JP2014023927A - Racquet configured with fewer cross strings than main strings - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a racquet capable of imparting more spin to a ball.SOLUTION: A racquet includes a frame having a head portion coupled to a handle portion, and a string bed of interlaced cross and main string segments. The head portion includes a hoop having inner and outer peripheral walls. The hoop defines a head size having a maximum longitudinal and transverse dimensions, a and b, respectively. The dimension a is at least 1.2 times longer than the dimension b. The inner peripheral wall includes string holes. Each of the cross segments transversely extends from one of the string holes to another, and each of the main segments longitudinally extends from one of the string holes to another. The cross segment closest to the handle portion and the end point of a segment of the longitudinal dimension a, on a the handle portion side, define a second longitudinal dimension c. The ratio of the dimension a to the dimension c is at least 6.5. The string bed has at least one more main segment than cross segment.

Description

RELATED APPLICATION This application claims priority based on US Provisional Patent Application No. 61 / 675,029, filed July 24, 2012, with the name of the invention RACQUET CONFIGURED WITH FEWER CROSS STRINGS THAN MAIN STRINGS. This application is filed on the same day as this application by William D. Severa, John B. Lyons, Robert T. Kapheim and Robert T. Thurman, and the title of the invention is RACQUET CONFIGURED WITH FEWER CROSS STRINGS THAN MAIN STRINGS. Related to 13 / 894,611. The contents of this document are included in this application.

  The present invention generally relates to sports rackets. More specifically, the present invention relates to a racket for use with a string bed having fewer horizontal string segments than vertical string segments.

  Sports rackets, such as tennis rackets, are widely known and generally include a frame having a head portion connected to a handle portion. The head portion supports a string bed having a plurality of vertical string segments interwoven with a plurality of horizontal string segments. Many rackets also include a throat portion that is disposed between the handle portion and the head portion and connects the handle portion to the head portion. A typical string bed of a sports racquet includes a central area and a peripheral area, which, after impact with the ball, gives the player the highest responsiveness, highest power, and the best “feel”. give. A central region, commonly referred to as a “sweet spot”, is generally defined as a region having a relatively high coefficient of restitution (COR) value within the string bed. In general, as the COR increases, the power increases and the reactivity increases.

  The configuration of the string bed and racket also contributes to the amount of spin that the player can hit the ball during play. If the ball can be spun (top spin or back spin), the player's ability to control the ball during play can be increased. For example, by applying a top spin to a tennis ball, the player can swing faster and hit the tennis ball more strongly, while keeping the tennis ball ready to continue playing on the court. By applying a topspin to the ball, the player can fly the ball higher, swing faster, let the ball go over the net, and keep the ball ready for play. Therefore, characteristics such as spin rate and spin ratio (ratio of the spin rate of the ball after impact to the spin rate of the ball before impact between the ball and the string bed) etc. can be used to evaluate the performance of the racket and / or player. It can be an important factor. Other characteristics (such as vertical string deflection, vertical string snapback time, vertical string snapback speed, etc.) may also be useful in determining the amount of spin that a stringed racket can apply to the ball.

  Conventional rackets employ various design features to improve the ability of the racket to spin the ball and / or to enlarge the sweet spot of the racket. Such design features include, for example, increasing the racket head size, increasing the tension of the racket string, changing the racket and / or the material of the racket string, and the vertical and / or horizontal string of the racket. May be increased in length. However, such a design change has problems such as reduced reliability, early string breakage, early racket failure, increased racket moment of inertia, and reduced operability.

  Therefore, there is always a need for a racket that can apply a greater spin to the ball during play. There is also a constant need for a racket with a larger sweet spot in order to increase the “dwell time” without degrading the overall performance of the racket. The sweet spot is enlarged, the deflection of the vertical string is increased, the snapback time of the vertical string is reduced, the snapback speed of the vertical string is increased, and the “residence time” is increased, while the inertia moment of the racket head is increased. It would be advantageous to provide a racket that does not increase or deteriorate the operability of the racket. There is also a need for a racket that can apply a greater spin to the ball without significantly different appearance and design from the design of a general sports racket.

One aspect of the present invention is a tennis racket used with a string bed formed by alternately braiding a plurality of vertical string segments with a plurality of horizontal string segments.
A frame that extends along the longitudinal axis and includes a head portion connected to the handle portion;
The head portion includes a hoop having an inner peripheral wall and an outer peripheral wall,
The hoop defines the head size of the racket,
The head size is 93 to 120 in ² and has a maximum vertical length a and a maximum horizontal length b.
The maximum vertical length a is not less than 1.2 times the maximum horizontal length b,
The inner peripheral wall includes a plurality of horizontal string holes and a plurality of vertical string holes,
Each of the horizontal string holes is configured to receive one end of the horizontal string segment, and each of the vertical string holes is configured to receive one end of the vertical string segment;
The number of vertical string holes is greater than the number of horizontal string holes, whereby the string bed used with the racket has more vertical string segments than the horizontal string segments.

Another aspect of the present invention is a tennis racket,
A frame that extends along the longitudinal axis and includes a head portion connected to the handle portion;
A string bed connected to the head of the racket;
With
The head portion includes a hoop having an inner peripheral wall and an outer peripheral wall,
The hoop defines a head size having a maximum vertical length a and a maximum horizontal length b;
The maximum vertical length a is not less than 1.2 times the maximum horizontal length b,
The inner peripheral wall includes a plurality of string holes,
The string bed includes a plurality of vertical string segments and a plurality of horizontal string segments interwoven with the plurality of vertical string segments,
Each of the lateral string segments extends laterally from one of the string holes to the other of the string holes;
Each of the vertical string segments extends substantially vertically from one of the string holes to the other of the string holes;
The horizontal string segment closest to the handle portion and the end point on the handle portion side in the section of the maximum vertical length a define a second vertical length c,
A ratio of the maximum vertical length a to the second vertical length c is 6.5 or more;
The string bed has one or more vertical string segments than the horizontal string segments.

