JP2004081292A - Racket frame - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lightweight racket frame having stably high rigidity, and appropriate vibration damping characteristics which can be controlled. <P>SOLUTION: The racket frame has a two-forked throat part which continues from a head part and a shaft part of a frame body. A first yoke and a second yoke are provided between both sides of the frame of the throat part. The first yoke and the head part are continued so as to surround a ball-hitting surface. The first yoke is formed as a separate member using a material different from that of the frame body. Both ends of the first yoke are extended towards the second yoke so as to form connecting auxiliary parts which are extended to the other yoke so as to be mechanically joined to a gut stretching part, the throat part and the second yoke. <P>COPYRIGHT: (C)2004,JPO

Description

【００５７】
（実施例１）
前記第１実施形態と同様の形状としたが、機械的接合のための凹凸部は設けず、別体第１ヨークとフレーム本体とは接着剤で固定した。第２ヨークはフレーム本体と一体成形した。第１ヨークについては、６ナイロンに長さ１ｍｍのカーボン繊維（短繊維）を３０％充填させた材料を使用した。射出成形用金型を使用して中実のヨークを射出成形した。
【００５８】
（実施例２）
前記第２実施形態に該当し、第２ヨークとフレーム本体とを別体とし、第１ヨークはフレーム本体と一体成形した。第２ヨークについては、６ナイロンに長さ１ｍｍのカーボン繊維（短繊維）を３０％充填させた材料を使用した。射出成形用金型を使用して中実のヨークを射出成形した。第２ヨークの形状は、上記第２実施形態と同様とした。その他は、実施例１と同様とした。
【００５９】
（実施例３）
前記第１実施形態に該当し、実施例１と同様に、第１ヨークとフレーム本体とを別体とし、第２ヨークはフレーム本体と一体成形した。第１ヨークについては、６ナイロンに長さ１ｍｍのカーボン繊維（短繊維）を３０％充填させた材料を使用した。射出成形用金型を使用して中実のヨークを射出成形した。第１ヨークの形状は、上記第１実施形態と同様とし、ヨークには凹部を配置し、フレーム本体の凸部と嵌合させることにより機械的接合を行った。その他は、実施例１と同様とした。
【００６０】
（実施例４）
前記第１実施形態の第１変形例の該当し、実施例１と同様に、第１ヨークとフレーム本体とを別体とし、第２ヨークはフレーム本体と一体成形した。第１ヨークとフレーム本体の接合部間に制振フィルムを介在させた。その他は、実施例３と同様とした。
【００６１】
（実施例５）
前記第１実施形態の第２変形例に該当し、実施例１と同様に、第１ヨークとフレーム本体とを別体とし、第２ヨークはフレーム本体と一体成形した。第１ヨークの形状は、ヨーク本体から延在する連結補助部は第２ヨークまで延在させず、スロート部にのみ接合させた。また、第１ヨークには凹部を配置し、フレーム本体の凸部と嵌合させることにより機械的接合を行った。その他は、実施例１と同様とした。
【００６２】
（実施例６）
前記第１実施形態の第３変形例に該当し、第１ヨークとフレーム本体とを別体とし、第２ヨークはフレーム本体と一体成形した。第１ヨークの形状は、ヨーク本体から延在する連結補助部を設けず、ヨーク本体のみとした。また、第１ヨークとフレーム本体には機械的接合のための凹凸部は設けず、接着剤で接合させた。その他は、実施例１と同様とした。
【００６３】
（比較例１）
第１ヨークのみを設け、第２ヨークは設けない、汎用のラケットの形状とした。予め第１ヨークを成形し、フレーム本体成形時に、第１ヨークとフレーム本体とを金型で一体成形した。第１ヨークはフレーム本体と同様の材質により構成した。
【００６４】
（比較例２）
予め第１ヨークおよび第２ヨークを成形し、フレーム本体成形時に予め成形した第１ヨーク、第２ヨークとフレーム本体とを一体成形した。第２ヨークはスロート部の略中央位置に、左右のスロート部を架橋するように設けた。第１ヨーク、第２ヨークはフレーム本体と同様の材質により構成した。
【００６５】
上記実施例１〜６及び、比較例１、２のラケットフレームに関し、それぞれ、後述する方法により面外１次減衰率、面外２次減衰率、反発係数（３点）を測定した。また実打テストを行った。
【００６６】
（ヨーク剛性）
図９に示すように、万能試験機６０を用い、３点曲げにより剛性値の測定を行った。万能試験機６０の圧子６１の下に測定点がくるように治具６２Ａ、６２Ｂの上にラケットフレーム１の測定部分（ヨークの所要位置）を配置した。治具６２Ａ、６２Ｂの間隔は７０ｍｍとした。治具６２Ａと治具６２Ｂの中心に圧子６１を設定した。圧子６１の先端の曲率は５Ｒ、治具６２Ａ、６２Ｂの先端の曲率は１０Ｒとした。圧子６１を上方（打球面に垂直な方向）より５ｍｍ／ｍｉｎ（圧子速度）で降下させ、荷重時の変位からバネ定数を算出し、剛性値を測定した。測定の加重点が、それぞれ第１ヨークの長さ方向中心、第２ヨークの長さ方向中心の各位置になるようにした。即ち、７０ｍｍの切り出し部の中心位置が第１ヨークの長さ方向中心、第２ヨークの長さ方向中心の各位置になるようにした。ラケットフレームの測定部分としては、第１ヨークと第２ヨークとした。具体的には、第１ヨークの長さ方向中心位置と、第２ヨークの長さ方向中心位置を各々測定点として、圧子により荷重を加えた。第１ヨークの長さ方向中心位置での剛性値を第１ヨーク剛性、第２ヨークの長さ方向中心位置での剛性値を第２ヨーク剛性とした。
【００６７】
（面外１次振動減衰率の測定）
各実施例及び比較例のラケットフレームを図１０（Ａ）に示すようにガット張架部３の上端を紐５１で吊り下げ、ガット張架部３とスロート部４との一方の連続点に加速度ピックアップ計５３をフレーム面に垂直に固定した。この状態で、図１０（Ｂ）に示すように、ガット張架部３とスロート部４の他方の連続点をインパクトハンマー５５で加振した。インパクトハンマー５５に取り付けられたフォースピックアップ計で計測した入力振動（Ｆ）と加速度ピックアップ計５３で計測した応答振動（α）をアンプ５６Ａ、５６Ｂを介して周波数解析装置５７（ヒューレットパッカード社製、ダイナミックシングルアナライザーＨＰ３５６２Ａ）に入力して解析した。解析で得た周波数領域での伝達関数を求め、テニスラケットの振動数を得た。振動減衰比（ζ）は下式より求め、面外１次振動減衰率とした。各実施例及び比較例のラケットフレームについて測定された平均値を上記表２に示す。
【００６８】
ζ＝（１／２）×（Δω／ωｎ）
Ｔｏ＝Ｔｎ／√２
【００６９】
