JP2014128414A - Tennis ball - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an unpressurized tennis ball that has a good hitting feeling and that can obtain the hitting feeling akin to a hitting feeling of a pressurized tennis ball.SOLUTION: In a tennis ball, a hollow part of a core is filled with a filler that is formed of a resin foam, and a difference between return hardness and hardness is 0.1 inch or less.

Description

  The present invention relates to a non-pressurized tennis ball in which a core is filled with a filler made of a resin foam.

  As a tennis ball, a ball having a core having a hollow part and a felt covered with the core is generally used. Usually, the core is formed into a spherical shape with rubber or the like, the felt is formed in a substantially bowl shape, and two felts are bonded to the core with an adhesive.

  Furthermore, as a tennis ball, the internal pressure of the ball is set to be higher than the atmospheric pressure and a repulsive force is applied to the pressure ball (pressured ball). By increasing the thickness, there is a non-pressurized ball (non-pressure ball) to which a repulsive force is applied, and the pressurized ball is said to have a better feel.

Conventionally, a tennis ball of Patent Document 1 has been proposed as a tennis ball having the same comfort as a pressurized ball and having a performance of maintaining bounce characteristics equivalent to a non-pressurized ball. The tennis ball of Patent Document 1 is a tennis ball including an elastomeric polyurethane foam having a density of 250 to 800 kg / m ³ , the foam is covered with a fiber material, the foam is an aromatic polyisocyanate, and a maximum of 0.03 meq / g. It is produced by reacting with a polyol containing at least 60% by weight of a polyol having the degree of unsaturation and using a foaming agent.

JP 2012-228534 A

  However, the tennis ball of Patent Document 1 has a hit feeling that does not reach the pressurized ball.

  The present invention has been made in view of the above circumstances, and is a non-pressurized tennis ball in which a hollow portion of a core is filled with a filler made of a resin foam, which has a good hit feeling and is close to a press ball. An object is to provide a tennis ball that can be obtained.

  In order to achieve the above object, the present invention is a non-pressurized tennis ball comprising a core having a hollow portion and a felt coated on the core, and formed by a resin foam in the hollow portion of the core A tennis ball is provided, wherein the difference between the return hardness and the hardness is 0.1 inch or less.

  In the tennis ball of the present invention, the hollow portion of the core is filled with a filler formed of a resin foam, and the difference between the return hardness and the hardness (the value obtained by subtracting the hardness from the return hardness) is 0.1 inch or less. Therefore, it is possible to obtain a hit feeling close to that of a pressurized ball. On the other hand, when the difference between the return hardness and the hardness exceeds 0.1 inch, the feel at impact becomes worse. The hardness and return hardness in the present invention refer to hardness and return hardness measured by a method in accordance with the test regulations of the International Tennis Federation (ITF). For tennis balls, the return hardness is greater than the hardness.

  In the present invention, the tennis ball may have the following configuration.

  (A) The filler is a single sphere formed of a resin foam, and the inner surface of the core and the outer surface of the filler are in contact with each other. According to this configuration, the filler is a single sphere, and the inner surface of the core and the outer surface of the filler are in contact with each other. And the like does not cause heat to adversely affect the ball performance, or generate a sound and impair the hitting sound. In addition, since the filler has a simple shape of a single sphere, the filler can be easily manufactured when the previously prepared filler is put into the core and the core is molded. Furthermore, since the filler has a simple shape of a single sphere, the filler can be easily produced by placing a foam material in the core and foaming the foam material. When a plurality of parts are joined to produce the single spherical filler, the filler is also included in the range of the single spherical filler.

(B) The density of the filler is 30 to 200 kg / m ³ . According to this configuration, it is possible to obtain a hit feeling closer to that of the pressurized ball. On the other hand, when the density of the filler is less than 30 kg / m ³ , the resilience performance and hardness of the ball become insufficient, and the performance as a ball may be deteriorated. When the density of the filler exceeds 200 kg / m ³ , the weight of the ball becomes too large, and the performance as a ball may be deteriorated. In addition, the structure whose density of a filler is 30-200 kg / m < ³ > is employ | adopted especially suitably, when a filler is formed with materials other than a polyurethane foam.