  In another aspect of the present invention, the tennis racket can be tested by a tennis ball spin test. In this spin test, the racket is secured to the test fixture by four spaced mounts so that the plane defined by the string bed is positioned at 30 degrees relative to the horizontal direction. The tennis ball is launched from the ball launcher toward the string bed at a speed of 38-42 miles per hour from an angle of 50 degrees with respect to an axis perpendicular to the plane of the string bed. The ball and string bed are monitored at 5000 frames per second by a high speed video system. The racket includes a frame and a monofilament racket string made of polyester. The frame includes a head portion extending along the longitudinal axis and connected to the handle portion. The head portion includes a hoop having inner and outer peripheral walls. The hoop defines a head size having a maximum vertical length a and a maximum horizontal length b. The maximum vertical length a is not less than 1.2 times the maximum horizontal length b. The inner peripheral wall includes a plurality of string holes. The racket string has a diameter of 1.10 to 1.55 mm. The racket string is connected to the head part to form a string bed. The string bed includes a plurality of vertical string segments and a plurality of horizontal string segments interwoven with the plurality of vertical string segments. Each of the horizontal string segments extends laterally from one of the string holes to the other of the string holes, and each of the vertical string segments is from one of the string holes to the other of the string holes Up to one of them. A string bed has one or more vertical string segments than horizontal string segments. When a tennis ball spin test is performed on a racket, one or more vertical string segments in contact with the tennis ball will give a snapback speed of 1 meter per second or more.

  In another aspect of the present invention, the tennis racket can be tested by a tennis string displacement test. In this tennis ball displacement test, the racket is attached to the test fixture by four spaced apart mounts so that the plane defined by the string bed is positioned at 90 degrees (or vertical) with respect to the horizontal direction. It is firmly fixed. The tennis ball is also launched from the ball launcher toward the string bed at a speed of about 60 feet per second from an angle of 45 degrees with respect to an axis perpendicular to the plane of the string bed. The ball and string bed are monitored at 5000 frames per second by a high speed video system. The racket includes a frame and a monofilament racket string made of polyester. The frame includes a head portion extending along the longitudinal axis and connected to the handle portion. The head portion includes a hoop having inner and outer peripheral walls. The hoop defines a head size having a maximum vertical length a and a maximum horizontal length b. The maximum vertical length a is not less than 1.2 times the maximum horizontal length b. The inner peripheral wall includes a plurality of string holes. The racket string has a diameter of 1.10 to 1.55 mm. The racket string is connected to the head part to form a string bed. The string bed includes a plurality of vertical string segments and a plurality of horizontal string segments interwoven with the plurality of vertical string segments. Each of the horizontal string segments extends laterally from one of the string holes to the other of the string holes, and each of the vertical string segments is from one of the string holes to the other of the string holes Up to one of them. A string bed has one or more vertical string segments than horizontal string segments. When a tennis ball displacement test is performed on a racket, a string deflection of 5 mm or more occurs in one or more vertical string segments in contact with the tennis ball.

  The invention will be more fully understood from the following detailed description and the accompanying drawings. In the drawings, like numerals indicate like parts.

It is a perspective view which shows the front of the racket of one Embodiment of this invention. It is a front view which shows the head part of the conventional racket containing a string bed. It is a front view which shows the head part of the other conventional racket containing a string bed. It is a front view which shows the head part of the racket of FIG. 1 containing a string bed. It is a front view which shows the head part of the racket containing the string bed of alternative embodiment of this invention. It is a front view which shows the head part of the racket containing the string bed of other alternative embodiment of this invention. It is a side view which shows the spin test equipment of a tennis boose. It is a side view which shows a racket displacement test equipment. It is a figure which shows the two-dimensional map of the restitution coefficient in the string bed of the conventional racket. It is a figure which shows the two-dimensional map of the coefficient of restitution in the string bed of the racket substantially the same as the racket of FIG. It is a figure which shows the two-dimensional map of the restitution coefficient in the string bed of the racket substantially the same as the racket of FIG.

  In FIG. 1, a sports racket is indicated by 10. The racket 10 in FIG. 1 is configured as a tennis racket. The racket 10 includes a frame 12 extending along a longitudinal axis 16, and the frame 12 includes a head portion 18, a handle portion 20, and a throat portion 22 that connects the head portion 18 and the handle portion 20. . The frame 12 has a tubular structure formed of a lightweight and strong material (preferably a carbon fiber composite material).

  In the present specification, the term “fiber composite material” or “composite material” means a plurality of fibers impregnated (or impregnated) into a resin. These fibers may be co-axially arranged in a sheet, layer or ply, or may be knitted or woven into a sheet or layer and / or chopped into one or more layers May be randomly distributed. A single ply typically includes hundreds or thousands of fiber bundles, which are initially arranged to extend coaxially and parallel to each other within the uncured resin. Each fiber bundle includes a plurality of fibers. These fibers are made of a material with high tensile strength, such as carbon. Alternatively, these fibers can be glass, graphite, boron, basalt, carrot, Kevlar®, Spectra®, polyparaphenylene-2, 6-benzobisoxazole (PBO), It may be made of other materials such as hemp and combinations thereof. In a preferred embodiment, the resin is preferably a thermosetting resin such as an epoxy resin or a polyester resin. In other preferred embodiments, the resin may be a thermoplastic resin. Composite materials are typically wound around mandrels and / or equivalent structures and cured under heat and / or pressure. During curing, the resin flows to completely disperse and impregnate the fiber substrate. When forming multiple layers or plies, the fibers may be arranged along a plurality of different directions relative to the longitudinal axis 16 and / or may be knitted or woven from layer to layer. Alternatively, the frame 12 may be formed of other materials, including alloys, other composite materials, wood, or combinations thereof.