（面外２次振動減衰率の測定）
ラケットフレームを図１０（Ｃ）に示すようにガット張架部３上端を紐５１で吊り下げ、スロート部４とシャフト部５との連続点に加速度ピックアップ計５３をフレーム面に垂直に固定した。この状態で、加速度ピックアップ計５３の裏側のフレームをインパクトハンマー５５で加振した。そして、面外１次振動減衰率と同等の方法で減衰率を算出し、面外２次振動減衰率とした。各実施例及び比較例のラケットフレームについて測定された平均値を上記表１に示す。
【００７０】
（反発係数の測定）
反発係数は、図１１に示すように、実施例及び比較例のラケットフレーム１を垂直状態でフリーとなるようにグリップ部を柔らかく吊り下げて、その打球面にボール打出機から一定速度Ｖ１（３０ｍ／ｓｅｃ）でテニスボールを打球面に衝突させ、跳ね返ったボールの速度Ｖ２を測定した。反発係数は発射速度Ｖ１、反発速度Ｖ２の比（Ｖ２／Ｖ１）であり、反発係数が大きい程、ボールの飛びが良いことを示している。このような方法で反発係数を測定した。
【００７１】
（実打評価）
テニスラケットの打球時の振動・飛びについてアンケート調査を行った。高得点ほど衝撃および不快感が少なく、また、飛びが良く、５点法（５点満点）で評価した。評価は、中・上級プレーヤー（テニス歴１０年以上、現在も週３日以上プレーする条件を満たす女性）５０名の採点結果の平均値をとった。
【００７２】
前記表１に示すように、第１ヨークまたは第２ヨークのいずれか一方をフレーム本体と別体とした実施例１〜６のラケットフレームは、ヨークをフレーム本体と一体成形した比較例１、２のラケットフレームに比べ、振動減衰性に優れていることが確認できた。また、ヨークとフレーム本体の接合部分に制振フィルムを介在させることにより、振動減衰性が大幅に向上することが確認できた。
【００７３】
また、第１ヨークをフレーム本体と別体とした実施例１、３〜６は、反発性能において特に優れていることが確認できた。
また、実打テストからも上記と同様の結果を得ることができた。
【００７４】
【発明の効果】
以上の説明より明らかなように、本発明によれば、ダブルヨークとするラケットフレームにおいて、フレーム本体と一方のヨークとを金型内で一体的成形せずに、フレーム本体に後付けで連結している。そのため、結合されたフレーム本体とヨークとの接合面は一体化させていないため、ラケットフレームの変形時に発生する剪断荷重が分散されずに上記接合面に集中して負荷され、それにより、フレーム全体に発生する振動を抑制することができる。
【００７５】
他方のヨークをフレーム本体と一体成形することで、フレーム本体の剛性を向上し、打球時に発生するフレーム本体の捻れを抑制することができるため、反発性能を向上させることができる。
また、複数の別部材の結合により振動減衰性を向上させているため、余分な重量増がなく、軽量である上に、機械的結合手段により結合させているため、剛性が低下することもなく、高い振動減衰性を得ることができる。
【００７６】
さらに、フレーム本体とヨークとの接合面の面積や、材料や接着剤の選定、形状の変更等により、打球感の好みにもなる振動減衰性の制御を可能としており、プレーヤーに応じた最適なラケットフレームを設計することができる。
【図面の簡単な説明】
【図１】本発明の第１実施形態のラケットフレームの概略正面図である。
【図２】フレーム本体と第１ヨークの要部拡大図である。
【図３】スロート部の断面図である。
【図４】本発明の第１実施形態の第１変形例ののラケットフレームの要部舞概略正面図である。
【図５】本発明の第１実施形態の第２変形例ののラケットフレームの要部概略正面図である。
【図６】本発明の第１実施形態の第３変形例ののラケットフレームの要部概略正面図である。
【図７】本発明の第２実施形態のラケットフレームの概略正面図である。
【図８】（Ａ）（Ｂ）（Ｃ）は第２実施形態の第１、第２、第３変形例の要部概略正面図である。
【図９】ヨーク剛性値の測定方法を示す図面である。
【図１０】（Ａ）（Ｂ）（Ｃ）はラケットフレームの振動減衰率の測定方法を示す概略図である。
【図１１】反発係数の測定方法を示す図面である。
【図１２】従来例を示す正面図である。
【符号の説明】
１　ラケットフレーム
２　フレーム本体
３　ヘッド部
４　スロート部
４ａ、４ｂ　両側部
５　シャフト部
６　グリップ部
１０（１０’）　第１ヨーク
１０Ａ　ヨーク本体
１０Ｂ　スロート接合用連結補助部
１０Ｃ　ヨーク接合用連結補助部
１０ａ　凹部
１１（１１’）　第２ヨーク[0001]
[Technical field to which the invention belongs]
INDUSTRIAL APPLICABILITY The present invention is suitably used as a racket frame, in particular, a hard tennis racket frame. Specifically, the structure of a yoke connected to the frame body is improved to improve vibration damping.
[0002]
[Prior art]
In recent years, racket frames are required to have performances such as lightness, high rigidity, high strength, and durability, and fiber reinforced resin (hereinafter referred to as FRP) is mainly used as a constituent material. Usually, the racket frame is formed from a thermosetting resin reinforced with high-strength, high-modulus fiber such as carbon fiber.
The fiber reinforced resin using the thermosetting resin as a matrix resin is excellent in rigidity, but there is a problem that the player easily becomes a tennis elbow because vibration is likely to occur when subjected to an impact.
[0003]
Therefore, for example, organic fibers such as aramid fibers and ultra high molecular weight polyester fibers may be used to improve the vibration damping properties of FRP using epoxy resin as a matrix resin and carbon fiber continuous fibers as reinforcing fibers. The vibration attenuation rate is 0.6 or less, the vibration attenuation rate is not so high, and the rigidity and strength are small. Therefore, reinforcement with only organic fibers has a problem in rigidity.
