JP5802490B2 - Artificial feather for shuttlecock, shuttlecock - Google Patents

Description

  The present invention relates to artificial feathers for badminton shuttlecocks. Specifically, the present invention relates to a technique for improving a wing shaft portion of an artificial feather. The present invention also relates to a shuttlecock using artificial feathers.

  The shuttlecock for badminton uses waterfowl feathers (natural feathers) for feathers (natural shuttlecocks) and artificial feathers made of nylon resin or the like (artificial shuttles) Cook) is known.

  As is well known, a natural shuttlecock uses about 16 natural feathers such as geese and ducks, and the end of each feather shaft is planted on a hemispherical base (base) made of cork covered with leather. This is the structure. And the blade | wing currently used for the natural shuttlecock has the small specific gravity, and it is the characteristics that it is very lightweight. In addition, the feather has high rigidity, and the natural shuttlecock provides a unique flight performance and a comfortable shot feeling.

  However, the feathers that are the raw material of the natural shuttlecock are collected from the above waterfowl and do not have to be the feathers of any part of the waterfowl. Only a few feathers can be collected from a waterfowl for a shuttlecock. That is, the production amount of the blades for the natural shuttlecock is limited. In recent years, due to the epidemic of bird flu, edible geese, which were the main source of natural feathers, have been disposed of in large quantities. Is expected.

  On the other hand, as an artificial shuttlecock, a well-known one having resin blades integrally formed in an annular shape is well known, but this artificial shuttlecock is independent of one blade at a time like a natural shuttlecock. Because it does not move, it is difficult to obtain the same flight performance as a natural shuttlecock. If it is going to realize the high rigidity of a feather with the resin-made feather formed by integral molding, weight reduction will become difficult. Therefore, artificial feathers that mimic natural feathers have been proposed.

  Here, based on ornithology, each part in the natural feather is associated with each part in the artificial feather, and the feather valve of the natural feather and the part corresponding to the feather shaft are referred to as a feather part and a feather shaft part, respectively. In this case, the artificial feather imitating a natural feather generally has a structure in which a rod-shaped wing shaft part is fixed to a thin film-like wing part. In order to approximate the performance of the artificial shuttlecock to that of a natural shuttlecock, the artificial feather is required to have both the characteristics of weight reduction and high rigidity. Specifically, the wings occupying a large surface area with respect to the entire artificial feather are required to be lighter than high rigidity, and it is necessary to use a material with a small specific gravity. On the other hand, since the wing shaft portion bears the function of withstanding the impact of hitting the ball and maintaining the shape of the entire artificial feather, it is necessary to use a highly rigid material. Therefore, Patent Documents 1 and 2 below describe an artificial feather using a lightweight and highly rigid fiber-reinforced resin for the wing shaft portion. Non-Patent Documents 1 and 2 below describe features and characteristics of various fiber reinforced resins.

JP 59-69086 JP 2008-206970 A

Carbon Fiber Association, “Characteristics and Properties of Carbon Fiber”, [online], [searched on August 19, 2010], Internet <URL: http://www.carbonfiber.gr.jp/tanso/03.html > Chemical Fiber Technology Improvement Research Committee, “Data collection on various high-performance fibers such as high-strength and high-modulus fibers”, [online], [searched on August 19, 2010], Internet <URL: http: / /www.kaizenken.jp/db/chap2.html>

  In general, a material having higher rigidity has a higher specific gravity. Therefore, a material having a specific gravity higher than that of the wing is naturally used for the wing shaft. Therefore, even if the surface area and volume of the entire artificial feather are small, weight reduction of the entire artificial feather is hindered unless the material of the wing shaft portion is carefully selected.

  As is well known, a fiber reinforced resin is a composite material in which a fiber such as glass fiber is included in a base resin (matrix) to improve the strength, and the specific gravity is smaller depending on the fibers included in the matrix. High rigidity material can be used. As fibers having lower specific gravity and higher rigidity, carbon fibers, aramid fibers, Zyron (registered trademark: Toyobo Co., Ltd.) and the like are well known. And, as is well known, carbon fiber reinforced resin, aramid fiber reinforced resin, Zylon reinforced resin, etc., which are fiber reinforced resins using these fibers, are glass fibers using glass which is a general fiber. Specific strength and specific rigidity are superior to reinforced resin. That is, it is light and strong. Therefore, if the wing shaft part is constituted by these fiber reinforced resins, the weight reduction and the high rigidity of the artificial feather can be achieved at a high level. Therefore, it can be said that these fiber reinforced resins are most suitable as the material of the wing shaft portion for the action of “striking” the shuttlecock.