The head portion 18 has a tubular structure including an inner peripheral wall 24 and an outer peripheral wall 26. The head portion 18 can be divided into a plurality of regions, such as, for example, the distal region 28, the first and second lateral regions 30, 32, and the proximal region 34. A hoop 36 is defined. The hoop 36 has a string bed region 38 that receives and supports the string bed 14 (FIG. 4). In the preferred embodiment, the proximal region 34 includes a yoke 40. In the present specification, the string bed area 38 may mean the head size of the racket 10. In the preferred embodiment, the head size of the racket 10 or the area of the string bed region 38 is in the range of 93 to 120 in ² . In other preferred embodiments, the racket 10 head size is in the range of 98-115 in ² . In alternative preferred embodiments, other head sizes may be used and are within the scope of the present invention. The string bed region 38 has a maximum vertical length a and a maximum horizontal length b. The hoop 36 can have any closed curved shape including, for example, a generally elliptical shape, a generally teardrop shape, a generally pear shape, and combinations thereof. The shape of the hoop 36 is preferably non-circular. The maximum vertical length is preferably at least 1.2 times the maximum horizontal length (a ≧ 1.2 × b). In a particularly preferred embodiment, the maximum vertical length is preferably at least 1.25 times the maximum horizontal length (a ≧ 1.25 × b).

  The yoke 40 is an elongated tubular structural member that extends from the first side region 30 to the second side region 32 of the head portion 18. In the preferred embodiment, the yoke 40 is integrally formed with the frame 12 that defines the proximal region 34. In alternative preferred embodiments, the yoke 40 may be connected to the frame 12 using adhesives, fasteners, bonds, and combinations thereof. The yoke is formed of a lightweight and strong material (preferably a carbon fiber composite material). Alternatively, the yoke 40 may be formed of other materials such as alloys, other composite materials including basalt fibers, and combinations thereof.

  In a preferred embodiment, the first and second lateral regions 30, 32 extend downward from the head portion 18 to form first and second throat tubes 42, 44 of the throat portion 22. The first and second throat tubes 42 and 44 gather and extend further downward to form the handle portion 20. The handle portion 20 includes a pallet (not shown), a grip 46, and a bat cap 48. In an alternative preferred embodiment, the handle portion 20 may be a tubular structure that does not include extensions from the first and second throat tubes. In this alternative preferred embodiment, the handle portion comprises a tubular structure that is separated from the throat portion or head portion of the frame, and includes known fasteners, mold forming techniques, bonding techniques, adhesives, or combinations thereof. And may be attached to the throat.

  In other preferred embodiments, the head portion 18 is directly connected to one or both of the throat portion 22 and the yoke 40 using known fasteners, adhesives, mechanical bonds, thermal bonds, or combinations thereof. Alternatively, the head portion 18 may be separated from one or both of the throat portion and the yoke by a vibration and shock absorbing material (eg, an elastomer). In yet another alternative preferred embodiment, the head portion 18 is integrally formed with one or both of the throat portion 22 and the yoke 40.

  2-6, a racket 10 configured to support a string bed 14 has a plurality of main string segments 50 alternately interwoven or knitted with a plurality of cross string segments 52. Is formed by. The string bed 14 is preferably configured to be substantially uniform so that the spacing between the string segments 50, 52 is constant. Alternatively, the string bed 14 has the closest spacing between the vertical and horizontal string segments of the string bed at the center of the string bed 14 (or near the geometric center of the string bed or string bed region). As long as possible, the intervals may be non-uniform. The vertical and horizontal string segments 50 and 52 may be formed from one continuous racket string, or may be formed from two or more racket strings. The racket string has a high tensile strength and is made of a flexible material. In preferred embodiments, the racket string may be formed from a polyester material, nylon, natural gut material, and / or synthetic gut material. The polyester material used to form the racket string may include polyetheretherketone (PEEK), polytetrafluoroethylene (PTFE), other polyester materials, and combinations thereof. The racket string may have a monofilament structure or a multifilament structure. The racket string may have a variety of different diameters (gauges). The diameter of the racket string is preferably in the range of 1.10 to 1.55 mm.

  The vertical and horizontal string segments 50, 52 refer to the racket string portions that form the string bed 14. A string bed generally defines a string bed plane 54. Each of the vertical and horizontal string segments 50, 52 may be understood to have first and second ends or ends. The racket string may be terminated, interrupted, or cut at the end or end, although it is not common. In other cases, the ends or ends of the vertical and horizontal string segments 50, 52 are locations where the vertical and horizontal string segments 50, 52 pass through the string holes in the hoop 36. The vertical and horizontal string segments 50, 52 extend substantially along the string bed plane 54 throughout the string bed region 38 from a point of view other than to facilitate weaving or weaving the vertical and horizontal string segments 50, 52. Is preferred. Maintaining the vertical and horizontal string segments 50, 52 throughout the string bed region 38 and approximately within the string bed plane 54 maximizes the playability of the entire string bed 14 and allows the player to Even when the ball is hit nearby, the player can be given higher ball control ability. In other preferred embodiments, a portion of the vertical and / or horizontal string may extend slightly away from the string bed plane 54 at or near its end. The inner and outer peripheral walls 24, 26 of the hoop 36 preferably have string holes for receiving racket strings. In a particularly preferred embodiment, the inner peripheral wall 24 is formed with a plurality of vertical string holes 56 and a plurality of horizontal string holes 58 for receiving the vertical and horizontal string segments 50, 52, respectively. The string holes 56, 58 can be circular, elliptical, rectangular, or any generally curved shape. The string holes 56, 58 may be formed in a dimension slightly larger than the diameter of the racket string or the diameter of the combination of the racket string and the grommet, or a dimension that allows the racket string to move or bend. The head portion 18 of the racket 10 may include one or more grommets or bumper guards that support and protect the racket string extending from one string hole to the other string hole.

