JPH08150227A - Tennis racket gut - Google Patents

Abstract

PURPOSE: To provide tennis racket gut made from a synthetic resin which has good resiliency and hitting feeling similar to natural gut. CONSTITUTION: In gut 1 for tennis racket made from a synthetic resin 2, spring constant is 25 to 90kg at the total load range of 20 to 30kg of a stress-strain curve and a variation of spring constant against load is 0 to -4kg/cm/kg in the tensile test using a sample of 40mm in length.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tennis racket gut, and more particularly, to improving the flight and feel of a synthetic fiber tennis racket gut used in a tennis racket.

[0002]

2. Description of the Related Art As a gut for a tennis racket, there is provided a gut (natural gut) obtained by applying a proper amount of twist to animal muscles such as intestines of cattle and sheep and whale muscles and coating them with a resin. Although this natural gut has good resilience, ball flight, shot feeling, etc., it has low durability and water resistance and is expensive.

On the other hand, various synthetic fiber gut (synthetic gut) is provided. This synthetic gut is
Durability and water resistance are good and it is cheap, but balls fly,
Since the shot feeling and the like are inferior to those of natural gut, various attempts have been made to obtain properties as close as possible to natural gut.

Conventionally, natural gut has excellent properties because the stress-strain curve obtained by a tensile test is linear and the stress "0" (origin) is higher than that of a synthetic gut.
It was believed to be due to the high initial spring constant near the rise from. Therefore, in order to approach the characteristics of natural gut, a synthetic gut having high elasticity and high strength using aramid fiber or the like has been proposed.

[0005]

Generally, the tension when a gut is stretched on a tennis racket is 18 to 31 kg (4
According to the spring constant-load diagram of the natural gut shown in FIG. 7 and the commercially available synthetic gut shown in FIG. 7 (the sample length is 40 mm), the spring of the natural gut in this load range. The constant is about 60 kg / cm, whereas the spring constant of the synthetic gut is 70 to 150 kg.
The spring constant of the synthetic gut is larger than that of the natural gut.

As shown in FIG. 8, the load-strain curve of a nylon fiber gut, which is the most general synthetic gut, has a straight line portion a rising from a load "0", a yield state b, and a load axis. The curve point c is concave to the straight line portion d, and the curve portion e is concave to the strain axis to reach the breaking point f. In the conventional synthetic gut, in the load-strain diagram, the curved portion c which is concave with respect to the load axis is the above 18 to 3
The load range was 1 kg (40 lb to 70 lb). That is, as shown in FIG. 8 and FIG. 7 described above, the spring constant of the synthetic gut tends to increase in the above load range. On the other hand, the spring constant of the natural gut in this load range is almost constant (gradient of change is almost “0”) as shown in FIG.

High spring constant in synthetic gut,
Also, the tendency that the spring constant tends to increase causes the feel at impact to be hard, which is a factor far from the characteristics of the natural gut. In this way, the conventional synthetic gut has different elastic properties from the natural gut in the load range corresponding to when it is stretched on the racket.
I could not get a soft feel at impact.

On the other hand, the present inventor has conducted various experiments,
As a result of the research, in the load range of 18 kg to 31 kg (40 to 70 lb) corresponding to the tension applied to the racket, the spring constant is small and the spring constant tends to be constant or decrease (the above-mentioned figure In the load-strain diagram of Fig. 8, it was found that the synthetic gut having the above-mentioned load range from the straight line portion d to the curved portion e) has the same characteristics as the natural gut.

In addition, the present inventor also found from the following molecular and physical considerations that the linear portion d of the load-strain curve shown in FIG.
Therefore, it was found that when the curve portion e is in the above load range, a synthetic gut having characteristics closer to those of the natural gut can be obtained as compared with the case where the straight portion a to the curve portion c is in the above load range. First, in the case of rubber, the load-strain curve can be quantitatively explained by considering the entropy of the network formed by chain molecules. This is
The main factor of the resistance to deformation of rubber is the realization of the so-called maximum entropy state under thermal vibration, that is, the tendency of the molecules of the amorphous part to adopt a random structure (resistance to external force) It is a thing.

