JPWO2020129114A1 - Golf club shaft and golf club - Google Patents

Abstract

It provides golf club shafts and golf clubs with excellent swing comfort without requiring delicate settings while maintaining the merits of short lengths. It has a shaft body extending in the longitudinal direction and a center of gravity shift member provided on the shaft body and shifting the center of gravity of the shaft to the tip side in the longitudinal direction so that the total length of the shaft is 43 inches or less. When cut, the position of the center of gravity of the shaft is set in the range of 39% to 45% when the tip portion in the longitudinal direction is 0% and the base end portion in the longitudinal direction is 100%. A golf club shaft that features that.

Description

The present invention relates to golf club shafts and golf clubs.

The applicant is a hollow formed by thermosetting a metal cylinder made entirely of a metal material and an uncured thermosetting resin prepreg that contains at least a part of the metal cylinder in the longitudinal direction and is wound in a plurality of layers around the metal cylinder. A patent right has been obtained for a golf club shaft having a cylindrical shaft body (Patent Document 1). The metal cylinder is located in a part of the hollow cylindrical shaft body in the longitudinal direction, and at least a part of the outer diameter side of the metal cylinder is buried in a buried concave cylinder formed in the inner wall of the shaft body. Therefore, the hand-side cylindrical end face of the metal cylinder and the hand-side concave cylindrical end face of the buried concave cylinder portion of the shaft body are in contact with each other.

Japanese Patent No. 4880063

The applicant is proceeding with research and development of a so-called short golf club shaft in which, for example, a shaft body having a shaft total length larger than 43 inches (for example, 45 inches or more) is cut so that the shaft total length is 43 inches or less. Since the short golf club shaft is short, it is easy to handle, and it is easy to receive an accurate impact at the sweet spot, so that there is an advantage that the meet rate is improved.

On the other hand, a short golf club shaft has a demerit that it tends to give an uncomfortable feeling to an advanced player and the launch angle of the ball tends to be small (it is difficult for the ball to rise). Therefore, when a short golf club shaft is used, it is conceivable that the weight of the club head is larger than the weight of the club head mounted on a normal golf club shaft that is not short.

However, increasing the weight of the club head affects the weight and balance of the entire golf club, so in some cases, delicate settings including adjustment of the overall length of the short golf club shaft may be required. be.

The present invention has been completed based on the above problem awareness, and provides a golf club shaft and a golf club with excellent swinging comfort without requiring a delicate setting while maintaining the merits of a short length. The purpose is.

The golf club shaft of the present embodiment has a shaft body extending in the longitudinal direction and a center of gravity shift member provided on the shaft body and shifting the center of gravity of the shaft toward the tip end side in the longitudinal direction. When cut so that the total length is 43 inches or less, the position of the center of gravity of the shaft is 39% to 39% when the tip portion in the longitudinal direction is 0% and the base end portion in the longitudinal direction is 100%. It is characterized in that it is set in the range of 45%.

The position of the center of gravity of the shaft is preferably set in the range of 41% to 44% when the tip portion in the longitudinal direction is 0% and the base end portion in the longitudinal direction is 100%. More preferably, it is set in the range of 5% to 43.5%.

The cutting length of the shaft body on the proximal end side in the longitudinal direction can be made larger than the cutting length of the shaft body on the distal end side in the longitudinal direction. Here, the cutting length on the tip side is used in the concept of including zero. That is, in addition to the case where the tip side and the proximal end side are cut, the case where only the proximal end side is cut without cutting the distal end side is included.

The ratio of the weight of the center of gravity shift member to the weight of the shaft body can be set in the range of 14% to 33%.

The ratio of the weight of the center of gravity shift member to the weight of the shaft body is preferably set in the range of 17% to 30%, and more preferably set in the range of 20% to 25%.

The center of gravity shift member may have a metal cylinder embedded in the inner peripheral surface of the shaft body.

The shaft body has a first region in which the outer diameter of the shaft decreases relatively gently and a second region in which the outer diameter of the shaft decreases relatively steeply in order from the base end side to the tip end side in the longitudinal direction. And a third region where the relative amount of change in the outer diameter of the shaft is the smallest.

The proportion of the first region in the longitudinal direction is 30% or more, the proportion of the second region in the longitudinal direction is 45% to 60%, and the proportion of the third region in the longitudinal direction is 45% to 60%. The proportion of can be 10% to 25%.