  When the string is stretched on the racket 10, the vertical string holes 56 formed in the inner peripheral wall 24 of the hoop 36 are positioned so that each vertical string segment 50 extends in a direction substantially parallel to the longitudinal axis 16 of the racket 10. It is preferable. The term extending substantially parallel to the longitudinal direction or extending substantially longitudinally means a direction extending collinearly or parallel to ± 2 ° of the longitudinal axis 16. Similarly, in the inner peripheral wall 24 of the hoop 36, when the string is stretched on the racket 10, each lateral string segment 52 extends in a direction substantially transverse (or vertical) to the longitudinal axis 16 (± 2 °). The lateral string hole 58 may be positioned at Thus, in a preferred embodiment, the string bed 14 includes a plurality of generally longitudinally extending vertical string segments 50 and a plurality of generally laterally extending lateral string segments 52. In other alternative embodiments, the vertical string holes 56 may be positioned within the inner peripheral wall 24 of the hoop 36 such that one or more vertical string segments extend in a direction that is not substantially vertical.

  In a preferred embodiment, each of the vertical and horizontal string holes 56, 58 includes or receives one or one end of the vertical and horizontal string segments 50, 52, respectively, and there are string holes through which the vertical or horizontal string segments are not threaded. The racket 10 is configured so that it does not. In a particularly preferred embodiment, two vertical string holes 56 and two horizontal string holes 58 are formed in the inner peripheral wall 24 of the hoop 36, thereby each having a separate vertical string segment 50 and a separate horizontal string. The segment 52 is stretched. Thus, there are no string holes through which no vertical or horizontal string segments are passed. In other words, no two string segments are passed through a single string hole, and there are no spare, extra, or unused string holes. In other preferred embodiments, one or more string holes may be positioned to receive the vertical and horizontal string segments 50,52. In other preferred embodiments, two or more vertical string segments or two or more horizontal string segments may pass through a single string hole.

  2 and 3 show two conventional racket heads 18. In FIG. 2, for the string bed 14 having 16 vertical string segments 50 and 18 horizontal string segments 52, the head portion 18 is arranged so that the inner peripheral wall of the hoop 36 includes a sufficient number of string holes. Is formed. In this specification, the stringing pattern of the racket of FIG. 2 is referred to as a 16 × 18 stringing pattern. In FIG. 3, for the string bed 14 having 18 vertical string segments 50 and 20 horizontal string segments 52, the head portion 18 is arranged so that the inner peripheral wall of the hoop 36 includes a sufficient number of string holes. Is formed. In this specification, the stringing pattern of the racket of FIG. 3 is referred to as an 18 × 20 stringing pattern. Other stringing patterns such as 14X16, 16X19, 16X20, etc. can also be used advantageously. In conventional stringing patterns such as the stringing patterns of FIGS. 2 and 3, the number of horizontal strings is always greater than the number of vertical strings. In rare cases, the stringing pattern may have the same number of vertical and horizontal string segments. Such conventional stringing patterns have been considered necessary due to the non-circular shape of the string bed region and existing racket hoops, and the strength and durability of the racket strings and frames. Due to the non-circular shape of the conventional racket hoop, the maximum vertical length is generally longer than the maximum horizontal length. Therefore, the area or space for stretching the horizontal string is larger than the vertical string. In order to spread the racket tension throughout the head and the racket so that neither the head nor the racket string fails, the laterally extending side is more than the longitudinal string extending vertically. The string needs to be used for the head. Conventional racket designs teach teaching away from having the same number of vertical and horizontal string segments. This is because, according to such a design, an excessive load and stress can be applied to the racket string and the head part. Therefore, it is very difficult to stretch the string on the racket so as not to cause a racket failure or a string failure during play. This is because it becomes difficult. Thus, decades of racket design used a non-circular head or hoop shape and had more horizontal string segments than vertical string segments.

  FIGS. 4-6 show three separate racket heads 18, each according to three separate preferred embodiments of the present invention. In FIG. 4, the inner peripheral wall 24 of the hoop 36 of the head portion 18 has 32 vertical string holes and 30 horizontal strings for receiving 16 vertical string segments 50 and 15 horizontal string segments 52, respectively. And thus form a 16 × 15 stringed pattern. A pair of horizontal string holes 58 closest to the handle portion 20 of the racket 10 define the end points of the horizontal line 60 extending from the first side region 30 to the second side region 32. The second vertical length c is defined by the point where the horizontal line 60 intersects the vertical axis 16 and the end point on the handle portion 20 side in the section of the maximum vertical length a. The spacing between the horizontal string segments 52 in the string bed 14 is optimized so that the ratio of the maximum vertical length a to the second vertical length c is 6.5 or more (a / c ≧ 6.5). Yes. In a particularly preferred embodiment, the distance between the horizontal string segments 52 in the string bed 14 is such that the ratio of the maximum vertical length a to the second vertical length c is 7.5 or more (a / c ≧ 7.5). So that it is optimized. Although the figure shows a 16 × 15 stringed pattern, the scope of the present invention includes other “minus 1” stringed patterns such as 20 × 19, 18 × 17, 14 × 13, for example.

