JP6725909B2 - Production method - Google Patents

Description

The present invention relates to golf club heads.

Various structures have been proposed to improve the performance of golf club heads. For example, Patent Document 1 discloses a golf club head in which a skeleton is provided inside a hollow golf club head to improve the degree of freedom in designing the center of gravity and the like. Further, for example, Patent Literatures 2 to 4 disclose golf club heads having a structure for reinforcing the central portion of the face portion. Patent Documents 5 and 6 disclose golf club heads that include replacement parts and that allow a user to select desired characteristics. Patent Documents 5 and 6 disclose, as replacement parts, replacement parts that promote damping of vibration of the face portion upon impact. Patent Document 7 discloses a golf club head having a structure for reinforcing the central portion of the face portion.

US Pat. No. 6,558,271 U.S. Pat. No. 7,140,977 U.S. Pat. No. 8,602,912 Japanese Patent No. 5438124 Japanese Patent No. 4608437 Japanese Patent No. 4608426 Special table 2012-525214 gazette

In a hollow golf club head represented by a driver head, the spring effect of the face portion affects the flight distance performance. On the other hand, R&A and USGA regulate the spring effect of the face portion of the driver head to a CT value of 257 μs or less (a coefficient of restitution of 0.83 or less). A golf club head having a spring effect close to such a regulation value is advantageous in terms of flight distance performance, but a manufacturing error occurs in manufacturing the golf club head. Therefore, if you design the golf club head so that the spring effect is as close to the regulation value as possible,
Individuals that exceed regulatory limits may be produced. If the design is performed with a margin with respect to the regulation value, there is a case where an individual having far lower than the regulation value and having poor flight performance is manufactured.

An object of the present invention is to reduce individual differences in spring effect.

According to the present invention, a measuring step of measuring a spring effect of a face portion of a hollow golf club head, and a plurality of adjusting devices are attached to the attaching portion of the golf club head based on the measurement result of the measuring step. A selecting step of selecting an adjusting device, wherein the CT value of the face portion is 257 μs or more in a state where the adjusting device is not attached to the attachment portion, and the plurality of adjusting devices are the degree of suppression of the spring effect varies from each other, the mounting portion, the provided on the sole portion of the golf club head, said plurality of adjusting devices, and the abutting member abuts on a rear surface of the face portion, the abutting member The contact member is attached to the mounting portion via the support member, and the plurality of support members support the contact member. Is a member whose directions are different from each other .

According to the present invention, individual differences in spring effect can be reduced.

FIG. 1A is a perspective view of a golf club head according to an embodiment of the present invention, and FIG. 1B is a view of the golf club head of FIG. FIG. 1A is a cross-sectional view taken along the line I-I of FIG. 1A, and FIGS. 3 is a flowchart of a manufacturing method according to an embodiment of the present invention. (A)-(C) is explanatory drawing of another example. (A) And (B) is explanatory drawing of another example. (A)-(C) is explanatory drawing of another example.

<First Embodiment>
FIG. 1(A) is a perspective view of a golf club head 1 according to an embodiment of the present invention, and FIG. 1(B) is a view of the golf club head 1 viewed from the sole portion 13 side. The golf club head 1 includes a head body 10 and an adjusting device 18.

The head body 10 is a hollow body, and its peripheral wall constitutes a face portion 11, a crown portion 12, a sole portion 13, and a side portion 14. The surface (front surface) of the face portion 11 forms a face surface (striking surface). Bulges and rolls can be formed on the face surface. The crown portion 12 forms the upper portion of the golf club head 1. The sole portion 13 forms the bottom portion of the golf club head 1. The side portion 14 forms a portion between the sole portion 13 and the crown portion 12. The head body 10 also includes a hosel portion 15 to which a shaft is attached.

An arrow d1 in FIG. 1A indicates the face-back direction, and an arrow d2 indicates the toe-heel direction. The face-back direction is usually the flight line direction (the target direction of the hit ball). The toe-heel direction is a direction connecting the toe side end and the heel side end of the sole portion 13. The vertical direction of the face portion 11 is based on the case where the golf club head 1 is in contact with the ground according to the specified lie angle. In the case of this embodiment, the direction is from the sole portion 13 to the crown portion 12.