(C) The core is made of rubber, the filler is made of polyurethane foam, and the density of the filler is 50 to 100 kg / m ³ . According to this configuration, it is possible to obtain a hit feeling closer to that of the pressurized ball. On the other hand, when the density of the filler is less than 50 kg / m ³ , the resilience performance and hardness of the ball become insufficient, and the performance as a ball may be deteriorated. When the density of the filler exceeds 100 kg / m ³ , the weight of the ball becomes too large, and the performance as a ball may be deteriorated.

  (D) The rebound resilience of the filler is 40 to 80%. According to this configuration, it is possible to obtain a hit feeling closer to that of the pressurized ball. On the other hand, when the impact resilience of the filler is less than 40% or more than 80%, the feel of a tennis ball may be lowered. The rebound resilience is a value expressed in% of the height of the upper end that is rebounded for the first time by matching the upper end of the filler to a height of 80 cm and dropping it on a horizontal floor surface.

  (E) The filler has a two-layer structure having an outer layer and an inner layer, and the inner layer has a higher hardness than the outer layer. According to this configuration, the manner in which the tennis ball is crushed differs depending on the strength of the hit ball, and a hit feeling closer to that of the pressurized ball can be obtained.

  (F) The filler has a two-layer structure having an outer layer and an inner layer, and the outer layer has a higher hardness than the inner layer. According to this configuration, the manner in which the tennis ball is crushed differs depending on the strength of the hit ball, and a hit feeling closer to that of the pressurized ball can be obtained.

  (G) The filler has a hollow portion inside. According to this configuration, the manner in which the tennis ball is crushed differs depending on the strength of the hit ball, and a hit feeling closer to that of the pressurized ball can be obtained.

  Further, in the present invention, the filler has a two-layer structure having an outer layer and an inner layer, the inner layer has a higher hardness than the outer layer, or the outer layer has a higher hardness than the inner layer, and further has an inner structure. It can be set as the structure which has a hollow part. According to this configuration, it is possible to obtain a hit feeling closer to that of the pressurized ball.

  The non-pressurized tennis ball of the present invention has a good hit feeling and can obtain a hit feeling close to that of a pressurized ball.

  Hereinafter, the present invention will be described in more detail.

  The tennis ball of the present invention has a core having a hollow portion and a felt covered with the core. In this case, the core can be formed of rubber such as natural rubber or polybutadiene rubber, injection-moldable thermoplastic resin, or the like. Also, as felt, woven felt or needle felt can be used. Woven felt is obtained by fluffing the surface of a woven fabric, and is produced by raising and shrinking raw material. Needle felt is a non-woven fabric with a fluffed surface, and is produced by performing needle processing on a raw material dough.

  In the tennis ball of the present invention, the hollow portion of the core is filled with a filler formed of a resin foam. In this case, the type of the resin foam is not limited, but examples include foams made of polyurethane, polystyrene, polyethylene, polypropylene, phenol resin, polyvinyl chloride, urea resin, silicone resin, polyimide, melamine resin, and the like. it can.

  The filler of the present invention can be produced by a known method using the materials described above. The tennis ball of the present invention is prepared by, for example, preparing two core-forming half shells and a separately prepared filler, bonding the two half shells with the filler inside, and vulcanizing them. Thus, the core can be manufactured. In addition, the tennis ball of the present invention is provided with two half shells for forming a core, and two half shells are bonded together with one or both of the half shells for forming a core in a state where a foam material is put, and this is vulcanized. By doing so, the core can also be manufactured. During the vulcanization, the foam material is heated to foam, and as a result, a filler made of a resin foam is filled into the core. Thereafter, the core is covered with felt.

  In the tennis ball of the present invention, the pressure of the gas in the core is set to the same level as the atmospheric pressure.

(Preparation of filler sample)
Single spherical filler samples A to F shown in Table 1 were produced by a known method.

The weight, density, rebound resilience, and hardness of samples A to F were measured. The methods for measuring density, impact resilience, and hardness are as follows. The results are shown in Table 1.
Density: The density was calculated as a sphere with a diameter of 5 cm.
-Rebound resilience: The upper end of the single spherical filler was adjusted to a height of 80 cm, dropped on a horizontal floor surface, and the height of the upper end that bounced for the first time was displayed in%.
Hardness: The stress when a test block having a thickness of 100 mm was compressed to 25% of the total thickness with a disk having a diameter of 200 mm was determined.