[0004]
Therefore, in recent years, a racket frame made of a fiber reinforced thermoplastic resin reinforced with continuous fibers using a thermoplastic resin excellent in vibration damping as a matrix resin has been provided. Specifically, a polyamide resin is used as a matrix resin, and continuous fibers or short fibers are used as reinforcing fibers, and the production methods are classified into the following three types. The vibration attenuation rate of the racket frame made of this fiber reinforced thermoplastic resin is 0.9 or more and has excellent vibration attenuation.
(1) Injection molding of polyamide resin containing short fibers. (Vibration damping factor 1.9%)
(2) The fibers of the matrix material and the reinforcing fibers are laminated in the shape of a fiber, and an internal pressure is applied at a high temperature, and the matrix resin is melted and molded. (Vibration damping factor 0.92%)
(3) Reactive injection molding (RIM) of polyamide resin monomer by preliminarily placing reinforcing fibers in the mold. (Vibration damping rate 1.1%)
The racket frame made of the above-mentioned fiber reinforced thermoplastic resin reflects the high toughness of the thermoplastic resin, and provides characteristics such as impact resistance and vibration damping that were not achieved with conventional thermosetting resin rackets. ing.
[0005]
However, in general, thermoplastic resins are more dependent on the environment in terms of elastic modulus and strength than thermosetting resins, and have such drawbacks that characteristics such as rigidity tend to change depending on the environment in which the racket frame is used.
[0006]
In order to solve the respective problems when the matrix resin is a thermoplastic resin and a thermosetting resin, a racket frame in which a thermoplastic resin and a thermosetting resin are combined has also been proposed.
For example, in Japanese Patent Laid-Open No. 6-63183, a portion extending from the throat portion to the grip portion is formed with a thermoplastic resin matrix, and a gut stretch portion (face portion) surrounding the hitting surface is formed from a thermosetting resin matrix. .
Japanese Patent Laid-Open No. 2000-70415 uses RIM nylon partially, previously formed a carbon fiber / RIM nylon yoke, and then placed in a mold of the frame main body. It is integrally formed with a laminate made of an epoxy resin prepreg.
[0007]
On the other hand, in order to improve the resilience of the racket, in Japanese Patent Laid-Open No. 7-275401, there is a double yoke racket provided with a first yoke 100 surrounding the striking surface shown in FIG. 12 and a second yoke 101 bridged in the throat part. Proposed.
In this double yoke racket, the gut 102 is passed through the through hole of the first yoke 100 and stretched through the second yoke 101, thereby increasing the substantial length of the gut 102 and expanding the sweet area and resilience. Is increasing.
[0008]
[Problems to be solved by the invention]
In the racket frame disclosed in Japanese Patent Laid-Open No. 6-63183, which is intended to enhance vibration damping, not only is it easily affected by the use environment but also the vibration mode of the racket because half of the frame body is formed of a thermoplastic resin matrix. Is not considered, and there is a problem that an effective vibration damping effect cannot be obtained.
Further, in the racket frame of JP-A-2000-70415 described later, since the string tension and the load at the time of hitting hit the joint portion between the yoke and the frame body directly, it is necessary to make the adhesion by integral molding very strong, In practice, there arises a problem that cracks occur at the joint. Further, although shear stress is generated at the interface of the joint portion, it is difficult to suppress frame vibration by that portion.
[0009]
In addition to the demand for increased vibration damping, the racket frame emphasizes the operability of the racket to support play styles such as spinning, and the weight is further reduced (reduction of moment of inertia). Has come to be desired. Therefore, when a vibration damping material that is separate from the racket frame is attached, there is a problem that the racket weight increases.
Furthermore, there is a case where a spin is applied with a wide portion of the hitting surface as a hit point, and an expansion of the sweet area is also desired.
However, in the case of the double yoke of FIG. 12, the gut 102 penetrating the first yoke 100 tends to generate vibration in the first yoke 100 at the time of hitting, and this vibration is transmitted from the frame body to the player, but the vibration is suppressed. There is a disadvantage that means are not provided.
[0010]
Furthermore, it has been found that the stability of the hitting surface is required in the racket for the player, and so-called in-plane rigidity is an important performance.
As described above, the racket frame is required to be light and easy to operate, and to have good vibration damping while having high rigidity, high strength, high repulsion and high surface stability.
[0011]
The present invention has been made in view of the above-described demands, and it is an object to provide a racket frame that has moderate vibration damping properties and is capable of controlling vibration damping properties, is lightweight, and has high rigidity and stability. It is said.
[0012]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the present invention has a throat portion that is continuous between the head portion and the shaft portion of the frame body, and a first yoke and a second yoke are provided between both side frames of the throat portion, The first yoke and the head portion are continuous to surround the ball striking surface, and one of the first yoke and the second yoke is formed of a material different from that of the frame body and mechanically joined to the frame body. A racket frame is provided in which the other yoke is formed as a unitary structure in the frame body and the mold by being joined together with and / or an adhesive.
[0013]
In the present invention, attention is paid to the coupling portion between the frame main body and the yoke, and vibration generated in the frame main body at the coupling portion can be effectively damped. As described above, the vibration damping performance is mainly provided at the joint between the frame main body and the yoke, so that the frame main body can be arbitrarily selected from materials that are mainly light in weight, rigid and strong.
[0014]
Conventionally, a racket frame made of ordinary FRP is integrally formed by inserting a layup (preliminary molded body) in which a prepreg constituting a frame body is wound around a tube and a yoke material into a cavity of a mold. . Therefore, the resin constituting the yoke and the resin of the frame main body are melted and firmly integrated. Therefore, stress is not concentrated on the joint surface (boundary) between the yoke and the frame body when the racket frame is deformed.
On the other hand, in the present invention, a double yoke having a first yoke and a second yoke is provided, and one of the yokes is not formed integrally with the frame body in the mold, but is formed as a separate body. And / or retrofitting with an adhesive. Since the joint surface between the frame main body and the yoke combined in this way is not an integral structure melted with each other, the shear load generated when the racket frame is deformed can be concentrated on the joint surface. As a result, vibration generated in the entire frame can be absorbed by the joint surface between the yoke and the frame body, and vibration attenuation can be achieved.
In particular, the portion where the yoke is coupled to the frame main body is a part where the frame is greatly deformed in the out-of-plane primary vibration or secondary vibration, and thus it is easy to concentrate the shear load on the joint surface. As a result, the racket frame Vibration generated on the whole can be effectively suppressed, and a racket frame with high vibration damping can be obtained.