The golf club head 1 is a golf club head for a driver. However, the present invention is applicable to other types of hollow golf club heads such as wood type golf club heads including fairway woods other than drivers.

The head body 10 can be made of a metal material, and examples of such a metal material include a titanium-based metal (for example, a titanium alloy of 6Al-4V-Ti), stainless steel, and a copper alloy such as beryllium copper. ..

The head body 10 can be assembled by joining a plurality of parts. For example, it can be composed of a body member and a face member. The main body member constitutes the peripheral portion of the crown portion 12, the sole portion 13, the side portion 14, and the face portion 11, and an opening is formed in a part of the portion corresponding to the face portion 11. The face member is joined to the opening of the main body member.

The head body 10 includes a mounting portion 16. In the case of the present embodiment, the mounting portion 16 is arranged on the sole portion 13. Specifically, the sole portion 13 includes a recessed portion 13a that is recessed from the surroundings, and the mounting portion 16 is formed on the wall portion of the recessed portion 13a and is located inside the head body 10. Further, the mounting portion 16 is located at the center of the sole portion 13 in the d2 direction, and is arranged at a position deviated to the face portion 11 side in the d1 direction.

In the case of this embodiment, the mounting portion 16 is a screw hole. The attachment portion 16 is formed so that its center line d3 intersects with the face portion 11. An adjusting device 18 can be attached to the attachment portion 16. Although the mounting portion 16 is located inside the head body 10, the provision of the recess 13a makes the mounting of the adjusting device 18 relatively easy.

In the case of the present embodiment, the adjusting device 18 constitutes a contact member that contacts the back surface of the face portion 11. Specifically, in the case of the present embodiment, the adjusting device 18 is a member that integrally includes the screw shaft 18a, the head portion 18b, and the tip portion 18c that faces the back surface of the face portion 11. The head portion 18b is formed with a bottomed hole that engages with a tool such as a hexagon wrench. The screw shaft 18a has a shaft diameter and a screw pitch with which the mounting portion 16 is screwed. The tip portion 18c constitutes a contact portion that contacts the back surface of the face portion 11 (the surface of the head body 10 on the inner space side). FIG. 2A is a cross-sectional view taken along the line I-I of FIG. 1A and shows a manner of contact of the tip portion 18 c with the back surface of the face portion 11.

When the tip portion 18c comes into contact with the face portion 11, the deformation of the face portion 11 is restrained more than when the tip portion 18c does not come into contact with the face portion 11. That is, the spring effect when the face portion 11 is hit is suppressed. The tip portion 18c may be in contact with the back surface of the face portion 11 in a natural state so as not to be pressed, or may be in contact with the face surface side so as to be pressed.

The manner of contact of the tip portion 18c with the face portion 11 affects the degree of restraint of deformation of the face portion 11. For example, the wider the contact area of the tip portion 18c with the back surface of the face portion 11, the higher the degree of restraint of the face portion 11. Therefore, the spring effect of the face portion 11 is adjusted by preparing a plurality of adjusting devices 18 having different degrees of suppression of the spring effect of the face portion 11 and selecting the adjusting device 18 according to the individual body of the head body 10. In addition, individual differences can be reduced.

2(B) to 2(F) exemplify five types of adjusting devices 18 that can be attached to the attaching portion 16. Each of the adjusting devices 18 shown in FIGS. 2B to 2F has a common overall length, and the screw shaft 18a and the head portion 18b have the same configuration, but the tip portions 18c have different shapes.

In each of the adjusting devices 18 of FIGS. 2B to 2D, the tip portion 18c has a tapered shape, but the areas of the tip surfaces are different from each other. The example has the largest area of the tip surface, and the example of FIG. 2D has the smallest area of the tip surface. The shape of the front end surface in FIGS. 2B to 2D is circular. The tip portion 18c of the adjusting device 18 of FIG. 2(E) is spherical. The tip portion 18c of the adjusting device 18 of FIG. 2(F) has a columnar shape, and the tip surface has the largest area among the adjusting devices 18 of FIGS. 2(B) to 2(F). Assuming that the contact area of the tip portion 18c with the back surface of the face portion 11 is the same as the area of the tip surface of the adjusting device 18, the degree of constraint of deformation of the face portion 11 is the adjusting device 18 of FIG. Is the highest.

