JPH1199229A - Shaft for golf club - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shaft which exhibits more accurate and unique EI distribution and GI distribution and has unique performances not only suppressing twist of the apex part but also amplifying bending and to improve flying distance and directional stability of a golf ball when the ball is hit by arranging a fiber-reinforced plastic with a specified physical value at a site being 30% from the apex part of the shaft. SOLUTION: The titled shaft for a golf club is such a shaft for a golf club that is constituted by using a carbon fiber-reinforced plastic raw material and is constituted in such a way that when the whole length is displayed on the axis X and the values of bending rigidity and twisting rigidity are displayed on the axis Y, the bending rigidity distribution by 30% from the apex part of the shaft is always a curve increasing to the right and the twisting rigidity distribution up to 30% from the apex part becomes a projected curve.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a distribution of bending stiffness (hereinafter simply referred to as EI distribution) and torsional stiffness distribution (hereinafter simply referred to as GI distribution) of a golf club shaft between golf club sets. It is about improvement.

[0002]

2. Description of the Related Art Shafts for golf clubs have recently been developed using FR.
Shafts made of P are widely used. These shafts are usually manufactured mainly by a sheet winding method or a filament winding method using a tapered mandrel. Also, these shafts
Important parameters in evaluating performance include bending hardness (hereinafter abbreviated as flex) and torsion angle (hereinafter abbreviated as flex).
However, in recent design concepts, terms such as flexural rigidity (hereinafter abbreviated simply as EI) and torsional rigidity (hereinafter simply abbreviated as GI) are used as design theories that replace flex and torque. The invention of a shaft related thereto has been disclosed in
No. 2-33872 is known.

[0003]

However, such a shaft as described above is a design or theoretical shaft considering only EI, a design or theoretical shaft considering only GI, Vague EI,
Only shafts with a limited range of GI numerical values have been proposed, and the performance of the shaft cannot be evaluated even by making full use of them.

That is, in the case of the conventional shaft A (normal shaft) shown in FIGS. 8 and 9, since the tip (TIP side) of the shaft is reinforced, the EI value at the foremost end is high, Next, the EI value at a portion of 5% to 10% from the tip portion becomes slightly lower, and the EI value tends to be distributed to the upper right toward the rear end portion (BUTT side) of the shaft. In such a shaft, Although it did not become extremely sharp, the torsion at the tip had a tendency to increase. In such a conventional general shaft, although it does not become extremely sharp, there is a problem that the torsion of the tip becomes large and the directionality of the golf ball at the time of hitting the ball becomes slightly unstable. I was

In the case of the conventional shaft B (shaft of Japanese Patent Publication No. 62-33872) shown in FIGS. 10 and 11, the outermost layer at the tip end has a bias layer extending over １ ／ of the entire shaft length. Is reinforced by winding, so that
The I value is high, then the EI value at the 15% portion from the tip (TIP side) is slightly lower, and the EI value tends to be distributed to the upper right toward the rear end (BUTT side).
From the graph showing the GI distribution, the GI value at a portion 15% from the front end is high and distributed in a convex shape, and becomes a curve to the upper right toward the rear end. In such a shaft, the twist of the tip is small, but it does not become extremely sharp, so even if it can be mastered by advanced users, beginners and weak golfers will find it difficult for golf balls to climb when hitting However, there was a problem that the length was shortened.

In the case of the conventional shaft C (shaft in which a low elasticity fiber reinforced plastic layer is disposed at the tip of the shaft) shown in FIGS. 12 and 13, a low elasticity fiber reinforced plastic layer is provided at the tip. Because of the arrangement, the EI value at the forefront is low, the EI value tends to be distributed to the upper right toward the rear end, and the graph showing the GI distribution further shows the EI value from the front (TIP side). It becomes a curve to the upper right toward the end (BUTT side). In such a shaft, although it is in a tongue, the torsion of the tip becomes large, so that beginners and weak golfers have difficulty in climbing a golf ball at the time of hitting and easily fly a distance, but at the time of hitting a ball, There was a problem that the directionality of the golf ball became slightly unstable.

[0007] In the present invention, 30 minutes from the tip of the shaft.
%, A clearer and more unique EI distribution and GI distribution are shown by placing fiber reinforced plastics with specific physical properties in the parts up to%, and not only suppressing the twisting of the tip but also amplifying the bending An object of the present invention is to provide a shaft having a unique performance capable of causing the golf ball to improve the flight distance and directional stability of a golf ball when hit.