A grip is attached to the outer peripheral surface of the first region, and a metal cylinder as the center of gravity shift member can be embedded in the inner peripheral surface of the third region.

The golf club of the present embodiment is characterized in that a club head and a grip are attached to any of the above-mentioned golf club shafts.

According to the present invention, it is possible to provide a golf club shaft and a golf club having excellent swing comfort without requiring a delicate setting while maintaining the merits of a short length.

It is a figure which shows an example of the appearance composition of the golf club by this embodiment. It is a figure which shows an example of the schematic structure of the golf club shaft by this embodiment. FIG. 2 is an enlarged view showing a contact portion between a shaft body and a metal cylinder circled in FIG. 2. It is the figure which looked at the golf club shaft of FIG. 2 from the tip side. It is a figure which shows the characteristic of three samples of the golf club shaft by this embodiment. It is a figure which shows an example of the transition of the shaft outer diameter in the longitudinal direction of a golf club shaft by this embodiment. It is a figure which shows an example of the transition of the shaft outer diameter in the longitudinal direction of the golf club shaft by the present embodiment and the golf club shaft by the comparative example 1-3. It is a figure which shows an example of the laminated prepreg which constitutes a shaft body.

FIG. 1 shows an example of the appearance configuration of the golf club 10 according to the present embodiment. The golf club 10 is mounted on a golf club shaft 100 extending in the longitudinal direction, a club head 200 mounted on the tip side (tip side) of the golf club shaft 100, and a base end side (bat side) of the golf club shaft 100. It has a grip 300. Although the club head 200 is drawn as an iron club head in FIG. 1, the club head 200 may be a driver club head.

A schematic configuration of the golf club shaft 100 according to the present embodiment will be described with reference to FIGS. 2 to 4. In FIG. 2, the golf club shaft 100 is drawn so that the outer diameter of the golf club shaft decreases at a uniform taper rate from the base end side (bat side) to the tip end side (tip side), but this is for convenience of drawing. This is due to the reason. Actually, the shaft outer diameter of the golf club shaft 100 has a characteristic configuration as described later with reference to FIG.

The golf club shaft 100 has a hollow tubular shaft body 110 made of fiber reinforced resin and a metal cylinder (center of gravity shift member, weight) 120 provided on the tip end side of the shaft body 110.

The shaft body 110 is made of, for example, FRP (Fiber Reinforced Plastics) formed by winding a plurality of layers of uncured thermosetting resin prepreg and heat-curing it. The shaft body 110 (golf club shaft 100) extends in the longitudinal direction and is cut so that the total length of the shaft is larger than 43 inches (for example, 45 inches or more) in the initial state and the total length of the shaft is 43 inches or less in the used state. , So-called short shaft body (golf club shaft). The cutting length of the shaft body 110 on the proximal end side in the longitudinal direction is larger than the cutting length of the shaft main body 110 on the distal end side in the longitudinal direction. Here, the cutting length on the tip side of the shaft body 110 is used in the concept of including zero. That is, in addition to the case where the tip end side and the proximal end side of the shaft main body 110 are cut, only the proximal end side may be cut without cutting the distal end side of the shaft main body 110. Whether or not the shaft body 110 is cut to adjust (shorten) the total length of the shaft can be grasped by observing at least one of the tip surface and the proximal end surface of the shaft body 110.

The metal cylinder 120 has a function of shifting the center of gravity of the shaft (the position of the center of gravity of the golf club shaft 100, the balance point) to the tip side by being provided on the tip side of the shaft body 110. The metal cylinder 120 is made of, for example, a metal material such as stainless steel, iron, aluminum, and tungsten, but is not limited to any material as long as it can add weight. Alternatively, instead of the metal cylinder 120, a resin cylinder made of a resin material such as a thermoplastic resin, a thermosetting resin, or rubber can be used as a “center of gravity shift member, weight”. As the thermoplastic resin, for example, polypropylene, polyterephthalate, polyethylene or the like can be used. As the thermosetting resin, for example, an epoxy resin, a phenol resin, an unsaturated polyester resin, a polyurethane, a polyimide, or the like can be used. As the rubber, for example, chloroprene rubber, fluororubber, chlorinated polyethylene, nitrile rubber, butyl rubber, ethylene propylene rubber and the like can be used.