Here, R&A and USGA regulate the spring effect of the face portion of the driver head to a CT value of 257 μs or less (a coefficient of restitution of 0.83 or less). A golf club head having a spring effect close to such a regulation value is advantageous in terms of flight distance performance, but a manufacturing error occurs in manufacturing the golf club head. Therefore, by selecting the type of the adjusting device 18, it is possible to absorb the manufacturing error and bring it closer to the CT value intended by the designer. FIG. 3 is a flowchart showing an example of a method for manufacturing a large number of golf club heads 1 to be shipped to the market.

In S1, the golf club head 1 is designed. If necessary, a prototype may be manufactured for verification work. In the design of the golf club head 1, the CT value of the face portion 11 of the head body 10 may be designed to be 257 μs or more, or the CT value of the head body 10 may actually be 257 μs or more. .. To manufacture a golf club head 1 having a CT value close to the regulation value by designing and manufacturing the CT value so that the CT value is close to the regulation value or exceeding the regulation value and lowering the CT value to the regulation value or less by selecting the adjusting device 18. You can

In S2, the head body 10 of the golf club head 1 designed in S1 is mass-produced. In parallel, the adjusting device 18 is also mass-produced. The components of the golf club head 1 are completed by S2.

In S3, the spring effect of the face portion 11 of the head body 10 mass-produced in S2 is measured. The head main body 10 to be measured may be a whole mass-produced product or a part of the mass-produced product. In the case of a part of mass-produced products, they are divided into groups based on the thickness of the face portion 11 and the like, and one or a plurality of head bodies 10 are subjected to measurement in group units, and are regarded as the measurement results of all mass-produced products in the group. The adjusting devices 18 may be selected in common. As a method of measuring the spring effect, for example, the CT value may be measured by a dedicated repulsion measuring device based on the pendulum test of R&G and USGA.

In S4, based on the measurement result of S3, the adjustment device 18 to be attached to the attachment portion 16 is selected from the plurality of adjustment devices 18, and attached to the attachment portion 16. As described above, the plurality of adjusting devices 18 are different from each other in the degree of suppression of the spring effect of the face portion 11, but the adjusting devices 18 that can be selected may be at least two types.

In S5, the spring effect of the face portion 11 of the golf club head 1 to which the adjusting device 18 is attached is measured again. The measuring method is the same as S3.

In S6, it is determined whether or not the remeasurement result in S5 is within the predetermined range. As the predetermined range, for example, the CT value may have an upper limit value of 257 μs and a lower limit value of 250 μs. When a measurement error is expected, for example, the CT value may have an upper limit value of 255 μs and a lower limit value of 248 μs. Further, when the adjustment device 18 is selected in units of groups as described above, the upper limit of the CT value may be set to 250 μs and the lower limit may be set to 240 μs in consideration of individual differences within the group.

When the remeasurement result is not within the predetermined range, the process returns to S4 and the adjustment device 18 is changed. For example, when the CT value exceeds the upper limit value, the adjustment device 18 having a higher degree of constraint of the face portion 11 is selected and attached. On the contrary, when the CT value is below the lower limit value, the adjusting device 18 having a lower degree of constraint of the face portion 11 is selected and attached.

If the remeasurement result is within the predetermined range, the final processing (decoration processing or the like) is performed as necessary, and the manufacturing of the golf club head 1 is completed.

As described above, in this embodiment, the individual difference in the spring effect of the face portion 11 can be reduced, and the golf club head 1 close to the regulation value of the CT value can be stably manufactured. Since the spring effect of the face portion 11 is adjusted by measuring the spring effect and selecting the adjusting device 18 based on the measurement result, the spring effect can be adjusted relatively easily.

