JPH0793952B2 - Golf club - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a golf club designed to achieve an improvement in head speed.

[Conventional technology]

The flight distance of a golf ball depends on the resilience characteristics of the golf ball. Generally, the repulsive force of a golf ball is high,
Further, it is considered that the harder the face surface of the head is, the more the golf ball flies. However, it is argued that the face surface of the head does not have to be simply hardened, but has an appropriate hardness. For example, Japanese Unexamined Patent Publication No. 61-22875 discloses that the hardness of the face surface of the head has an optimum value determined based on the mechanical impedance, and if the optimum value is exceeded, the resilience characteristic deteriorates. ing. However, in addition to such quasi-static characteristics, the flight distance of the golf ball is related to dynamic characteristics.

The flight distance of a golf ball is almost determined by the head speed, head weight, and launch angle in a swing. A fast swing is required to increase the head speed, but even if the golf club is simply swung in a rod shape, the head speed is not as high as expected. In order to increase the head speed, it is necessary to swing using the elasticity of the shaft. That is, if the shaft is elastically deformed so that the head is delayed in the initial stage of the downswing, and the shaft is swung so as to restore the elasticity of the shaft immediately before the impact, the speed at the time of elastic recovery of the shaft is added to the swing speed. And the head speed increases.
In this way, the elasticity of the shaft is very important, and today, in order to improve the head speed, the swing theory related to the hardness of the shaft and the frequency theory about the combination of the hardness of the shaft and the weight of the head are developed. Has been done.

[Problems to be Solved by the Invention]

However, there has been no proposal to improve the head speed by utilizing the impact characteristics corresponding to the impact torsion bending of the club at the time of impact. The inventor of the present invention, as indicated by the point X in FIG. 4, shows that at the time of impact, the tip portion of the shaft dynamically follows the impact between the head and the golf ball, and in a short period of time, the tip of the shaft is almost in a V shape. It was found that it bends in a shape. Shock is a phenomenon that occurs in a short time,
Usually, such bending of the shaft due to the impact between the head and the golf ball cannot be visually recognized, and conventionally, there has been no idea to improve the head speed and directionality in consideration of the bending of the shaft due to such impact.

The inventor of the present invention has found that the deformation behavior of the tip of the shaft under impact is visualized, and the impact of the head and the golf ball causes the tip side of the shaft and the vicinity of the neck portion to bend, and the dynamics of such shaft I noticed that the general bending is important for improving the head speed. Simply put, the head retracts relative to the shaft within a short time due to the collision with the golf ball, and the shaft receives the force of the swing to move forward and the force of the head to retract. , The tip of the shaft bends. That is, when the forward inertia of the entire club is impacted, only the head receives the retracting force, absorbs the elastic strain energy, and instantly deforms. Thus, on the one hand, the head retreats relative to the shaft due to the collision with the golf ball, but on the other hand, since the golf club continues to swing, the head advances with the shaft relative to the ball, Continues to contact the golf ball even after the collision, and after a certain time from the start of the collision, the golf ball starts to fly away from the head (contact time Tc
Called). In the conventional golf club, it was found that the bending of the tip of the shaft due to the impact of the head is restored after the contact time Tc has elapsed. Therefore, the head retreats relative to the shaft, resulting in a decrease in head speed.

The object of the present invention, when the golf club is impacted with a golf ball, undergoes impact torsion bending, elastic strain energy is accumulated in the shaft tip side and in the vicinity of the neck portion, and within the contact time Tc, the elastic strain energy is transferred to the ball. It is to provide a golf club that increases the speed of the ball and improves the directionality by efficiently adding to the.

[Means for Solving the Problems]

In order to solve the above-mentioned object, a golf club according to the present invention is provided with a shaft attached to a neck portion of a head, and an impact of a tip end side of the shaft and a portion near the neck which are dynamically bent by the impact of the head at the time of impact. A means for increasing the responsiveness is provided, and the means for increasing the impact responsiveness comprises a core with high impact responsiveness provided inside the tip side of the shaft and in the vicinity of the neck portion. The head is advanced in the direction in which the ball jumps out during contact, and further, core contact members are provided on both sides of the core, and the core contact members on both sides can be adjusted by rods extending substantially along the center of the core. It is characterized by being combined with.

[Work]

In the above structure, the shaft is partially bent dynamically due to the impact of the head at the time of impact, but since the impact response of the bent part of the shaft is made high, the golf ball is hit by the golf ball after the head hits the golf ball. Before jumping out of the head, that is, while the head is in contact with the golf ball, the head collides with the golf ball and retracts relatively to the shaft, and conversely the head advances relatively to the shaft. The forward movement of the head with respect to the shaft can add to the speed of the swing mainly about the shaft to improve the head speed. Hereinafter, this phenomenon is referred to as a snapback effect. Further, in the present invention, the core abutting members on both sides of the core are adjustably coupled by the rods, so that the core is adjustably tightened. Therefore, when the head collides with the golf ball, the maximum It can be adjusted for a kickback effect.

