JPH07121286B2 - Golf club shaft - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a golf club shaft, and more particularly, it eliminates twisting of the golf club shaft at the time of swinging or impact, and prevents twisting of the face surface of the club head with respect to the golf ball. It allows you to point in the right direction.

2. Description of the Related Art In a conventional golf club shaft, its geometrical principal axis and elastic principal axis coincide with each other. That is, as shown in FIG. 13, the portion of the golf club shaft 1 to which the grip 2 is attached becomes the fixed end when the player holds the grip 2, and the tip of the golf club shaft 1 to which the club head 3 is attached is the free end. And the golf club shaft 1
The position of the elastic principal axis E ₁ at the free end of the tip of the is coincident with the geometrical principal axis G. The elastic main axis referred to here is different from the geometrical main axis, and refers to the axis of symmetry when considering the elastic modulus, and as will be described later, in the case of the present invention, even if a load is applied, it bends, It refers to the axis that connects the load point that does not twist and the fixed end of the pipe.

On the other hand, as shown in FIG. 14, the center of gravity of the weight of the normal club head 2 (wood) (hereinafter simply referred to as the center of gravity) A,
Further, the geometrical center of gravity B of the scoring area 4 provided on the face surface 3a of the club head 3 and shown by oblique lines in the drawing is about 20 to 20 from the geometrical main axis G of the golf club shaft 1.
At a distance of 50 mm. That is, conventionally, the position E ₁ of the elastic main shaft at the tip of the golf club shaft 1, the center of gravity A of the club head, and the geometric center of gravity B of the scoring area 4 coincide with each other while the player holds the grip 2. Didn't.

Generally, when a shaft having a geometrical principal axis and an elastic principal axis coincident with each other is subjected to a bending torsion by applying a load to a point which is not on the geometrical principal axis, bending and twisting occur. Therefore, in the case of the conventional golf club shaft in which the geometric main axis and the elastic main axis are coincident with each other, the center of gravity of the club head is not located on the geometric main axis, so that the eccentric load (inertia force) is applied to the golf club shaft 1 at the time of swinging. The bending and twisting force of () causes the golf club shaft 1 to be twisted as well as bent. Similarly, at the time of impact, the position of the geometric center of gravity of the scoring area does not coincide with the geometric main axis of the shaft. Therefore, the repulsive force applied from the hit golf ball to the scoring area 4 of the club head 3 causes the golf club to hit. A bending and twisting force is applied to the shaft 1, so that the golf club shaft 1 is twisted as well as bent.

Problems to be Solved by the Invention As described above, when the golf club shaft 1 is not only bent but also twisted at the time of swinging and at the time of impact, the face surface 3a of the club head 3 becomes the geometric main axis G of the golf club shaft 1. It will rotate against.
Therefore, even if the player intends to hit the golf ball with the face surface 3a accurately, the rotation of the face surface 3a actually causes the direction of the face surface 3a with respect to the ball to be straightened, and the golf ball to be hit straight in the aimed direction. It does not fly and warps, making it difficult to obtain directionality.

The present invention has been made in order to solve the above problems in the conventional golf club shaft, and reduces the twist generated at the time of swinging or at the time of impact, and the face surface of the club head is formed by the twist. Without rotating about the geometric main axis of
An object of the present invention is to provide a golf club shaft which can accurately fly a hit golf ball in a required direction.

Means for Solving the Problems The present invention has been made based on the following principles.