[0015]
In addition, the other yoke is formed integrally with the frame body and the mold in the same manner as in the past, and the resin is melted to form an integral structure, so that the rigidity of the racket frame can be increased, and the ball collision The twist of the racket frame which sometimes occurs can be suppressed. Thereby, energy loss becomes small and resilience can be improved.
In this way, vibration damping can be achieved by the yoke formed separately and joined to the frame body, and the resilience can be improved by the yoke integrally formed with the frame body, so that both the vibration damping and the resilience can be achieved. Can be planned.
[0016]
The yoke formed of a material different from that of the frame main body includes a connection auxiliary portion extending to the other yoke side at both ends connected to the frame main body, and the connection auxiliary portion is joined to the inside of the throat portion. Preferably it is.
Furthermore, the connection auxiliary portion may extend to the other yoke, and the connection auxiliary portion may be joined to the throat portion and the other yoke.
[0017]
With the above structure, the joining area between the frame main body and the yoke can be changed, the vibration damping property can be controlled, and the vibration damping factor can be set appropriately according to the preference of the shot feeling.
[0018]
The area of each joint surface between the frame body and the yoke to be joined later as a separate body is at least 10 cm. ² Above, preferably 20cm ² Or more, more preferably 30 cm ² That's it.
The area is 10cm ² If it is smaller, there is a problem that a sufficient vibration damping effect cannot be obtained. From the viewpoint of vibration damping properties, it is better that the area of the joint surface is larger, but 60 cm from the point of racket frame strength and weight. ² It is preferable that:
[0019]
The other yoke formed integrally with the frame body may be formed of the same material as the frame body.
Specifically, when the first yoke that is continuous with the head portion of the frame body and surrounds the ball striking surface is formed of a material different from that of the frame body and is formed of a thermoplastic resin having a rigidity lower than that of the frame body, the first yoke The movable range of the gut stretched on the ball when hitting is increased, and the resilience can be improved.
On the other hand, if the second yoke attached to the region surrounded by both sides of the first yoke and the throat portion is formed integrally with the frame main body, the second yoke can suppress the twist of the throat portion at the time of hitting the ball. The energy loss at the time of hitting can be reduced, and the resilience performance can be improved.
[0020]
The first yoke that is integrally formed in the frame body and the mold may be formed integrally with the frame body and the mold, and the second yoke may be formed of a material different from that of the frame body. In this case, if the first yoke is formed of a highly rigid resin in the same manner as the frame main body, twisting of the frame main body at the time of hitting can be suppressed, and the resilience can be improved and the controllability can be improved.
[0021]
It is preferable that a vibration absorbing material is interposed in at least a part of a joint surface where the yoke formed of a material different from that of the frame body and the frame body are mechanically joined and / or joined via an adhesive.
[0022]
The mechanical bonding means is a means for bonding without using an adhesive material or chemical bonding force, and is a means for bonding by a combination of a difference in shape or the like of objects to be bonded or a combination of changes. Specific examples include uneven fitting, screwing, fitting, meshing, hook locking, bolts / nuts, springs, etc., and uneven fitting, screwing, etc. are preferably used.
This mechanical coupling force naturally needs to be able to maintain the string force and to withstand the impact force of the ball.
Specifically, one of the inner surface of the frame body and the joint surface of the yoke is provided with a convex portion or a concave portion, while the other is provided with a concave portion or a convex portion that fits into the convex portion or the concave portion, and these are provided by concave and convex fitting. Are connected.
In that case, if the convex part is provided in the frame main body and the concave part is provided in the yoke, the restriction of the yoke with respect to the frame main body is reduced, and the fitting can be easily performed. Moreover, it is preferable that the hollow part is provided in the frame main body according to the shape of the connection auxiliary part. Thereby, since a connection auxiliary | assistant part and a frame main body are fittingly locked together, both position shift can be prevented and a coupling force can be raised.
[0023]
As said adhesive agent, a highly flexible thing is preferable and there exist adhesive agents, such as urethane type, besides an epoxy type, and a specific example is enumerated below.
-High peel strength impact resistant adhesive based on cyanoacrylate and elastomer. For example, 1731/1733 manufactured by Three Bond.
-A room temperature curing type two-component epoxy resin having stable toughness by uniformly dispersing rubber fine particles in an epoxy resin, for example, 2082C of Three Bond Co., Ltd.
A one-component moisture-curing elastic adhesive that contains a silyl group-containing special polymer as the main component and cures by reacting with a small amount of moisture in the air. For example, 1530 manufactured by ThreeBond.
・ Urethane adhesive "Esprene"
・ Ciba Geigy "Redux 609""AW106 / HV953U""AW136A / B"
・ LOCTITE "E-214"
・ 3M "DP-460""9323B / A"
[0024]
When mechanically bonded or / and bonded with an adhesive as described above, the bonding force between the frame body and the yoke can be secured, and the vibration damping is improved by this bonding. It is not necessary to attach to the head, there is no extra weight increase, and the weight can be reduced.
[0025]
Furthermore, as described above, if a vibration absorbing material (damping film / sheet / damping paint) is interposed in at least a part of the joint surface of the joint between the yoke and the frame body, the vibration damping effect is further increased. Can be increased
Further, the damping performance can be easily adjusted by selecting the vibration absorbing material.
These vibration absorbing materials may be used alone or in combination with an adhesive.
When the adhesive and the vibration absorbing material are interposed on the joint surface between the frame main body and the yoke, it is possible to prevent the generation of unpleasant sound.
As the vibration damping film, a dice porgy film manufactured by CCI is preferably used.
[0026]
The frame body is made of a pipe integrally formed from a fiber reinforced resin, and continuously forms a head portion (gut stretch portion), a throat portion, a shaft portion, and a grip portion surrounding the hitting surface. Thus, by forming the frame main body from one member, the shear load is concentrated on the joint surface of the joint portion between the frame main body and the separate yoke.
The frame body preferably uses continuous fibers as reinforcing fibers in terms of weight reduction, rigidity, and strength. The matrix resin may increase strength and rigidity as a thermosetting resin, and may further increase vibration damping as a thermoplastic resin. That is, by giving the vibration damping function to the joint surface between the frame main body and the separate yoke, the FRP of the frame main body is arbitrarily selected according to the main function of the racket frame.