〔Example〕

Referring to FIGS. 1 and 2, the golf club 10 includes a head 12 and a shaft 14, and a grip 16 is provided on an upper end portion of the shaft. In the example, the head
With a hollow structure of 12, the head 12 has an integrally formed neck portion 20, and the lower end portion of the shaft 14 is fitted into this neck portion 20. The shaft 14 is fixed to the neck portion 20.

As shown in FIGS. 1 and 2, the tip portion 14a of the shaft 14 (indicated by the arrow l) has a different shock response from the upper portion thereof, that is, the tip portion 14a of the shaft. It is formed so as to improve impact response.

As shown in FIG. 1, the shaft 14 has a step portion 22,
22 is thicker on the upper side and thinner on the lower side. In the embodiment shown in FIG. 1, the step portion 22 is the upper limit of the tip portion 14a that enhances the shock response of the shaft 14, and the lower limit is the neck portion 2.
It is the tip of the part (fitting part) attached to 0. In this way, the tip portion 14a of the shaft 14 having high impact response is
Includes the portion from the attachment to the neck portion 20 to the portion above it. The length of the tip portion 14a varies depending on the length of the neck portion 20 and the like, but, for example, the length above the attachment portion to the neck portion 20 is several cm to 30 cm. A core 24 having a high impact response is inserted into the tip portion 14a of the shaft 14 so as to be in close contact with the inner peripheral surface of the shaft 14. The core 24 is formed of, for example, a highly elastic amorphous alloy, various composite materials, an intermetallic compound, or a ceramic material under impact.

In FIG. 1, a hole is provided at the center of the core 24, and a bolt (rod) 26 is passed through the hole. Washer-shaped core abutting members 28 and 30 are provided on both sides of the core 24, and the head of the bolt (rod) 24 engages with one core abutting member 28, and the screw at the tip of the bolt (rod) 24 is screwed. By tightening the nut 32 onto the core abutting member 30 on the head 12 side, the core 24 can be adjusted, and shock response corresponding to the vibration mode peculiar to the shaft 14 can be obtained. There is. The nut 32 can be tightened with the sole plate of the head 12 removed, but when the head 12 does not have a hollow structure, the nut 32 and the core abutting member 30 of the 12 heads are large enough to pass through the neck portion 20. Shaft
Adjustments can be made while removing 14.

In the embodiment shown in FIG. 1, the core abutting members 28 and 30 are substantially brought into contact with the step portion 22 of the shaft 14 and the tip of the shaft 14, respectively, so that the core 24 is fixed to the shaft 14. On the other hand, in the embodiment shown in FIG. 3, the core contact member 28 contacts the step portion 22 of the shaft 14, and
The core abutting member 30 on the head 12 side abuts on the tip portion of the shaft 14 and the inner surface of the neck portion 20, so that rigidity is improved by integration.

FIG. 4 is a diagram showing the swing of the golf club 10 in stages. (A) shows the start point of impact.
(B) shows after the head 12 collides with the golf ball,
The head 12 retracts relative to the shaft 14 due to the impact with the golf ball, and the tip portion 14a of the shaft 14 is bent at a position indicated by X. Since this bending occurs within a very short time due to impact, it is difficult to simply confirm it visually, but it is confirmed by visualizing the deformation behavior of the shaft tip under impact and analyzing the visualization model. can do. FIG. 7 is a diagram showing this state in detail. The two-dot chain line Y is the axis of the shaft 14, and the one-dot chain line Z is the center line of the deformed portion of the shaft 14 on the tip side. The head 12 is tilted with respect to the axis Y,
At the same time, the loft angle also changes.

The flexure X provides reference data for estimating the amount of time the head 12 is retracting relative to the shaft 14 and the amount of displacement. Therefore, the impact response of the core 24 can be determined while looking at the bent portion X. Also, with reference to the bent portion X, the core 24
By finely adjusting the rigidity of, the shock response corresponding to the vibration mode peculiar to the shaft 14 can be obtained. Adjustment method 1
The first is to adjust the bent portion X so that it approaches the head 12 side on the shaft 14, which leads to shortening the cycle of impact vibration of the head 12.