  However, fibers having a lower specific gravity and higher rigidity often have a dark color (black, brown, etc.). That is, the fiber reinforced resin using those fibers is colored in a dark color. For example, carbon fibers are black and aramid fibers are brown. Zylon is gold or reddish brown. The fiber reinforced resin is colored in the color of the reinforced fiber contained in the matrix. Badminton is the sport with the fastest hitting speed as the initial speed and is an indoor competition. Therefore, in the shuttlecock, if the wing shaft of the artificial feather is dark, There arises a problem that the contrast ratio with the color of the shaft portion is lowered and the shuttlecock becomes difficult to see. In particular, when the shuttlecock rotates, the athlete recognizes the presence region of the artificial feather in the shuttlecock as an intermediate color between the white of the wing and the dark color of the wing shaft, and the visibility becomes extremely poor. That is, the dark-colored fiber reinforced resin described above becomes an undesired material for the act of “seeing” the shuttlecock.

  Accordingly, an object of the present invention is to provide an artificial feather for a shuttlecock having a light and highly rigid wing shaft portion while ensuring good visibility, and a shuttlecock using the artificial feather. .

The main invention for achieving the above object is an artificial feather for a shuttlecock that is planted in a ring shape around the periphery of the circular upper end surface of the base portion with the hemispherical base portion of the shuttlecock as the lower side,
Simulating natural feathers, comprising a thin film-like wing part corresponding to the feather valve, and a wing shaft part corresponding to the wing shaft, extending continuously from the upper tip toward the lower end,
The normal direction of the film surface of the wing toward the outside of the shuttlecock is the front direction,
The wing shaft portion is fixed to the wing portion over the lower end of the wing portion from the tip, and a rod-shaped base shaft portion made of a white resin material extending from the tip toward the end direction; It is composed of a rod-shaped reinforcing portion made of a dark-colored fiber reinforced resin fixed in a state of being in contact with the base shaft portion while extending in the vertical direction,
The fiber reinforced resin is darker than the white resin material, has a low specific gravity, high specific strength and specific rigidity,
The wing shaft portion is in a state where the artificial feather is implanted in the base portion, and when viewed from the front direction, the reinforcing portion is concealed by the base shaft portion ,
The reinforcing portion is laminated on the back surface of the base shaft portion,
The base shaft portion is a laminated region with the reinforcing portion, and at least in a region exposed above the base portion, has a U-shaped groove shape that extends in the vertical direction and opens to the back surface side, and the reinforcing portion includes the groove It is set as the artificial feather for shuttlecocks characterized by being arrange | positioned inside .

  According to the artificial feather for a shuttlecock of the present invention, light weight, high strength, and high rigidity can be achieved using a dark-colored fiber reinforced resin while ensuring good visibility. A shuttlecock using the artificial feather can be expected to obtain the same visibility, flight performance, and feel at impact as a natural shuttle. In addition, it is possible to provide an inexpensive shuttlecock that does not depend on the production amount of natural feathers, which are natural materials, and has excellent productivity. Other effects of the present invention will be clarified in the following description.

It is a perspective view of the artificial shuttlecock using the artificial feather | wing which concerns on the Example of this invention, and is a perspective view when it sees from the base part side (downward). It is a perspective view when the said artificial shuttlecock is seen from upper direction. It is a perspective view which shows the basic structure of the artificial feather | wing concerning the Example of this invention. It is a perspective view of the wing shaft part which comprises the artificial feather | wing concerning the said Example. It is a four-view figure of the said wing shaft part. It is a figure for demonstrating the effect show | played by the front projection shape of the base shaft part and reinforcement part which comprise the said wing shaft part. It is a perspective view of the wing shaft part which constitutes the artificial feather of other examples of the present invention. It is a perspective view of the wing shaft part which constitutes the artificial feather of other examples of the present invention. It is a perspective view of the wing shaft part which constitutes the artificial feather of other examples of the present invention. It is a perspective view of the wing shaft part which constitutes the artificial feather of other examples of the present invention.

=== Characteristics of Embodiments of the Invention ===
In the process of conceiving the present invention, the inventors first listed the flight performance similar to that of a natural shuttlecock as the performance required for an artificial shuttlecock. It is premised on using a low specific gravity material, for example, a resin molded into a film or a foamed material. Based on this, the performance required for artificial feathers was considered. It was concluded that it is important to carefully select the material of the wing shaft part in order to achieve both weight reduction and high rigidity of the entire wing including the thin film wing part.

  As described above, fiber reinforced resin is suitable from the viewpoint of weight reduction and high rigidity. However, the fiber-reinforced resin often has a dark color due to the dark-colored reinforcing fibers in the matrix, and deteriorates visibility. The inventors of the present invention created the present invention by intensive research on the structure of the wing shaft part that can improve visibility while using a dark-colored fiber reinforced resin.