As shown in FIG. 3, a buried concave cylindrical portion 112 is formed at the distal end side end portion of the inner wall 111 of the shaft main body 110. A part of the outer diameter side of the metal cylinder 120 is buried in the buried concave cylinder portion 112 (the metal cylinder 120 is embedded in the inner peripheral surface of the shaft body 110), and the base end side cylinder end surface 121 of the metal cylinder 120 is formed. The base end side cylindrical end surface 113 of the buried concave cylindrical portion 112 is abutted and abuts in the longitudinal direction. As a result, the metal cylinder 120 does not come off from the shaft body 110 toward the proximal end side even when an impact during a swing or a collision is applied, and the durability of the golf club shaft 100 can be improved. Since the club head 200 is attached to the tip end of the shaft body 110, the metal cylinder 120 does not come off from the shaft body 110 to the tip side even if an impact during a swing or a collision is applied.

The contact length A between the base end side cylindrical end surface 121 of the metal cylinder 120 and the base end side cylindrical end face 113 of the buried concave cylindrical portion 112 is preferably in the range of 0.05 mm to 0.5 mm. If the contact length A is smaller than 0.05 mm, the metal cylinder 120 may come off from the shaft body 110 toward the proximal end side when an impact is applied during a swing or a collision. If the contact length A is larger than 0.5 mm, the shaft body 110 becomes too thin, and the shaft is formed at the contact portion between the base end side cylindrical end surface 121 of the metal cylinder 120 and the base end side cylindrical end face 113 of the buried concave cylinder portion 112. The fiber reinforced resin layer of the main body 110 may be dented, cut or broken.

As shown in FIGS. 3 and 4, the tip-side cylindrical end face 122 of the metal cylinder 120 is exposed to the shaft tip-side end face 114 of the shaft body 110. Thereby, it is possible to confirm that the metal cylinder 120 is buried in the shaft tip side by visually observing the shaft tip side end surface 114 of the shaft body 110. Further, the metal cylinder 120 can remarkably exhibit the action of shifting the center of gravity of the golf club shaft 100 toward the tip end side of the shaft.

In the golf club shaft 100 according to the present embodiment, the position of the center of gravity of the shaft shifted by the metal cylinder 120 in the shaft body 110 cut so that the total length of the shaft is 43 inches or less is set to 0% at the tip in the longitudinal direction. , When the base end portion in the longitudinal direction is 100%, it is set in the range of 39% to 45%. Further, the position of the center of gravity of the shaft shifted by the metal cylinder 120 shall be set in the range of 41% to 44% when the tip portion in the longitudinal direction is 0% and the base end portion in the longitudinal direction is 100%. Is preferable, and it is more preferable to set it in the range of 42.5% to 43.5%.
By setting the position of the center of gravity of the shaft shifted by the metal cylinder 120 within the above range, it is possible to easily adjust various parameters such as the weight, frequency, and torque of the golf club shaft 100. Further, it is possible to realize an excellent swinging comfort without requiring a delicate setting while maintaining the merit when the golf club shaft 100 is made short.
When the position of the center of gravity of the shaft shifted by the metal cylinder 120 is closer to the tip side than the position of 39% (when the lower limit of the conditional expression is exceeded), various parameters such as the weight, frequency, and torque of the golf club shaft 100 Adjustment becomes difficult.
When the position of the center of gravity of the shaft shifted by the metal cylinder 120 is closer to the base end side than the position of 45% (when the upper limit of the conditional expression is exceeded), there is a demerit when the golf club shaft 100 is shortened (for swinging comfort). It becomes difficult to eliminate the feeling of strangeness and the difficulty of raising the ball. Further, when the weight of the club head is increased in order to eliminate the demerit, a delicate setting including adjustment of the total length of the short golf club shaft may be required.
By the way, the position of the center of gravity of the shaft in the conventional short shaft body (golf club shaft) is closer to the base end side than the position of 48% or 50% (the upper limit of the conditional expression is greatly exceeded).

FIG. 5 shows the characteristics of three samples of the golf club shaft 100 according to the present embodiment. As shown in FIG. 5, samples 1, 2 and 3 having a total shaft length larger than 43 inches (for example, 45 inches or more) and having different characteristics in the initial state were prepared. Then, for each sample 1-3, the position of the center of gravity of the shaft is set when the total length of the shaft is 43 inches, 42 inches, 41 inches, and 40 inches by cutting the shaft base end side with a cutting amount larger than the shaft tip side. Monitored.

