KR100681296B1 - Golf club head - Google Patents

Abstract

While improving the rigidity of the center portion of the face shell, the difference between the flying distance due to hitting the center portion and the flying distance due to hitting the toe side and the heel side is minimized as much as possible, and a golf club head having a metal shell structure with improved hitting performance is provided. .

In the golf club head comprised so that a main body may become hollow by a metal outer shell structure, the thick part is formed in the longitudinal direction of the substantially center of the face outer shell used as a strike surface.

Description

Golf club head {GOLF CLUB HEAD}

1 is an exploded perspective view showing a configuration of a first embodiment of the present invention.

Fig. 2 is a diagram showing the formation state of the face shell of the first embodiment of the present invention.

3 is a view for explaining the striking performance of the first embodiment of the present invention.

4 is a numerical table of experimental results comparing the coefficient of rebound coefficients.

5 is a numerical table showing experimental results for comparing flying distance measurements.

6 is a numerical table of experimental results for comparing measured coefficients of rebound coefficient due to differences in thick parts.

7 is a numerical table of experimental results for comparing flying distance measurement values due to differences in thick parts.

Fig. 8 is a diagram showing a state of formation of the face shell of the second embodiment of the present invention.

Fig. 9 is a diagram showing a state of forming a face shell according to the third embodiment of the present invention.

It is a figure which shows the formation state of the face outer shell of 4th Example of this invention.

It is a figure which shows the formation state of the face outer shell of 5th Example of this invention.

It is a figure explaining the area which forms the thick part of this invention.

It is a figure which shows the formation state of the face outer shell of the other Example of this invention.

It is an exploded perspective view which shows the structure of the conventional golf club head.

It is a figure which shows the formation state of the face outer shell of the conventional golf club head.

It is a figure explaining the hitting performance of the conventional golf club head.

<Description of the symbols for the main parts of the drawings>

1: golf club head

2: face shell

2a: thick parts

3: crown shell

4: soul shell

5: hosel shell

The present invention relates to the improvement of the preferred face outside angle applied to the golf club head of the metal shell structure, so that the difference in flying distance becomes small even when the golf ball is hit at different positions at the face outside.

Since the golf club head of the metal shell structure can reduce the weight of the golf ball while reducing the weight, it is employed in a type commonly referred to as a driver, and a number of improvements have been made. The golf club head having the metal shell structure is formed by joining and assembling a plurality of components, for example, a face shell, a crown shell, a soul shell, and a hosel shell.

Fig. 14 is a view showing the configuration of the golf club head 11 having such a metal shell structure, wherein the face shell 12, the crown shell 13, the soul shell 14, and the hosel shell 15 face each other. The open end to be joined is welded and assembled, and the joining portion is polished to complete the golf club head 11. On the other hand, the tip of the extension portion 15a of the hosel shell 15 is welded to the inner bottom of the soul shell 14, while the tip of the shaft is inserted into and fixed to the core hole 15b formed in the hosel shell 15. The golf club is completed.

In the golf club head 11 of the conventional metal shell structure structured as described above, in order to increase the distance, the face shell 12 is generally reduced by reducing the thickness of the face shell 12 or the like. It is trying to bend easily. When the stiffness of the face outer shell 12 is lowered, the center portion is most bent, and it is difficult to bend gradually toward the outer circumference. The greater the amount of deflection, the greater the repulsion force, and the flying distance can be increased by hitting the golf ball at the center portion.

By the way, when the thickness of the face shell 12 is made thin and the rigidity is low, the distance of the golf ball caused by the hit at the center portion can be increased, but the durability of the center portion is lowered because the amount of deflection increases, and this portion is damaged. There is a problem that it is easy to be. As a means to solve this problem, an attempt has been made to form an annular or circular thick portion in the center portion and to solve this problem. This is to increase the thickness in the annular region sandwiched between the central region and the outer edge region, and is to suppress deformation and improve durability (for example, Japanese Patent Laid-Open No. 2002-331051).

15 is a view showing the formation of the face shell 12 of the golf club head 11 has been improved, the broken line (R1) of the outer edge portion of the face shell 12 is crown outer shell 13, the soul shell shell (14) and the junction part with the hosel outer shell 15 are shown, and the inner ring line R2 and the outer ring line R3 of the thick part 12a formed in the back center part of the face outer shell 12 are shown with a broken line. Therefore, the face outer shell 12 configured as described above has increased rigidity in the outer peripheral portion and the central portion thereof.

