JPH07178205A - Racket - Google Patents

Abstract

PURPOSE:To improve the spin and repulsion properties in the case where a ball is hit in the central part of a gut surface by delineating respectively plural regions in the specific positions in the major axis and minor axis direction of the gut surface and respectively specifying the ratios of the respective mean lengths of the meshes in these regions. CONSTITUTION:The first and secondary boundary lines P1, P2 are set in the respective positions of 1/15 and 2/5 of the overall length L of the major axis Y on both sides of the major axis Y from the central point O of the gut surface 4 to delineate the first and second regions A1, A2, of the major axis Y. The ratio 11/12 between the respective mean values 1, 12 of the lengths in the major axis Y direction of the meshes M formed at the intersected points of the respective gut K, J in the respective directions of the major axis Y and the minor axis X in the respective regions A1, A2 is specified to 1.2 to 2.0. Further, the third and fourth boundary lines P3, P4 are set in the respective positions of 1/ 5 and 2/ 5 of the overall length W on both sides of the minor axis X. The ratio m1/m2 between the respective mean values m1, m2 of the lengths in the minor axis X direction of the meshes M in third and fourth regions B1, B2 delineated by these lines is set at 1.2 to 2.0.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a racket in which a gut such as a tennis racket, a badminton racket, and a squash racket is stretched and used, and in particular, a rebound when hit at a central portion including a sweet spot on the gut surface of the racket. The present invention relates to an improvement in the feel and shot feeling, and an improvement in control performance when hit at the periphery of the gut surface.

[0002]

2. Description of the Related Art Generally, in a racket such as a tennis racket, the way to stretch the gut (gut pattern) is such that the closer to the center of the face (gut face) on which the gut is stretched, the closer the gap between the adjacent guts is ( (Kaisho 61-4665),
At any position on the gut surface, the force (surface pressure) required to give a constant displacement in the direction perpendicular to the gut surface (out-of-plane direction) is set to be substantially constant.

[0003]

When the surface pressure distribution on the gut surface is almost constant, the gut density is high and the surface pressure is high at the central part of the gut surface, so that the gat surface is hit at the central part. In this case, the amount of deformation of the gut is small, the friction between the gut and the ball is small, and it is difficult to impart spin to the ball. Further, in the central portion of the gut surface, as described above, the surface pressure is high, so that sufficient resilience performance cannot be obtained. Here, if the tension of the gut is stretched loosely in order to improve the spin performance when hitting the ball in the center of the gut surface and improve the resilience performance, the surface pressure of the gut surface is almost constant, so The surface pressure will also be low, and the overall control performance will be poor.

The present invention has been made in order to solve the problems in the conventional racket as described above, and spins the ball when hit at the center of the gut surface including the sweet spot. The purpose of this is to improve the resilience and control performance when hitting the ball on the periphery of the gut surface.

[0005]

Therefore, according to the present invention, the first boundary lines are set at positions of 2/15 of the total length in the long axis direction on both sides in the long axis direction from the center point of the gut surface. The central portion of the gut surface sandwiched between the 1 boundary lines is defined as the first region in the long axis direction, and the total length in the long axis direction from the center point is 2 in the long axis direction.
A second boundary line is set at a position of / 5, and a region sandwiched between the first boundary line and the second boundary line is defined as a second region in the long axis direction, and a gut in the long axis direction in the first region in the long axis direction is set. The ratio of the average value of the lengths of the meshes formed by the intersections of the guts in the short axis direction in the major axis direction to the average value of the lengths of the meshes in the major axis direction in the second region in the major axis direction is 1.2. Set to ~ 2.0, and
A third boundary line is set on both sides in the minor axis direction from the center point of the gut surface at a position of ⅕ of the entire length in the minor axis direction, and the central portion of the gut surface sandwiched between the third boundary lines is the minor axis. The second boundary is set as the first area in the direction, and the fourth boundary line is set on both sides of the entire length in the short axis direction from the center point at a position of 2/5 of the entire length in the short axis direction, and is sandwiched between the third boundary line and the fourth boundary line. The region defined as the second region in the short axis direction,
The ratio of the average value of the short-axis direction length of the mesh in the short-axis direction first region to the average value of the short-axis direction length of the mesh in the short-axis direction second region is 1.2 to 2. The racket is characterized by being set to 0.