(C) shows the moment when the golf ball is about to fly away from the head 12. The golf ball is in contact with the head 12 from (a) to (c), and this time is referred to as the contact time Tc as described above. If the bent portion X is restored and the head 12 is moved forward relative to the shaft 14 by the time shown in (c), the head speed is improved as compared with the conventional one due to the snapback effect. . (D)
Thus, when the golf ball jumps out of the head 12, the shock vibration of the shaft 14 is damped.

FIG. 5A is a diagram showing impact vibration of the head 12 at the time of impact of the golf club 10 obtained by the present invention. Assuming that the reference position of the head 12 with respect to the shaft 14 is the time point of FIG. 4 (a), the head 12 retracts relatively to the shaft axis due to the collision with the golf ball, and the tip end side of the shaft and the portion near the neck are It bends and elastic strain energy is stored. The head begins to return after reaching the peak of vibration. When a half cycle of the vibration of the vibration system formed by the head 12 and the shaft 14 elapses, the head 12 returns to the reference position, and from then onward, the head 12 moves forward relative to the shaft 14 and its relative position. Forward movement improves head speed. As a result, the accumulated elastic strain energy is efficiently added to the ball, increasing the ball speed. Thus, in order to improve the head speed, the time until the head 12 moves forward relative to the shaft 14, that is, the half cycle time T _A of the vibration is smaller than the contact time T _C. So that the head
It is important to shorten the cycle of 12 shock vibrations.

FIG. 5B is a diagram showing shock vibration at the time of impact in a conventional golf club. When the head collides with the golf ball, similarly, the tip side of the shaft and the portion near the neck are bent, and elastic strain energy is accumulated. However, since the ball jumps out from the head before the half cycle of the vibration of the head elapses, the accumulated elastic strain energy is not efficiently added to the ball, and it is not possible to increase the ball speed.

FIG. 6A is a diagram showing a change in loft angle at the time of impact in the present invention and FIG. 6B is a diagram showing a prior art. The head 12 and the shaft 14 receive torsion and bending at the same time at the time of impact, and the loft angle also changes, which causes the directionality of the flight to change. Is preferred. Therefore, in the present invention, the half cycle T _B of the impact torsional vibration is the contact time.
It should be exactly equal to T _C. In the conventional type, the half cycle T _B of the impact torsional vibration is larger than the contact time T _C , which causes the golf ball to pop out before the restoration of the change in the loft angle is achieved, causing the directionality to be unstable. Was invited.

〔The invention's effect〕

As described above, according to the present invention, the shaft is attached to the neck portion of the head, and the impact responsiveness of the tip end side of the shaft which is dynamically bent by the impact of the head at the time of impact and the portion near the neck portion Since the golf club is subjected to impact torsional bending at the time of impact with the golf ball, elastic strain energy is accumulated near the tip of the shaft and near the neck, and the elastic strain energy is increased within the contact time Tc. Effectively increases the speed of the ball,
And a golf club which improves directionality can be provided. In addition, the neck part has improved shock response,
Since it is strong against stress at the time of impact, it is possible to prevent breakage of the shaft.

[Brief description of drawings]

FIG. 1 is a partially enlarged view of the golf club of the first embodiment of the present invention, FIG. 2 is a view showing the golf club of FIG. 1, and FIG. 3 is a first view showing the golf club of the second embodiment. A similar view, FIG. 4, is a view showing the swing of the golf club in stages,
FIG. 5A is a diagram for explaining the behavior of the shock-vibrating head of the present invention, FIG. 5B is a diagram for explaining the behavior of the shock-vibrating head of the prior art, and FIG. 6A is a loft angle of the shock-vibrating head of the present invention. FIG. 6B is a diagram for explaining the change, FIG. 6B is a diagram for explaining the change in the loft angle of the head that undergoes impact vibration according to the related art, and FIG. 7 is a diagram showing the state of FIG. 4B in detail. 10 ... Golf club, 12 ... Head, 14 ... Shaft, 14a ... Tip part, 20 ... Neck part, 24 ... Core, 26 ... Bolt, 28, 30 ... Core abutting member.

Claims (2)

[Claims] 1. A head provided with a shaft attached to a neck portion of the head, and means for enhancing the impact responsiveness is provided at the tip end side of the shaft which is dynamically bent by the impact of the head at the time of impact and in the vicinity of the neck portion. The means for enhancing the impact response comprises a core having high impact response provided inside the tip side of the shaft and in the vicinity of the neck portion,
While the head and the golf ball are in contact with each other, the head is advanced in the ball ejection direction. Further, core abutting members are provided on both sides of the core, and rods extending substantially along the center of the core are provided on both sides of the core. A golf club, wherein contact members are adjustably coupled. 2. The golf club according to claim 1, wherein the core contact member on the head side is in contact with the tip and neck of the shaft.