On the other hand, the fiber is composed of a crystalline portion and an amorphous portion. It is not the crystalline part that has a great influence on the physical properties of the fiber, but rather the amorphous part, but the much larger part of the crystalline material than rubber hinders the movement of the chain molecule segment, It can be said that Young's modulus is higher than rubber. Furthermore, in fibers, secondary bond forces such as van der Waals forces and hydrogen bonds are also involved, and between the entropic force that the molecule tries to shrink and the internal energy force that is based on the attraction between the molecules. It seems that a kind of balance is maintained. In the straight line portion a of the load-strain curve of the fiber, the amorphous portion first extends, and the crystalline portion extends only about 10% of the amorphous portion. As the fiber stretches, the crystalline portion antagonizes the stretch, and the inertial force acts entropically. However, the effect of entropy is still small, and the internal energetic attraction is much larger. Generally, the initial elastic modulus is in this range.

In the range from the yield state b to the curved portion c, the segment of the chain molecule is deformed so much that the random network structure begins to be strongly oriented and the linear portion d to the curved portion e has an entropic inertia. The effects of both power and energetic attraction are manifested. A larger chain-shaped segment flow occurs in the middle of the curved portion e, and finally breaks. Thus, it is in the first half of the straight line portion d to the curved line portion e that the fiber exhibits entropic elasticity like rubber, and in this portion, the synthetic gut has characteristics similar to those of the natural gut.

In view of the above points, the present invention solves the problems of the conventional synthetic gut, and provides a synthetic fiber racket gut having characteristics such as good ball flight close to natural gut and soft shot feeling. It is made for the purpose of providing.

[0013]

Accordingly, the present invention provides a racket gut made of synthetic fiber, having a sample length of 4
20 to 30 of load-strain diagram in 0 mm tensile test
The spring constant is 25 to 9 in the entire load range of kg.
The present invention provides a racket gut characterized in that the inclination of the change of the spring constant with respect to the load is 0 to -4 kg / cm / kg.

[0014]

In the racket gut according to the present invention, the spring constant is set to the load constant in the entire load range of 20 to 30 kg of the load-strain curve, that is, the load range corresponding to the tension applied to the racket. The spring constant is 25 to 90 kg / cm, which is almost the same as the natural gut in the range, and the slope of the change of the spring constant with respect to the load in this load range is 0 to -4 kg / cm, which is almost the same as that of the natural gut.
Since it is set to / kg, jumping when hitting the ball,
The soft shot feeling and the coefficient of restitution are almost the same as those of the natural gut, and the ball can be hit with the same feeling as when using the natural gut.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the embodiments shown in the drawings. A racket gut 1 (hereinafter, simply referred to as “gut”) made of synthetic fiber according to the embodiment shown in FIG. 1 is a tennis racket gut having a fiber thickness of 3
~ 3000 denier, elastic modulus about 200 ~ 1000
It has a multi-filament structure in which about 3 to 2000 fibers 2 of kg / mm ² are twisted together and bonded and coated with a resin. This fiber 2 is a fiber made of a polyamide resin such as nylon 6 or nylon 66. The twist pitch of the fibers 2 is set to 3 to 40 mm / turn, but in some cases, the fibers are simply aligned without twisting.
Furthermore, the draw ratio of the heat drawing described below is 0% to 50%.

In this embodiment, by adjusting the fiber thickness of the fiber 2, the elastic modulus, the amount of fibers to be twisted (the amount of fibers used), the pitch of twist when twisting the fibers, the stretch ratio of the gut, etc. Corresponding to the case where the sample is stretched and used, the spring constant in the load range of 20 to 30 kg (40 to 70 lb) of the load-strain curve in the tensile test with a sample length of 40 mm and the slope of the change of the spring constant with respect to the load are shown below. Is set to the range.