And the Example of this invention may be equipped with the following characteristics in addition to the characteristic with which the Example corresponding to the said main invention is provided.
The reinforcing portion is laminated on the back surface of the base shaft portion.
When the wing shaft portion is viewed from the front and back directions, the rod-shaped base shaft portion is thicker than the reinforcing portion at least in a region exposed above the base portion.
The base shaft portion is a laminated region with the reinforcing portion, and at least in a region exposed above the base portion, has a U-shaped groove shape that extends in the vertical direction and opens to the back surface side, and the reinforcing portion includes the groove Be placed inside the.
The reinforcing part has a front shape in which the thickness in the front and back direction is larger than the width in the direction parallel to the laminated surface when viewed from above and below in at least the region exposed above the base part. .
A white pigment is added to the white resin material.

  In addition, the Example of this invention has extended also to the shuttlecock using the artificial feather for shuttlecocks in any one of the above-mentioned.

=== Structure of artificial shuttlecock ===
1 and 2 are external views of an artificial shuttlecock (hereinafter referred to as a shuttlecock) 1 including an artificial feather 10 according to an embodiment of the present invention. FIG. 1 is a perspective view when the shuttlecock 1 is viewed from below when the base portion 2 is downward, and FIG. 2 is a perspective view when viewed from above. A plurality (for example, 16 pieces) of artificial feathers 10 simulating natural feathers are planted in an annular shape along the circumference of the flat upper surface of the hemispherical base portion 2 so that the diameter increases upward. At the same time, they are fixed to each other by a string-like member (for example, cotton thread) 3 to form a skirt portion 4.

=== Structure of artificial feather ===
<About each part>
The artificial feather 10 which is the subject of the present invention has a basic structure in which a rod-like wing shaft part 20 is fixed to a thin film wing part 12 by bonding or integral molding. FIG. 3 shows the structure of the artificial feather 10 in the embodiment of the present invention. FIG. 3A is a perspective view of the artificial feather 10 when the shuttlecock 1 is viewed from the outside, and FIG. 3B is a perspective view when viewed from the inside. Here, if the vertical and horizontal directions and the front / back relation of the artificial feather 10 are defined based on the state of being attached to the base part 2 of the shuttlecock 1, the wing shaft part 20 extends downward from the upper end of the wing part 12. It will be. For convenience, the upper end 21 of the wing shaft portion 20 is defined as the “tip” and the lower end 22 is defined as the “end”, and the surface of the wing portion 12 or the wing shaft portion 20 facing the outside of the shuttlecock 1 is The surface facing inward of the shuttlecock 1 is referred to as “back surface” 14. Further, the direction orthogonal to the extending direction of the wing shaft portion 20 in the plane of the wing portion 12 is defined as the left-right direction. About the left and right, it follows the direction when the artificial feather | wing 10 is seen from the surface 13 side in the state which made the wing shaft part 20 upright. Further, in the following, in the wing shaft portion 20, a region fixed to the wing portion 12, that is, a region from almost the upper end to the lower end of the wing portion 12 is referred to as a wing support portion 23, and from the lower end to the end of the wing portion 12 In a region, that is, a natural feather, a part corresponding to a part called a feather or a feather pattern protruding from a feather valve as a part of a feather shaft is referred to as a feather part 24.

<Schematic structure of artificial feather>
The artificial feather 10 shown in FIG. 3 has a structure in which the wing shaft portion 20 is fixed to the back surface 14 of the thin wing portion 12. The wing portion 12 can be formed of a nonwoven fabric or a resin molded product. In this example, a non-woven fabric that can reproduce the outer shape of a natural feather feather valve by simply cutting is used. In addition, since a nonwoven fabric may loosen a fiber at the time of a hit and a fiber may scatter, when shuttlecock 1 cuts a wind at high speed and flies, so that wing part 12 can maintain its own shape, On the surface of the wing portion 12, a reinforced film formed by applying a resin is formed. Unlike a film material that is coated with an adhesive, the reinforced coating is formed on the surface of the wing 12 by applying a resin dissolved in a solvent and volatilizing the solvent. Naturally, it is much lighter and thinner than the film material.

For reference, Table 1 below shows the characteristics of various resins used as the reinforcing coating.

  In Table 1, by applying a reinforced coating, each resin is adjusted in film thickness, concentration with respect to the solvent during the coating process, etc., so that the weight increase of the wing 12 of only the nonwoven fabric is 0.005 g. It shall be. Various coating methods such as a dip method, a spray method, and a roll coating method can be employed for forming the reinforced film.