When hitting the golf ball by the golf club head 11 formed as described above, when the hitting point is the sweet spot in the center, the hitting stress is concentrated in the center to obtain the greatest repulsive force, and at the same time, the flying distance can be increased, Deformation of the face shell 12 is suppressed by the thick portion 12a, so that durability can be improved.

By the way, as shown in FIG. 16A, when the hitting point SP of a golf ball becomes a toe side, and a hitting force F is applied to this, the tow side of the thick part 12a bends in a centripetal direction ( Fa) occurs, and a stress Fb in which the heel side bends in the centrifugal direction occurs. That is, the thick portion 12a is twisted and rotated at the center of the face shell 12 to generate couple forces, bending deformation occurs in opposite directions at the toe side and the heel side, and concentration of the impact stress. Because of this dispersion, the repulsive force is lowered. As shown in FIG. 16B, in the case where the striking point SP is at the heel side, similarly, the repulsive force of the face shell 12 decreases due to the right force generated in the thick portion 12a.

This causes a large area of the thick portion 12a in the face outer shell 12, but the shape of the thick portion 12a greatly affects it. That is, as described above, the face shell 12 can obtain a high repulsive force by lowering the rigidity and making it easy to bend, but with the conventional configuration, the thick portion 12a becomes a resistor that inhibits the bendability. The stiffness on the heel side is increased. Therefore, in the conventional golf club head 11 configured as described above, the flying distance by the strike of the center portion and the flying distance of the toe side and the heel side are greatly different.

The present invention has been made in view of such a conventional problem, and the difference between the flying distance due to hitting the center portion and the flying distance due to hitting the toe side and the heel side is made as small as possible while improving the rigidity of the center portion of the face shell. To improve the hitting performance of the golf club head of the metal outer structure.

Therefore, this invention solved the said subject by each means demonstrated below. That is, in this invention, in the golf club head comprised so that a main body might become hollow by a metal outer shell structure, the thick part is formed in the longitudinal direction of the substantially center of the back surface outer surface used as a strike surface.

Preferably, in the golf club head, the thick portion is formed over the crown outer shell and the soul outer shell.

Preferably, in the said golf club head, the thickness of the outer shells other than a thick part shall be 2.5 mm or less.

Preferably, in the golf club head, the loft angle is 15 degrees or less.

Preferably, in the golf club head, a thick portion on the rear face outer face is joined by welding.

Preferably, in the golf club head, the thick portion of the face shell is integrally formed by forging or casting.

Preferably, in the golf club head, the material of the thick portion is different from the material of the face shell.

According to the present invention, a golf club head configured to have a hollow body by a metal shell structure includes a face shell serving as a striking surface, and the face shell is formed in a longitudinal direction at a substantially horizontal center of the rear surface thereof. A golf club head provided with a thick portion, wherein the thick portion is formed within a range of 50% of the transverse length of the face shell in a lateral centerline symmetry of the face shell.

Preferably, in the golf club head, the face shell is further provided with a toe side thin portion and a heel side thin portion formed by sandwiching a thick portion, so as to satisfy the following equation.

O.2t _B ≤t _A ≤0.8t _B

0.2t _B ≤t _C ≤0.8t _B

Here, t _B is the maximum thickness of the thick portion, t _A is the thickness of the toe side thin portion, t _C is the thickness of the heel side thin portion.

Best Mode for Carrying Out the Invention

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail based on drawing.

1 to 3 are views showing the configuration of the head body of the metal shell structure according to the first embodiment of the present invention, the face shell (2), crown shell (3), soul shell (4), hosel shell ( The open ends of each of 5) are joined to each other by welding, and the joined portions are polished to complete the golf club head 1. On the other hand, the tip of the extension portion 5a of the hosel shell 5 is welded to the inner bottom of the soul shell 4, while the tip of the shaft is inserted into the core hole 5b formed in the hosel shell 5 to be fixed. The golf club is completed.

And although the thick part 2a is formed in the longitudinal direction of the substantially center of the back surface of the said face outer shell 2, this thick part 2a may be integrated by welding, and is integrally formed by forging or casting. You may do so. In addition, the thick part 2a to form may be the same material as the face outer shell 2, and may employ | adopt a different material.

FIG. 2 is a view showing a state in which the face outer shell 2 of the golf club head 1 of the present invention configured as described above is formed, and the broken line L1 at the outer edge portion is the crown outer shell 3 of the face outer shell 2, The junction part with the sole outer shell 4 and the hosel outer shell 5 is shown, and the external shape of the thick part 2a formed in the back surface of the face outer shell 2 is shown with the broken line L2. The face outer shell 2 configured as described above has a large mass of the portion where the thick portion 2a is formed, so that the stiffness of the center portion is increased.