<Second embodiment>
As a result of the measurement in S3, the CT value of the face portion 11 of the head body 10 may already be within the predetermined range. In this case, it is not necessary to attach the adjusting device 18 in terms of spring effect. However, if the adjusting device 18 is not attached, the position of the center of gravity, the weight of the head, and the like may change significantly, which may affect the performance of the golf club head 1. Therefore, the adjusting device 18 that does not affect the spring effect can be included in the plurality of adjusting devices 18 that can be selected in S4.

4A and 4B show an example thereof. In the adjusting device 18 of the figure, the tip portion 18c is configured to be short, and as shown in FIG. 4A, the tip portion 18c is separated from the back surface of the face portion 11 in a natural state. Therefore, the deformation of the face portion 11 is not restrained at the time of hitting, or the tip portion 18c only slightly contacts the face portion 11, and the spring effect of the face portion 11 is hardly affected. On the other hand, the screw shaft 18a and the head portion 18b are the same as those of the other adjusting device 18, and it is possible to avoid a case where the position of the center of gravity of the golf club head 1, the head weight and the like are greatly different.

<Third embodiment>
In the first embodiment, the adjusting device 18 is configured to integrally include the screw shaft 18a, the head portion 18b, and the tip portion 18c, but the tip portion 18c may be selectable. FIG. 4C shows an example thereof. In the example of the figure, an engaging portion 18e is formed on the tip surface of the screw shaft 18a, and the tip portion 18c is provided with an engaging portion 18d that engages with the engaging portion 18e. In the example of the figure, the engaging portion 18e is a bottomed hole, and the engaging portion 18d is a shaft inserted into this hole. The engaging portion 18e and the engaging portion 18d may be fitted to each other, or may be joined by an adhesive or the like.

<Fourth Embodiment>
In the first embodiment, the plurality of adjusting devices 18 have different tip portions 18c from each other in shape, but at least a part of the materials of the adjusting device 18 may be different from each other. Due to the different materials, the deformation of the adjustment device 18 with respect to the deformation of the face portion 11 at the time of impact also differs, and the degree of suppression of the spring effect of the face portion 11 can be made different. In this case, the plurality of adjusting devices 18 may all have different shapes of the tip end portions 18c, may have the same shape, or may have the same shape and different shapes.

Examples of the material include metals such as stainless steel and aluminum, as well as resins and rubbers. When the material has high rigidity, the degree of suppression of the spring effect is relatively high, and when the material has low rigidity, the degree of suppression of the spring effect is relatively low.

Between each conditioning device 18, the parts of different material may be wholly or partly. In the case where it is a part, for example, the tip portion 18c may be selectable as in the third embodiment, and the plurality of tip portions 18c may be made of different materials.

<Fifth Embodiment>
In the first embodiment, the plurality of adjusting devices 18 have different tip portions 18c from each other in shape, but the positions of contacting the back surface of the face portion 11 may be different from each other. 5A and 5B show an example thereof. FIG. 5(A) shows an exploded view, and FIG. 5(B) shows an assembly drawing.

The adjusting device 18 of the present embodiment includes a contact member 181 and a support member 182. The contact member 181 has a configuration similar to that of the adjusting device 18 of the first embodiment, and is a member integrally provided with a screw shaft 181a, a head 181b, and a tip portion 181c facing the back surface of the face portion 11. .. The contact member 181 is attached to the mounting portion 16 via the support member 182, and the tip portion 18c constitutes a contact portion that contacts the back surface of the face portion 11.

The support member 182 is an angle adjustment member that adjusts the orientation of the contact member 181. The support member 182 has a screw hole 182a into which the screw shaft 18a is screwed. The fixing structure of the support member 182 to the mounting portion 16 may be a screw structure, a press-fitting fitting, or an adhesive bonding.