[0027]
Examples of the resin used in the racket frame of the present invention include a thermosetting resin and a thermoplastic resin. Specifically, examples of the thermosetting resin include an epoxy resin, an unsaturated polyester resin, and a phenol resin. Examples include resins, melamine resins, urea resins, diallyl phthalate resins, polyurethane resins, polyimide resins, silicon resins, and the like. As thermoplastic resins, polyamide resins, saturated polyester resins, polycarbonate resins, ABS resins, polyvinyl chloride resins, polyacetal resins, polystyrene resins, polyethylene resins, polyvinyl acetate resins, AS resins, methacrylic resins , Polypropylene resin, fluorine resin and the like.
[0028]
Moreover, as a reinforcing fiber used for fiber reinforced resin, the fiber generally used as a high performance reinforcing fiber can be used. For example, carbon fiber, graphite fiber, aramid fiber, silicon carbide fiber, alumina fiber, boron fiber, glass fiber, aromatic polyamide fiber, aromatic polyester fiber, ultrahigh molecular weight polyethylene fiber, and the like can be given. Metal fibers may also be used. Carbon fiber is preferred because of its light weight and high strength. These reinforcing fibers may be either long fibers or short fibers, and two or more of these fibers may be mixed and used. The shape and arrangement of the reinforcing fibers are not limited. For example, any shape and arrangement such as a single direction, a random direction, a sheet shape, a mat shape, a woven fabric (cross) shape, and a braided shape can be used.
[0029]
The frame body is not limited to a prepreg laminate, and a layup is formed by winding reinforcing fibers around a mandrel with filament winding, and this is placed in a mold to rim nylon or the like. A frame body formed by filling a thermoplastic resin can also be used.
[0030]
The yoke made of a material different from that of the frame main body is made of fiber reinforced resin, resin alone, metal, wood, or a composite material thereof.
As said metal, lightweight metals, such as aluminum, titanium, magnesium, or the alloy which has each metal as a main component is used. In view of the high vibration damping effect, a fiber reinforced thermoplastic resin is more preferable. As the matrix resin, for example, a polyamide resin or an alloy of polyamide and ABS is preferably used.
[0031]
The manufacturing method of the yoke is
Manufacturing method of injection molding in a state reinforced with short fibers such as carbon fiber,
A method of weaving a polyamide fiber and a carbon fiber combed yarn in a braid (braid), and heating and melting the polyamide in the reinforcing fiber;
It is possible to employ a method of molding RIM nylon, in which a foamed epoxy is coated with a nylon tube and carbon braid is further laminated to inject a RIM nylon monomer.
[0032]
Of the first yoke or the second yoke, the rigidity value of the yoke that is separate from the frame main body is 60 kgf / cm or more and 500 kgf / cm or less.
The reason for the above range is that if the yoke stiffness value is smaller than 60 kgf / cm, the strength of the yoke tends to be weak. On the other hand, if it is greater than 500 kgf / cm, the yoke will not be sufficiently bent and the coefficient of restitution will be difficult to improve.
In addition, Preferably it is 100 kgf / cm or more and 450 kgf / cm or less, More preferably, it is 200 kgf / cm or more and 350 kgf / cm or less.
[0033]
The rigidity value of the yoke is a rigidity value measured at the central position in the longitudinal direction of the yoke in the direction perpendicular to the ball striking surface (frame thickness direction). As will be described later, the rigidity value is measured by a three-point bending method so that the distance between the two fulcrums is 70 mm and the center position between the two fulcrums is the rigidity measurement position (the center position in the longitudinal direction of the yoke). Measuring.
[0034]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the drawings of the following embodiments, the yoke to be retrofitted is shown with a cross hatching, clearly distinguishing it from the other yoke formed integrally with the frame body.
[0035]
1 to 3 show a racket frame 1 according to a first embodiment of the present invention.
The racket frame 1 includes a frame body 2, a first yoke 10, and a second yoke 11. The frame body 2 comprises a head part (gut stretch part) 3 surrounding the ball striking face F, a throat part 4, a shaft part 5, and a grip part 6, and the first yoke 10 is connected to the frame body 2 by retrofitting. The first yoke 10 and the head portion 3 surround the ball striking surface. The second yoke 11 is connected to the throat portion 4 in a region surrounded by the first yoke 10 and the throat portion 4, and is formed as an integral structure in the frame body 2 and the mold.
[0036]
The first yoke 10 includes a yoke main body 10A that closes the opening of the head portion 3 and surrounds the ball striking surface, and extends from both ends of the yoke main body 10A that joins the frame main body 2 to the left and right side portions 4a of the throat portion 4. The throat bonding auxiliary connecting portion 10B for bonding to the inner surface of 4b, and the second yoke connecting auxiliary connecting portion 10C for connecting the lower end of the throat bonding auxiliary connecting portion 10B to the second yoke 11 are provided. It has a trapezoidal frame shape. The area where the first yoke 10 and the frame body 2 are joined is 30 cm. ² It is said.
[0037]
While the concave portions 10a are provided at both ends of the yoke body 10A, the convex portions 2a are projected from the inner surface of the corresponding frame body 2, and the concave portions 10a are fitted into the convex portions 2a to perform mechanical coupling. ing. Further, the first yoke 10 and the frame main body 2 are coupled with a urethane adhesive in addition to the mechanical coupling.
[0038]
As shown in FIG. 3, the throat joint connection auxiliary portion 10B extending from both ends of the yoke main body 10A is bonded with an adhesive by overlapping the outer surface 10d with the inner surfaces 2d of the left and right side frames 2 of the throat portion 4. ing. The dimension W2 in the thickness direction of the auxiliary connecting portion 10B is made smaller than the dimension W1 in the thickness direction of the frame body 2 so that the first yoke 10 does not protrude from the frame body 2.
[0039]
The weight of the first yoke 10 to be retrofitted is 10 to 30 g, and is about 5 to 20% of the low frame weight composed of the total weight of the first yoke 10, the second yoke 11 and the frame body 2.
The racket frame of the embodiment has a hitting area of 115 square inches and a racket frame weight of 246 g.
[0040]
The frame body 2 forms a layup (preliminary molded body) in which prepregs in which reinforcing fibers made of carbon fibers are impregnated with an epoxy resin of a matrix resin are formed on the outer periphery of the tube, and this is heated and cured in a mold. Forming.
The first yoke 10 to be retrofitted is made of a material in which 6% nylon, which is a thermoplastic resin, is filled with 30% carbon fiber (short fiber) having a length of 1 mm, and is made of a solid injection-molded body.