The racket of the present invention having the above structure is
The surface pressure decreases as it approaches the central part of the gut surface and increases as it approaches the peripheral part.Therefore, when the ball is hit at the central part of the gut surface, the amount of deformation of the gut is large and the friction between the gut and the ball is large. It is sufficient, spin is easily applied to the ball, and sufficient resilience performance is obtained. Further, since the racket of the present invention has a high surface pressure in the peripheral portion of the gut surface as described above, the control performance when hitting in the peripheral portion of the gut surface is improved.

[0007]

[Examples] As a result of various experiments and researches, the present inventor easily spins the ball when hit at the center of the gut surface, and has sufficient resilience performance when hit at the center of the gut surface. We have found a gut pattern that improves the control performance when hitting at the periphery of the gut surface.

FIGS. 1 and 2 show a racket according to the present invention having the above-mentioned gut pattern. This racket 1
Then, in the plurality of gut holes provided in the gut tension portion 2a of the frame 2, the gut J in the short axis X direction and the gut K in the long axis Y direction are provided.
Is stretched to form the gut surface 4. This gut side 4
Then, the adjacent short axis X direction Gut J and the adjacent long axis Y
The gut K in the direction forms a plurality of rectangular meshes M having a length 1 in the major axis Y direction and a length m in the minor axis X direction.

As shown in FIG. 1, from the center point O of the gut surface 4, which is the intersection of the short axis X and the long axis Y, to both sides in the long axis Y direction.
First boundary lines P1 and P1 parallel to the short axis X are set at positions of 2/15 of the total length L in the long axis Y direction.
The central portion 4a of the racket sandwiched between P1 is defined as the long-axis direction first area A1. Also, the total length L from the center point O in the major axis Y direction
Second boundary lines P2, P2 parallel to the short axis X at a position of 2/5 of
Is set, and the region sandwiched between the first boundary line P1 and the second boundary line P2 is defined as the long-axis direction second region A2. The length axially mean l ₁ of the long axis Y direction length of the mesh M in the first region A1, the long axial average length of the long axis Y direction of the mesh M in the second region A2 l ₂ And the ratio (l ₁ / l ₂ ) to 1.2 is set to 1.2 or more and 2.0 or less. That is, in the racket 1 according to the present invention, 1.2 ≦ l ₁ / l ₂ ≦ 2.0.

Further, as shown in FIG. 2, on both sides of the gut surface 4 in the short axis X direction from the center point O, a third portion parallel to the long axis Y is provided at a position of ⅕ of the total length W in the short axis X direction. The boundary lines P3 and P3 are set, and the central portion 4a of the racket sandwiched between the third boundary lines P3 and P3 is defined as the short-axis direction first region B1. In addition, the long axis Y is located at a position of 2/5 of the total length W in the short axis X direction from the center point O
The fourth boundary lines P4 and P4 parallel to the third boundary line P
A region sandwiched between the third boundary line P4 and the fourth boundary line P4 is defined as a second region B2 in the short axis direction. Then, the average value m ₁ of the lengths of the meshes M in the minor axis X direction in the minor axis direction first region B1 and the average value m ₁ of the lengths of the meshes M in the minor axis direction X in the minor axis direction second region B2. The ratio with ₂ (m ₁ / m ₂ ) is set to 1.2 or more and 2.0 or less. That is, in the racket 1 according to the present invention,
1.2 ≦ m ₁ / m ₂ ≦ 2.0.

Further, in this racket 1, the length l in the major axis direction and the length m in the minor axis direction of the mesh M are largest at the central portion 4a of the gut surface 4 and gradually increase toward the peripheral portion 4b. It is set to be small.

In the racket 1 of the present invention having such a gut pattern, the surface pressure of the central portion 4a of the gut surface 4 is low, and the surface pressure becomes high as it approaches the peripheral portion 4b. for that reason,
In this racket 1, when the ball is hit at the central portion 4a of the gut surface, the surface pressure of this portion is lower than that of the peripheral portion 4b of the gut surface, so the amount of change in the gut J and K is large. Therefore, when hitting the ball in the central portion 4a, it is easy to spin the ball and the resilience is also good. On the other hand, when a ball is hit at the peripheral portion 4b of the gut surface, the surface pressure at this portion is higher than that at the central portion 4b of the gut surface.
The control performance when hitting with b is improved.

3 and 4 show a first embodiment of the present invention. The racket 1A according to the first embodiment is a tennis racket, and is used with a gut stretched on the gut tension portion 2a of the frame 2.