FIG. 3 schematically shows the state of the moment when the golf ball hits the golf ball by the golf club head 1 of the first embodiment, and FIG. 3A strikes the golf ball at the strike point SP on the toe side. The case where the striking force F is applied is shown. In this state, since the mass in the transverse direction of the thick portion 2a of the face shell 2 is insufficient, there is no room for the right force. Therefore, the front face of the face shell 2 is centered, although there is a local difference in size. It can be bent in the direction and deformed, and large damping of repulsive force can be prevented. This also applies to the case where the striking point SP is at the heel side, as shown in FIG. 3B, and can prevent large attenuation of the repulsive force without being influenced by the right hand force of the thick portion 2a.

In order to verify these results, Applicants attempted a plurality of experiments having different conditions, and the results are shown in the numerical table of FIGS. 4 to 7. Fig. 4 is a measurement result of the coefficient of rebound, and the starting head A, the comparison head A, and the comparison head B employed in this experiment are all titanium heads produced by the 4pcs forging method. The starting head A sets the thickness of the thick portion of the face shell 2 to 10 mm, the other portion to 2 mm, and sets the loft angle to 15 degrees or less. On the other hand, the thick portion may be formed on the face outer shell in various ways as described below. In the present invention, the thickness of the thick portion includes the thickness of the face outer shell even when the thick portion is formed of a material different from the face outer shell. The thickness of the thick part.

The comparative head A is a general structure which made the whole face into the uniform thickness of 2.6 mm, without forming a thick part. The comparison head B forms a circular thick portion having a diameter of 40 mm at the face center, and makes the other portion 2 mm thick. On the other hand, the starter head A, the comparison head A, and the comparison head B each had a crown outer shell and a soul outer shell having a thickness of 1 mm, and the outer shell of the hosel was cut out of a round bar, and each of the outer shells was welded, polished, and finished. .

In the experimental method, the golf ball was hit at three positions on the toe side and the heel side 20 mm away from the center and center of each golf club head, and the coefficient of rebound was calculated and calculated from the speed at the time of the rebound of the golf ball. This experimental result shows that the largest difference in the comparison of the coefficient of repulsion at the position of 20 mm away from the central repulsion coefficient as shown in Fig. 4, i.e., the maximum crossover is the smallest at the starting head A of the present invention, It can be found that the difference in repulsion coefficient between the toe side and the heel side is small.

Next, an experiment was performed in which the golf ball was hit by using the start head A, the comparison head A, and the comparison head B, and the specific distance thereof was measured. This is completed as a golf club by attaching a shaft and a grip to each head, swinging it at a head speed of 40 meters per second by a robot flying distance meter, measuring the flying distance of the golf ball 5 times at this time, and calculating the average value of FIG. 5. Shown in As is apparent from the results shown in the drawing, the maximum intersection of the flying distance when hitting in the center and the hitting distance when hitting at a position 20 mm away from the center is the smallest in the start head 1 of the present invention, It can be seen that the difference in distance between the toe side and the heel side is small.

FIG. 6 shows experimental results for confirming what happens when the thicknesses of the thick portion 2a of the face shell 2 are different. The thickness of the thick portion of the starting heads A to D is 10 mm. It is set to -4 mm. As the comparison head A, the same one as the comparison head A in the above-described experiment was used. Fig. 6 is an experimental result carried out in the same manner as the experiment of the coefficient of repulsion described above, and as apparent from the results shown in the figure, as the thickness of the thick portion decreases, the maximum intersection of the coefficient of repulsion becomes slightly larger, When compared with the result of comparison head A, no significant difference is found.

Therefore, experiments were conducted using the start heads A to D and the comparison head A to measure the distance of the golf ball. This swings at a head speed of 40 meters per second by the robot flying distance measuring device as in the above-described experiment, and measures the flying distance of the golf ball at this time five times and shows the average value in FIG. 7. As apparent from the results shown in the drawing, the maximum intersection of the flying distance when hitting at the center and the hitting distance when hitting at a position 20 mm away from the center is 7 to 9 m in the starting heads A to D. Compared with the comparison head A, a large difference of 14 m was found.

As shown in the above results, in the present invention, since the warp amount of each part of the striking surface can be adjusted by the shape and the material of the longitudinal thick portion 2a formed on the back surface of the face shell 2, various other Embodiments can be constructed. That is, FIG. 8 shows a second embodiment, and as shown in the figure, the thick portion 2a formed on the rear surface of the face shell 2 is formed in two divided states in the longitudinal direction. Compared with the first embodiment, the rigidity of the center portion is made low to facilitate bending.