The second yoke 11 is made of a laminated body of carbon fiber prepregs like the frame body 2.
[0041]
The frame body 2 and the second yoke 11 layup (preliminary molded body) are inserted into the mold cavity and clamped, and then heated and cured while supplying the required pressure to the tube of the frame body 2, The frame body 2 and the second yoke 11 are formed as an integral structure.
As described above, after the frame body 2 and the second yoke 11 are integrally formed by a mold, the first yoke 10 is retrofitted to the frame body 2, and the head portion 3 and the first yoke 10 of the frame body 2 are then attached. And surrounding the ball striking face.
[0042]
As described above, in the racket frame 1 of the first embodiment, the first yoke 10 is retrofitted to the frame body 2 and is bonded by the mechanical coupling means and the adhesive. Therefore, the shearing force generated by the deformation of the head portion 3 at the time of hitting the ball concentrates on the joint surface between the first yoke 10 and the frame body 2, and the vibration damping performance of the racket frame 1 can be enhanced. Furthermore, since the coupling auxiliary portions 10B and 10C are joined to the throat portion 4 and the second yoke 11, vibration generated in the throat portion 4 and the second yoke 11 is also absorbed by the joint surface with the coupling auxiliary portions 10B and 10C. Can do.
[0043]
On the other hand, since the second yoke 11 attached to the area surrounded by both sides of the first yoke 10 and the throat portion 4 is formed integrally with the frame main body 2, the second yoke 11 allows the throat portion at the time of hitting the ball to be hit. 4 can be suppressed, energy loss during hitting can be reduced, and resilience performance can be improved.
In addition, since the first yoke 10 is formed of a thermoplastic resin that is less rigid than the frame body 2 and has excellent vibration damping properties, the movable range of the gut stretched over the first yoke 10 during hitting is increased, Resilience can be improved.
Furthermore, since the vibration damping function has a vibration damping function at the joint between the first yoke 10 and the frame main body 2, there is no need to separately attach a vibration damping member to the racket frame, and there is no extra weight increase, The racket frame can be made lightweight.
[0044]
FIG. 4 shows a first modification of the first embodiment.
In the above-described embodiment, the first yoke 10 and the frame body 2 are coupled by the mechanical coupling means and the adhesive. However, the vibration damping property is further improved by interposing the damping film 200 on the joint surface between the first yoke 10 and the frame body 2. be able to.
[0045]
FIG. 5 shows a second modification of the first embodiment. The first yoke 10 to be retrofitted is a second yoke joint that joins the second yoke 11 by extending only the throat joint connection auxiliary portion 10B from the yoke body 10A. There is no connection auxiliary part. Other configurations are the same as those of the first embodiment.
[0046]
FIG. 6 shows a third modification of the first embodiment. The first yoke 10 to be retrofitted is provided with only the yoke main body 10A, and is not provided with a connection auxiliary portion for joining with the throat and the second yoke.
[0047]
Even if the connection assisting portion is made smaller or eliminated as in the second and third modifications, vibrations can be absorbed by the portions where both ends of the yoke body are coupled to the frame body.
In the above embodiment, a urethane-based adhesive is used for the joint surface between the first yoke and the frame main body. However, an adhesive having excellent vibration absorption may be used depending on the required performance. good.
In the above embodiment, the first yoke is molded from a thermoplastic resin, and is particularly excellent in moldability and vibration damping properties. However, the first yoke can also be a hollow body made of fiber reinforced resin, which increases strength and lightness. You can also.
[0048]
FIG. 7 shows a racket frame 1 according to the second embodiment of the present invention.
In the second embodiment, the first yoke 10 ′ is integrally formed with the frame main body 2 and the mold, while the second yoke 11 ′ is retrofitted to the frame main body 2.
[0049]
The second yoke 11 ′ is made of a material in which 6% nylon, which is a thermoplastic resin, is filled with 30% carbon fiber (short fiber) having a length of 1 mm, and is made of a solid injection-molded body. The frame main body 2 is the same as that of the first embodiment, and the first yoke 10 'is formed of the same material as the frame main body.
[0050]
The second yoke 11 ′ has both ends of the yoke body 11A ′ coupled to the left and right side frames 4a and 4b of the throat part 4 in a region surrounded by the left and right side frames of the throat part 4 and the first yoke 10 ′. . Furthermore, the throat joint connection auxiliary portion 11B ′ for joining to the inner surfaces of the left and right side frames 4a and 4b of the throat portion is extended from the both end joint portion toward the first yoke 10 ′ side, and the tip is connected. A yoke auxiliary connecting portion 11C ′ for joining to the lower surface (the surface opposite to the ball striking surface side) of the first yoke 10 ′ is provided, and has an inverted trapezoidal frame shape.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.
[0051]
The second yoke 11 ′ and the frame body 2 are coupled with a urethane adhesive. The frame body 2 and the second yoke 11 ′ thus coupled can concentrate the shearing force generated when the racket frame 1 is deformed on the joint surface, and can improve the vibration damping property.
[0052]
In this embodiment, the weight of the second yoke 11 ′ is 20 g in this embodiment, and is about 12% of the low frame weight, which is the total weight of the second yoke 11 ′ and the frame body 2 ′. The hitting area is 115 square inches and the racket frame weight is 244 g.
[0053]
In the racket frame 1 according to the second embodiment, the second yoke 11 ′ is joined to the frame body 2 by an adhesive, and the shearing force generated when the racket frame 1 is deformed is concentrated on the joint surface between them. The vibration damping performance of the racket frame 1 can be enhanced. Further, since the first yoke 10 'is formed of a highly rigid resin like the frame main body 2, the twist of the frame main body 2' can be suppressed at the time of hitting, and the resilience is improved and the controllability is improved. improves.
[0054]
8A, 8B, and 8C show a modification of the second embodiment.
FIG. 8A corresponds to a first modification of the second embodiment of FIG. 4, and a damping film 200 is interposed on the joint surface between the second yoke 11 ′ and the frame body 2.
FIG. 8B corresponds to a second modification of the second embodiment, and only the throat joint connection auxiliary portion 11B ′ is extended from the yoke body 11A ′ of the second yoke 11 ′, and the first yoke 10 ′. Is not joined.
FIG. 8C corresponds to a third modification of the second embodiment. The second yoke 11 ′ is only the yoke body 11 A ′, and both ends thereof are joined to the frame body 2.