In a pipe or a solid shaft at least partially formed of an anisotropic material such as a fiber reinforced resin, the fiber angle of the anisotropic material is partially circumferentially and at least partially in the thickness direction. It has been clarified by the applicant of the present invention that the elastic main axis of the pipe or the shaft can be set to an arbitrary position by making the elastic main axis different from the geometrical main axis. (See Japanese Patent Application Laid-Open No. 3-227616 (Japanese Patent Application No. 2-210982)) For example, in the pipe-shaped structure 10 made of fiber reinforced resin shown in FIGS. When the cylindrical coordinates [(r, θ, Z) system coordinates] are taken so as to coincide with each other, the geometrical principal axis G (of the fiber F at the portion 10a where 0 ° ≦ θ <180 ° is taken regardless of Z and r. That is, the angle (fiber angle) with respect to the Z axis is α ₁ = 30 °, while 180 ° ≦ θ <360
The fiber angle is β ₁ = −30 ° in the 10 ° portion 10b.
As shown in FIG. 19, when the pipe-shaped structure 10 has a fixed end 10c at one end and a free end 10d at the other end, the elastic main axis E does not coincide with the geometrical main axis G, and the free end 10d is It is located on point Q.

When a load which does not pass through the point on the elastic main axis E is applied downward in the above state, the pipe-shaped structure 10 is bent and twisted as shown in FIGS. 20 and 21.
On the other hand, when a downward load is applied so as to pass through the point Q on the elastic main axis E, as shown in FIG. 22 and FIG. 23, it is bent but is not twisted.

The present invention applies the unique deformation behavior obtained by forming the above anisotropic material to a golf club shaft.

Therefore, according to the present invention, when the golf club is placed on a horizontal plane in a predetermined state, a plane which is parallel to the intersecting line formed by the face surface of the club head and the horizontal plane and which includes the geometric main axis of the shaft is defined as the specific plane. Sometimes, at least a part of the golf club shaft is formed of a material having anisotropy, which is one kind or a combination of plural kinds of fiber reinforced resin, fiber reinforced rubber, and oriented rubber, When the fiber angle and / or the orientation angle of the material having directionality are partially different in the circumferential direction and at least in part in the thickness direction and 200 mm is fixed from the grip side end of the golf club shaft, A golf ball characterized in that the elastic main axis in the specific plane is set so as to pass through the intersection of the perpendicular line drawn from the center of gravity of the club head to the specific plane and the specific plane. It is intended to provide a club shaft.

Here, when the golf club is placed on a horizontal plane in a predetermined state, the bottom surface 3b of the club head 3 is in contact with the ground (horizontal plane H) as shown in FIG. 24 and FIG. A state in which a predetermined lie angle γ and loft angle δ are set.

Further, according to the present invention, when a golf club is placed in a predetermined state on a horizontal plane, a plane parallel to a line of intersection between the face surface of the club head and the horizontal plane and including the geometric main axis of the shaft is set as the specific plane. Sometimes, at least a part of the golf club shaft is formed of a material having anisotropy, which is one kind or a combination of plural kinds of fiber reinforced resin, fiber reinforced rubber, and oriented rubber, When the fiber angle and / or the orientation angle of the material having directionality are partially different in the circumferential direction and at least in part in the thickness direction and 200 mm is fixed from the grip side end of the golf club shaft, The elastic main axis in the specific plane is set so as to pass through the intersection of the perpendicular line drawn from the geometric center of gravity of the scoring area to the specific plane and the specific plane. It is intended to provide a golf club shaft to the butterfly.

Specifically, the deviation at the tip of the golf club shaft on the club head side of the elastic main axis in the specific plane when fixing 200 mm from the grip side end of the golf club shaft is the geometric main axis of the golf club shaft. From 20 to 50
It is set to mm. As the fiber-reinforced resin, glass fiber, carbon fiber, various organic fibers, alumina fiber, silicon carbide fiber, metal fiber and / or a fiber made of a mixture thereof, woven cloth, mat, or the like is used as the reinforcing fiber material, and the resin is used as the resin. Resins such as polyamide, epoxy and polyester are preferably used.

The entire golf club shaft may be formed of the above fiber reinforced resin, or in addition to the fiber reinforced resin, a fiber reinforced rubber,
Anisotropic material such as oriented rubber or /
Alternatively, a resin or rubber that does not contain fibers may be partially used in combination.

Further, the shafts made of the above-described materials may have the same axial length, or the axial length may be changed. In the present invention, the material and structure of the shaft are not limited as long as the position of the elastic main axis at the tip of the shaft can be set to the above-mentioned predetermined position by using an anisotropic material for at least a part.