The position of the shaft center of gravity of sample 1 is set to 40.5% when the total length of the shaft is 43 inches, 40.2% when the total length of the shaft is 42 inches, and the total length of the shaft is 41 inches. At the time, it is set to 39.9%, and when the total length of the shaft is 40 inches, it is set to 39.6%.
The position of the shaft center of gravity of sample 2 is set to 42.6% when the total length of the shaft is 43 inches, 42.3% when the total length of the shaft is 42 inches, and the total length of the shaft is 41 inches. At the time, it is set to 42.0%, and when the total length of the shaft is 40 inches, it is set to 41.7%.
The position of the shaft center of gravity of sample 3 is set to 44.4% when the total length of the shaft is 43 inches, 44.1% when the total length of the shaft is 42 inches, and the total length of the shaft is 41 inches. At the time, it is set to 43.8%, and when the total length of the shaft is 40 inches, it is set to 43.5%.

In the golf club shaft 100 according to the present embodiment, the ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 is set in the range of 14% to 33%. The ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 is preferably set in the range of 17% to 30%, and more preferably set in the range of 20% to 25%.
By setting the ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 within the above range, it is possible to easily adjust various parameters such as the weight, frequency, and torque of the golf club shaft 100. Further, by facilitating the effect of shifting the center of gravity by the metal cylinder 120, the position of the center of gravity of the shaft can be easily set in the range of 39% to 45%.
When the ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 is greater than 33% (when the upper limit of the conditional expression is exceeded), it becomes difficult to adjust various parameters such as the weight, frequency, and torque of the golf club shaft 100. turn into.
When the ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 is less than 14% (when the lower limit of the conditional expression is exceeded), it becomes difficult to obtain the effect of shifting the center of gravity by the metal cylinder 120. For example, it becomes difficult to set the position of the center of gravity of the shaft in the range of 39% to 45%.

The ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 in sample 1 is set to 29.8% when the total length of the shaft is 43 inches, and is set to 30.5% when the total length of the shaft is 42 inches. When the total length of the shaft is 41 inches, it is set to 31.4%, and when the total length of the shaft is 40 inches, it is set to 32.2%.
The ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 in sample 2 is set to 22.1% when the total length of the shaft is 43 inches, and is set to 22.7% when the total length of the shaft is 42 inches. When the total length of the shaft is 41 inches, it is set to 23.3%, and when the total length of the shaft is 40 inches, it is set to 24.0%.
The ratio of the weight of the metal cylinder 120 to the weight of the shaft body 110 in Sample 3 is set to 18.1% when the total length of the shaft is 43 inches, and is set to 18.6% when the total length of the shaft is 42 inches. When the total length of the shaft is 41 inches, it is set to 19.2%, and when the total length of the shaft is 40 inches, it is set to 19.8%.

FIG. 6 shows an example of the transition of the shaft outer diameter (OD (mm)) in the longitudinal direction (X (mm)) of the golf club shaft 100 according to the present embodiment. FIG. 6 is data after cutting so that the total length of the shaft is 43 inches or less.

As shown in FIG. 6, the shaft main body 110 has a first region A1, a second region A2, and a third region A3 in this order from the proximal end side to the distal end side in the longitudinal direction. There is. In the first region A1, the outer diameter of the shaft of the shaft body 110 decreases relatively gently from the proximal end side to the distal end side in the longitudinal direction. In the second region A2, the shaft outer diameter of the shaft body 110 decreases relatively steeply from the proximal end side to the distal end side in the longitudinal direction. In the third region A3, the relative amount of change in the shaft outer diameter of the shaft body 110 in the longitudinal direction is the smallest (it is substantially straight). A grip 300 is attached to the outer peripheral surface of the first region A1 of the shaft main body 110, and a metal cylinder 120 is embedded in the inner peripheral surface of the third region A3 of the shaft main body 110.

The ratios of the first region A1, the second region A2, and the third region A3 in the longitudinal direction preferably satisfy the following conditional expressions, respectively. That is, the proportion of the first region A1 in the longitudinal direction is 30% or more, the proportion of the second region A2 in the longitudinal direction is 45% to 60%, and the proportion of the third region A3 in the longitudinal direction is The ratio is preferably 10% to 25%. In the example of FIG. 6, the ratio of the first region A1 occupying the longitudinal direction is set to 32%, and the ratio of the second region A2 occupying the longitudinal direction is set to 50%, occupying the longitudinal direction. The proportion of the third region A3 is set to 18%.

