The present invention relates to a golf club head and a manufacturing method for the same.
The heads of wood golf clubs have conventionally undergone many improvements, and in particular, various proposals have been made for a reduction in the weight of the crown portion. For example, with the golf club head disclosed in Patent Literature 1, the weight of the crown portion is reduced by forming multiple regions having a small thickness in the crown portion.
Patent Literature 1: JP 2005-312942A
However, reducing the thickness of the crown portion has the problem of a reduction in the durability of the golf club head. Specifically, the crown portion is subjected to high impact when a ball is hit with a club, and damage such as cracking can possibly occur if the thickness of the crown portion is reduced. Also, there is the problem that it is difficult to maintain durability while reducing the weight of the crown portion, as well as effectively increase the horizontal moment of inertia (moment of inertia about a vertical axis that passes through the center of gravity of the golf club head) without increasing the weight of the golf club head. The present invention has been achieved in order to solve the above-described problems, and an object thereof is to provide a golf club head that enables increasing the moment of inertia while also improving durability, and a manufacturing method for the same.
A golf club head according to the present invention is a golf club head including a crown portion, wherein the crown portion has a first region having a first thickness and a plurality of second regions having a second thickness that is smaller than the first thickness, the plurality of second regions are distributed in a radiating fashion so as to extend from an origin toward a peripheral portion of the crown portion excluding a face side, the origin being located within 15 mm of the center of gravity of the golf club head in a toe-heel direction and also being located in the vicinity of the face side in a face-back direction in a plan view, a portion of the first region arranged between adjacent second regions is configured such that the width of the first region portion increases as the first region portion extends from the origin side to the peripheral portion side, the peripheral portion of the crown portion is configured by the first region, and edges of the second regions on the peripheral portion side are connected to the peripheral portion configured by the first region.
In the above golf club head, a transition portion in which the thickness changes between the first thickness and the second thickness may be provided between the first region and the second regions, and the width of the transition portion may be in a range of 0.5 to 10 mm.
In any of the above golf club heads, the width of the first region portion arranged between adjacent second regions may be in a range of 1 to 8 mm in an end portion on the origin side, and be in a range of 5 to 20 mm in an end portion on the peripheral portion side.
In any of the above golf club heads, the crown portion may be formed from a titanium alloy, and the first thickness may be in a range of 0.5 to 0.8 mm, and the second thickness may be in a range of 0.2 to 0.6 mm.
In any of the above golf club heads, the crown portion may be formed from stainless steel or maraging steel, and the first thickness may be in a range of 0.8 to 1.5 mm, and the second thickness may be in a range of 0.5 to 1.3 mm.
In any of the above golf club heads, the second regions may be configured such that the width of each second region increases as the second region extends from the origin side to the peripheral portion side.
A manufacturing method for a golf club head according to the present invention includes: a step of preparing a mold for a golf club head that has a crown portion, the crown portion having a first region having a first thickness and a plurality of second regions having a second thickness that is smaller than the first thickness, the plurality of second regions being distributed in a radiating fashion so as to extend from an origin toward a peripheral portion of the crown portion excluding a face side, the origin being located within 15 mm of the center of gravity of the golf club head in a toe-heel direction and also being located in the vicinity of the face side in a face-back direction in a plan view, a portion of the first region arranged between adjacent second regions being configured such that the width of the first region portion increases as the first region portion extends from the origin side to the peripheral portion side, the peripheral portion of the crown portion being configured by the first region, and edges of the second regions on the peripheral portion side being connected to the peripheral portion configured by the first region; and a step of injecting molten metal through at least one gate provided in the mold, the gate being provided at a position that corresponds to the first region in the peripheral portion of the crown portion.
The present invention enables increasing the moment of inertia while also improving durability.
An embodiment of a golf club head according to the present invention will be described below with reference to the drawings.