In the third embodiment shown in FIG. 9, the thick portion 2a is formed over the crown outer shell 3 and the sole outer shell 4, and as opposed to the second embodiment, the rigidity of the central portion is increased, making it difficult to bend. The fourth embodiment shown in FIG. 10 is a modification of the third embodiment, and has a thickened portion 2a having a thinner central portion, which can lower the rigidity of the central portion as compared with the third embodiment. The fifth embodiment shown in FIG. 11 is also a modification of the third embodiment, and the stiffness of the center portion is made low by breaking the continuation of the thick portion 2a in the middle.

Next, with reference to FIG. 12, the area which provides the thick part of this invention is demonstrated concretely.

In the figure, C1 shows the centerline of the face shell 2 and C2 shows the centerline in the longitudinal direction of the face shell 2. L is the horizontal length of the face shell.

In the present invention, the thick portion is preferably within the range of 50% of the horizontal length L of the face shell 2 from the center line C1 with the center line C1 in the horizontal direction of the face shell 2 as the symmetry axis. (2a) is formed. That is, when the range in which the thick portion 2a is provided is set to L _B , the expression L _B ≦ 0.5 × L is satisfied.

In addition, although the thick part of 1st Example is shown as a thick part in FIG. 12, it cannot be overemphasized that it can be set as the thick part of 2nd-5th Example mentioned above.

In addition, as long as it forms within 50% of the horizontal length of the face shell 2 in the symmetry of the center line C1, it is a thick part extended in the soul-crown direction as shown in FIG. It can also be set as the thick part inclined with respect to C1).

Next, the thickness regulation of this invention is demonstrated concretely.

In the present invention, when the face shell 2 is composed of a thick portion 2a, a toe side thin portion sandwiching it from both sides in the horizontal direction, and a heel side thin portion, the thickness of each of these portions is preferably expressed by the following equation. To be satisfied.

0.2t _B ≤t _A ≤0.8t _B

0.2t _B ≤t _C ≤0.8t _B

Here, t _B is the thickness of the thick portion 2a, that is, the maximum thickness of the face shell 2, t _A is the thickness of the heel side thin portion, and t _C is the thickness of the toe side thin portion.

On the other hand, although the thick part 2a can be raised at an angle of 90 degrees to the heel side and the toe side thin part, it is preferable that each surface (upper surface) is connected smoothly. On the other hand, Preferably the heel side and toe side thin parts other than a thick part are made into uniform thickness.

As described above, according to the present invention, the degree of freedom of formation of the thick portion 2a is high, and the rigidity of the center portion, the toe side, and the heel side can be easily set in the form of the thick portion 2a. In addition, since the thick portion 2a is formed in the longitudinal direction of the center of the back face outer surface, even when the toe or heel side is out of the center portion, even when the toe or heel side becomes a hitting point, there is no significant difference in repulsion rate and flying distance and stable hitting performance. Is obtained.

According to the present invention, the difference between the flying distance due to hitting the center portion and the flying distance due to hitting the toe side and the heel side can be made as small as possible while improving the rigidity of the center portion of the face shell. It can improve performance.

Claims (9)

In the golf club head configured to be hollow by a metal shell structure, A golf club head, comprising: a thick portion formed in the longitudinal direction at approximately the center of the face outer surface rear surface serving as the striking surface. The golf club according to claim 1, wherein the thick portion is formed over the crown outer shell and the soul outer shell. The golf head according to claim 1 or 2, wherein the thickness of the face shells other than the thick portion is 2.5 mm or less. The golf head according to claim 1 or 2, wherein the loft angle is 15 degrees or less. The golf club head according to claim 1 or 2, wherein a thick portion on the rear face of the face is formed by welding. The golf club head according to claim 1 or 2, wherein the thick portion on the back face face is integrally formed by forging or casting. The golf club head according to claim 1 or 2, wherein a material of the thick portion is different from that of the face shell. In the golf club head configured to be hollow by a metal shell structure, Including a face shell which becomes the hitting surface, The face outer shell is provided with a thick portion formed in the longitudinal direction at approximately the center of the horizontal direction of the back surface, And the thick portion is formed within 50% of the transverse length of the face shell in a lateral centerline symmetry of the face shell.  The golf club head according to claim 8, wherein the face outer shell further includes a toe side thin portion and a heel side thin portion formed by sandwiching the thick portion, and satisfy the following expression. _{O.2t B ≤t A ≤0.8t B ··· (} 1) 0.2t _B ≤t _C ≤0.8t _B (2) Here, t _B is the maximum thickness of the thick portion, t _A is the thickness of the toe side thin portion, t _C is the thickness of the heel side thin portion.

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