JP4382572B2 - Durability shuttlecock and method of manufacturing the same - Google Patents

Description

  The present invention relates to a shuttlecock used in badminton competitions. More specifically, the present invention relates to a shuttlecock in which durability of the blade is improved in a shuttlecock configured using natural feathers. The present invention also relates to a method for manufacturing the shuttlecock.

  As shown in FIG. 2, the shuttlecock is composed of a hitting head 21 and a skirt portion 26 implanted therein. The hitting head 21 is formed of a natural cork, PVC, polyurethane, polyolefin, or the like, and is usually covered with synthetic leather. The skirt portion 26 is formed by implanting a plurality of blades 24 of waterfowl and land birds with the blade shaft 23 in the head 21 for impact so that the blade portion 22 forms a skirt shape. Further, the blades 24 are connected to each other by a thread 25.

  Instead of using the natural waterfowl and landbird feathers described above, a skirt formed of a synthetic resin, such as nylon, in a skirt shape approximating the aerodynamic characteristics of natural feathers was implanted in the head for impact. A shuttlecock is also known.

  Here, the shuttlecock is required to have performance such as flight stability, in particular, flight distance and flight trajectory uniformity. In this respect, a shuttlecock configured using natural blades is the best. Therefore, it is widely used including official matches.

  However, a shuttlecock using natural blades has a drawback of poor durability although it has very good flight characteristics. Natural feathers are susceptible to humidity and temperature and are more likely to break when dried. Particularly in winter when the humidity is low and the temperature is low, the blades are deprived of moisture and become brittle, and the blades are damaged or the blade shaft is easily broken.

  Further, natural feathers are subjected to a bleaching treatment for removing attached dirt as a pretreatment before being implanted in the head for impact. Such a bleaching process makes the blades more susceptible to the influence of humidity and temperature as described above, and easily breaks.

  In JP-A-2003-199857, for the purpose of preventing the blade from drying and maintaining the durability, a moisture retaining film formed on the surface of the blade by an oil or a surfactant coating process is provided. A shuttlecock is disclosed.

JP 2003-199857 A

  An object of the present invention is to provide a shuttlecock that can prevent the blades from drying over a long period of time and maintain durability. Another object of the present invention is to provide a method for manufacturing the shuttlecock.

  As a result of intensive studies, the present inventors treated the blade surface with at least one compound selected from amino acids, amino acid derivatives, and polyamino acids, or salts thereof, thereby making the blades hygroscopic. The present inventors have found that the durability of the shuttlecock can be improved, and the present invention has been achieved.

  The present invention relates to a shuttlecock configured using bird feathers, wherein the surface of the feather is treated with at least one compound selected from amino acids, amino acid derivatives, and polyamino acids, or salts thereof. There is a shuttlecock.

  The present invention provides at least one compound selected from amino acids, amino acid derivatives, and polyamino acids, or salts thereof in an aqueous medium on the surface of a shuttlecock blade constituted by bird feathers. This is a method for manufacturing a shuttlecock for applying a surface treatment by applying a treatment liquid.

  According to the present invention, when the surface of a natural blade is treated with at least one compound selected from amino acids, amino acid derivatives, and polyamino acids, or salts thereof, each of the compounds becomes a natural blade. Therefore, the shuttlecock is provided with moisture absorption and moisture retention properties, and is resistant to changes in humidity and temperature, particularly drying, and has excellent durability. At the same time, the texture and feel of the blade is improved by the action of the treated compound.

An embodiment of the present invention will be described with reference to FIG.
FIG. 1 is a schematic configuration diagram of an example of a shuttlecock according to the present invention.

  In the shuttlecock 10 of the present invention, a skirt portion 16 is implanted in the head 11 for hitting.

  The blade | wing 14 which comprises the skirt part 16 is a natural water bird or a land bird's feather | wing.

  The blade 14 is formed by implanting the blade shaft 13 in the head 11 for impact so that the blade portion 12 forms a skirt shape. In addition, the blades 14 are stabilized by being connected to each other by a thread 15 on the blade shaft 13.

  The surface of each blade 14 constituting the shuttlecock 10 is treated with at least one compound selected from amino acids, amino acid derivatives, and polyamino acids, or salts thereof. The surface of the blade 14 composed of the blade portion 12 and the blade shaft 13 may be entirely covered with a moisturizing film formed by the compound coating process. Moreover, the moisture retention film of the said compound may be formed in a part of surface.

  Next, amino acids, amino acid derivatives, polyamino acids, or salts thereof used for the surface treatment will be described.

  Amino acids include glycine, alanine, valine, leucine, isoleucine, serine, threonine, aspartic acid, glutamic acid, lysine, hydroxylysine, arginine, phenylalanine, tyrosine, histidine, tryptophan, proline, oxyproline, ortinin, etc. In addition to α-amino acids, β-amino acids such as β-alanine and β-aminobutyric acid, which are non-protein amino acids, γ-amino acids such as γ-aminobutyric acid and carcinine, and δ-amino acids such as δ-aminyl levulinic acid are used. be able to.