  Table 1 shows the breaking strength (N) and the breaking elongation (%) as relative values when the wing portion 12 having no reinforcing coating is taken as 1. As shown in Table 1, it was confirmed that the breaking strength (N) and the breaking elongation (%) were both improved by providing the reinforced coating except for some exceptions. In particular, it was found that aqueous polyurethane is excellent in cutting strength (N) and cutting elongation (%). In addition, since an aqueous | water-based polyurethane does not use an organic solvent, when manufacturing the artificial feather | wing 10, an environmental load can be reduced. In this embodiment, aqueous polyurethane is used as the reinforcing film.

  On the other hand, the structure of the wing shaft part 20 is a feature of the artificial feather 10 of the present embodiment, and is composed of two rod-shaped members (30, 40) made of different materials. One rod-like member 40 is mainly made of a fiber reinforced resin that contributes to weight reduction and high rigidity of the wing shaft portion 20, and this member (hereinafter referred to as a reinforcement portion) 40 has a dark color due to the fiber reinforced resin. I am tinged. The other rod-shaped member 30 is a member for improving the visibility of the shuttlecock 1 (hereinafter referred to as the base shaft portion 30), has a white color (white, ivory, etc.) and is reinforced with fibers in the reinforcing portion 40. A structure for exposing the dark color of the tree to the front surface 13 side while concealing the dark color of the tree from the front surface 13 of the shuttlecock 1 is provided.

  As illustrated in FIG. 3, the wing shaft portion 20 in the artificial feather 10 of the present embodiment has a structure in which a base shaft portion 30 and a reinforcing portion 40 are laminated on the front surface 13 side and the back surface 14 side, respectively. . In the drawing, the base shaft portion 30 and the reinforcing portion are indicated by different hatching. In this example, a protrusion 25 is formed below the back surface 14 of the reinforcing portion 40, and this protrusion 25 is formed when the end 22 side of the wing shaft portion 20 is implanted in the base portion 2 of the shuttlecock 1. This is a “return” for preventing “missing” of the artificial feather 10.

=== Structure of the wing shaft ===
As described above, the greatest feature of the artificial feather 10 of this embodiment is the structure of the wing shaft portion 20. 4 and 5 show the structure of the wing shaft 20 in this embodiment. 4 is a perspective view of the wing shaft portion 20 when viewed from the back side, and FIGS. 5A to 5D are a plan view of the front surface 13 side and a plan view of the back surface 14 side, respectively. The side view when it sees from a side view and the front-end | tip 21 side is shown. In addition, about the front view of FIG.5 (D), it expanded and showed from FIG.5 (A)-(C). Also here, the base shaft portion 30 and the reinforcing portion 40 are indicated by different hatching. As described above, the wing shaft portion 20 of the artificial feather 10 according to the present embodiment has a structure in which the base shaft portion 30 on the front surface 13 side and the reinforcing portion 40 on the back surface 14 side are laminated. The laminated structure of the wing shaft part 20 is one of the features in the present embodiment, but more important features are the material of the base shaft part 30 and the reinforcing part 40 and the visibility of the material in the laminated structure. There is an arrangement relationship between the related base shaft portion 30 and the reinforcing portion 40.

<Reinforcement material and layout>
The base shaft portion 30 is made of a resin that looks white based on light scattering caused by the three-dimensional molecular structure of the resin, such as polyamide 12 (nylon 12) or a glass fiber reinforced resin using the polyamide 12 as a matrix (hereinafter, for convenience, “ It is referred to as a “white resin” and has a color similar to the wing 12. On the other hand, the reinforcing portion 40 is a fiber reinforced resin, and is formed of a resin having a small specific gravity and a large specific strength and specific rigidity, such as a carbon fiber reinforced resin and an aramid fiber reinforced resin. Moreover, the fiber itself contained in the resin is a dark color, and the resin is colored in the dark color and colored in the dark color. That is, the color of the base shaft portion 30 is a relatively light color relative to the reinforcing portion 40.

  As described above, the dark-colored fiber reinforced resin is an ideal material for the act of “striking” the shuttlecock 1, but there are many problems for the act of “seeing”. Certainly, there may be white fiber reinforced resins with excellent specific strength and specific rigidity, but fiber reinforced resins that are widely used industrially, are easily available, and are relatively inexpensive are dark. There are many. Therefore, in this embodiment, the dark-colored reinforcing portion 40 is laminated on the back surface 14 of the base shaft portion 30 made of white resin. As a result, when the shuttlecock 1 is viewed from the outside, the base shaft portion 30 made of white resin is on the front surface 13 side, and the dark-colored reinforcing portion 40 is difficult to see from the outside of the shuttlecock 1. Yes.