By setting the ratio of the first region A1 to the longitudinal direction to 30% or more, the first region A1 can be secured as the mounting region of the grip 300. When gripping the grip 300 with both left and right hands, if the area gripped by the right hand is narrower than the area gripped by the left hand, the grip 300 will be gripped more than necessary with the right hand, so the probability of missed shots tends to increase. be.
If the ratio of the first region A1 having a gentle taper shape is set to 30% or more and secured as the mounting region of the grip 300, the thickness of the region gripped by both the left and right hands will be substantially the same, and the right hand will have more grip strength than necessary. Since it is not necessary to clench the grip 300, it is possible to increase the probability of a nice shot.
On the contrary, when the ratio of the first region A1 is less than 30%, the attachment region of the grip 300 straddles the first region A1 and the second region A2, so that the region gripped by the left hand is gripped by the right hand. Since the area becomes narrower and the grip 300 is squeezed with more grip strength than necessary in the right hand, the probability of a missed shot increases.

By setting the ratio of the third region A3 to the longitudinal direction to 10% to 25%, the third region A3 is secured as the buried region of the metal cylinder 120, and the weight, frequency, and torque of the golf club shaft 100 are secured. It is possible to easily adjust various parameters such as.
As described above, the metal cylinder 120 is embedded in the inner peripheral surface of the third region A3 of the shaft body 110. When the ratio of the third region A3 to the longitudinal direction is smaller than 10%, it becomes difficult to secure the third region A3 as the buried region of the metal cylinder 120.
If the ratio of the third region A3 to the longitudinal direction is larger than 25%, it becomes difficult to adjust various parameters such as the weight, frequency, and torque of the golf club shaft 100.

By setting the ratio of the second region A2 in the longitudinal direction to 45% to 60%, excellent hitting comfort (feeling) is realized, and the first region A1 is secured as the mounting area of the grip 300. The third region A3 can be secured as a buried region of the metal cylinder 120.
When the ratio of the second region A2 to the longitudinal direction is smaller than 45%, the taper ratio (diameter reduction degree) of the golf club shaft 100 (shaft body 110) becomes too steep, and the feel of hitting is uncomfortable. May occur.
When the ratio of the second region A2 to the longitudinal direction is larger than 60%, the first region A1 cannot be secured as the mounting region of the grip 300, and / or the third region A3 is the embedded region of the metal cylinder 120. There is a risk that it will not be possible to secure it.

FIG. 7 is a diagram showing an example of the transition of the shaft outer diameter in the longitudinal direction of the golf club shaft 100 according to the present embodiment and the golf club shaft according to Comparative Example 1-3. The transition of the shaft outer diameter in the longitudinal direction of the golf club shaft 100 according to the present embodiment is as described with reference to FIG. On the other hand, the golf club shaft according to Comparative Example 1-3 is not divided into the first region A1, the second region A2, and the third region A3, and covers the entire area in the longitudinal direction. The diameter is reduced from the base end side to the tip end side with a substantially constant taper ratio.

When manufacturing the golf club shaft 100 as described above, a gently tapered surface for forming the first region A1 (for example, a taper ratio of 5/1000) and a second region A2 are formed. A modified mandrel (not shown) having a steep tapered surface (for example, a taper ratio of 13/1000) and a substantially straight surface for forming the third region A3 as an outer diameter shape is prepared. Next, the inner peripheral surface of the metal cylinder 120 is fitted into the substantially straight surface of the deformed mandrel. Next, a plurality of prepregs are laminated and wound around the outer peripheral surface of the deformed mandrel and the metal cylinder 120. Next, the plurality of prepregs are heat-cured to form a golf club shaft 100 in which the shaft body 110 and the metal cylinder 120 are integrated. Finally, the deformed mandrel is pulled out from the golf club shaft 100 to remove the deformed mandrel.