Operation As described above, in the golf club shaft according to the present invention, the swing is set by setting the elastic main axis on the above-mentioned specific plane so as to pass through the intersection of the perpendicular line drawn from the center of gravity of the club head to the specific plane and the specific plane. Twisting can be prevented against the bending and torsional load generated therein. In addition, by setting the elastic main axis on the above-mentioned specific plane so that it passes through the intersection of the perpendicular line drawn from the geometric center of gravity of the scoring area to the specific plane and the specific plane, it is twisted against the bending and torsional load generated during impact. Can be prevented. Therefore, it is possible to solve the problem that the shaft is twisted, which is one of the factors that makes it difficult to fly the golf ball straight, and it is possible to fly the golf ball more straightly as compared with the conventional golf club shaft.

EXAMPLES Next, the present invention will be described in detail based on the examples shown in the drawings.

In the following examples, for convenience of explanation, the cylindrical coordinates (r, θ, Z) are set so that the geometric main axis G of the golf club shaft becomes the Z axis.

The golf club shaft 12 of the first embodiment shown in FIGS. 1 to 5 is made of only FRP (carbon fiber reinforced epoxy composite material), and is manufactured by a method of laminating cut prepreg sheets as described below. ing.

The golf club shaft 12 has a total length L of 1200 mm,
At the edge 12a on the side where the grip 13 shown in FIG. 6 is attached,
The outer diameter OD ₁ is 15.6 mm and the inner diameter ID ₁ is 12.6 mm.
The outer diameter and the inner diameter from 12a to l ₁ = 200 mm are set to be the same to form the grip mounting portion 12c. The length l ₂ = 1000 mm from the tip of the grip mounting portion 12c to the tip edge 12b of the golf club shaft 12 on which the club head 14 shown in FIG. 6 is mounted is tapered to form the tip edge 12b. Has an outer diameter OD ₂ of 7.5 mm and an inner diameter ID ₂ of 4.5 mm.

As described above, the grip 13 is externally fitted and fixed to the grip mounting portion 12c at one end of the golf club shaft 12, and at the other end, as shown in FIGS. 6 and 7 in the first embodiment. The club head 14 which is made of iron is attached to the.

The center of gravity A of the weight of the club head 14 is located at l ₃ = 34 mm from the geometric main axis G of the golf club shaft 12. The position of the center of gravity A of the club head 14 is determined by the shape and weight distribution of the club head 14.

Further, in the club head 14, the scoring area 15 indicated by diagonal lines on the face surface 14a is substantially trapezoidal, and the geometric center of gravity B of the scoring area 15 is the golf club shaft.
It is at a position of l ₄ = 37 mm from the geometrical spindle G when it is attached to 12. The position of the geometrical center of gravity B is determined by the shape of the scoring area 15.

In the golf club shaft 12 of the first embodiment, the material, the fiber angle, and the portion for varying the fiber angle are set so that the elastic main axis E ₃ passes through the center of gravity A of the club head 14.
That is, regardless of Z, the fiber angle is set to α ₂ = 6 ° in the part 12d where 0 ° ≦ θ <180 °, and the fiber angle is set to β ₁ = −30 ° in the part 12e where 180 ° ≦ θ <360 °. And above part 12
Each of d and 12c is formed by stacking 12 layers of prepreg sheets.

The golf club shaft 12 is manufactured by a semi-peripheral prepreg sheet cut to have a fiber angle of α ₂ and a half-perimeter prepreg sheet cut to have a fiber angle of β ₂ on a mandrel. Each part 12c, 1
After being laminated in order in 2d, a wrapping tape is spirally wound and pressed, and then cured in an oven to manufacture.

In the golf club shaft 12 of the first embodiment, the geometrical principal axis G and the elastic principal axis E ₃ are made different from each other by making the angle of the fiber in the circumferential direction with respect to the geometrical principal axis G of one part different from the other portion as described above. There is a gap between and.