  In the present embodiment, the base shaft portion 30 is made of polyamide 12 reinforced with glass fibers, and the reinforcing portion 40 is made of carbon fiber reinforced resin. As the matrix of the carbon fiber reinforced resin, the same polyamide 12 as the base shaft portion 30 can be used. And the wing shaft part 20 in the artificial feather | wing 10 of a present Example has the base shaft part 30 white, and the reinforcement part 40 is black. Of course, the material used for the wing shaft portion 20 is not limited to this example. For example, the base shaft portion 30 may be made of various white resins such as PBT and ABS. An aramid fiber reinforced resin or the like can be used for the reinforcing portion 40. Further, the resin constituting the base shaft portion 30 can be used as a matrix of the fiber reinforced resin of the reinforcing portion 40.

  In addition, as a reason to use dark fiber reinforced resin such as carbon fiber reinforced resin and aramid fiber reinforced resin for the reinforcing portion 40, in addition to being easily available and low in price, dark fiber reinforced resin, For sports equipment manufacturers that manufacture shuttlecocks, it is also a material that is used to handling and familiar with characteristics. Dark colored reinforcing fibers are often used for tennis, badminton rackets, golf clubs, and the like.

<Width relationship>
In the artificial feather 10 of the present embodiment, white resin and dark fiber reinforced resin are used on the front surface 13 side and the back surface 14 side of the wing shaft portion 20, respectively. Furthermore, the projected shape of the base shaft portion 30 and the reinforcing portion 40 from the front and back directions, that is, the size relationship between the widths of the base shaft portion 30 and the reinforcing portion 40 in the left-right direction is defined. As shown in FIGS. 5C and 5D, the projected shape when viewed from the front and back directions is made larger at the base shaft portion 30 than at the reinforcing portion 40. That is, the width (thickness) in the left-right direction when viewed from the front and back directions is larger in the base shaft portion 30 than in the reinforcing portion 40. Thereby, even when the artificial feather 10 is viewed from an oblique direction, the dark-colored reinforcing portion 40 is hidden behind the white base shaft portion 30 on the front surface 13 side, and the artificial feather 10 is arranged in an annular shape in the shuttlecock 1. That is, when the artificial feather 10 is gradually rotated around the wing shaft portion 20 as an axis, the rotation angle range in which the wing shaft portion 20 is visually recognized as white can be increased.

  Further, in the artificial feather 10 of the embodiment, the wing support part 23 of the wing shaft part 20 is fixed on the back surface of the wing part 12. That is, the front surface 13 of the base shaft portion 30 is fixed to the back surface of the wing portion 12. In such a front / back relationship between the wing part 12 and the wing shaft part 20, since the width of the base shaft part 30 is wider than the reinforcing part 40, the contact area between the wing part 12 and the wing shaft part 20 can be increased. The fixing strength between the wing part 12 and the wing shaft part 20 can be further increased.

<About the method of manufacturing the wing shaft>
The artificial feather 10 of the present embodiment is manufactured, for example, by bonding the wing shaft part 20 to the wing part 12 produced by cutting a nonwoven fabric. For the wing shaft portion 20 having a laminated structure, the base shaft portion 30 and the reinforcing portion 40 can be individually molded and bonded to each other by bonding or welding, but the material and matrix are thermoplastic. By using a resin, it can be manufactured using a known injection molding technique such as two-color molding or insert molding. Accordingly, the wing shaft portion 20 can be manufactured as a molded product in which the base shaft portion 30 and the reinforcing portion 40 are integrally fixed without separately providing a process for fixing such as adhesion. In addition, when forming the wing | blade part 12 with a thermoplastic resin instead of a nonwoven fabric, all the components of the artificial feather | wing 10 including the wing | blade part 12 can be formed with an injection molding technique.

=== About the cross-sectional shape of the reinforcing portion ===
As described above, in the artificial feather 10 of the present embodiment, the wing shaft portion 20 has a structure in which a white resin and a dark fiber reinforced resin are laminated, and the white base shaft portion 30 is a front surface. By arranging the reinforcing part 40 of the fiber reinforced resin excellent in specific strength and specific rigidity on the back side 14 side, it is arranged on the 13 side, while ensuring the visibility by the wing shaft part 20 with the conventional white resin, further Light weight, high strength and high rigidity have been achieved. When the wing shaft portion 20 is viewed from the front and back directions, the reinforcing portion 40 is made relatively thin with respect to the base shaft portion 30, so that the dark-colored reinforcing portion 40 becomes less visible from the outside of the shuttlecock 1. I am doing so.