[0008]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a golf club shaft made of a carbon fiber reinforced plastic material. When the torsional stiffness value is displayed on the graph as the Y axis, the EI distribution of the portion up to 30% from the tip (TIP side) of the shaft is always a right-upward curve. The GI distribution of the portion is a shaft for a golf club, which is configured to have a convex curve.

The present invention also relates to a shaft tip (TI
The ratio of the EI value of the (P side) to the EI value of the portion 30% from the tip portion is 1: 1.1 to 1: 2, and the torsional rigidity value of the portion 30% from the tip portion of the shaft and the tip portion of the shaft. From 3
The ratio to the maximum GI value between the 0% sites is 1: 1.1.
A shaft characterized by having a rigidity distribution ratio of １ ： 1: 2.

[0010] Further, the present invention provides a method for manufacturing a shaft having the above-described configuration, in which the shaft from the tip of the shaft is 3
The shaft is characterized by winding a low elastic carbon fiber reinforced plastic material and an ultra high elastic carbon fiber reinforced plastic material cut by a required length from a portion up to 0% as a boundary by a specific method.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention relates to a shaft constituted by using a carbon fiber reinforced plastic material, wherein a total length of the shaft is represented on a graph as an X axis, and a bending rigidity value and a torsional rigidity value are represented on a graph as a Y axis. 30% from shaft tip
The EI distribution of the region up to is always a curve that rises to the right,
The GI distribution in the region from the tip of the shaft to 30% from the tip is preferred to have a high rigidity distribution with a convex curve so that the head speed is high and the twist of the tip of the shaft is small. It is possible to provide a shaft suitable for an advanced person who prefers a shaft whose tip portion becomes better. Furthermore, the ratio of the EI value of the tip of the shaft to the EI value of the portion 30% from the tip is 1: 1.1 to 1: 2, and the GI value of the portion 30% from the tip and 3 from the tip.
The maximum GI value between the 0% sites is 1: 1.1 to 1.
By configuring the stiffness distribution ratio to be 1: 2,
Further, the user's needs can be subdivided.

[0012]

Embodiments of the present invention will be described below with reference to the drawings. (Embodiment 1) FIG. 1 shows an embodiment 1 of the present invention.
FIG. 4 is an EI distribution diagram of FIG. The horizontal axis (X axis) in the figure represents the shaft length (the tip is 0 mm), and the vertical axis (Y axis) represents the bending stiffness value (EI value).
The bending stiffness value (EI value) of the portion from the tip of the shaft to 30% (point A) always rises to the right as shown by the curve A of the present invention. The portion indicated by the dotted line in the figure is the EI distribution of the portion of the conventional shaft up to 30% from the tip of the shaft. FIG. 2 is a GI distribution diagram of claim 1 according to the embodiment of the present invention. The horizontal axis (X axis) in the figure represents the shaft length (the tip is 0 mm), and the vertical axis (Y axis) represents the torsional stiffness value (GI value). The GI value of the portion up to 30% (point B) is a convex curve like the curve B of the present invention. The part shown by the dotted line in the figure is 30% from the tip of the shaft of the conventional shaft.
It is a GI distribution of the site up to.

(Embodiment 2) FIG. 3 is an EI distribution diagram of claim 2 according to an embodiment of the present invention, and the horizontal axis (X axis) in the figure is used.
Represents the shaft length (the tip is 0 mm), and the vertical axis (Y
The axis) represents the bending rigidity value (EI value), and the hatched portion in the figure indicates that the ratio of the EI value at the tip of the shaft to the EI value at 30% (point A) from the tip of the shaft is 1: 1.1 to 1:
2 is shown. FIG. 4 is a GI distribution chart of claim 2 according to the embodiment of the present invention, and the horizontal axis (X axis) in the figure is
The shaft length (the tip of the shaft is 0 mm), the vertical axis (Y axis) represents the torsional rigidity value (GI value), and the hatched portion in the figure is 30% (point B) from the tip of the shaft. The range in which the GI value is maximum between the region and the region 30% from the tip of the shaft, and the ratio of the GI value is 1: 1.1 to 1: 2.