The deviation between the elastic main axis E ₃ and the geometric main axis G is caused by fixing the grip attaching portion 12c as shown in FIG.
From the center of gravity A of the club head 14 in the direction perpendicular to the face surface 14a of the club head 14, the elastic main axis E _{3 in} the cantilever beam having a length l ₂ = 1000 mm with a fixed end at 200 mm from When the golf club is placed on a horizontal surface in a predetermined state (as shown in FIGS. 24 and 25, the bottom surface 14b of the club head 14 is in contact with the horizontal surface H so that the golf club has a predetermined position. Lie angle γ and loft angle δ) of the club head 14
When the plane parallel to the intersecting line of the horizontal plane and including the geometrical main axis of the shaft is set as the specific plane, the specific plane when fixing 200 mm from the grip 13 side end of the golf club shaft 12 The elastic spindle E ₃ of the club head 14
Is set so that it passes through the intersection of the perpendicular line drawn from the center of gravity A of the shaft to a specific plane and the specific plane. In this case, the deviation is l ₅ = 35.7 mm at the tip side of the shaft and the elastic spindle
E ₃ passes through point Q.

Like the golf club shaft, when the elastic main axis is deviated from the geometrical main axis, when the elastic main axis is bent and twisted in a state where a load is applied to a point on the elastic main axis, flexure occurs, but twisting does not occur. The deformation behavior is as described above.

Therefore, in the golf club shaft 12 of the first embodiment, with the grip 13 side fixed, the club head 14
The elastic main axis E _{3 in the} direction perpendicular to the face surface 14a of the club head 14 is made to coincide with the center of gravity A of the club head 14 so that the elastic main axis passes through the center of gravity A. Since it is set so as to pass through the intersection of the perpendicular line drawn from the center of gravity of the head to a specific plane and the specific plane, it is possible to prevent bending and twisting that acts when a load (inertial force) is applied to the elastic main axis when the golf club swings. As a result, only the tip of the golf club shaft 12 is bent and is not twisted. Therefore, the face surface 14 of the club head 14
Since a does not rotate with respect to the golf club shaft 12, the face surface 14a can be exactly aimed at the golf ball.

FIG. 11 shows a golf club shaft 22 according to the second embodiment of the present invention.
And the golf club shaft 22 has 0 ° ≦ θ <180
In the portion 22a of °, from the inside, there are 3 layers of 2 prepreg sheets with α ₃ = 45 ° and α ₄ = −45 °, and then three layers,
Three layers with α ₅ = 0 ° and three layers with α ₆ = 25 ° are stacked.

On the other hand, in the portion 22b where 180 ° ≦ θ <360 °, β ₃ from the inside
= ₃ ° with 3 layers of β ₅ = 0 °, and 3 layers of β ₅ = 0 °, and 3 layers of β ₅ = −25 °. Piled up.

That is, in the golf club shaft 22 of the second embodiment, the portion 22c from the inner surface end to the third layer is composed of the same layer in which two 45 ° and -45 ° prepreg sheets are laminated as one set, and the fourth layer On the other hand, the portion 22d up to the sixth layer is composed of the same layer of 0 °, and in the portion 22e from the seventh layer to the ninth layer, as described above, the fiber angle of the portion 22f is 25 ° and that of the portion 22g. The fiber angle is different from -25 °.

The other structure of the second embodiment, the club head to be attached, and the grip are the same as those of the first embodiment described above. As described above, in the golf club shaft 22, it is a part of the circumferential direction and a radial direction of the part. As shown in FIG. 8, the elastic main axis E _{4 in the} direction perpendicular to the face surface 14a is changed to the geometric center of gravity of the scoring area 15 of the club head 14 by making the fiber angles different from each other as described above. B
Through the elastic main axis, that is, in the above-mentioned specific plane
E ₄ is set so as to pass through the intersection of the perpendicular line drawn from the geometrical center of gravity B of the scoring area 15 to the specific plane and the specific plane.