  By the way, when it is going to improve the performance of the wing part 20 which has a laminated structure of white resin and dark fiber reinforced resin further, while achieving weight reduction using more fiber reinforced resin, strength and There are contradictory demands for further improving the rigidity and a desire to make the dark-colored fiber reinforced resin thinner to make it difficult to see from the outside. Therefore, in the artificial feather 10 according to the embodiment of the present invention, not only the width of the base shaft portion 30 is made wider than that of the reinforcing portion 40 but also the cross-sectional shape of the reinforcing portion 40 having excellent specific strength and specific rigidity is devised to reinforce. While making the dark color of the portion 40 more difficult to see from the outside of the shuttlecock, it is possible to more effectively absorb the impact at the time of hitting.

  FIG. 6 is a diagram for explaining the structure for further improving the performance. In this figure, the front view when the wing shaft part 20 is viewed from the tip 21 side is shown. The impact when hitting the shuttlecock is transmitted in the direction from the front surface 13 to the back surface 14 of the artificial feather 10, that is, a force is applied in the direction of bending the wing shaft portion 20 inward. The thickness t in the front and back direction, which is the direction of the force applied at the time of hitting, is larger than the width w parallel to the laminated surface with the base shaft portion 30 so that the front projection shape of the reinforcement portion 40 exists so that many fiber reinforced resins exist. The shape is increased. As a result, the width w becomes narrower and the dark colored reinforcement portion 40 becomes harder to see from the outside, and a sufficient thickness t is provided in the direction of the force at the time of hitting, so that the impact at the time of hitting can be absorbed more effectively. It is like that.

<Evaluation of the wing shaft>
The artificial feather 10 of the present embodiment uses a reinforced fiber resin for a part of the wing shaft portion 20 with respect to the wing shaft portion 20 formed of only a conventional white resin, so that the strength and the rigidity are increased. It is clear that can be achieved. Here, with respect to the wing shaft portion 20 having the structure shown in FIGS. 4 and 5, the wing shaft portion when the material of the base shaft portion 30 and the reinforcing portion 40 was changed was prepared as a sample. And the weight of each sample was measured and the effect of weight reduction was evaluated. The ratio of the volume v of the reinforcing portion 40 to the volume V of the base shaft portion 30 is v / V = 0.81, and the volume of the base shaft portion 30 having a relatively large specific gravity is larger. Further, the front shape of the wing shaft portion 20 is T = 2.0 mm, t = 1.0 mm, W = 2.0 mm for each of T, t, W, and w in the wing shaft portion shown in FIG. w = 0.7 mm. In addition, since the wing shaft portion 20 has a shape that gradually increases from the tip 21 to the end 22, each value of T, t, W, and w indicates a maximum value.

Table 2 shows the measurement results of the above weights.

  In Table 2, a sample s3 is the wing shaft portion 20 in the artificial feather 10 of the present embodiment. In the sample s3, although the volume V of the base shaft portion 30 is larger than the volume v of the reinforcing portion and the structure is less likely to reduce the effect of weight reduction, all is formed of carbon fiber reinforced resin. A weight increase of 0.01 g over the sample s1 and a weight reduction of 0.01 g were achieved compared to the case of the sample s2 formed entirely of white resin. That is, although the volume of the reinforcement part 40 is small, the effect of weight reduction is remarkable. Of course, the carbon fiber reinforced resin is superior in strength and rigidity to the glass fiber reinforced resin.

  In addition, the wing shaft part 20 in the artificial feather 10 of the present embodiment has strength and rigidity compared to the sample s3 formed entirely of white resin according to the material, volume, shape, and the like of the base shaft part 30 and the reinforcing part 40. The wing shaft part 20 achieves weight reduction while increasing the strength, achieves weight reduction after maintaining the same strength, and increases strength and rigidity while maintaining the same weight. The overall characteristics can be freely controlled. And the characteristic of the wing shaft part 20 should just adjust suitably according to the use (for competition, practice, etc.) of a shuttlecock, and a user's skill.

=== Other Embodiments ===
<About the width of the base part and the reinforcement part>
In the above embodiment, the width of the base shaft portion 30 of the wing shaft portion 20 is larger than the width of the reinforcing portion 40 over the entire length from the tip 21 to the end 22 thereof. However, the base portion 30 is not widened with respect to the reinforcing portion 40, and the reinforcing portion 40b is made thicker in the front and back directions while the base shaft portion 30b and the reinforcing portion 40b have the same width as the wing shaft portion 20b shown in FIG. It is good also as a shape which becomes. Thereby, the visibility is slightly inferior, but the relative volume of the reinforcing portion 40b in the wing shaft portion 20b is increased, so that the durability is improved. Therefore, for example, it is suitable for a shuttlecock for practice use where further improvement in durability is desired. Even if the widths of the base shaft portion 30b and the reinforcing portion 40b are the same, when the wing shaft portion 20b is viewed from the tip 21 side, the shape of the reinforcing portion 40b is trapezoidal with the back surface 14 side as the upper base. If so, the visibility does not deteriorate significantly.