FIG. 8 shows an example of the laminated prepreg constituting the shaft main body 110. This laminated prepreg is configured by laminating carbon prepregs P1-P8 in this order on the upper layer of the metal cylinder 120. The carbon prepregs P1 and P4 are 0 ° prepregs in which the long fiber direction is parallel to the longitudinal direction of the shaft, and are partial prepregs arranged on a part of the tip side in the longitudinal direction. The carbon prepregs P2 and P3 are a pair of bias prepregs having a long fiber direction of ± 45 ° with respect to the longitudinal direction of the shaft, and are full-length prepregs over the entire length in the longitudinal direction. The carbon prepreg P5-P7 is a 0 ° prepreg whose long fiber direction is parallel to the longitudinal direction of the shaft, and is a full-length prepreg over the entire length in the longitudinal direction. The carbon prepreg P8 is a 0 ° prepreg whose long fiber direction is parallel to the longitudinal direction of the shaft, and is a reinforcing prepreg wound around the tip end side of a deformed mandrel. The laminated prepreg illustrated in FIG. 8 is only an example, and various design changes can be made to the number and structure of the laminated prepregs.

For a plurality of testers of advanced golfers, a trial hitting event was held with a golf club shaft 10 according to the present embodiment and a golf club shaft in which a club head with a heavier weight is attached to a conventional short golf club shaft. The impression of the plurality of testers was that the golf club shaft 10 according to the present embodiment was generally superior in hitting comfort (feeling).

In the above embodiment, the case where the position of the center of gravity of the shaft is adjusted by using the metal cylinder 120 embedded in the inner peripheral surface of the shaft body 110 as a “center of gravity shift member, weight” has been described as an example. There is a degree of freedom in the specific mode of the "weight", and various design changes are possible. For example, the position of the shaft center of gravity may be adjusted by including the metal-containing prepreg in the prepreg constituting the shaft body 110 and using this as a “center of gravity shift member, weight”. Further, the position of the center of gravity of the shaft may be adjusted by devising the laminated structure of the prepregs constituting the shaft 110 and using this as a "center of gravity shift member, weight".

The golf club shaft and golf club according to the present embodiment are, for example, a golf club shaft and golf club having excellent swing comfort without requiring a delicate setting for a golf player while maintaining the merit of being short. It is preferable in that it can provide.

10 Golf club 100 Golf club shaft 110 Shaft body 111 Inner wall 112 Buried concave cylinder 113 Base end side cylinder end face 114 Shaft tip side end face 120 Metal cylinder (center of gravity shift member, weight)
121 Base-side cylindrical end face 122 Tip-side cylindrical end face 200 Club head 300 Grip A1 First area A2 Second area A3 Third area

Claims (8)

The shaft body extending in the longitudinal direction and
A center of gravity shift member provided on the shaft body and shifting the center of gravity of the shaft toward the tip end side in the longitudinal direction.
Have,
When the shaft body is cut so that the total length of the shaft is 43 inches or less, the position of the center of gravity of the shaft is when the tip portion in the longitudinal direction is 0% and the base end portion in the longitudinal direction is 100%. Is set in the range of 39% to 45%,
A golf club shaft characterized by that. The cutting length of the shaft body on the proximal end side in the longitudinal direction is larger than the cutting length of the shaft body on the distal end side in the longitudinal direction.
The golf club shaft according to claim 1. The ratio of the weight of the center of gravity shift member to the weight of the shaft body is set in the range of 14% to 33%.
The golf club shaft according to claim 1 or 2. The center of gravity shift member has a metal cylinder embedded in the inner peripheral surface of the shaft body.
The golf club shaft according to any one of claims 1 to 3. The shaft body has a first region in which the outer diameter of the shaft decreases relatively gently and a second region in which the outer diameter of the shaft decreases relatively steeply in order from the base end side to the tip end side in the longitudinal direction. And a third region with the smallest relative change in shaft outer diameter.
The golf club shaft according to any one of claims 1 to 4. The proportion of the first region in the longitudinal direction is 30% or more, the proportion of the second region in the longitudinal direction is 45% to 60%, and the proportion of the third region in the longitudinal direction is 45% to 60%. The ratio is 10% to 25%,
The golf club shaft according to claim 5. A grip is attached to the outer peripheral surface of the first region, and a metal cylinder as the center of gravity shift member is embedded in the inner peripheral surface of the third region.
The golf club shaft according to claim 5 or 6, wherein the golf club shaft. A golf club according to any one of claims 1 to 7, wherein a club head and a grip are attached to the golf club shaft.

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