The contact position of the tip portion 181c with respect to the face portion 11 affects the degree of restraint of deformation of the face portion 11. For example, when the contact position of the tip portion 181c is the central portion of the face portion 11, the degree of restraint of the entire face portion 11 increases. On the other hand, when the abutting position of the tip portion 181c is the peripheral portion of the face portion 11, the degree of restraint of the entire face portion 11 is lower than that in the central portion. Therefore, a plurality of support members 182 that support the contact member 181 so that the positions of the back surfaces of the face portions 11 with which the contact member 181 abut are different from each other are prepared, and the support member 182 according to the individual head body 10 is prepared. By selecting, the spring effect of the face portion 11 can be adjusted and individual differences can be reduced. Although it is possible to prepare the contact member 181 for each support member 182, this embodiment exemplifies a configuration in which the contact member 181 can be commonly used for each support member 182.

6A to 6C exemplify three kinds of adjusting devices 18 (particularly, the supporting member 182) which can be attached to the attaching portion 16. The supporting members 182 of the examples of FIGS. 5A and 5B and the examples of FIGS. 6B to 6C are in contact with each other because their outer shapes or the directions of the screw holes 182a are different from each other. The position of the back surface of the face portion 11 with which the member 181 abuts is different.

The support member 182 of FIG. 6A is configured such that the contact position of the contact member 181 is located closer to the sole portion 13 side than in the example of FIGS. 5A and 5B. The support member 182 of FIG. 6B is configured such that the contact position of the contact member 181 is located further toward the sole portion 13 side than in the example of FIG. 6A. In the example of FIG. 5B, the example of FIG. 6A, and the example of FIG. 6B, the degree of constraint of deformation of the face portion 11 is highest in the example of FIG. The example of 6(B) is the lowest.

The example of FIG. 6C is an example of the adjusting device 18 that does not affect the spring effect, and its purpose is the same as that of the second embodiment. In the case of the present embodiment, by making the thickness of the support member 182 thicker, the tip portion 181c is separated from the back surface of the face portion 11 in the natural state. Therefore, the deformation of the face portion 11 is not restrained at the time of hitting, or the tip portion 18c only slightly contacts the face portion 11, and the spring effect of the face portion 11 is hardly affected. On the other hand, it is possible to avoid a case where the position of the center of gravity of the golf club head 1, the head weight, and the like are greatly different.

In the case of this embodiment, since the contact member 181 is common to each support member 182, in S4 of FIG. 3, the support member 182 may be selected from the plurality of support members 182 based on the measurement result of S3. Become.

Note that it is also possible to apply the configuration example of the adjusting device 18 of the first embodiment to the third embodiment to the contact member 181 of the present embodiment.

<Sixth embodiment>
In the first to fifth embodiments, the attachment portion of the adjusting device 18 is the sole portion 13, but it may be the crown portion 12 or the side portion 14. Further, although the adjusting device 18 and the mounting portion 16 are provided as one, a plurality of sets may be provided. When a plurality of sets of adjusting devices 18 and mounting portions 16 are provided, the structures of all the sets may be the same, or there may be sets having different structures (for example, the set of the first embodiment and the set of the fifth embodiment are mixed). May be.

10 golf club head 11 face part 16 mounting part 18 adjusting device

Claims (2)

A measuring step for measuring the spring effect of the face portion of the hollow golf club head,
A selection step of selecting an adjustment device to be attached to the attachment portion of the golf club head from among a plurality of adjustment devices based on the measurement result of the measurement step,
A CT value of the face portion is 257 μs or more in a state where the adjustment device is not attached to the attachment portion,
Wherein the plurality of adjusting devices, unlike degree of suppression of the spring effect of the face portion to each other,
The mounting portion is provided on the sole portion of the golf club head,
The plurality of adjustment devices are configured by a combination of a contact member that contacts the back surface of the face portion and one of a plurality of support members that support the contact member,
The abutment member is attached to the attachment portion via the support member,
The plurality of support members are members in which the directions of the contact members to be supported are different from each other,
A manufacturing method characterized by the above. The manufacturing method according to claim 1 , wherein
The contact member has a screw shaft, and the plurality of support members have screw holes that are screwed into the screw shaft,
The plurality of support members are members in which the directions of the contact members to be supported are different from each other due to the different outer shapes or the directions of the screw holes.
A manufacturing method characterized by the above.

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