<Areas planted in the base>
In the shuttlecock 1 using the wing shaft portion 20 of the above embodiment, the end 22 side of the wing shaft portion 20 is planted in the base portion 2, and this planted region that is not exposed to the outside (planting region) ), Visibility is not a problem. Therefore, the reinforcing portion 40 may be wider than the base shaft portion 30 in the planting region. Of course, the base shaft portion 30 may be formed only in a region exposed to the outside of the base portion 2 (exposed region), and the planting region may be only the reinforcing portion 40. Since the material of the reinforcing portion 40 is lighter and stronger than the material of the base shaft portion 30, the occupation ratio of the reinforcing portion 40 may be positively increased for portions that cannot be seen from the outside.

<About laminated area>
In the above embodiment, the wing shaft portion 20 has the reinforcing portion 40 laminated on the back surface 14 side of the base shaft portion 30 over the entire length from the tip 21 to the end 22 thereof. In the wing shaft portion 20, the wing handle portion 24 is directly impacted at the time of hitting, so it is necessary to increase the rigidity, and it is essential to have a two-layer structure of the base shaft portion 30 and the reinforcing portion 40. . Moreover, the thickness of the wing shaft part 20 is also required to some extent. Therefore, the wing shaft part 20 has a shape in which the tip 21 is thin and gradually becomes thicker toward the end 22 side.

  By the way, it was discovered in the creation process of the present invention that the fiber reinforced resin constituting the reinforcing portion 40 is oriented so that the thinner the fiber reinforced resin, the higher the strength. Therefore, when the upper end of the reinforcing portion 40 is extended to the upper end of the base shaft portion 30 and the upper end of the reinforcing portion 40 is naturally narrowed, there is a possibility that the strength reduction effect due to the orientation can be compensated by the strength improving effect due to the orientation. . However, in the narrow part on the tip 21 side of the wing shaft part 20, the wing part 12 absorbs a certain impact when hitting the ball, and extending the reinforcing part 40 to the tip of the wing shaft part 20 is an extremely thin region. Molded products made of two different resins are injection-molded, and it is necessary to strictly control the molding conditions in order to obtain the accuracy of the injection molding. Therefore, unlike the wing shaft portion 20c shown in FIG. 8, the reinforcing portion 40c may not be stacked on the tip 21 side, and the reinforcing portion 40c may be stacked from the middle of the base shaft portion 30c toward the distal end 22. . Since the fiber reinforced resin is more expensive than the white resin, reducing the area of the reinforcing portion 40c made of the fiber reinforced resin relatively leads to cost reduction.

<About laminated shape>
In the artificial feather 10 of the above-described embodiment, the front projection shape of the wing shaft portion 20 includes a substantially rectangular base shaft portion 30 flat in the front and back direction and a substantially rectangular reinforcing portion 40 having a long side in the front and back direction. The shape was simply laminated in the direction. In addition to this embodiment, in order to further improve the visibility, like the wing shaft portion 20d shown in FIG. 9, the base shaft portion 30d is opened on the back surface 14 side and is formed into a U-shaped groove extending in the vertical direction. The reinforcing portion 40d may be arranged in the U-shaped groove. Accordingly, the reinforcing portion 40d cannot be seen even when the wing shaft portion 20d is viewed from the left and right.

  Of course, the wing shaft portion has a structure in which the reinforcing portion made of fiber reinforced resin that contributes to weight reduction and high rigidity is concealed by the base shaft portion so that it cannot be seen at least when viewed from the front surface 13 side. As long as the wing shaft portion (20, 20b to 20d) described above is used, the base shaft portion (30, 30b to 30d) and the reinforcing portion (40, 40b to 40d) are not stacked. As in the wing shaft portion 20e shown in FIG. 6, the reinforcing portion 40e may be arranged in the hollow interior of the hollow rod-shaped base shaft portion 30e.

<Relationship between wing and shaft>
Each of the wing shaft portions (20, 20b to 20e) may be fixed to either the front surface 13 side or the back surface 14 side of the wing portion 12. Except for the wing shaft portion 20e shown in FIG. 10, the reinforcing portion (40, 40b to 40d) is laminated on the back surface 14 side of the base shaft portion (30, 30b to 30d), and the wing shaft portion (20, 20b to 20d). When viewed from the back surface 14 side, the reinforcing portions (40, 40b to 40d) having a dark color are exposed. Therefore, in these wing shaft portions (20, 20b to 20d), it can be said that it is easier to see the wing shaft portion (20, 20b to 20d) fixed to the back surface 14 side of the wing portion 12. In particular, like the wing shaft portion (20, 20b, 20d) shown in FIGS. 5, 7, and 9, the reinforcing portion (40, 40b, 40d) is the tip 21 of the wing shaft portion (20, 20b, 20d). In the structure extended to the end, visibility is improved when the wing 12 is fixed to the back surface 14 side. On the other hand, if the wing shaft portion (20, 20b to 20e) is fixed to the front surface 13 side of the wing portion 12, the lash portion (20, 20b-20e), the possibility of wing 12 being damaged can be reduced.