In the first embodiment, the gut tension portion 2a of the frame 2 is provided with guts J ₁ , J ₂ , ... J ₂₀ , J ₂₁ in the short axis X direction.
The horizontal for string holes _{a 1, a 2 ... a 20} , a 21 and _{b 1, b 2 ... b 20} , b 21 for tensioning are provided. Here, lateral gut holes a ₁ , a ₂ ... A ₂₀ , a ₂₁ and lateral gut holes b ₁ , b ₂ ... b
Of the holes ₂₀ and b ₂₁ , holes having the same subscripts face each other in the direction of the short axis X, and one gut J ₁ , J ₂ ... J ₁₅ , J ₂₁ is inserted therethrough.

Furthermore, the gut tension section 2a of the frame 2, the major axis Y direction gut _{K 1, K 2, ... K} 15, vertical-string holes c ₁ for tensioning the K _16, c ₂ ... c ₁₅ , c ₁₆ and d ₁ , d ₂ ... d ₁₅ , d ₁₆ are provided. Here, the vertical gut holes c ₁ , c ₂ ... C ₁₅ , c ₁₆ and the vertical gut holes d ₁ , d ₂ ... d
Of the holes ₁₅ and d ₁₆ , the holes with the same subscripts face each other in the major axis direction, and one gut K ₁ , K _2, ... K ₁₅ , K ₁₆ is inserted therethrough.

The stretched guts J ₁ , J _2, ... J ₂₀ , J ₂₁ ,
The total length W of the gut surface 4 formed by K ₁ , K ₂ ... K ₁₅ , K _{16 in} the short axis X direction is 240 mm, and the total length L in the long axis Y direction is 320.
mm.

In this racket 1A, the distance between the end 4c of the gut surface 4 on the side of the top portion 2b and the gut J ₁ , the distance between adjacent guts J ₁ , J ₂ ... J ₂₀ , J ₂₁ in the minor axis direction, and The lateral gut holes a ₁ , a ₂ ... A ₂₀ , a ₂₁ and b ₁ , so that the distance between the gut J ₂₁ and the end 4d of the gut surface 4 on the side of the yoke portion 2c becomes the distance shown in Table 1, respectively. b ₂ ... b ₂₀ , b ₂₁
Are arranged.

[0018]

[Table 1]

Further, in this racket 1A, the gut surface 4
Between the left end 4e of the and the gut K ₁ , the adjacent major axis Y
Direction Gut K ₁ , K ₂ ... K ₁₅ , K ₁₆ distance, Gut K
The vertical gut holes c ₁ , c ₂ ... C ₁₅ , so that the distance between ₁₆ and the right end 4f of the gut surface 4 becomes the distance shown in Table 2 below.
c ₁₆ and d ₁ , d _2, ... D ₁₅ , d ₁₆ are arranged.

[0020]

[Table 2]

Therefore, in the first embodiment, the first boundary lines P1 and P1 are set at positions of 2 / 15L on both sides in the major axis Y direction from the center point O of the gut surface 4, and the first boundary lines P1 and P1 are set. The area sandwiched between the two is defined as the first area A1 in the major axis direction, and the second boundary line P is located at a position of 2 / 5L on both sides in the major axis Y direction from the center point O.
2 and P2 are set, and a region sandwiched between the first boundary line P1 and the second boundary line P2 is defined as a long axis direction second region A2, the long axis direction Y direction of the mesh M in the long axis direction first region A1 The average length l ₁ and the mesh M in the long-axis direction second region A2
The ratio (l ₁ / l ₂ ) to the average value l ₂ of the lengths in the major axis Y direction is 1.38.

Further, the third boundary lines P3, P3 are set at positions of ⅕ W from the center point O of the gut surface 4 to both sides in the short axis X direction, and the portions sandwiched by the third boundary lines P3, P3. Is defined as the first region B1 in the short axis direction, and the fourth boundary lines P4 and P4 are set at positions of 2/5 W from the center point O to both sides in the short axis X direction.
When the region sandwiched between the boundary line P3 and the fourth boundary line P4 is defined as the short-axis direction second region B2, the average value m ₁ of the length of the mesh M in the short-axis direction first region B1 in the short axis X direction, The ratio (m ₁ / m ₂ ) to the average value m ₂ of the length of the mesh M in the minor axis direction second region B2 in the minor axis X direction is 1.44.