(Production of tennis ball)
Tennis balls 1 to 9 shown in Table 2 were produced. The cores of tennis balls 1-9 were made of rubber, and the cores of tennis balls 1-7 were made of the same rubber. Further, in the tennis ball filled with the filler, the inner surface of the core and the outer surface of the filler were brought into contact with each other.
Non-pressurized tennis balls 1 to 6 filled with a filler: Two half shells were bonded together in a state where the filler samples A to F were put in a hollow portion, and vulcanized to obtain a core. After that, a tennis ball was manufactured by covering the core with felt.
Pressurized tennis ball 7 filled with a filler: Two half shells were bonded together in a state where the filler sample B was put in a hollow portion, and this was vulcanized to obtain a core. In this case, the core pressure was increased by molding the core in a pressurized atmosphere. After that, a tennis ball was manufactured by covering the core with felt.
Pressurized tennis ball 8 without filler: two half shells were bonded together and vulcanized to obtain a core. In this case, the core pressure was increased by molding the core in a pressurized atmosphere. After that, a tennis ball was manufactured by covering the core with felt.
Non-pressurized tennis ball 9 without filler: two half shells were bonded together and vulcanized to obtain a core. After that, a tennis ball was manufactured by covering the core with felt.

  The mass, outer diameter, hardness, return hardness, and rebound of tennis balls 1 to 9 were measured by a method in accordance with the test regulations of the International Tennis Federation (ITF). The results are shown in Table 2.

(Considerations regarding fillers and tennis balls)
From the results of Tables 1 and 2, the following was found.
(A) Since the core of the tennis ball in the present embodiment is made of rubber and the filler is made of polyurethane foam, the density of the filler is preferably 50 to 100 kg / m ³ . In this respect, since the density of the filler sample A is 30 kg / m ³ , the tennis ball 1 using the filler sample A has a hardness difference of more than 0.1 inch and a small rebound. Further, since the density of the filler material sample D is 110 kg / m ³ , the tennis ball 4 using the filler material sample D has an excessively large ball weight and a small rebound.
(A) Tennis balls 2, 3, 5, 6, and 7 using filler samples B, C, E, and F having a density in the range of 50 to 100 kg / m ³ have appropriate ball weights and are rebounded. Was found to be large. In addition, when the core is made of rubber and the filler is made of polyurethane foam, it is a knowledge obtained from various experiments that the density of the filler is preferably 50 to 100 kg / m ^3. In the examples, some of the experimental results are shown.
(C) Although the density of the filler sample F having a hollow portion is relatively large, it was found that the mass of the entire filler is appropriate because of the hollow portion, the ball weight is appropriate, and the rebound is increased. . In addition, in the filler in this invention, you may provide a hollow part in the filler of two or more layers multilayer structure.
(D) Although the rebound is preferably 140 cm or more, the tennis ball 9 which is a conventional normal non-pressurized ball has a rebound of 139 cm, and is difficult to hit.

(Evaluation of actual hitting of tennis balls)
The actual hit evaluation of tennis balls 1 to 9 was performed. As a result, the non-pressurized tennis ball of the present invention filled with the filler had a better hit feeling than the non-pressurized tennis ball not filled with the filler, and was close to the pressurized tennis ball. In addition, the non-pressurized tennis ball of the present invention filled with a filler generates heat when the fillers come into contact with each other in the core or the filler and the inner surface of the core come into contact with each other. There was no adverse effect or sound was generated and the hitting sound did not deteriorate.

Claims (8)

  A non-pressurized tennis ball comprising a core having a hollow portion and a felt coated on the core, the hollow portion of the core being filled with a filler formed of a resin foam, A tennis ball having a difference from hardness of 0.1 inch or less.   The tennis ball according to claim 1, wherein the filler is a single sphere formed of a resin foam, and an inner surface of the core is in contact with an outer surface of the filler. The tennis ball according to claim 1, wherein the density of the filler is 30 to 200 kg / m ³ . The core according to any one of claims 1 to 3, wherein the core is made of rubber, the filler is made of polyurethane foam, and the density of the filler is 50 to 100 kg / m ³ . Tennis ball.   The tennis ball according to claim 1, wherein a rebound resilience of the filler is 40 to 80%.   The tennis ball according to any one of claims 1 to 5, wherein the filler has a two-layer structure having an outer layer and an inner layer, and the inner layer has a higher hardness than the outer layer.   The tennis ball according to any one of claims 1 to 5, wherein the filler has a two-layer structure including an outer layer and an inner layer, and the outer layer has a higher hardness than the inner layer.   The tennis ball according to claim 1, wherein the filler has a hollow portion therein.