First, in this embodiment, the spring constant in the entire load range is set to 25 to 90 kg / cm, and the spring constant of the natural gut in the same load range (about 60 kg / cm).
cm) is set close to it. That is, in this embodiment, the loads are 20 kg, 22 kg, 24 kg, 26 kg,
The spring constants measured at 6 points of 28 kg and 30 kg are all 2
It is set within the range of 5 kg / cm to 90 kg / cm. The upper limit of the spring constant is 90 kg / c as described above.
The reason why m is set is that, as described above, when the spring constant is large, the shot feeling becomes hard and becomes a factor that is far from the characteristics of the natural gut. Further, the lower limit of the spring constant is set to 25 kg / cm as described above. If the spring constant is too small, the durability as a gut and the shot feeling when hitting the ball by adjusting the racket are lost. This is because if the spring constant is obtained, sufficient durability and shot feeling can be obtained.

Further, in this embodiment, the inclination of the change of the spring constant with respect to the load is -4 kg in the entire load range.
/ Cm / kg to 0 kg / cm / kg, the slope of the change in the spring constant of the natural gut in the same load range (about 0 k
g / cm / kg). That is,
In this embodiment, a load of 20 kg to 22 kg and a load of 22 kg
-24kg, load 24kg-26, 26kg-28k
g, the gradient of the change of the spring constant in the 5 sections of 28 kg to 30 kg is set within the range of 0 to -4. The upper limit of the slope of the change of the spring constant with respect to the load is set to "0" as described above, because the spring constant of the natural gut in the same load range is almost constant (the slope of the change of the spring constant as described above). Is almost "0"). on the other hand,
The lower limit of the slope of the change of the spring constant with respect to the load is set to -4 kg / cm / kg as described above, when the tendency of the spring constant to decrease is too large, the durability as a gut and when hitting the ball by adjusting the racket There is no feel at impact, but if the slope of the change of the spring constant is about this level, sufficient durability,
This is because a soft shot feeling can be obtained.

The gut 1 of this embodiment corresponds to the tension when the tennis racket is stretched and used as described above.
Since the spring constant and the inclination of the change of the spring constant with respect to the load in the entire load range of 31 kg (40 to 70 lb) are close to those of the natural gut, when the tennis ball is stretched and the tennis ball is hit, the natural You can get the same resilience, ball flight, and soft shot feeling as a gut. In addition, since the gut 1 of this example is made of synthetic fiber, it has excellent durability and water resistance as compared with natural gut,
And it is cheap.

The gut 1 according to the above embodiment is manufactured by a known method as follows. First, fibers in pellet form are spun and drawn to form filaments. Next, two or more filaments are aligned or twisted with a twisting machine and adhered and coated with an adhesive. Further, heat drawing is performed to improve the strength.

The present invention is not limited to the above embodiment, and various modifications can be made as long as the spring constant in the above load range and the inclination of change in the spring constant are within the above range. For example, the fibers forming the gut are not limited to polyamide resins such as nylon 6 and nylon 66, and may be synthetic fibers such as polyvinylidene and modified nylon. Further, the above adhesive is not limited to nylon 6 and various other adhesives such as nylon and urethane can be used.

Experimental Example An experiment was conducted to confirm the effect of the present invention. As an experimental example, five kinds of nylon 6 gut (Experimental Example 1 to Experimental Example 5) according to the present invention were prepared. The thickness of the fiber, the elastic modulus of the fiber, the total amount of the fiber used for the gut, the pitch of the twist, and the draw ratio in each experimental example were set within the range of the above-described examples as shown in Table 1 below, and 2
The spring constant in the entire load range of 0 kg to 30 kg (40 lb to 70 lb) is set to 25 to 90 kg / cm, and the slope of the change of the spring constant with respect to the load is set to the range of 0 to -4. The spring constant-strain curve and the load-strain curve of Experimental Example 1 to Experimental Example 5 are as shown in FIGS. 2 and 3, respectively.