As shown in
The face portion 1 has a face surface, which is the surface for hitting a ball, and the crown portion 2 is adjacent to the face portion 1 and constitutes the upper surface of the head. The sole portion 3 constitutes the bottom surface of the head, and is adjacent to the face portion 1 and the side portion 4. Also, the side portion 4 is the portion between the crown portion 2 and the sole portion 3, and extends from the toe side of the face portion 1, across the back side of the head, to the heel side of the face portion 1. Furthermore, the hosel portion 5 is the portion provided adjacent to the heel side of the crown portion 2, and has an insertion hole 51 for the insertion of the shaft (not shown) of the golf club. A central axis Z of the insertion hole 51 conforms to the axis of the shaft. Although the head described here is a wood head such as a driver (#1) or fairway wood head, it is not limited to being a wood head, and may be a so-called utility head, hybrid head, or the like.
The following describes the aforementioned reference state. First, as shown in
In the present embodiment, the boundary between the crown portion 2 and the side portion 4 can be defined as follows. Specifically, if a ridge line is formed between the crown portion 2 and the side portion 4, that ridge line serves as the boundary. On the other hand, if a clear ridge line is not formed, the boundary is the outline that is seen when the head is placed in the reference state and viewed from directly above the center of gravity of the head. Similarly, in the case of the boundary between the crown portion 2 and the face portion 1 as well, if a ridge line is formed, that ridge line serves as the boundary. However, if a clear ridge line is not formed, the periphery (boundary) of the face portion 1 is defined by positions Pe where, in cross-sections E1, E2, E3, and so on that include a straight line N connecting a head center of gravity G and a sweet spot SS as shown in
The volume of this golf club head is, for example, preferably 300 cm3 or more, more preferably 400 cm3 or more, and particularly preferably 420 cm3 or more. Having such a volume is advantageous for the head in terms of increasing comfort when the club is held and also increasing the sweet spot area and the moment of inertia. Note that although an upper limit is not particularly defined for the head volume, practically it is, for example, desirably 500 cm3 or less, or desirably 470 cm3 or less when complying with R&A or USGA rules and regulations.
Also, the head can be formed from a titanium alloy having a specific gravity of approximately 4.4 to 4.5 (Ti-6Al-4V), for example. Besides a titanium alloy, the head can be formed from one or two or more materials selected from among stainless steel, maraging steel, an aluminum alloy, a magnesium alloy, an amorphous alloy, and the like.
Note that the head of the present embodiment is constituted by combining a head body that has at least the crown portion 2 with another portion. For example, a configuration is possible in which only the face portion 1 is constituted by another member, and the head is constituted by attaching the face portion 1 to the head body, and it is also possible to form a head body in which an opening is provided in the sole portion 3 and the side portion 4, and to block the opening with another member.
Next, the crown portion 2 will be described with reference to
Note that as shown in
Due to providing the second regions 22 having a small thickness in the crown portion 2 as described above, the amount of weight that corresponds to the reduction in thickness compared to the first region 21 can be distributed to the side portion 4, for example. This enables increasing the moment of inertia of the head. This point will be described with reference to
The thickness of the regions 21 and 22 can be defined as follows. Specifically, in consideration of strength and rigidity, in the case where the head body is formed from a titanium alloy, a thickness D1 (first thickness) of the first region 21 can be set to 0.5 to 0.8 mm, and a thickness D2 (second thickness) of the second regions 22 can be set to 0.2 to 0.6 mm, for example, but the thicknesses differ according to the material that is used. Also, in the case where the head body is formed from stainless steel or maraging steel, the thickness D1 of the first region 21 can be set to 0.8 to 1.5 mm, and the thickness D2 of the second regions 22 can be set to 0.5 to 1.3 mm.
Reference sign S1 denotes the projected area of all of the second regions 22 in the plan view of the head shown in
Also, as shown in
Also, the peripheral portion 23 of the crown portion 2 is constituted by the first region 21. Accordingly, the edge of each of the second regions 22 on the peripheral portion 23 side is not directly connected to the side portion 4, but rather is separated from the side portion 4 by portions of the large-thickness first region 21. The width X of these portions of the first region 21 can be set to 1 to 30 mm, for example. If this width X is less than 1 mm, there is the risk of diminishing the effect of increasing the moment of inertia. Accordingly, this width X is more preferably 3 mm or more, and particularly preferably 5 mm or more. On the other hand, if this width X is greater than 30 mm, there is the risk of impairing the reduction of the weight of the crown portion 2. Accordingly, the width X is more preferably 20 mm or less, and particularly preferably 10 mm or less.