Embodiment 3 FIG. 5 is a plan view showing a carbon fiber reinforced plastic material (prepreg sheet) constituting a shaft according to an embodiment of the present invention. That is, FIG.
As shown in FIG. 1, the carbon fiber reinforced plastic material constituting the shaft 1 of the present invention comprises a bias member 2, a reinforcing member 3, and a straight member 4, and the bias member 2
The front bias member 2A, which forms a portion 1B from the tip (TIP side) 1A of the shaft to approximately 30% of the entire length of the shaft, has a fiber orientation angle of ± 40 ° to ± 50 ° with respect to the entire length of the shaft. Ultra high elasticity (tensile elastic modulus 45)
000 kgf / mm ² or more) A carbon fiber reinforced plastic material, and a portion 1B, which is approximately 30% of the front end portion 1A of the shaft with respect to the entire length of the shaft, and a rear end portion of the shaft (BUT
The rear bias member 2B constituting up to 1C on the T side) is formed of a highly elastic (less than 40,000 kgf / mm ² ) carbon fiber reinforced plastic material having a fiber orientation angle of ± 50 ° to ± 60 °. The fiber angle is 0 ° to ± 15 ° with respect to the full length direction of the shaft at the portion 1B from the tip 1A of the shaft to 30% as the reinforcing member 3 as the biasing member 2 combining the carbon fiber reinforced plastic material. A carbon fiber reinforced plastic material having a low elastic modulus (tensile elastic modulus of 10,000 kgf / mm ² or less) having a fiber angle of 0 ° to ± 15 ° with respect to the full length direction of the shaft as the straight member 4 is arranged. High strength (tensile elastic modulus 25000 kgf / mm ² or more to less than 40000 kgf / mm ² ) This is a golf club shaft 1 which is a feature. The low elastic modulus (tensile elastic modulus of 10,000 kgf / mm ² or less) used in this example
Tensile modulus 4 for carbon fiber reinforced plastic material
500 kgf / mm ² -tensile modulus of elasticity 5500 kgf / m
Those having a size of about m ² are preferred. In the present embodiment,
Approximately 30 from the shaft tip 1A to the entire length of the shaft
% Of the front bias member 2A forming the portion 1B of the shaft and a rear bias member 2B constituting the portion from the portion 1B of about 30% of the front end portion 1A of the shaft to the rear end portion 1C of the shaft with respect to the entire length of the shaft. A carbon fiber reinforced plastic material having physical property values is joined and used. At this time, a carbon fiber reinforced plastic material cut obliquely is used as shown in FIG. In this case, it is possible to prevent the occurrence of stress concentration at these joints.

Embodiment 4 FIG. 6 is a plan view showing a carbon fiber reinforced plastic material (prepreg sheet) constituting a shaft according to an embodiment of the present invention. That is, FIG.
As shown in FIG. 1, the carbon fiber reinforced plastic material constituting the shaft 1 of the present invention comprises a bias member 2, a reinforcing member 3, and a straight member 4, and the bias member 4 has a fiber orientation with respect to the full length direction of the shaft. Angle is ± 40
High elasticity in the range of ° to ± 60 ° (tensile elasticity 40000k
gf / mm ² ) A carbon fiber reinforced plastic material is disposed, and the straight member 4 has a high strength (tensile elastic modulus of 25,000 kgf / mm ² or more) in a fiber angle range of 0 ° to ± 15 ° with respect to the entire length direction of the shaft. 40000kgf
/ Less than ² mm) A carbon fiber reinforced plastic material is disposed, and the tip 1A of the shaft is used as the reinforcing member 3A (the shape can be an isosceles triangular shape or a trapezoidal shape).
And a low elastic modulus (tensile elastic modulus of 10,000 kgf / mm ²⁾ having a fiber angle in the range of 0 ° to ± 15 ° with respect to the entire length of the shaft at a portion 1B up to approximately 30% of the entire shaft length.
Hereinafter, a carbon fiber reinforced plastic material is arranged, and further, as a reinforcing member 3B (a shape can be selected from an isosceles triangular shape or a trapezoidal shape), the fiber orientation angle is ± 40 ° to ± 50 ° with respect to the entire length direction of the shaft. A golf club shaft 1 comprising an ultra-high elasticity (tensile elastic modulus of 45000 kgf / mm ² or more) carbon fiber reinforced plastic material. The low elastic modulus (tensile elastic modulus of 10,000 kgf / mm) used in this example
² or less) For carbon fiber reinforced plastic material, tensile modulus of elasticity 4500 kgf / mm ² to tensile modulus of 5500 k
It is preferably about gf / mm ² .