  In FIG. 5, the inner peripheral wall 24 of the hoop 36 of the head portion 18 has 32 vertical string holes and 28 horizontal strings for receiving 16 vertical string segments 50 and 14 horizontal string segments 52, respectively. And thus forms a 16 × 14 stringed pattern. Similar to the string tension pattern of FIG. 4, the distance between the horizontal string segments 52 in the string bed 14 is such that the ratio of the maximum vertical length a to the second vertical length c is 6.5 or more (a / c ≧ 6.5). ) Is optimized. In a particularly preferred embodiment, the distance between the horizontal string segments 52 in the string bed 14 is such that the ratio of the maximum vertical length a to the second vertical length c is 7.5 or more (a / c ≧ 7.5). So that it is optimized. Although the figure shows a 16 × 14 stringed pattern, the scope of the present invention includes other “minus 2” stringed patterns such as 20 × 18, 18 × 16, 14 × 12, for example.

  In FIG. 6, the inner peripheral wall 24 of the hoop 36 of the head portion 18 has 32 vertical string holes and 26 horizontal strings for receiving 16 vertical string segments 50 and 13 horizontal string segments 52, respectively. And therefore forms a 16 × 13 stringed pattern. Similar to the string tension pattern of FIG. 4, the distance between the horizontal string segments 52 in the string bed 14 is such that the ratio of the maximum vertical length a to the second vertical length c is 6.5 or more (a / c ≧ 6.5). ) Is optimized. In a particularly preferred embodiment, the distance between the horizontal string segments 52 in the string bed 14 is such that the ratio of the maximum vertical length a to the second vertical length c is 7.5 or more (a / c ≧ 7.5). So that it is optimized. Although the figure shows a 16X13 stringing pattern, the scope of the present invention includes other "minus 3" stringing patterns such as 20X17, 18X15, 14X11, for example. In still other preferred embodiments, stringing patterns of minus 4 or minus 5 or more may be used. Maintaining the string bed in the string bed plane throughout the string bed area, positioning the vertical and horizontal strings in approximately vertical and horizontal directions, respectively, using a non-circular head, and optimizing the string spacing (second By adjusting the characteristics of the racket, such as by optimizing the vertical length), a racket having fewer horizontal strings than the vertical string can be created without causing premature failure of the racket and string I understood it.

  The racket of the present invention can provide a number of significant advantages to the racket user. According to the racket of the present invention, the player can apply a higher spin to the ball than the conventional racket design, so that the player can apply a higher spin to the ball. Increase in spin ratio and increase in spin ratio. By using the racket of the present invention, characteristics such as the snapback (displacement and return) speed of the vertical string segment hitting the ball and the deflection of the vertical string can be greatly improved. According to the specific configuration of the racket of the present invention, such as the head size, the ratio of the longitudinal lengths a to c, the arrangement of the string holes, and the optimum spacing between the string segments, all the above-described characteristics can be improved. Increased snapback speed and increased string deflection allow the user to apply more spin to the ball, allowing the ball to swing faster and stronger to prevent the ball from exiting the court. You can hit the ball over the net. Furthermore, according to the racket of the present invention, a larger and more powerful sweet spot can be given to the racket and the player.

  From June 20, 2012 to July 6, 2012, the Wilson Sporting Goods Company at Wilson Innovation Center Spin Lab in Schiller Park, Illinois conducted a test using three racket models. The effect of the present invention was revealed. The Wilson Innovation Center Spin Lab used the Trackman (R) ball tracking system by Trackman A / S in Vedbaek, Denmark. Two of the racket models used were conventional models, and the third model was a Wilson® racket model Steam 99S with a 16 × 15 stringed pattern and other inventive features. . The first test racket is a racket model manufactured by Babolat VS in Lyon, France, Babolat (registered trademark) Pure Drive, which is an example of a conventional racket. The second test racket is a Wilson® racket, model Steam 99, manufactured by the Wilson Sporting Goods Company in Chicago, Illinois. Each of the three racquets was tensioned with 60 lbs of Luxilon® 4G polyester monofilament racquet string having a diameter of 1.25 mm. Each of the three rackets was painted white and all brand and model labels were removed.

Twenty-four players with different abilities struck 5-7 times with each of three different rackets. For each shot, three rackets were randomly exchanged. Each player was given one of the three rackets. For each shot, the player randomly received one of the three rackets, and continued until each player obtained 5-7 shot records using each racket. The data reduction method had the following requirements.
1. A shot must have a record of the amount of spin.
2. The ball must cross the net.
3. The length of the shot must be less than 88 feet.
4). The shot must land within ± 18 feet in the horizontal direction with respect to the center line.
5. In order to remove the frame hit ball, the ball speed must exceed 40 mph.
6). The player must have at least three hit records for each of the three rackets.

  The results of the player test using three rackets showed that the ball speed, ball spin, launch angle, trajectory height, and landing angle were greatly improved by the racket of the present invention compared to the two conventional racket models. (Table 1-1, Table 1-2). The racket of the present invention has improved the player's ability to spin the ball during the test, so the player can increase ball speed and ball spin to improve ball trajectory and launch angle. I was able to. As a result, the player can hit the ball stronger and faster and keep the ball playable and increase the trajectory length so that the ball is kept playable across the net. it can.

