JP5987468B2 - Golf club head - Google Patents

Description

  The present invention relates to a golf club head.

  Japanese Patent Application Laid-Open No. H10-228561 describes a technique for making a ball hitting sound higher like a metal head by using a highly elastic fiber in a part of a crown portion formed of a fiber reinforced resin in a golf club head.

JP 2004-89268 A

  By the way, the crown portion has an effect of improving the initial velocity of the ball by transmitting the force when the ball is deformed and returned to the original position through the face portion to the ball. For example, the thinner the crown portion, the greater the deformation at the time of hitting, and this effect also increases. However, if the crown portion is too thin, excessive vibration is generated and energy is consumed, and the force transmitted to the ball is reduced. Therefore, it is conceivable that only a part of the crown portion is thinned so that the force due to the deformation of the crown portion is appropriately transmitted to the ball. In the technique of Patent Document 1, a golf club head in which various areas of the crown portion are thinned has been proposed. However, this is only for improving the hitting sound, and if any area is thinned, the initial velocity of the ball is improved. This point is not considered.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to improve the initial velocity of a ball hit with a golf club head having a crown portion in which a part of the rigidity is reduced.

In order to solve the above problems, the present invention includes a face portion on the front side, the hollow golf club head having a crown portion and a sole portion behind of the face portion, the crown portion, toe the crown portion a central region Ru center near of the crown portion a central region heel direction and respectively in the longitudinal direction in the center of the nine divided regions divided into three - the front of the central area of the divided region a front region adjacent to the toe side region adjacent to the toe side of the central region of the divided region, the central region of the crown portion, the rigidity than the portion excluding the front region and the toe side region Provided is a golf club head characterized by being lowered .

Further, the present invention provides a hollow golf club head having a face portion on the front side and a crown portion and a sole portion on the rear side of the face portion. A central region at the center of the nine divided regions divided into three in the direction and in the center of the crown portion; and a front region that is the divided region adjacent to the front side of the central region; In addition, the present invention provides a golf club head characterized in that a low-rigidity portion having lower rigidity than other portions is provided .

  According to the present invention, it is possible to improve the initial velocity of a ball hit with a golf club head having a crown portion with a part of the rigidity being reduced.

It is a figure which shows the external appearance of the golf club in embodiment. It is a figure which shows the external appearance of a golf club head. It is a figure which shows the cross section of a golf club head. It is a figure which shows the inner surface of a crown part. It is a figure which shows the cross section of a crown part. It is a figure which shows the example of the external appearance of the crown part in each process. It is a figure which shows an example of the shape of the golf club head deform | transformed at the time of hitting. It is a figure which shows an example of the relationship between the thickness of a crown part, and the flight distance of a ball | bowl. It is a figure for demonstrating the difference in the initial velocity of a ball by the presence or absence of a 2nd thin part. It is a figure which shows the flight distance of a ball | bowl. It is a figure which shows the amount of hook spins of a ball | bowl. It is a figure which shows the magnitude | size of the vibration in the main sound frequency of a golf club head. It is a figure which shows the example of the crown part in a modification. It is a figure which shows the example of the crown part in a modification. It is a figure which shows the example of the crown part in a modification. It is a figure which shows the example of the shape of the rib in a modification. It is a figure which shows the example of the cross section of the crown part in a modification.

[Embodiment]
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram illustrating an appearance of a golf club 1 according to the embodiment. The golf club 1 includes a golf club head 10, a shaft 11, and a grip 12. A golf club head 10 is attached to one end of the shaft 11, and a grip 12 is attached to the other end. The golf club head 10 is made of titanium and has a face portion 20. FIG. 1A shows the golf club 1 when the face portion 20 is viewed from the front. Of the golf club head 10, the side attached to the shaft 11 is called the heel side, and the opposite side is called the toe side. A direction from the toe side toward the heel side (direction indicated by an arrow A1 in the figure) is referred to as a toe / heel direction. In FIG.1 (b), the golf club 1 seen from the toe side is shown. The side of the golf club head 10 where the face portion 20 is located is called the front side, and the opposite side is called the back side. A direction from the front side toward the rear side (direction indicated by an arrow A2 in the drawing) is referred to as a front-rear direction.

  FIG. 2 is a view showing the appearance of the golf club head 10. The golf club head 10 includes a face portion 20, a crown portion 30, a sole portion 40, and a hosel portion 50. FIG. 2 shows the golf club head 10 as seen from the front side (face portion 20 side). The face portion 20 is a portion of the golf club head 10 that collides with the ball and transmits the kinetic energy of the golf club 1 to the ball. The face unit 20 has a face surface 21. The face surface 21 is a surface exposed to the outside of the golf club head 10 in the face portion 20, and is a surface on which the colliding ball comes into contact.