In this experiment, guts of Comparative Examples 1 to 5 shown in Table 1 below were prepared. Comparative Example 1 is a comparative example corresponding to Experimental Example 5, the fiber thickness, the fiber elastic modulus, the amount of fibers used, and the pitch of twist are the same as those in the fifth experimental example, but the draw ratio is 25%. As a result, the spring constant in the above load range is set to 75 to 150 kg / cm, and the inclination of the spring constant is set to 2.1 to 5.4 kg / cm / kg by making it different from Experimental example 5 (stretching ratio 0%). Both the constant and the slope of the change of the spring constant with respect to the load are set outside the scope of the present invention.

Comparative Example 2 is a Comparative Example corresponding to Experimental Example 1, the fiber thickness, the amount of fibers used, the twist pitch and the draw ratio are the same as those of the first Experimental Example, but the elastic modulus of the fiber is by varying the experimental example 1 (elastic modulus of the fiber is about 300 kg / mm ²⁾ as approximately 500kg / mm ^2, 77~114kg the spring constant in the load range / cm, the inclination of the spring constant 1.1 .About.2.6 kg / cm / kg, both the spring constant and the slope of the change of the spring constant with respect to the load are set outside the range of the present invention.

Comparative Example 3 is a comparative example corresponding to Experimental Example 4, in which the thickness of the fiber, the elastic modulus of the fiber, the pitch of the twist, and the draw ratio are the same as those in Experimental Example 4, but the amount of fiber used is 75
The spring constant in the above load range is set to 17 to 20 kg / cm, which is outside the range of the present invention, by setting the denier to be 60 denier and different from the fourth experimental example (8820 denier used). However, the slope of the change of the spring constant with respect to the load in the above load range in Comparative Example 3 is 0 to -0.7.
And is within the scope of the present invention.

The comparative example 4 is a comparative example corresponding to the experimental example 3. The fiber thickness, the elastic modulus of the fiber, the pitch of the twist, and the draw ratio are the same as those of the experimental example 3, but the amount of fiber used is 75
By setting the denier to be different from that of Experimental Example 3 (fiber material 8820 denier used), the inclination of the change of the spring constant with respect to the load in the above load range is set to -3.9 to -4.7, which is outside the range of the present invention. are doing. However, Comparative Example 4
The spring constant in the above load range is 34 to 77 k
g / cm, which is within the scope of the present invention.

Comparative Example 5 is a Comparative Example corresponding to Experimental Example 5, the fiber thickness, the fiber elastic modulus, the twist pitch and the draw ratio are the same as those in Experimental Example 5, but the amount of fiber used is 11
Experimental Example 5 (10080 denier) as 340 denier
The spring constant in the above load range is 82 to 94 kg / cm, and the inclination of the spring constant is 0 to 12.5.
Both the spring constant and the slope of the change in the spring constant with respect to the load are set as kg / cm / kg outside the range of the present invention. The spring constant-load curve and the load-strain curve of Comparative Example 1 to Comparative Example 5 are as shown in FIGS. 4 and 5, respectively.

[0028]

[Table 1]

In the present experiment, the above-mentioned Experimental Examples 1 to 5 and Comparative Examples 1 to 5 were examined by a feeling test to see if they had a ball flying, a shot feeling, and a feeling close to that of a natural gut. In addition, the coefficient of restitution was measured for Experimental Examples 1 to 5 and Comparative Examples 1 to 5. In addition to the above Comparative Examples 1 to 5, a natural gut (VS ALL made by BABOLAT is used.
The feeling test and the coefficient of restitution were also measured for SEASON).

In the above-mentioned feeling test such as flight of the ball, the guts of each of the experimental examples and the comparative examples were used as tennis rackets (D
27 kg (60 l) of warp threads in UNLOP PRO-70)
b), tensioned with 21.6 kg (48 lb) of weft, 110
We made some amateur top players actually hit a tennis ball, and totaled the number of people who answered "good" about the flight of the ball.