[0055]
Examples 1 to 6 and Comparative Examples 1 and 2 of the racket frame of the present invention were prepared and measured for physical properties.
In both the examples and the comparative examples, the frame body has a hollow shape made of fiber reinforced resin, has a cross-sectional shape with a thickness of 28 mm, a width of 13 mm to 16 mm, and has the same shape with a hitting area of 115 square inches. Created by.
A fiber reinforced thermosetting resin prepreg sheet (CF prepreg (Toray T300, 700, 800, M46J)) made of carbon fiber is laminated on a mandrel (φ14.5) covered with an internal pressure tube made of 66 nylon. Then, a vertical laminate was molded. The prepreg angles were 0 °, 22 °, 30 °, and 90 °, and laminated. The mandrel was extracted and the laminate was set in a mold. The mold is clamped, the mold is heated to 150 ° C., heated for 30 minutes, and at the same time, 9 kgf / cm in the internal pressure tube ² The air pressure was applied, the pressure was maintained, and the product was formed by heating and pressing. Table 1 below shows the material, joining mode, weight, and balance of the first yoke and the second yoke.
[0056]
[Table 1]

[0057]
(Example 1)
The shape was the same as that of the first embodiment, but the uneven portion for mechanical joining was not provided, and the separate first yoke and the frame body were fixed with an adhesive. The second yoke was formed integrally with the frame body. For the first yoke, a material in which 6 nylon was filled with 30% carbon fiber (short fiber) having a length of 1 mm was used. A solid yoke was injection molded using an injection mold.
[0058]
(Example 2)
Corresponding to the second embodiment, the second yoke and the frame main body are separated, and the first yoke is integrally formed with the frame main body. For the second yoke, a material in which 6 nylon was filled with 30% carbon fiber (short fiber) having a length of 1 mm was used. A solid yoke was injection molded using an injection mold. The shape of the second yoke was the same as that of the second embodiment. Others were the same as in Example 1.
[0059]
(Example 3)
Corresponding to the first embodiment, similarly to Example 1, the first yoke and the frame main body were separated, and the second yoke was formed integrally with the frame main body. For the first yoke, a material in which 6 nylon was filled with 30% carbon fiber (short fiber) having a length of 1 mm was used. A solid yoke was injection molded using an injection mold. The shape of the first yoke was the same as that of the first embodiment, and a concave portion was disposed in the yoke, and mechanical joining was performed by fitting with the convex portion of the frame body. Others were the same as in Example 1.
[0060]
Example 4
Corresponding to the first modification of the first embodiment, like the first example, the first yoke and the frame body are separated, and the second yoke is formed integrally with the frame body. A vibration damping film was interposed between the joints of the first yoke and the frame body. Others were the same as in Example 3.
[0061]
(Example 5)
This corresponds to a second modification of the first embodiment, and the first yoke and the frame main body are separated as in the first embodiment, and the second yoke is formed integrally with the frame main body. As for the shape of the first yoke, the connection auxiliary portion extending from the yoke main body was not extended to the second yoke, but was joined only to the throat portion. Further, a concave portion was disposed in the first yoke, and mechanical joining was performed by fitting with the convex portion of the frame body. Others were the same as in Example 1.
[0062]
(Example 6)
This corresponds to a third modification of the first embodiment, in which the first yoke and the frame main body are separated, and the second yoke is integrally formed with the frame main body. The shape of the first yoke is only the yoke body without providing the connection auxiliary portion extending from the yoke body. Further, the first yoke and the frame main body were not provided with an uneven portion for mechanical joining, and were joined with an adhesive. Others were the same as in Example 1.
[0063]
(Comparative Example 1)
Only the first yoke was provided, and the second yoke was not provided. The first yoke was formed in advance, and the first yoke and the frame main body were integrally formed with a mold when the frame main body was formed. The first yoke was made of the same material as the frame body.
[0064]
(Comparative Example 2)
The first yoke and the second yoke were formed in advance, and the first yoke, the second yoke, and the frame body that were previously formed at the time of forming the frame body were integrally formed. The second yoke was provided at a substantially central position of the throat portion so as to bridge the left and right throat portions. The first yoke and the second yoke were made of the same material as the frame body.
[0065]
Regarding the racket frames of Examples 1 to 6 and Comparative Examples 1 and 2, the out-of-plane primary attenuation rate, the out-of-plane secondary attenuation rate, and the coefficient of restitution (3 points) were measured by the methods described later. An actual hit test was also conducted.
[0066]
(Yoke rigidity)
As shown in FIG. 9, a universal testing machine 60 was used to measure the stiffness value by three-point bending. The measurement part (required position of the yoke) of the racket frame 1 was arranged on the jigs 62A and 62B so that the measurement point was below the indenter 61 of the universal testing machine 60. The interval between the jigs 62A and 62B was 70 mm. An indenter 61 was set at the center of the jig 62A and the jig 62B. The curvature of the tip of the indenter 61 was 5R, and the curvature of the tips of the jigs 62A and 62B was 10R. The indenter 61 was lowered at a rate of 5 mm / min (indenter speed) from above (in a direction perpendicular to the ball striking surface), the spring constant was calculated from the displacement under load, and the stiffness value was measured. The weighting points for measurement were set to the respective positions in the longitudinal center of the first yoke and the longitudinal center of the second yoke. That is, the center position of the 70 mm cut-out portion was set to be the center of the first yoke in the length direction and the position of the second yoke in the length direction. The measurement part of the racket frame was the first yoke and the second yoke. Specifically, a load was applied by an indenter with the longitudinal center position of the first yoke and the longitudinal center position of the second yoke as measurement points. The rigidity value at the center position in the length direction of the first yoke was defined as the first yoke rigidity, and the rigidity value at the center position in the length direction of the second yoke was defined as the second yoke rigidity.
[0067]
(Measurement of out-of-plane primary vibration damping rate)
As shown in FIG. 10A, the racket frame of each example and comparative example is suspended by the string 51 at the upper end of the gut stretcher 3 and accelerated to one continuous point of the gut stretcher 3 and the throat 4. A pickup meter 53 was fixed perpendicularly to the frame surface. In this state, as shown in FIG. 10B, the other continuous point of the gut stretch portion 3 and the throat portion 4 was vibrated with an impact hammer 55. An input vibration (F) measured by a force pickup meter attached to the impact hammer 55 and a response vibration (α) measured by an acceleration pick-up meter 53 are subjected to a frequency analysis device 57 (manufactured by Hewlett-Packard Company, dynamics) through amplifiers 56A and 56B. Single analyzer HP3562A) was input and analyzed. The transfer function in the frequency domain obtained by the analysis was obtained, and the frequency of the tennis racket was obtained. The vibration damping ratio (ζ) was obtained from the following equation, and used as the out-of-plane primary vibration damping rate. Table 2 shows the average values measured for the racket frames of the examples and comparative examples.