Further, in this embodiment, the length l in the major axis direction and the length m in the minor axis direction of the mesh M are set to be smaller stepwise from the central portion 4a to the peripheral portion 4b.

Since the racket 1A of this embodiment has the gut pattern as described above, the central portion 4a of the gut surface 4 is
Surface pressure is low, while the surface pressure of the peripheral portion 4b is high. Figure 5
Racket 1A of the first embodiment measured by the measuring device of (A)
The surface pressure of is shown in FIGS. 6 and 7.

In FIG. 5 (A), 10 is a universal compression / tensile tester in which a cylindrical jig 12 having a diameter of 22 mm is attached to the tip of a load frame 11 which moves vertically. In the racket 1A, the gut stretched portions 2a of the frame 2 are fixed on the fixed base 13 at eight places.

The load frame 11 is moved downward in the drawing, the jig 12 is pressed against the gut surface 4, and the reaction force value of the gut surface 4 is detected by the load cell 14. The detected reaction force value and the displacement of the jig 12 from the state of contacting the gut surface 4 with a reaction force of 0 are input to the XY printer 16 via the controller 15, and as shown in FIG. , The horizontal axis is the displacement and the vertical axis is the reaction force.

FIG. 6 shows the surface pressure (gut surface 4) when the distance from the tip 4c on the side of the top portion 2b on the major axis Y is changed.
Shows the reaction force when the is displaced by 5 mm. At this time, the gut pulled up the warp yarn with 551b and the weft yarn with 441b.
Further, FIG. 7 shows the surface pressure when the distance from the left end portion 4e of the gut surface 4 on the short axis X is made different.

As is apparent from FIG. 6, in the racket 1A of the embodiment, the surface pressure at the central portion 4a of the gut surface 4 is as low as about 12.5 kg, whereas the end portion 4c on the top portion 2b side is low. The surface pressure is as high as about 180 kg near the side and near the end 4d on the side of the yoke portion 2c.

As is clear from FIG. 7, in the racket 1A of the first embodiment, the surface pressure of the central portion 4a of the gut surface 4 is about 12.5 kg, whereas the left end of the gut surface 4 is In the vicinity of the portion 4e and the right end portion 4f, the surface pressure is as high as about 80 kg.

As described above, in the racket 1A of the embodiment, the surface pressure at the central portion 4a of the gut surface is low, and the surface pressure becomes higher toward the peripheral portion 4b. Therefore, in this racket 1A, when hitting at the center of the gut surface, the surface pressure is lower than that of the peripheral portion 4b of the gut surface 4.
Since the amount of deformation is large, the resilience is good and the ball can be spinned relatively easily.
Further, when hitting at the peripheral portion 4b of the gut surface 4, the contact pressure is higher than that of the central portion 4b of the gut surface 4, so that the contract performance can be improved.

[0031]

Experimental Example An experiment was conducted to confirm the effect of the present invention. As a comparative example, a conventional racket 1B (Dunlop DP-80 manufactured by Sumitomo Rubber Industries, Ltd.) shown in FIG. 8 was prepared.

This racket 1B has guts J ₁ , J ₂ ... J ₁₈ , J ₁₉ in the short axis X direction and guts K ₁ , K _{2 in the} long axis Y direction.
K ₁₅ and K ₁₆ are stretched, and the total length W of the gut surface 4 in the short axis X direction is 240 mm, and the total length L in the long axis X direction is 320 mm.

In this racket 1B, the gap between the end 4c of the gut surface 4 on the top portion 2b side and the gut J ₁ , the gap between adjacent guts J ₁ , J ₂ ... J ₁₈ , J ₁₉ in the minor axis direction, and The distance between the gut J ₁₉ and the end 4d of the gut surface 4 on the side of the yoke portion 2c is set to the distance shown in Table 3.

[0034]

[Table 3]

In this racket 1B, the gut surface 4
Left end portions 4c and the distance between the gut K ₁ of gut K ₁ of the adjacent longitudinally, K ₂ ... K _15, the distance between K _16, gut K ₁₆
The distance between the right end 4d of the gut surface 4 is set to the distance shown in Table 4 below.