On the other hand, the restitution coefficient is measured as shown in FIG. 6 by a tennis racket 5 in which a gut is stretched with the above tension.
Was held vertically, the tennis ball 6 was made to collide with the ball striking surface at a constant velocity V ₁ , and the velocity V ₂ of the bounced tennis ball 6 was measured. The coefficient of restitution is the ratio of the speeds V ₁ and V ₂ (V ₂ / V ₁ ). It indicates that the larger the coefficient of restitution (V ₂ / V ₁ ) is, the better the flight of the ball is.

The results of the above-mentioned feeling tennis and the measurement of the coefficient of restitution are shown in Table 2. In Table 2, in the column of whether the ball is flying, feel at impact, and feeling close to natural gut, ◎ means “more than 90 out of 110” is “good”.
○: 70 to 89 out of 110 people answered “good”, Δ: 50 to 69 out of 110 people answered “good”, ×: 50 out of 110 people Less than indicates that the answer is "good".

[0033]

[Table 2]

As shown in Table 2 above, the flying and hit feelings of the balls of Experimental Examples 1 to 5 are Comparative Examples 1 to 5 respectively.
It is more favorable, and it can be confirmed that by setting the spring constant and the inclination of the change of the spring constant with respect to the load as in the present invention, the flight of the ball and the feel at impact are improved. In addition, as shown in Table 2 above, the shot feeling of Experimental Examples 1 to 5 has a feeling closer to that of natural gut than Comparative Examples 1 to 5, and the spring constant and the change of the spring constant with respect to the load are different. It can be confirmed that if the inclination is set as in the present invention, a feeling close to that of natural gut can be obtained. Further, regarding the coefficient of restitution (V ₂ / V ₁ ), as shown in Table 2, the natural gut is 0.432, whereas in Experimental Examples 1 to 5, 0.423 to 0.433, Comparative Example 1
From Comparative Example 5, it can be confirmed that the gut of the present invention has a coefficient of restitution similar to that of the natural gut, which is 0.419 to 0.421.

[0035]

As is apparent from the above description, the racket gut according to the present invention has a load-strain curve of 20 to 3 inclusive.
In the load range of 0 kg, that is, in the whole range of the load range corresponding to the tension applied to the racket, the spring constant is set to 25 to 90 kg / cm, which is almost the same as the spring constant of the natural gut in this load range, and Since the inclination of the change of the spring constant with respect to the load in the load range is set to 0 to -4 kg / cm / kg, which is almost the same as that of the natural gut,
The flight, the soft shot feeling, and the coefficient of restitution when hitting a ball are almost the same as those of the natural gut, and the ball can be hit with the same feeling as when the natural gut is used.

The racket gut according to the present invention is
Since it is made of synthetic fiber, it has excellent durability and water resistance and is inexpensive.

[Brief description of drawings]

FIG. 1 is a schematic perspective view showing a racket gut according to an embodiment of the present invention.

FIG. 2 is a diagram showing a relationship between a spring constant and a load of the racket gut in Experimental Examples 1 to 5.

FIG. 3 is a diagram showing the relationship between the load and strain of the racket gut in Experimental Examples 1 to 5.

FIG. 4 is a diagram showing the relationship between the spring constant and the load of the racket gut of Comparative Examples 1 to 5.

5 is a diagram showing the relationship between the load and strain of the racket gut of Comparative Examples 1 to 5. FIG.

FIG. 6 is a schematic diagram for explaining a coefficient of restitution.

FIG. 7 is a diagram showing a relationship between a spring constant and a load of a natural gut and a conventional synthetic gut.

FIG. 8 is a diagram showing a relationship between a load and a strain of a nylon fiber gut.

[Explanation of symbols]

 1 racket gut 2 fiber 5 tennis racket 6 tennis ball

Claims (1)

[Claims] 1. A gauze for a racket made of synthetic fiber, wherein the load-strain curve in a tensile test with a sample length of 40 mm covers the entire range of a load range of 20 to 30 kg.
The spring constant is 25 to 90 kg / cm, and the slope of the change of the spring constant with respect to the load is 0 to -4 kg / cm / kg.
A gut for a tennis racket characterized by being.