In the second embodiment, since the elastic main axis E ₄ is set as described above, the golf club shaft 22 is not twisted by the repulsive force from the golf ball hit at the time of impact,
The face surface 14a of the club head 14 does not rotate with respect to the geometrical principal axis G of the golf club shaft 12 and can hit the ball straight.

The present invention is not limited to the above-described embodiments, and for example, the material of the golf club shaft is not limited to the above FRP, and fiber reinforced rubber, rubber having anisotropy, etc. can be used in combination. Is. Further, the shape of the golf club shaft such as the length, the outer diameter, and the inner diameter can be arbitrarily determined. Further, although the iron club head is attached as the club head in the above-mentioned embodiment, it is needless to say that the present invention can be applied to the case of a wood club head as shown in FIG.

<Example> It was confirmed by the following experiment that the position of the elastic main axis of the golf club shaft according to the present invention can be set to an arbitrary position.

The experiment was conducted with the first structure having a laminated structure as shown in Table 1 above.
Golf club shafts of Examples to 7th Examples,
The test was performed on a total of eight golf club shafts of a comparative example of a type in which the elastic main axis and the geometrical main axis coincide with each other.

The first to seventh embodiments have the following features.

1st Example: It corresponds to the said 1st Example, and the fiber angle is constant in the thickness direction (r direction), and it has the laminated structure only by a symmetrical symmetrical laminated layer.

Second Experimental Example, Third Experimental Example: A symmetrical laminated structure having two prepreg sheets made of an anisotropic material or a symmetrical laminated structure of 0 ° is provided on the inner circumference, and an asymmetric layer is provided on the outer circumference. .

Fourth Experimental Example: The composition is the same as that of the second experimental example and the third experimental example, and two types of materials are used.

Fifth Experimental Example, Sixth Experimental Example, Seventh Experimental Example: These correspond to the second embodiment, and are made of an anisotropic material on the inner peripheral side.
It has a symmetrical laminated structure composed of a combination of 45 ° laminated layers and 0 ° laminated layers and a laminated structure in which a relative symmetrical layer is provided on the outer peripheral side.

In the above-described first to seventh experimental examples, the position of the elastic main shaft at the tip of the shaft is changed by the respective laminated configurations.

The material is a boron fiber reinforced epoxy composite material in the outer layer of the fourth experimental example (indicated by * in Table 1), but the other layers are all carbon reinforced epoxy resin.

The experimental method was as follows. For the above eight golf clubs, the jig 18 shown in FIG. 9 and the jig shown in FIG. 10 were fixed with 200 mm fixed from the end of the golf club shaft on the grip 13 side and projected 1000 mm. 0mm, 20mm, 30mm, 50mm from the geometric main axis G on the tip side of the golf club shaft using 20
A force of 2.0 kg was applied to the distance.

The results of the above experiment have the values shown in Table 2 below. Further, when a graph as shown in FIG. 12 was drawn for the first experimental example from the values in Table 2, it was found from this graph that the position of the elastic main shaft at the tip of the shaft was 35.7 mm. In other experimental examples as well, it was found from the same graph that the position of the elastic main shaft at the tip of the shaft had the values shown in Table 3 below.

As is clear from this experimental example, in the golf club shaft according to the present invention, the elastic main axis can be arbitrarily set by changing the material, the fiber angle, the arrangement of the parts that make the fiber angle different, etc. The elastic main axis at the tip of the club shaft passes through the center of gravity of the club head and / or the geometric center of gravity of the scoring area, that is, the elastic main axis in the above-mentioned specific plane is the center of gravity of the club head and / or the geometry of the scoring area. It can be set so as to pass through the intersection of the perpendicular line drawn from the geometric center of gravity to the specific plane and the specific plane.