  Table 2 below is a set of flight predictions made by the Wilson Sporting Goods Company using the Wilson trajectory model for tennis balls. The calculation result of the Wilson trajectory model is consistent with the Doppler radar measurement result of the tennis ball after impact. This Wilson trajectory model represents a significant advantage that can be achieved by increasing the spin rate of the tennis ball after impact with the racket.

  Therefore, every time the spin amount applied to the tennis ball as a top spin increases by 100 rpm, the decrease in the distance traveled by the general ground stroke until the ball falls on the court is 6-12 depending on the speed of the ground stroke. It was seen in the range of inches.

  In FIG. 7, Wilson Sporting Goods Company also performed a tennis ball spin test using a spin test assembly 70. In this tennis ball spin test, the racket 10 is secured to the test fixture 72 by four spaced apart mounts 74 so that the plane defined by the string bed 76 is positioned at 30 degrees with respect to the horizontal direction. And fixed. The tennis ball 78 was fired from the ball launcher 80 toward the string bed 14 at a speed of 38 to 42 miles per hour from an angle of 50 degrees with respect to an axis perpendicular to the plane of the string bed. The ball and string bed were monitored by the high speed video system 82 at 5000 frames per second. Ball launcher 80 is configured to spin the ball as it exits the ball launcher. An example of such a device is the ATEC® Casey Pro 3G pitching device manufactured by the Athletic Training Equipment Company in Sparks, Nevada. The high speed video was positioned at one or more locations to allow optimal recording of tennis ball spin and / or string segment movement (deflection). In FIG. 7, the high speed video system is arranged in one place. In other suitable configurations, the video system may be located at other locations. As a result of the Wilson tennis ball spin test, the spin rate and spin ratio of the tennis ball after impact with the racket of the present invention were significantly improved as compared with other existing racket configurations.

  In FIG. 8, Wilson Sporting Goods Company also conducted a tennis ball displacement test using the displacement test assembly 100. In this tennis ball displacement test, the racket 10 is tested for testing by four spaced apart mounts 104 so that the plane defined by the string bed 106 is positioned 90 degrees (or vertical) with respect to the horizontal direction. It was firmly fixed to the fixture 102. The tennis ball 108 was fired from the ball launcher 110 toward the string bed 14 at a speed of about 60 feet per second from an angle of 45 degrees with respect to an axis perpendicular to the plane of the string bed. The ball and string bed were monitored by the high speed video system 82 at 5000 frames per second. The ball launcher 110 is preferably an air cannon. The high speed video was positioned at one or more locations to allow optimal recording of tennis ball spin and / or string segment movement (deflection). In FIG. 8, the high-speed video system is arranged in one place. In other suitable configurations, the video system may be located at one or more other locations. As a result of the Wilson tennis ball displacement test, a significant improvement was observed in the string deflection of the vertical string hit by the tennis ball and the snapback time and speed of the vertical string hit by the ball.

The Wilson tennis ball spin test and the Wilson displacement test were performed on four racket models. Three of the racket models are conventional models, and the fourth model is the head size 99in ² Wilson (R) racket model Steam 99 with a 16x15 string tension pattern and other features of the present invention. . The first test racket is a racket model manufactured by Babolat VS in Lyon, France, Babolat (registered trademark) Pure Drive, which is an example of a conventional racket. The second test racket is a racket model manufactured by Babolat VS in Lyon, France, Babolat (registered trademark) Aero Pro Drive, which is an example of a conventional racket. The third test racket is a model Steam 100, a head size 100 in ² Wilson® racket manufactured by Wilson Sporting Goods Company in Chicago, Illinois. Each of the four racquets was stretched with a 60 lb tension of a Luxilon® 4G polyester monofilament racquet string having a diameter of 1.25 mm.

  In the Wilson tennis ball spin test, the angular velocity of the fired tennis ball before hitting was about 1400 rpm. The rebound speed was 20-30 miles per hour. The bounce angle was 80 to 90 degrees (vertical direction or substantially vertical direction) with respect to the horizontal direction.

  The high-speed camera 82 may be positioned 3 feet from the racket fixture 72, perpendicular to the path of the ball 78, or positioned elsewhere to obtain the desired image for measurement. Good. The camera 82 was focused on the contact point (center of the string bed 14). In order to record as many ball positions as possible without degrading the video quality, the video was recorded at 5000 frames per second.

  In this study, a Wilson® US Open® tennis ball with a quadrant logo was used for tracking by the high-speed video analysis software TEMA. With this quadrant option, the position of the quadrant icon of the ball can be grasped, and the spin amount can be traced over the entire movement path of the ball. This data was transferred to an Excel template, which calculated the average speed and spin rate for the most stable part of the video. Six videos were recorded for each racket / string pattern.

The Wilson Tennis Ball Spin Test and the Wilson Displacement Test were also performed on a series of Wilson® Six One rackets that had the same frame and hoop shape and size (105 in ² ) as each other, but had different stringing patterns. It was. Each racket had 16 vertical string segments and a different number of horizontal string segments. These rackets comprise a planar string bed extending over the stringing area and vertical and horizontal string segments extending substantially in the vertical and horizontal directions, respectively. The spacing between strings was optimized. String deflection (Tables 3 and 4), snapback time (Table 5), snapback speed (Tables 6 and 7), and spin rate obtained from the Wilson tennis ball spin test for the Wilson Six One racket series (Table 8) is shown below.

  The test results in Tables 3-8 show significantly advantageous performance characteristics obtained with the racket of the present invention. Tables 3 and 4 show that the racket of the present invention having a smaller number of horizontal string segments deflects the vertical string segments more than a racket having a larger number of horizontal string segments. The deflection of the vertical string is a measure of the movement of the vertical string after impact with the tennis ball. The greater the deflection, the higher the string's ability to spin the ball. This test data indicates that, in a racket string having a string diameter of 1.25 to 1.55 mm, the string deflection of the vertical string segment in contact with the tennis ball in the Wilson spin test is 5 mm or more. Further, the string deflection may be 10 mm or more, and may be greater than 20 mm.