As shown in
The following describes an example of a method of manufacturing a golf club head configured as described above. The golf club head of the present embodiment is a hollow structure, and therefore can be manufactured by joining two or more members. Specifically, it can be manufactured by joining a head body, in which one or two or more openings in communication with the internal space are formed, with another member for blocking the opening. As described above, the head body includes at least the crown portion 2, and it can be manufactured by casting using a known lost-wax precision casting method, for example. This point will be described with reference to FIG. 8.
As shown in
When molten metal made of the above-described metal material is injected into the above-described mold through the first to third gates 101 to 103, the molten metal flows in the crown portion 2 in the following manner. First, since the first and second gates 101 and 102 oppose the peripheral portion 23 of the crown portion 2, that is to say, oppose the first region having a large thickness, molten metal easily flows through them. After flowing through the first and second gates 101 and 102, the molten metal flows along the peripheral portion 23 toward the hosel portion 5 side, while also heading toward the origin S side as it flows through the first region portion 21 on the toe side and the first region portions 21 arranged between adjacent second regions 22. As the first region portions 21 extend to the origin S side, their width decreases, and therefore pressure acting on the molten metal increases. For this reason, in order to release this pressure, the molten metal flows out of the first region portions 21 into the adjacent second regions 22. Specifically, this molten metal is gradually pushed from the first region portions 21 to the adjacent second regions 22 from the origin S side of the first region portions 21 toward the peripheral portion 23 of the crown portion 2. Also, the molten metal injected through the third gate 103 also similarly flows along the peripheral portion 23 toward the toe side, while also flowing into the first region 21 toward the face side. As the pressure rises, the molten metal flows from the face side of the first region 21 to the second regions 22. In this way, molten metal can be caused to sufficiently reach the small-thickness second regions 22 as well.
The above embodiment can obtain the following effects.
(1) In the crown portion 2, large-thickness first region portions 21 are arranged between adjacent small-thickness second regions 22, thus making it possible to suppress a reduction in mechanical strength caused by the reduction in thickness. Also, by adjusting the number of and positions of the second regions 22, a large-thickness first region portion 21 can be arranged in the central portion of the crown portion 2 that is subjected to high impact, which also has the advantage of making it possible to ensure strength for the head. Furthermore, since the first region portions 21 are distributed in a radiating fashion so as to extend from an origin on the face side toward the back side, impact force from hitting a ball can be allowed to escape in a radiating fashion toward the peripheral portion 23 of the crown portion 2, and this also makes it possible to suppress a reduction in mechanical strength.
(2) The first region portions 21 arranged between adjacent second regions 22 are configured such as to increase in width as they extend from the origin S side to the peripheral portion 23 side, thus making it possible to cause the weight distribution of the reduced-weight crown portion 2 to increase toward the peripheral portion 23. This enables increasing the moment of inertia about the vertical axis passing through the center of gravity of the head, thus making it possible to improve directionality when hitting a ball.
(3) Since multiple second regions 22 having a small thickness are provided in the crown portion 2, the weight of the crown portion 2 can be reduced. Also, the amount of weight corresponding to the reduction in thickness for weight reduction can be distributed to other portions of the head as described above. This enables improving the degree of freedom in head design. For example, if the above-described weight is distributed to the sole portion 3 of the club head, the center of gravity can be lowered, consequently making it possible to raise the launch angle. Alternatively, if the weight is distributed to the side portion 4, the moment of inertia about the vertical axis passing through the center of gravity of the head can be increased, thus making it possible to improve directionality when hitting a ball.
(4) When using casting to manufacture a head body that includes the above-described crown portion, the peripheral portion 23 of the crown portion 2 is constituted by the first region 21 that has a large thickness, thus making it easier for molten metal to be poured through these portions. Also, the molten metal flowing through the peripheral portion 23 flows around the crown portion 2 while also flowing through the large-thickness first region 21 toward the origin S side. The pressure acting on the molten metal flowing through the first region 21 increases as it approaches the face side, and therefore the molten metal flows into adjacent second regions 22 in order to release this pressure. Accordingly, molten metal can be caused to sufficiently reach the small-thickness second regions 22 as well, thus making it possible to prevent molding defects.
Although an embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be carried out without departing from the gist of the invention. The following are examples of modifications.