[0068]
ζ = (1/2) × (Δω / ωn)
To = Tn / √2
[0069]
(Measurement of out-of-plane secondary vibration attenuation rate)
As shown in FIG. 10C, the upper end of the gut stretcher 3 is suspended by a string 51, and the acceleration pickup meter 53 is fixed perpendicularly to the frame surface at a continuous point between the throat 4 and the shaft 5. In this state, the frame on the back side of the acceleration pickup meter 53 was vibrated with an impact hammer 55. Then, the attenuation rate was calculated by a method equivalent to the out-of-plane primary vibration attenuation rate, and the out-of-plane secondary vibration attenuation rate was obtained. Table 1 shows the average values measured for the racket frames of the examples and comparative examples.
[0070]
(Measurement of coefficient of restitution)
As shown in FIG. 11, the coefficient of restitution is such that the grip portion is gently suspended so that the racket frames 1 of the example and the comparative example are free in the vertical state, and a constant velocity V1 (30 m) is applied to the ball striking surface from the ball launcher. / Sec), the tennis ball collided with the ball striking surface, and the velocity V2 of the rebounded ball was measured. The restitution coefficient is the ratio (V2 / V1) of the firing speed V1 and the rebound speed V2, and the larger the restitution coefficient, the better the ball flies. The coefficient of restitution was measured by such a method.
[0071]
(Actual hit evaluation)
A questionnaire survey was conducted on the vibration and flying of tennis rackets when hitting. The higher the score, the less impact and discomfort, the better the flying, and the evaluation was made by a 5-point method (full score 5). The evaluation was based on the average of the scoring results of 50 middle and advanced players (women who have played tennis for more than 10 years and still meet the requirements of playing more than 3 days a week).
[0072]
As shown in Table 1, the racket frames of Examples 1 to 6 in which either the first yoke or the second yoke is separated from the frame body are comparative examples 1 and 2 in which the yoke is integrally formed with the frame body. Compared to the racket frame, it was confirmed that the vibration damping was superior. It was also confirmed that the vibration damping property was greatly improved by interposing a damping film at the joint between the yoke and the frame body.
[0073]
Moreover, it was confirmed that Examples 1, 3 to 6 in which the first yoke was separated from the frame main body were particularly excellent in resilience performance.
In addition, the same results as above were obtained from the actual hit test.
[0074]
【The invention's effect】
As is clear from the above description, according to the present invention, in the racket frame as a double yoke, the frame main body and one yoke are connected to the frame main body by retrofitting without being integrally formed in the mold. Yes. For this reason, since the joined surfaces of the frame body and the yoke are not integrated, the shear load generated when the racket frame is deformed is concentrated and applied to the joined surface without being dispersed. The vibration which occurs in can be suppressed.
[0075]
By integrally molding the other yoke with the frame main body, the rigidity of the frame main body can be improved and the twist of the frame main body that occurs at the time of hitting can be suppressed, so that the resilience performance can be improved.
In addition, since vibration damping is improved by connecting a plurality of separate members, there is no extra weight increase and the weight is light, and since the connection is made by mechanical connection means, the rigidity does not decrease. High vibration damping can be obtained.
[0076]
In addition, the vibration attenuation can be controlled according to the feel of the shot by changing the area of the joint surface between the frame body and the yoke, selecting materials and adhesives, changing the shape, etc. A racket frame can be designed.
[Brief description of the drawings]
FIG. 1 is a schematic front view of a racket frame according to a first embodiment of the present invention.
FIG. 2 is an enlarged view of main parts of a frame main body and a first yoke.
FIG. 3 is a cross-sectional view of a throat portion.
FIG. 4 is a schematic front view of main parts of a racket frame according to a first modification of the first embodiment of the present invention.
FIG. 5 is a schematic front view of a main part of a racket frame according to a second modification of the first embodiment of the present invention.
FIG. 6 is a schematic front view of a main part of a racket frame according to a third modification of the first embodiment of the present invention.
FIG. 7 is a schematic front view of a racket frame according to a second embodiment of the present invention.
FIGS. 8A, 8B, and 8C are schematic front views of main parts of first, second, and third modified examples of the second embodiment. FIGS.
FIG. 9 is a drawing showing a method for measuring a yoke stiffness value.
FIGS. 10A, 10B, and 10C are schematic views illustrating a method of measuring a vibration attenuation rate of a racket frame.
FIG. 11 is a drawing showing a method for measuring the coefficient of restitution.
FIG. 12 is a front view showing a conventional example.
[Explanation of symbols]
1 Racket frame
2 Frame body
3 Head
4 Throat
4a, 4b Both sides
5 Shaft part
6 Grip part
10 (10 ') 1st yoke
10A Yoke body
10B Connection auxiliary part for throat joint
10C Yoke joint auxiliary connection part
10a recess
11 (11 ') 2nd yoke

Claims (6)

The throat portion where the head portion of the frame body and the shaft portion are continuous is bifurcated, and a first yoke and a second yoke are provided between both side frames of the throat portion so that the first yoke and the head portion are continuous. To surround the ball striking face,
Either one of the first yoke and the second yoke is formed of a material different from that of the frame main body, and is mechanically joined to the frame main body by retrofitting and / or bonded via an adhesive. A racket frame characterized in that the yoke is formed as an integral structure in the frame body and the mold. The yoke formed of a material different from that of the frame main body includes a connection auxiliary portion extending to the other yoke side at both ends connected to the frame main body, and the connection auxiliary portion is joined to the inside of the throat portion. The racket frame according to claim 1. The racket frame according to claim 2, wherein the connection auxiliary portion is joined to the other yoke. The racket frame according to any one of claims 1 to 3, wherein the other yoke is formed of the same material as that of the frame main body. 2. A vibration absorbing material is interposed at least at a part of a joint surface for mechanically joining a yoke formed of a material different from that of the frame body and the frame body and / or joining them via an adhesive. The racket frame according to claim 1. The racket frame according to any one of claims 1 to 5, wherein a joint area between the one yoke and the frame body is 10 cm ² or more and 60 cm ² or less.

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