form here consists of a compact element (1) made of flexible elastomer material, which is fixed on the cords (3) and (4). The rigid element (5) in phantom view comprises the eccentric rotary prominence (6) which takes place in an opening (7) that comprises the element (1). The adjustment tongue (2) for stiffening the semi-rigid articulation of the rotary part rotates under the action of

  The ninety degree human in the axis (T) of the plane parallel to the sieve of the racket.

  In Figure 2 we see that the device is very compact and that the adjustment tab (2)

  is not very prominent on the device.

  Figure 3 shows a section along the axis of a rope. We can clearly see that the

  rigid pivoting part (5) here comprises a recess (8) or comes to position the rope (3).

  The two parts, upper (9) and lower (10), of this housing (8) are rounded in order to allow the rigid part (5) to be able to pivot. It will be noted here that the spacing between the two parts, upper (9) and lower (10), of the rigid element (5) is greater than

diameter of the rope (4).

  Figure 4 which is a side view along the transverse axis of the strings (3) and (4) shows

  the slots (11) and (12) where the strings (3) and (4) are inserted.

  4 Figure 5 which is a following section (AA) of the device of Figure 1 shows that the rigid part (5) has a small protrusion on its upper part (13) or is inserted the cavity (14) of the tongue (2). This arrangement allows the tongue to pivot

under the action of humans.

  Figure 6 which is a radial section (C.C.) of the device of Figure 1 better presents the characteristics of the movable part. One distinguishes the metal part (15) fixed on the mobile preomience (6) which the allourdei and increases the effect of rotation of the rigid unit. In contrast, the other protrusion (16) has a recess (17) to lighten it, so as not to

  brake the inertia of the part (6) comprising the metal part (15).

  Figures 7 and 8 which are a following section (B'.B ') of the device according to Figure 1 shows the rotational movement of the movable part, in a direction of rotation (Si) for Figure 7, and (S2) for figure 8. We distinguish on these figures, the mass of inertia (15) which is here

  cylindrical. The recess (17) of the part (1 6) is also cylindrical.

  Figures 9 and 10 are views (BB) of the device according to Figure 1 but with the tongue (2) oriented in the longitudinal axis the rigid part (5) interposed between the strings (3) and (4 ) These figures help to better understand how the tongue (2) stiffens the semi-rigid joint, and brakes in rotation, here limited, of the mobile part (6). It is clearly seen that when the tongue (2) overlaps the elastomer of the compact element (1) located on the rigid part (5), the said tongue slows down the movement of the rotary part (6). But the movement of the part (6) is not stopped, because the flexible elastomer of the element (1) deforms. This deformation indicated by arrows in these figures allows the prominence (6), aided by the inertia induced following a ball hit from the metal part (15), to move. The greater resistance to rotation of the mobile part (5) and (6) allows it to enter into phase with the lower frequencies, those of the frame of the racket, to better dissipate the vibrational energy. It will also be noted that thanks to their rounded shape, the upper (9) and lower (10) parts of the rigid element (5) allow the latter element, therefore also t to the prominence (6) which is united,

move in rotation.

  The device according to the invention can be manufactured by molding plastic, flexible or rigid material. The dimensioning of the parts constituting the device, in particular the rigid pivoting element (5) and its rotary prominence (6) makes it possible to use more or less hard material. The metal part (15) can be made by turning or cutting by cold striking. The part (5) and the part (6) can be two separate parts, the part (6) comprises

  then a passage allowing the part (5) to cross it.

  It goes without saying that the materialization according to the drawing is given as an indication. All the variations in shape of a device allowing, the association of an element fixing on a sieve of a tennis racket or other ball game with a movable part moving in rotation to attenuate the consecutive vibrations at a ball hit, will not come out

of the scope of the invention.

  The present invention is particularly intended to dampen vibrations on each type

tennis racket.

Claims (3)

RESELL ICATIONS   1 / Anti-vibration device for tennis racket in flexible and compact material (1) inserted between two strings (3 and 4) of a tennis racket sieve, characterized in that it comprises a movable element attached in rigid material (5) and (6), the said movable element (5,) and (6)) moving in rotation to absorb vibrations following an impact of ball on the sieve.   2 / anti-vibration device for tennis racket according to claim 1 characterized in that the movable element (6) comprises an attached metal mass (15) in order to increase its inertia.   3 / anti-vibration device for tennis racket according to claim 1 characterized in that the movable element (5) and (6) comprises a tongue (2) articulated in the axis of the plane of the sieve, the rotation of said tongue (2) for modifying the stiffness and / or the amplitude of the movements of part (5) and (6), in order to adapt the frequency of the latter to   racket vibrations to dampen.