(Embodiment 5) FIG. 7 shows Embodiment 4 of the present invention.
It is a top view which shows the carbon fiber reinforced plastic material (prepreg sheet) which comprises the shaft of another form. That is, as shown in FIG. 7, the carbon fiber reinforced plastic material constituting the shaft 1 of the present invention is composed of the bias member 2,
The bias member 4 includes a reinforcing member 3 and a straight member 4. The bias member 4 has a total length of 1143 mm, and has a fiber orientation angle of ± 40 ° to ± 60 ° with respect to the entire length direction of the shaft. mm ² )
A carbon fiber reinforced plastic material is arranged in four plies, and the straight member 4 has a total length of 1143 mm and a high strength (having a tensile elastic modulus of 25,000 kgf / mm ² or more in a fiber angle range of 0 ° to ± 15 ° with respect to the entire shaft direction). ~ 40
000 kgf / mm ² ) A carbon fiber reinforced plastic material is arranged in three plies, and the reinforcing member 3A ′ (shape is
An isosceles triangular shape or a trapezoidal shape (not shown) can be selected. ) Is 380 m in length, and the portion 1 extends from the tip 1A of the shaft to approximately 30% of the entire length of the shaft.
B: Fiber angle ± 40 ° ~
Ultra high elasticity in the range of ± 60 ° (tensile elastic modulus 45000kg
f / mm ² or more) A carbon fiber reinforced plastic material is disposed between the bias member 2 and the straight member 4, and a reinforcing member 3B ′ (shape is an isosceles triangle or a trapezoidal shape, not shown). Can be selected.), A low elastic modulus (tensile) having a fiber angle in the range of ± 0 ° to ± 15 ° with respect to the entire length of the shaft from the tip portion 1A of the shaft to a portion 1B up to approximately 30% of the entire length of the shaft. Elastic modulus 100
(00 kgf / mm ² or less) A golf club shaft 1 comprising a carbon fiber reinforced plastic material disposed on the straight member 4. The low elastic modulus (tensile elastic modulus 1
0000 kgf / mm ² or less) Regarding carbon fiber reinforced plastic material, tensile modulus of elasticity is 4500 kgf / mm ² 〜
Those having a tensile modulus of about 5500 kgf / mm ² are preferred.

FIG. 7 is a plan view showing a state in which a predetermined number of the bias member 2, the reinforcing member 3, and the straight member 4 are wound and laminated on a mandrel (core bar) 5, respectively. Gold) After winding and laminating around 5,
The wrapping tape is wound and cured by heating, and after cooling, the mandrel is pulled out to remove the wrapping tape, and the outer periphery of the shaft is polished and painted to complete the golf club shaft of the present invention. In addition,
As in the fourth embodiment of the present invention, a configuration in which the reinforcing member 3 is disposed between the bias member 2 and the straight member 4 which are the carbon fiber reinforced plastic material constituting the shaft, and an embodiment which is a modified embodiment of the fifth embodiment As in Example 5, the reinforcing member 3 is disposed between the biasing member 2 and the straight member 4, and the reinforcing member 3 is further placed on the straight member 4.
It is possible to provide a golf club shaft 1 having a configuration in which is disposed, and with such a configuration, it is possible to provide a golf club shaft that meets the configuration requirements of the present invention.

[0018]

As described above, according to the present invention, by arranging a fiber reinforced plastic having a specific property value in a portion up to 30% from the tip of the shaft, the tip of the shaft is improved, and the tip of the shaft is improved. In addition, since the torsion is suppressed and the weight of the shaft is reduced, it is possible to provide an effect that a shaft suitable for a golfer who prefers a fast tone with a high head speed can be provided.

[Brief description of the drawings]

FIG. 1 is a graph showing an example of EI distribution according to one embodiment of a shaft of the present invention.

FIG. 2 is a graph showing an example of GI distribution according to an embodiment of the shaft of the present invention.

FIG. 3 is a graph showing the EI distribution of the shaft of the present invention.

FIG. 4 is a graph showing a GI distribution of the shaft of the present invention.

FIG. 5 is a plan view showing the shape of the carbon fiber reinforced plastic material of the shaft according to the present invention.

FIG. 6 is a plan view showing the shape of the carbon fiber reinforced plastic material of the shaft according to the present invention.

FIG. 7 is an explanatory view showing a situation where a carbon fiber reinforced plastic material for a shaft according to the present invention is wound around and laminated on a mandrel.

FIG. 8 is a graph showing the EI distribution of the shaft of Conventional Example A.

FIG. 9 is a graph showing an example of a GI distribution of the shaft of Conventional Example A.