As the amino acid derivative, a compound in which a part of the amino group of the amino acid is substituted can be used.
The amino group substituent is not particularly limited as long as it does not impair the water-solubility of the amino acid, but is usually an alkyl group, alkoxyalkyl group, hydroxyalkyl group, cyanoalkyl group, acyl group, aryl group, polyalkylene oxide group, alkyl group. Examples include ether polyalkylene oxide groups.
Specific examples include N, N-dimethylglycine, N-methylglycine, N, N-bishydroxyethylglycine, N-methylalanine and the like.

As other amino acid derivatives, the general formulas RCH (NH ₂ ) CO—, RCH (NH ₂ ) CO ₂ ¹⁻ , RCH (NH ₂ ) CONH ₂ , RCH (NH ₂ ) CH ₂ OH, RCH (NH ₂ ) CHO, A compound represented by RCH (CO ₂ H) NH— can also be used.

The polyamino acid used in the present invention consists of a polypeptide obtained by dehydration condensation of the above amino acid and / or amino acid derivative. The α-amino acid may be an optical isomer or a racemate. A modified body such as a derivative or a soluble cross-linked body can also be used.
Polyamino acids and polypeptides obtained by decomposing natural proteins can also be used. For example, a hydrolyzed silk protein can be mentioned.
Among polyamino acids, the lower the molecular weight, the higher the hygroscopicity and moisture retention. On the other hand, the higher the molecular weight, the better the texture of the blade.

  Examples of the amino acid, amino acid derivative, and polyamino acid salt include metal salts such as sodium, potassium, calcium, and magnesium.

  The compounds such as amino acids have very high biocompatibility. Therefore, the affinity with the natural bird feather is very good, and by treating the surface of the feather, it is possible to impart moisture absorption and moisture retention properties possessed by the compound such as the amino acid to the feather. At the same time, the effect of the above compound has an effect of improving the texture and feel of the blade.

  Next, a method for manufacturing the shuttlecock will be described.

If at least one compound selected from the above-mentioned amino acids, amino acid derivatives, and polyamino acids, or salts thereof is water-soluble, it is dissolved in water, and if it is difficult to dissolve in water, an appropriate interface is used. Using an activator, it is dispersed in water to obtain a treatment liquid.
It is preferable to use a treatment solution containing 0.5 to 20% by weight of the compound. At a concentration of 0.5% by weight or less, when the treatment liquid is applied to the blade, the amount of the compound such as amino acid adhering to the surface of the blade is small, so that the hygroscopicity and moisture retention imparted to the blade are small. This is because the effect of improving durability is low. Further, when the concentration is 20% by weight or more, there is a feeling of stickiness when applied to the blade, and the commercial value is lowered.

  As a method of applying the treatment liquid containing the compound such as amino acid on the surface of the blade, there are a method of immersing in the treatment liquid, a method of spraying the treatment liquid, and the like. For this purpose, it is preferable to apply the front and back of the blades with a cloth, sponge, brush or the like in which the treatment liquid is absorbed.

  By applying the treatment liquid containing the compound such as amino acid to the entire blade by the above-described method, the surface of the entire blade composed of the blade portion and the blade shaft can be obtained as a shuttlecock treated with the compound. it can. The blade part and the blade shaft are given moisture absorption and moisture retention by a compound such as an amino acid. As a result, even in a low humidity atmosphere, breakage of the blade portion and breakage of the blade shaft are reduced, and the durability of the shuttlecock is improved.

[Example 1]
A treatment solution was obtained by preparing a 2% by weight aqueous solution of glycine. Next, using the sponge which absorbed the said process liquid, it apply | coated to the surface of the shuttlecock blade part and the blade shaft. Thereafter, it was naturally dried to obtain a shuttlecock whose surface was treated with glycine.

[Example 2]
A treatment solution was prepared by adding 95 parts by weight of water to 5 parts by weight of SC-1000 (produced by Ohara Palladium Chemical Co., Ltd.) consisting of a hydrolyzate of silk fibron and water-soluble urethane. Next, using the sponge which absorbed the said process liquid, it apply | coated to the surface of the shuttlecock blade part and the blade shaft. Then, it dried naturally and obtained the shuttlecock which processed the surface of the blade | wing with SC-1000.

[Example 3]
A treatment solution was prepared by adding 95 parts by weight of water to 5 parts by weight of Lanogen TS-52K (manufactured by Takamatsu Yushi Co., Ltd.) whose main component is an amino acid modified product. Next, using the sponge which absorbed the said process liquid, it apply | coated to the surface of the shuttlecock blade part and the blade shaft. Then, it dried naturally and obtained the shuttlecock which processed the surface of the blade | wing with Lanogen TS-52K.