[0036]

[Table 4]

In this comparative example, the first boundary lines P1 and P1 are located at positions of 2 / 15L from the center point O of the gut surface 4 in the long axis Y direction, and 2 are located from the center point O in the long axis Y direction. /
The second boundary lines P2 and P2 are set at the position of 15L, and the region sandwiched by the first boundary lines P1 and P1 is defined as the first region A in the major axis direction.
1. If the region sandwiched between the first boundary line P1 and the second boundary line P2 is the long-axis direction second region A2, the long-axis direction first region A1
Ratio of the average value l ₁ of the lengths of the mesh M in the major axis Y direction to the average value l ₂ of the lengths of the mesh M in the major axis Y direction in the major area second region A2 (l ₁ / l ₂ ) is 0.63.

Further, the third boundary lines P3 and P3 are located at positions of 1/5 W from the center point O of the gut surface 4 to both sides in the short axis X direction, and are located at positions of 2/5 W from the center point O to both sides in the short axis X direction. The fourth boundary lines P4 and P4 are set to the third boundary lines P3 and P3, and the region sandwiched between the third boundary lines P3 and P3 is defined as the first region B1 in the minor axis direction, and the region sandwiched between the third boundary line P3 and the fourth boundary line P4. Minor axis direction second area B2
Then, the average value m ₁ of the lengths of the meshes M in the minor axis direction in the minor axis direction first region B1 and the minor axis direction second region B
The ratio (m ₁ / m ₂ ) to the average value m ₂ of the length of the mesh M in the direction of the short axis X in _{No. 2} is 0.74.

The surface pressure of the racket 1B of the comparative example is shown in FIG.
The results measured by the device shown in (A) are as shown in FIGS. 9 and 10. As shown in FIGS. 9 and 10, in the racket 1B of the comparative example, the surface pressures of the central portion 4a and the peripheral portion 4b of the gut surface 4 are substantially the same and have a uniform surface pressure distribution.

In this experiment, 17 top-level amateur players used the racket 1A of the example and the racket 1B of the comparative example to make 20 balls for each of the central portion 4a of the gut surface 4 and the peripheral portion 4b of the gut surface. Hitting ~ 30 balls, resilience, controllability, impact when hit,
Regarding shot feeling and spin performance, "normal", "good",
A three-level evaluation of "bad" was performed. Nylon gut is used as the gut, and the warp yarn is 551b and the weft yarn is 441b.
Laid in.

The number of people who evaluated each item in Tables 5 and 6 below is shown. From Table 5, the racket 1A of the example is compared with the racket 1B of the comparative example, and when hit at the central portion 4a of the gut surface 4, the racket 1 of the comparative example.
It can be confirmed that the resilience performance is better than that of B and that the spin tends to be applied well. Further, it can be confirmed from Table 6 that the control performance is higher than that of the comparative example when the ball is hit at the peripheral portion 4b of the gut surface 4.

[0042]

[Table 5]

[0043]

[Table 6]

A repulsion test was conducted on the racket 1A of the example and the racket 1C of the comparative example. In this repulsion test, as shown in FIG. 11, the hard tennis ball 20 having an initial velocity V ₀ collides against the gut surface 4 of the racket 1A of the example and the racket 1B of the comparative example, and the velocity of the tennis ball 20 bounced back. Vr was measured. In this case, the coefficient of restitution is represented by the following equation (1).

(Repulsion coefficient) = Vr / V ₀ (1)

The results of the repulsion test are shown in FIG. As is clear from FIG. 12, it can be confirmed that the racket 1A of the example has better resilience performance than the racket 1B of the comparative example when hitting near the central portion 4a of the gut surface 4.

[0047]

As is apparent from the above description, in the racket according to the present invention, the first boundary line is located on both sides in the major axis direction from the center point of the gut surface and at a position of 2/15 of the total length in the major axis direction. Is set, the central portion of the racket sandwiched between the first boundary lines is defined as the first region in the long axis direction, and the second boundary line is set at a position of ⅕ of the total length in the long axis direction from the center point. When the region sandwiched between the first boundary line and the second boundary line is the second region in the long axis direction, the mesh formed by the intersection of the gut in the long axis direction and the gut in the short axis direction in the first region in the long axis direction The ratio of the average length value in the long axis direction to the average length value in the long axis direction of the mesh in the second region in the long axis direction is 1.2 or more and 2.0 or less. Further, in the racket of the present invention, the third boundary line is set on both sides in the short axis direction from the center point of the gut surface at a position of ⅕ of the entire length in the short axis direction, and the third boundary line is sandwiched between the third boundary lines. The central part of the racket is defined as the first region in the short axis direction, and the fourth boundary line is set at a position ⅕ of the total length in the short axis direction from the center point, and is sandwiched between the third boundary line and the fourth boundary line. When the region is defined as the second region in the short axis direction, the average value of the length in the short axis direction of the mesh in the first region in the short axis direction and the length in the short axis direction of the mesh in the second region in the short axis direction The ratio to the average value is 1.2 or more 2.
It is set to 0 or less. Therefore, in the racket of the present invention,
The surface pressure at the central part of the gut surface is low, while the surface pressure becomes higher toward the periphery. Therefore, when a ball is hit at the center of the gut surface, the friction between the gut and the ball is large due to the large amount of deformation of the gut due to the low surface pressure at this part, and it is relatively easy to spin the ball. In addition to being able to do, the resilience performance is also good.