FIG. 10 is a graph showing the EI distribution of the shaft of Conventional Example B.

FIG. 11 is a graph showing a GI distribution of the shaft of Conventional Example B.

FIG. 12 is a graph showing the EI distribution of the shaft of Conventional Example C.

FIG. 13 is a graph showing the GI distribution of the shaft of Conventional Example C.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Shaft 1A Shaft tip part (TIP side) 1B 30% from tip part 1C Shaft rear end part (BUTT side) 2 Bias member 2A Front bias member 2B Rear bias member 3 Reinforcement member 3A Reinforcement member 3B Reinforcement member 4 Straight member 5 Mandrel

Claims (4)

[Claims] 1. A shaft for a golf club constituted by using a carbon fiber reinforced plastic material, wherein when a total length of the shaft is represented on an X axis and a bending rigidity value and a torsional rigidity value are represented on a Y axis, a graph of the shaft is obtained. The bending stiffness distribution of the part from the tip to 30% is always a curve that rises to the right,
A shaft for a golf club, wherein the torsional stiffness distribution at a portion from the tip end of the shaft to 30% is a convex curve. 2. The shaft according to claim 1, wherein a ratio of a bending stiffness value of a tip portion of the shaft to a bending stiffness value of a portion 30% from the tip portion of the shaft is 1: 1.1 to 1: 2, and a tip portion of the shaft. The ratio between the torsional stiffness value of the portion from 30% to the maximum torsional stiffness value between the portions 30% from the tip of the shaft is 1: 1.1 to 1: 2. The shaft for a golf club according to claim 1, wherein 3. The carbon fiber reinforced plastic material constituting the shaft comprises a biasing member, a reinforcing member, and a straight member, and the biasing member extends from a tip portion of the shaft to approximately 30% of the entire length of the shaft. The front bias member to be formed is made of an ultra-high elasticity (tensile elastic modulus of 45000 kgf / mm ² or more) carbon fiber reinforced plastic material having a fiber orientation angle of ± 40 ° to ± 50 ° with respect to the entire length of the shaft, and On the other hand, the rear bias member, which constitutes a portion from approximately 30% of the front end of the shaft to the rear end of the shaft, has a fiber orientation angle of ± 50 °.
High elasticity of up to ± 60 ° (tensile modulus of 40000 kgf
/ Less than ² mm) formed of carbon fiber reinforced plastic material, arranged as a bias member combining these carbon fiber reinforced plastic materials, and as a reinforcement member at a portion up to 30% from the tip of the shaft in the full length direction of the shaft. On the other hand, a low elastic modulus in the range of the fiber angle of 0 ° to ± 15 ° (tensile elastic modulus of 10,000 kgf / mm ² or less)
A carbon fiber reinforced plastic material is arranged, and a high strength (tensile elastic modulus of 25,000) having a fiber angle in the range of 0 ° to ± 15 ° with respect to the full length direction of the shaft as a straight member
kgf / mm ² or more and less than ~40000kgf / mm ²⁾
3. The golf club shaft according to claim 1, wherein a carbon fiber reinforced plastic material is disposed. 4. The carbon fiber reinforced plastic material constituting the shaft comprises a bias member, a reinforcing member, and a straight member, and the bias member has a fiber orientation angle of ± 40 ° to ± 40 with respect to a full length direction of the shaft. A high elasticity (tensile modulus of less than 40,000 kgf / mm ² ) carbon fiber reinforced plastic material in a range of 60 ° is disposed, and the fiber angle is 0 as a straight member with respect to the entire length direction of the shaft.
High strength in the range of ° to ± 15 ° (Tensile modulus 25000k
gf / mm ² or more to less than 40,000 kgf / mm ² ) A carbon fiber reinforced plastic material is arranged, and as a reinforcing member, approximately 3 from the tip of the shaft to the entire length of the shaft.
A low elastic modulus (a tensile elastic modulus of 100%) having a fiber angle in the range of 0 ° to ± 15 ° with respect to the entire length of the shaft in a portion up to 0%.
(00 kgf / mm ² or less) A carbon fiber reinforced plastic material is disposed, and as a reinforcing member, a super-high elasticity (tensile elastic modulus 45000 kgf / mm ²⁾ having a fiber orientation angle of ± 40 ° to ± 50 ° with respect to the entire length direction of the shaft. The shaft for a golf club according to claim 1 or 2, wherein a carbon fiber reinforced plastic material is arranged.