<About white resin>
The white resin constituting the base shaft portion (30, 30b to 30e) may be a white substance itself, or a transparent resin (acrylic resin, PC, etc.) with a white pigment (titanium oxide, calcium carbonate). Etc.) may be dispersed. Of course, even if the resin substance itself is white, the occupied area of the reinforcing part (40, 40b to 40e) in the wing shaft part (20, 20b to 20e) is relatively enlarged to further reduce the weight and increase the strength. In the case of achieving a high rigidity and a high rigidity, it is also conceivable to reduce the thickness of the base shaft portion (30, 30b to 30e) in the front and back direction. If the base shaft portion (30, 30b to 30e) is thin, the color of the reinforcing portion (40, 40b to 40e) of the back surface 14 is transparent to the front surface 13 side through the base shaft portion (30, 30b to 30e). There is also. Even in such a case, a white pigment may be added to the resin constituting the base shaft portion (30, 30b to 30e) to reduce the light transmittance. In addition, when the pigment is added to the base portion 30 at a weight ratio of 0.5% with respect to the sample s3 shown in Table 2 as an example of the present invention, the degree of whiteness is higher than the sample s3 in visual inspection. Further, the intensity of light transmitted from the back surface 14 side toward the front surface 13 side was also reduced. Moreover, the increase / decrease in the weight with respect to sample s3 was not recognized.

  As described above, the artificial feather of the present invention can be variously modified with respect to the above-described embodiments. In any case, the layout and specific structure of the wing shaft, the amount of white pigment added to the base shaft, etc., can be used for shuttlecock applications (for practice, for official competitions, etc.) and required performance (cost, visual recognition) Depending on the property, durability, flight performance, etc.).

  The present invention can be applied to a badminton shuttlecock.

1 artificial shuttlecock, 2 base part, 3 string-like member, 4 skirt part,
10 artificial feathers, 12 wings, 20, 20b to 20e wing shaft, 23 wing support,
24 Feather handle, 30, 30b-30e Base shaft, 40, 40b-40e Reinforcing part

Claims (5)

An artificial feather for a shuttlecock that is planted in an annular shape on the periphery of the circular upper end surface of the base portion, with the hemispherical base portion of the shuttlecock as the bottom,
Simulating natural feathers, comprising a thin film-like wing part corresponding to the feather valve, and a wing shaft part corresponding to the wing shaft, extending continuously from the upper tip toward the lower end,
The normal direction of the film surface of the wing toward the outside of the shuttlecock is the front direction,
The wing shaft portion is fixed to the wing portion over the lower end of the wing portion from the tip, and a rod-shaped base shaft portion made of a white resin material extending from the tip toward the end direction; It is composed of a rod-shaped reinforcing portion made of a dark-colored fiber reinforced resin fixed in a state of being in contact with the base shaft portion while extending in the vertical direction,
The fiber reinforced resin is darker than the white resin material, has a low specific gravity, high specific strength and specific rigidity,
The wing shaft portion is in a state where the artificial feather is implanted in the base portion, and when viewed from the front direction, the reinforcing portion is concealed by the base shaft portion ,
The reinforcing portion is laminated on the back surface of the base shaft portion,
The base shaft portion is a laminated region with the reinforcing portion, and at least in a region exposed above the base portion, has a U-shaped groove shape that extends in the vertical direction and opens to the back surface side, and the reinforcing portion includes the groove An artificial feather for a shuttlecock, characterized in that the artificial feather is arranged on the inside . 2. The artificial feather for a shuttlecock according to claim 1, wherein the white resin material is a white resin substance and a white pigment added to the resin . In Claim 1 or 2, when the wing shaft portion is viewed from the front and back direction, the thickness of the rod-shaped base shaft portion is thicker than the reinforcing portion at least in a region exposed above the base portion.
An artificial feather for a shuttlecock characterized by that.   In any one of Claims 1-3, when the said reinforcement part is seen from an up-down direction at least in the area | region exposed above the said base part, the thickness of a front-back direction is larger than the width | variety of a lamination surface and a parallel direction. An artificial feather for a shuttlecock, characterized by having a front shape that increases.   The shuttlecock using the artificial feather for shuttlecocks in any one of Claims 1-4.

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