Effect As is clear from the above description, since the golf club shaft according to the present invention is formed by using at least a part of a material having anisotropy, the club head has a fixed end on the grip side. The position of the elastic spindle at the free end on the specializing side can be set to any position by shifting it from the geometrical spindle, and the elastic spindle on the above-mentioned specific plane is a perpendicular line drawn from the center of gravity of the club head to the specific plane. By setting so as to pass through the intersection of the and the specific plane, it is possible to eliminate the twist of the golf club shaft due to the inertial force generated by the weight of the club head at the time of swing, and to fly the ball accurately and straightly.

Further, when the elastic main axis on the specific plane is set so as to pass through the intersection of the perpendicular line drawn from the geometric main axis of the scoring area to the specific plane and the specific plane, the ball is added to the scoring area at the time of impact. The twist due to the repulsive force can be reduced, and the ball can be hit without rotating the face surface of the club with respect to the golf club shaft.

[Brief description of drawings]

1 is a plan view showing a first embodiment of a golf club shaft according to the present invention, FIG. 2 is a perspective view of FIG. 1, FIG. 3 is a sectional view taken along line III-III of FIG. 2, FIG. FIG. 5 is a schematic view showing the fiber angle of the first embodiment, FIG. 6 is a schematic view showing a state in which the club head and the grip are attached to the golf club shaft in the first embodiment, and FIG. 7 is a club head (iron). FIG. 8 is a schematic plan view showing a state where one end of the golf club shaft of the first embodiment is fixed, and FIG.
Figure and Figure 10 are schematic perspective views showing how to attach the jig.
FIG. 11 is a sectional view showing a second embodiment of the present invention, FIG. 12 is a graph showing experimental results of the first embodiment, FIG. 13 is a schematic plan view showing a conventional golf club shaft, and FIG. A schematic view showing a club head (wood), FIG. 15, FIG. 16, FIG. 17 and FIG. 18 are schematic views showing a pipe-like structure for explaining the principle of the present invention, and FIG. Schematic perspective view showing a state in which the pipe-like structure in the figure is cantilevered, FIG. 20, FIG.
22 and 23 are schematic views showing deformation behavior of the pipe of FIG. 15 of the present invention, FIG. 24 is a front view of a club head for explaining a lie angle, and FIG. 25 is a loft angle. It is a side view of a club head for doing. 12 ... Golf club shaft, 13 ... Grip, 14 ... Club head, 14a ... Face surface, 15 ... Scoring area.

Claims (3)

[Claims] 1. When a golf club is placed on a horizontal plane in a predetermined state, a plane parallel to a line of intersection between the face surface of the club head and the horizontal plane and including the geometric main axis of the shaft is a specific plane. In addition, at least a part of the golf club shaft is formed of a material having anisotropy, which is one kind or a combination of plural kinds of fiber reinforced resin, fiber reinforced rubber, and oriented rubber, Of 200 mm from the grip side end of the golf club shaft by partially varying the fiber angle and / or the orientation angle of the elastic material in the circumferential direction and at least in part in the thickness direction. A golf club characterized in that an elastic main axis in a specific plane is set so as to pass through an intersection of the perpendicular line drawn from the center of gravity of the club head to the specific plane and the specific plane. Shaft. 2. When a golf club is placed in a predetermined state on a horizontal plane, a plane parallel to a line of intersection between the face surface of the club head and the horizontal plane and including the geometric main axis of the shaft is a specific plane. In addition, at least a part of the golf club shaft is formed of a material having anisotropy, which is one kind or a combination of plural kinds of fiber reinforced resin, fiber reinforced rubber, and oriented rubber, Of 200 mm from the grip side end of the golf club shaft by partially varying the fiber angle and / or the orientation angle of the elastic material in the circumferential direction and at least in part in the thickness direction. The elastic main axis in the specific plane is set so as to pass through the intersection of the perpendicular line drawn from the geometric center of gravity of the scoring area to the specific plane and the specific plane. Golf club shaft that. 3. The geometric main axis of the golf club shaft is the deviation of the elastic main axis in the specific plane at the tip of the golf club shaft on the club head side when 200 mm is fixed from the grip side end of the golf club shaft. From 20 to 50
Claim 1 or Claim 2 set to be mm
The golf club shaft according to claim 1.