  The face portion 20 is connected to the crown portion 30 on the side facing the sky when the user holds the golf club 1, and is connected to the sole portion 40 on the side facing the ground. In the golf club head 10, the side on which the crown portion 30 is located is referred to as the crown side, and the side on which the sole portion 40 is located is referred to as the sole side. A direction from the crown side toward the sole side (direction indicated by an arrow A3 in the figure) is referred to as a crown / sole direction. The hosel portion 50 is a portion of the golf club head 10 to which a shaft is attached. The crown part 30 is connected to the hosel part 50.

  FIG. 3 is a view showing a cross section of the golf club head 10. FIG. 3 shows a cross section taken along line III-III in FIG. The face portion 20, the crown portion 30, and the sole portion 40 form a hollow space B <b> 1 inside the golf club head 10. The sole portion 40 has a substantially constant thickness. The crown portion 30 has an edge portion 100 and a thin portion 200. The edge portion 100 is a portion that is located at the end of the crown portion 30 and forms an edge. The term “end” as used herein refers to a portion of the crown portion 30 that is connected to the face portion 20 and the sole portion 40. The edge portion 100 has the same thickness as the sole portion 40. The thin portion 200 is a portion having a smaller thickness than the edge portion 100. The thin portion 200 includes a first thin portion 300 and a second thin portion 400 that have different thicknesses. The second thin portion 400 is thinner than the first thin portion 300. In other words, the thickness of the crown portion 30 decreases in the order of the edge portion 100, the first thin portion 300, and the second thin portion 400. The edge portion 100, the first thin portion 300, and the second thin portion 400 have inner surfaces 101, 301, and 401 on the hollow space B1 side, respectively. Although ribs are provided on the inner surfaces 301 and 401, they are not shown in FIG.

  FIG. 4 is a diagram showing the crown portion 30 as viewed from the hollow space B1 side. In FIG. 4, nine regions C <b> 1 to C <b> 9 that divide the crown portion 30 and the entire region C <b> 0 combining these regions are indicated by a two-dot chain line. The region C0 is a region that is in contact with the toe side, heel side, front side, and rear side end portions of the inner surface 101 of the edge portion 100, and that has opposing sides along the toe / heel direction and the front-rear direction as outer peripheries. . The nine regions C1 to C9 are regions obtained by dividing the region C0 into three parts at equal intervals in the toe-heel direction and dividing into three parts at equal intervals in the front-rear direction. The regions C1, C2, and C3 are regions located on the toe side, the center, and the heel side when the rear region when the region C0 is divided into three in the front-rear direction and further divided into three in the toe-heel direction. Regions C4, C5, and C6 are regions located on the toe side, the center, and the heel side when the center region when the region C0 is divided into three in the front-rear direction and further divided into three in the toe-heel direction. Regions C7, C8, and C9 are regions located on the toe side, the center, and the heel side when the region C0 is divided into three in the front-rear direction and further divided into three in the toe-heel direction.

  The edge portion 100 is provided along the end of the crown portion 30. The thin portion 200 is surrounded by the edge portion 100. In the thin portion 200, the first thin portion 300 is provided in a portion included in the regions C1, C2, C3, C6, C7, and C9. In addition, a second thin portion 400 is provided in a portion of the thin portion 200 included in the regions C4, C5, and C8. In FIG. 4, in order to show the second thin portion 400 in an easily understandable manner, the boundary between the second thin portion 400 and another portion is indicated by a solid line that is thicker than the other lines. As described above, the second thin portion 400 includes a central region (region C5) in the center of the other eight regions among the nine regions, and a front region (region C8 of the region C8) in front of the central region. And a toe side region (region C4) located on the toe side of the central region.