Although the second regions 22 are fan-shaped in the above embodiment, they do not need to be strictly fan-shaped, and they need only be shaped such that the width increases as they extend from the origin S side toward the peripheral portion 23 side. For example, the second regions 22 may be shaped so as to be curved overall due to the radial portions of the fan shape being formed by curved lines rather than straight lines. Accordingly, the first region portions 21 arranged between adjacent second regions 22 may also be shaped so as to extend in a curved manner from the origin S side toward the peripheral portion 23 side, for example. Also, the end portions of the second regions 22 on the face side do not need to have a sharp shape, and they can be formed so as to be arc-shaped or the like. Also, the width of the second regions 22 does not necessarily need to change, and as long as at least the width W of the first region portions 21 between adjacent second regions 22 increases toward the peripheral portion 23 side, the second regions 22 may have a constant width as they extend from the origin S side toward the peripheral portion 23 side. Also, there is no particular limit on the number of second regions 22.
Although the mold is provided with three gates in the above embodiment, there is no limitation to this. Specifically, it is sufficient that at least one of the gates is provided at a position that opposes the peripheral portion 23 of the crown portion 2 so as to enable molten metal to be poured into the peripheral portion 23 of the crown portion 2.
Although the head of the above embodiment is constituted by combining a head body that has at least the crown portion 2 with another portion, the present invention is also applicable to a head in which only the crown portion 2 is formed by a separate member. For example, in the case of constituting the head such that the head body includes a face portion, a side portion, a sole portion, and an opening for the crown portion, and fitting the crown portion into the opening, the above-described first and second regions can be formed in the crown portion.
The following describes working examples of the present invention. Note that the present invention is not limited to the following working examples.
Golf club heads according to eight types of working examples having various modes of crown portions and according to five types of comparative examples were created. These golf club heads were manufactured by constituting the face portion by a separate member and joining it to the head body. The face portion was formed by performing press processing on “Super TI-X51AF” (manufactured by Kobe Steel, Ltd.), which is a rolled material. The head body was then formed by performing lost-wax precision casting using molten metal made of a titanium alloy (Ti-8Al-2V). Working Examples 1 to 8 and Comparative Examples 1 to 5 were created in the modes indicated in Table 1 below. Note that in all of the working examples and the comparative examples, the head weight was 195 g and the head volume was 460 cc. Accordingly, in the case providing small-thickness second regions in the crown portion, the overall weight of the head is kept the same due to the amount of weight corresponding to the reduction in thickness being distributed to the side portion as shown in
Working Examples 1 to 8 and Comparative Examples 1 to 5 have the following characteristics. In the figures used in the following descriptions, the second regions are enclosed in dashed lines. Also, the transition portions are sometimes omitted.
As shown in
The crown portion of Working Example 2 is the same as that of Working Example 1 with the exception that, as shown in
The crown portion of Working Example 3 is the same as that of Working Example 1 with the exception that, as shown in
The crown portion of Working Example 4 is the same as that in Working Example 1 with the exception that the width of the transition portions is smaller than in Working Example 1.
The crown portion of Working Example 5 is the same as that in Working Example 1 with the exception that the width of the transition portions is larger than in Working Example 1.
The crown portion of Working Example 6 is the same as that in Working Example 5 with the exception that the width of the transition portions is larger than in Working Example 5.
The crown portion of Working Example 7 is the same as that in Working Example 1 with the exception that the transition portion is not provided.
The crown portion of Working Example 8 is the same as that in Working Example 6 with the exception that the width of the transition portions is larger than in Working Example 6.
As shown in
As shown in
The crown portion of Comparative Example 3 is the same as that in Working Example 1 with the exception of not having the peripheral portion. Specifically, as shown in
The crown portion of Comparative Example 4 is the same as that in Working Example 1 with the exception that the second regions are not provided, and the thickness is constant. The thickness of the crown portion is the same as that of the second regions in Working Example 1.
The crown portion of Comparative Example 5 is the same as that in Working Example 1 with the exception that the second regions are not provided, and the thickness is constant. The thickness of the crown portion is the same as that of the first region in Working Example 1.
The following points were evaluated in the above-described working examples and comparative examples.