  The terms snapback time and snapback speed mean the time and speed of the vertical string segment when the vertical string segment returns from the maximum deflection position to the initial position before impact, respectively. Snapback time and speed are inversely proportional to each other. As the snapback time decreases, the snapback speed increases. Snapback time and speed can be used to assess the ability of a string bed and racket to spin a tennis ball. Tables 5-7 show that in the racket of the present invention in which the number of horizontal string segments was reduced, the snapback time was reduced overall and the snapback speed was significantly increased. The increased snapback speed makes it easier for the vertical string segments to snap back at least partially while the tennis ball is in contact with the string bed after impact. The higher the snapback speed, the more spin is applied to the ball by snapping back or returning the vertical string segment to the initial position. Test data shows that in a racket string with a string diameter of 1.45 to 1.55 mm, one or more vertical string segments in contact with the tennis ball produced a snapback speed of 1 meter per second or more. ing. Furthermore, the test data show that in a racket string with a string diameter of 1.25 to 1.38 mm, one or more vertical string segments in contact with the tennis ball produced a snapback speed of 2 meters per second or more. Is shown.

  Table 8 shows that the racket of the present invention has a higher spin ratio. Spin ratio is a measure of the spin of a tennis ball. The spin ratio is the ratio of the spin amount after the impact of the tennis ball with the tennis racket to the spin amount before the impact of the tennis ball with the tennis racket. The higher the spin ratio, the greater the spin on the ball. The test data shows that in a racket string having a string diameter of 1.25 to 1.55 mm, the ratio of the spin amount after hitting to the spin amount before hitting is 1.67 or more. Further, the test data shows that in a racket string having a string diameter of about 1.5 mm, the ratio of the spin amount after hitting to the spin amount before hitting is 1.8 or more.

With reference to FIGS. 9 to 11, it will be described that the sweet spot is enlarged by applying the present invention to a racket. 9-11 show the results of performing coefficient of restitution (COR) tests on three separate rackets. Each of the three rackets has a similar head and hoop shape and size. All three of the racquet has a hoop or head size of approximately 99in ^2. The shape of the three racket heads or hoops is a conventional, general, generally elliptical head shape.

  9 to 11 are map diagrams of regions of various COR values for the racket of the present invention and two conventional rackets. COR is the ratio of the rebound velocity of the ball to the incident velocity of the ball (eg tennis ball). The COR values in FIGS. 9-11 were measured at an incident velocity of 90 feet per second (± 5 feet per second). Each map shows the COR value obtained from the impact of the string bed and the ball at a number of dispersed positions in the string bed. Only the handle of the racket was supported by the test apparatus. More specifically, the test apparatus secured the proximal end of the handle (the approximately 6 inch portion proximal to the handle). By attaching the test device to the racket, the proximal end of the handle was prevented from moving or twisting in the direction of the x, y or z axis. Each racket of FIGS. 9-11 used a 16 gauge string tensioned to 55 pounds. The racket was evaluated for stringing at the approximate center of the string bed.

FIG. 9 shows the COR area for a racket having substantially the same frame as the racket of FIG. 10 except for the features of the present invention. The racket in FIG. 9 is a racket model, Babolat (registered trademark) Pure Drive, manufactured by Babolat VS in Lyon, France, and forms a conventional racket. The racket of FIG. 8 has a 16 × 19 stringing pattern. Table 9 shows the numerical values of the COR area of the racket mapped in FIG. The maximum COR value of the racket of FIG. 9 was 0.40, and the area of the 0.40 COR region was 7.29 in ² .

FIG. 10 shows the COR area of another conventional racket. This racket is a Wilson racket, model Steam 99, manufactured by Wilson Sporting Goods Company in Chicago, Illinois. This racket has substantially the same shape, head size, and weight as the racket of FIG. 11, and has the same shape, head size, and weight as the racket of FIG. The racket of FIG. 9 has a 16 × 18 stringing pattern. Table 9 shows the numerical values of the COR area of the racket mapped in FIG. The maximum COR value of the racket of FIG. 10 was 0.40, and the area of the 0.40 COR region was 7.58 in ² .

FIG. 11 shows an enlarged COR area in the racket of the present invention. The racket of FIG. 11 has a 16 × 15 stringing pattern and other inventive features. Table 9 also shows the numerical values of the COR area of the racket mapped in FIG. The maximum COR value of the racket in FIG. 11 was 0.45, and the area of the 0.40 COR region was 9.903 in ² .

  9 to 11, a curve displayed as 0.40 indicates a boundary line of a region on the string having a COR of 0.40 or more. The curve labeled 0.35 shows the boundary line of the region on the string where the COR was 0.35 or higher. Similarly, the other curves in FIGS. 9-11 show the boundary lines of the regions on the string corresponding to various COR values. In FIG. 11, the curve displayed as 0.45 shows the boundary line of the area on the string where the COR is 0.45 or more. A racket “sweet spot” is generally defined as an area within a string bed having one of the following COR values: 0.25 or more, 0.30 or more, or 0.35 or more. The numbers on the horizontal and vertical axes in FIGS. 9 to 11 represent the distance from the center of the string tension surface. For example, the center of the string tension surface is expressed as 0.00. The position 2 inches to the right of the center of the stringing surface is written as 2.00, and the position 2 inches to the left of the center is written as -2.00.

  Table 9 below summarizes the COR data of FIGS.