On the other hand, when the ball is hit at the peripheral portion of the gut surface, the surface pressure of this portion is higher than the surface pressure at the central portion, so that the resilience performance and the spin performance at the time of hitting the central portion are maintained, It is possible to improve control performance when hitting a ball in the peripheral portion.

[Brief description of drawings]

FIG. 1 is a partial plan view showing a racket of the present invention.

FIG. 2 is a partial plan view showing a racket of the present invention.

FIG. 3 is a partial plan view showing the racket of the embodiment.

FIG. 4 is a partial plan view showing the racket of the embodiment.

FIG. 5A is a schematic view showing a surface pressure measuring device,
(B) is a schematic diagram showing the output of the XY recorder.

FIG. 6 is a graph showing the relationship between the surface pressure and the distance from the top of the racket of the example.

FIG. 7 is a graph showing the relationship between the surface pressure and the distance from the left end of the racket of the example.

FIG. 8 is a partial front view showing a racket of a comparative example.

FIG. 9 is a graph showing the relationship between the surface pressure and the distance from the top of the racket of the comparative example.

FIG. 10 is a graph showing the relationship between the surface pressure and the distance from the left end of the racket of the comparative example.

FIG. 11 is a schematic view showing a method of a repulsion test.

FIG. 12 is a diagram showing the results of a repulsion test.

[Explanation of symbols]

 1,1A, 1B Racket 2 Frame 2a Gut tension part A1 Long axis direction first area A2 Long axis direction second area B1 Short axis direction first area B2 Short axis direction second area J, K Gut M Mesh P Boundary line X short axis Y long axis

Claims (1)

[Claims] 1. The total length (L) in the major axis (Y) direction is 2 on both sides of the gut surface (4) in the major axis (Y) direction from the center point (O).
The first boundary line (P1) is set at the position of / 15, and the central portion (4) of the gut surface (4) sandwiched by the first boundary line (P1) is set.
a) is the first region (A1) in the long axis direction and the center point
Set the second boundary line (P2) at a position of 2/5 of the total length (L) in the major axis (Y) direction on both sides of the major axis (Y) direction from (O),
A region sandwiched between the first boundary line (P1) and the second boundary line (P2) is defined as a long-axis direction second region (A2), and the long-axis (Y) direction in the long-axis direction first region (A1) is defined. The average value (l ₁ ) of the lengths in the major axis (Y) direction of the mesh (M) formed by the intersections of the gut (K) and the gut (J) in the minor axis (X) direction and the major axis direction The ratio (l ₁ / l ₂ ) to the average value (l ₂ ) of the lengths of the mesh (M) in the long axis (Y) direction in the two regions (A2) is set to 1.2 to 2.0,
Also, a third boundary line (P3) is provided on both sides in the minor axis (X) direction from the center point (O) of the gut surface (4) at a position ⅕ of the total length (W) in the minor axis (X) direction. The central portion (4a) of the gut surface (4) sandwiched between the third boundary lines (P3) is set to the first in the minor axis direction.
Along with the area (B1), 2 / of the total length (W) in the short axis (X) direction from the center point (O) to the short axis (X) direction
The fourth boundary line (P4) is set at the position of 5, and the region sandwiched between the third boundary line (P3) and the fourth boundary line (P4) is defined as the second region (B2) in the minor axis direction. The average value (m ₁ ) of the lengths of the meshes (M) in the minor axis (X) direction in the direction first region (B1) and the minor axis (M1) of the meshes (M) in the minor axis direction second region (B2) ( The ratio (m ₁ / m ₂ ) to the average value (m ₂ ) of the length in the X direction is 1.2 to
A racket characterized by being set to 2.0.