(a) Moment of Inertia
Each head was placed in the reference state, and the moment of inertia (horizontal moment of inertia) about the vertical axis passing through the center of gravity of the head was measured. The measurement was performed using the Moment of Inertia Measuring Instrument with model number 005-002 from Inertia Dynamics, Inc. The higher the value is, the smaller the amount of head wobble during a missed shot, which is more favorable.
(b) Length of Impact Reverberation
The length of impact reverberation was subjected to sensory evaluation when ten testers perform test hits. The testers were average golfers (handicap of 15 to 25) having a head speed of 40 m/s. The same FRP shaft (MP 700 Flex R made by Dunlop Sports Co., Ltd.) was attached to the heads of the above working examples and comparative examples to create 45.5 inch wood golf clubs, and they were used to perform test hits with two-piece golf balls (DDH Tour Special made by Dunlop Sports Co., Ltd.). Ten levels were used in the evaluation, and the sensory test was performed with level 6 being assumed to be the most appropriate reverberation length, and the level value rising as the reverberation length increased.
(c) Castability
The molded head bodies were visually checked, and the head was determined to be a defective product if the molten metal did not sufficiently reach any portion. 200 head bodies were created, and the following grades were given: A if the defect percentage was 0% to 2%, B if 2% to 6%, C if 6% to 10%, D if 10% to 20%, and E if 20% or more.
(d) Durability Evaluation
Durability was evaluated using an impact robot (Shot Robo-3DX made by Miyamae Co., Ltd.). Two-piece golf balls (DDH Tour Special made by Dunlop Sports Co., Ltd.) were hit with the center of the face at a head speed of 50 m/s, and the following grades were given: A if the number of test hits performed before the head body cracked was 10,000 or more, B if 8,000 to 10,000, C if 6,000 to 8,000, D if 4,000 to 6,000, and E if less than 4,000.
The results were as follows.
The following observations were made regarding the working examples and comparative examples. First, a comparison of Working Example 1 and Comparative Examples 1 and 2, in which the area of the second regions is the same, shows that the moment of inertia is higher in Working Example 1 than in Comparative Examples 1 and 2. This is thought to be due to the fact that in Working Example 1, the large-thickness first region portions extend in a radiating fashion from the origin toward the peripheral portion, and the width of the first region portions also increases as they extend from the origin toward the peripheral portion. Also, due to this configuration, durability is more favorable in Working Example 1 than in Comparative Examples 1 and 2. In other words, this is thought to be due to the fact that the end portions of the first region portions in the crown portion can be grouped close together at positions in the vicinity of the impact point on the face, and the width of the first region portions can be increased at in the peripheral portion of the crown portion. The other working examples also had more favorable durability than Comparative Examples 1 to 4 for similar reasons or due to having a thick peripheral portion. Note that although Comparative Example 5 has favorable durability, the crown portion is formed with only thick portions, and the amount of weight corresponding to the reduction in thickness of the crown portion is not distributed to the side portions as it is in the working examples, and therefore the moment of inertia is smaller than in all of the working examples. Furthermore, since the width of the transition portions is appropriate in Working Examples 1 to 6, the evaluation of impact reverberation length is comparatively close to 6.
Also, regarding castability, the width of the first region portions arranged between second regions is constant in Comparative Examples 1 and 2, and therefore pressure does not readily act on the molten metal as it flows through these regions, and thus the molten metal does not readily flow to the second regions. It is thought that molding defects often occur for this reason. In Comparative Example 3, the first region portions having a large thickness are not formed in the peripheral portion of the crown portion, and therefore the molten metal does not readily flow to the crown portion, and it is though that molding defects often occur for this reason. In Comparative Example 4, the thickness of the crown portion is small, and therefore the molten metal does not readily flow to the crown portion, and furthermore the durability is low.
Number | Date | Country | Kind |
---|---|---|---|
2013-017516 | Jan 2013 | JP | national |
This application is a continuation of co-pending U.S. patent application Ser. No. 14/168,799 filed on Jan. 30, 2014, which claims the benefit of Japanese Patent Application No. 2013-017516 filed on Jan. 31, 2013. The entire contents of all of the above applications are hereby incorporated by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 14168799 | Jan 2014 | US |
Child | 15218746 | US |