  The comparison of FIGS. 9 to 11 and the data in Table 9 show that the racket of the present invention has a significantly larger “sweet spot” than either conventional racket of FIGS. 9 and 10. In the racket of the present invention shown in FIG. 11, the area is enlarged in regions within the boundary lines of various COR values, and a higher COR value (0.45) is obtained. In the 0.40 COR region, the improvement in the sweet spot region is very significant, increasing by more than 31%.

  According to the present invention, the performance of a racket can be greatly improved by improving the player's ability to spin the ball and increasing the size of the racquet's sweet spot. According to the present invention, the sweet spot of the racket is enlarged, the deflection of the vertical string is increased, the snapback time is decreased, the snapback speed of the vertical string is increased, and the “dwell time” is increased. In addition, the moment of inertia of the racket head does not increase and the maneuverability of the racket does not deteriorate.

  Although preferred embodiments of the invention have been described and illustrated herein, those skilled in the art will appreciate numerous other configurations. Therefore, the present invention is not limited to the above-described one, and the scope is defined only by the description of the scope of claims.

Claims (23)

In a tennis racket used with a string bed formed by alternately braiding a plurality of vertical string segments with a plurality of horizontal string segments,
A frame that extends along the longitudinal axis and includes a head portion connected to the handle portion;
The head portion includes a hoop having an inner peripheral wall and an outer peripheral wall,
The hoop defines the head size of the racket,
The head size is 93 to 120 in ² and has a maximum vertical length a and a maximum horizontal length b.
The maximum vertical length a is not less than 1.2 times the maximum horizontal length b,
The inner peripheral wall includes a plurality of horizontal string holes and a plurality of vertical string holes,
Each of the horizontal string holes is configured to receive one end of the horizontal string segment, and each of the vertical string holes is configured to receive one end of the vertical string segment;
A racket wherein the number of vertical string holes is greater than the number of horizontal string holes, whereby the string bed used with the racket has more vertical string segments than the horizontal string segments.   The racket according to claim 1, wherein the maximum vertical length a is 1.25 or more of the maximum horizontal length b.   The inner peripheral wall defines four or more vertical string holes more than the horizontal string holes, whereby the string bed used with the racket is two or more more vertical than the horizontal string segments. The racquet of claim 1, comprising string segments.   The inner peripheral wall defines six or more vertical string holes more than the horizontal string holes so that the string bed used with the racket is three or more more vertical than the horizontal string segments. The racquet of claim 1, comprising string segments. A pair of the lateral string holes closest to the handle portion of the racket define a horizontal line;
The racket according to claim 1, wherein a ratio of the maximum vertical length a to a vertical distance c from the bottom of the hoop to the horizontal line is 6.5 or more.   The racket according to claim 5, wherein a ratio of the maximum vertical length a to a vertical distance c from the bottom of the hoop to the horizontal line is 7.5 or more.   The racket according to claim 1, wherein the frame is formed of a fiber composite material. The racket according to claim 1, wherein the head size is 98 to 115 in ² . In tennis racket,
A frame that extends along the longitudinal axis and includes a head portion connected to the handle portion;
A string bed connected to the head of the racket;
With
The head portion includes a hoop having an inner peripheral wall and an outer peripheral wall,
The hoop defines a head size having a maximum vertical length a and a maximum horizontal length b;
The maximum vertical length a is not less than 1.2 times the maximum horizontal length b,
The inner peripheral wall includes a plurality of string holes,
The string bed includes a plurality of vertical string segments and a plurality of horizontal string segments interwoven with the plurality of vertical string segments,
Each of the lateral string segments extends laterally from one of the string holes to the other of the string holes;
Each of the vertical string segments extends substantially vertically from one of the string holes to the other of the string holes;
The horizontal string segment closest to the handle portion and the end point on the handle portion side in the section of the maximum vertical length a define a second vertical length c,
A ratio of the maximum vertical length a to the second vertical length c is 6.5 or more;
The racquet wherein the string bed has one or more vertical string segments than the horizontal string segments. The racket according to claim 9, wherein the head size is 93 to 120 in ² . The racket according to claim 9, wherein the head size is 98 to 115 in ² .   The racket according to claim 9, wherein the maximum vertical length a is 1.25 or more of the maximum horizontal length b.   The racket of claim 9, wherein the string bed has two or more vertical string segments than the horizontal string segments.   10. A racket according to claim 9, wherein the string bed has three or more more vertical string segments than the horizontal string segments. A pair of the lateral string holes closest to the handle portion of the racket define a horizontal line;
The racket according to claim 9, wherein a ratio of the maximum vertical length a to a vertical distance c from the bottom of the hoop to the horizontal line is 6.5 or more.   The racket according to claim 9, wherein a ratio of the maximum vertical length a to the second vertical length c is 7.5 or more.   The racket according to claim 9, wherein the frame is formed of a fiber composite material. The frame further includes a throat portion disposed between the head portion and the handle portion,
The head portion includes an upper region and first and second lateral regions,
The frame further includes a yoke connected to the first and second lateral regions and extending between the first and second lateral regions, whereby the upper region, the first and second regions The racquet of claim 9, wherein two side regions and the yoke define the hoop.   The racket according to claim 18, wherein the string bed does not extend to the handle portion side beyond the yoke.   The racket according to claim 9, wherein the string bed is formed of a monofilament racket string made of polyester.   The racquet of claim 9, wherein at least one of the string holes includes at least two string segments.   The racket of claim 9, wherein each of the string holes includes only one of the horizontal string segments or only one of the vertical string segments.   The racquet of claim 9, wherein each of the string holes includes one or more of the string segments.