(Evaluation)
The following evaluation was performed about the shuttlecock of Examples 1-3 and a comparative example by making the shuttlecock which has not processed the surface of the blade | wing into a comparative example.

(1) Surface adhesion amount: Rate of weight increase (% by weight)
In order to see the amount of compounds such as amino acids adhering to the surface of each shuttlecock blade obtained, the weight of the shuttlecock before and after the surface treatment was measured, and the weight increase rate was calculated by the following formula.
Weight increase rate (% by weight) = {(W ₁ −W ₀ ) / (W ₀ )} × 100
W ₀ : Weight of shuttlecock before surface treatment W ₁ : Weight of shuttlecock after surface treatment The results are shown in Table 1.

In addition, the shuttlecock blades were separated, and the weight of only the shuttlecock blades was measured. The weight of the blades before and after the treatment was measured, and the weight increase rate was calculated by the following formula.
Weight increase rate (% by weight) = {(w ₁ −w ₀ ) / (w ₀ )} × 100
w ₀ : Weight of blade before surface treatment w ₁ : Weight of blade after surface treatment Table 1 shows the results.

(2) Hygroscopicity and moisture retention: moisture content (% by weight)
The obtained shuttlecock blades were separated, and the moisture content of each shuttlecock blade was measured. The blade was left in an atmosphere of a temperature of 20 ° C. and a humidity of 50% for 4 hours, and the weight after standing was measured. The water content was calculated by the following formula.
Water content (% by weight) = {(w _a1 −w _a0 ) / (w _a0 )} × 100
w _a0 : Absolutely dry weight w _a1 : Weight after standing Absolutely dry weight means the weight when the blades of each shuttlecock are dried at 120 ° C. for 1 hour.
The water content was measured five times for each sample, and the average value is shown in Table 1.

  For the blades left for 4 hours in an atmosphere at a temperature of 20 ° C. and a humidity of 60%, the water content was determined in the same manner as described above, and the results are shown in Table 1.

(3) Durability test Using the shuttlecocks obtained, two senior badminton players held a match in the form of a match in January in winter. The breakage of the blade part and the blade shaft was observed to evaluate how many sets can be used, and Table 1 shows the number of sets that could be used without any problems.

  As a result, 10 sets of shuttlecocks obtained in Example 1 could be used without problems. And when it evaluated that it was unusable, only the blade | wing part was damaged and the failure | damage of the blade axis | shaft was not observed.

  The shuttlecock obtained in Example 2 could be used without eleven sets of problems. Moreover, when it was evaluated as unusable, only the blade portion was damaged and the blade shaft was not damaged.

  The shuttlecock obtained in Example 3 could be used without any problem for 12 sets. Moreover, when it was evaluated as unusable, only the blade portion was damaged and the blade shaft was not damaged.

  On the other hand, the shuttlecock obtained in the comparative example was broken in 3 sets and could not be used. Moreover, the damage was observed not only on the blade part but also on the blade shaft.

(4) Sensory evaluation The texture of each shuttlecock blade obtained was evaluated by hand as compared with the shuttlecock blade of the comparative example, and the results are shown in Table 1.

From the measurement results of the weight increase rate shown in Table 1, it was shown that compounds such as amino acids were attached to the surface of the shuttlecock blade.
Moreover, from the measurement result of the moisture content, the shuttlecock blades obtained in Examples 1 to 3 have higher hygroscopicity and moisture retention than the shuttlecock blades of the comparative examples, and the effect is particularly low. Was shown to be prominent.
In addition, from the results of the durability test, it was shown that the shuttlecocks obtained in Examples 1 to 3 were clearly superior in durability compared to the shuttlecocks of the comparative examples.
Furthermore, from the results of sensory evaluation, it was shown that the shuttlecock blades obtained in Examples 1 to 3 had a better touch than the blades of the comparative example.

It is a schematic block diagram of an example of the shuttlecock of this invention. It is a schematic block diagram of an example of a general shuttlecock.

Explanation of symbols

10: Shuttle cock 11: Head for impact 12: Blade portion 13: Blade shaft 14: Blade 15: Engagement thread 16: Skirt portion 21: Head portion for impact 22: Blade portion 23: Blade shaft 24: Blade 25: Entrainment yarn 26: Skirt

Claims (2)

  A shuttlecock configured using bird feathers, wherein the surface of the feather is treated with at least one compound selected from amino acids, amino acid derivatives, and polyamino acids, or salts thereof. . A treatment liquid containing an amino acid, an amino acid derivative, and a polyamino acid or a salt thereof in an aqueous medium on the surface of a shuttlecock blade composed of bird feathers. A method for manufacturing a shuttlecock that is applied and surface-treated.

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