  Of the second thin portion 400, the portion located in the front region (hereinafter referred to as “front region portion 410”) is located on the toe side and the heel side of the front region (region C8) (regions C7 and C9, respectively). The thickness is smaller than As described above, the crown portion 30 is made of titanium, and the rigidity decreases as the thickness decreases. In other words, the front region 410 is a low-rigidity portion (first low-rigidity portion) that has lower rigidity than the regions on the toe side and heel side than the front region. Of the second thin portion 400, the portion located in the central region (hereinafter referred to as “central region portion 420”) is a region on the heel side and the rear side of the central region (region C5) (region C6 and region C5, respectively). It is a low-rigidity portion (second low-rigidity portion) having a thickness smaller than that of C2), that is, low rigidity. In addition, in the second thin portion 400, a portion located in the toe side region (hereinafter referred to as “toe side region portion 430”) is a region on the front side and the rear side of the toe side region (region C4) (each region). It is a low-rigidity portion (third low-rigidity portion) that is smaller in thickness than C7 and C1), that is, has low rigidity. As described above, each of the low-rigidity portions (the front region portion 410, the central region portion 420, and the toe-side region portion 430) has a smaller thickness than the portions other than the low-rigidity portion (that is, the rigidity is low). Lower).

  The thin portion 200 is provided with a plurality of ribs 500. The plurality of ribs 500 extend in the toe-heel direction, and extend in one of two directions that form an angle of about 60 degrees (for example, 55 degrees to 65 degrees) with respect to the ribs. There is. As the ribs 500 are located on the front side, the distance between the ribs 500 is reduced. The thickness of the edge part 100, the 1st thin part 300, the 2nd thin part 400, and the rib 500 is demonstrated with reference to FIG.

  FIG. 5 is a view showing a cross section of the crown portion 30. FIGS. 5A, 5B, and 5C show cross sections of the crown portion 30 in the arrow views Va-Va, Vb-Vb, and Vc-Vc in FIG. 4, respectively. In FIG. 5, only the end face is shown for easy understanding of the characteristics of the crown portion 30. FIG. 5A shows an end face of the crown portion 30 in the regions C7, C8, and C9. The edge part 100 and the 1st thin part 300 are provided in the part contained in area | region C7 and C9 among the crown parts 30. FIG. Similarly, the second thin portion 400 is provided in the region C8. The edge portion 100, the first thin portion 300, and the second thin portion 400 have a thickness of L100, L300, and L400, respectively. As described above, the relationship between the thicknesses is L100> L300> L400. In the present embodiment, L100, L300, and L400 are 0.75 mm, 0.55 mm, and 0.35 mm, respectively.

  Of the ribs 500, the first thin portion 300 has a first rib 530, and the second thin portion 400 has a second rib 540. The height of the first rib 530 from the inner surface 301 of the first thin portion 300 is L530. The height of the second rib 540 from the inner surface 401 of the second thin portion 400 is L540. The height relationship of these ribs is L530> L540. In this embodiment, L530 and L540 are 0.15 mm and 0.10 mm, respectively. Further, the thickness (L300 + L530) of the portion where the first rib 530 is provided in the first thin portion 300 is smaller than the thickness L100 of the edge portion 100.

  In FIG.5 (b), the end surface of the crown part 30 in area | region C4, C5, and C6 is shown. The edge part 100 and the 2nd thin part 400 are provided in the part contained in the area | region C4 among the crown parts 30, and the 2nd thin part 400 is similarly provided in the area | region C5. That is, the second thin portion 400 is provided from the region C4 to the region C5. Similarly, the region C6 is provided with an edge portion 100 and a first thin portion 300. In FIG.5 (c), the end surface of the crown part 30 in area | region C1, C2, and C3 is shown. The edge part 100 and the 1st thin part 300 are provided in the part contained in area | region C1 and C3 among the crown parts 30. FIG. Similarly, the first thin portion 300 is provided in the region C2. That is, the first thin portion 300 is provided from the region C1 to the region C3.

The above is the configuration of the golf club head 10. The golf club head 10 is manufactured through the following processes. The operations in these steps may be automatically performed by a machine controlled by a computer or the like. In the following description, it is assumed that an operator operates each machine to perform each operation. In the following, the process of forming the crown portion 30 will be mainly described.
FIG. 6 is a diagram illustrating an example of the appearance of the crown portion in each process in which the crown portion 30 is formed. In FIG. 6, the surface on the side where the crown portion is depressed, that is, the surface facing the hollow space B1 when the golf club head 10 is configured is shown. In the following drawings including FIG. 6, such a surface is referred to as an “inner surface” for convenience of explanation. First, in the first step, an operator processes titanium by forging to form a crown portion 30x shown in FIG. The crown portion 30x has an overall thickness L100 similar to the edge portion 100 shown in FIG.

  Next, in the second step, the worker performs chemical milling on a part of the inner surface 31x of the crown part 30x, and the thickness (L100) of the part is changed to the first rib 530 shown in FIG. Is reduced to the same (L300 + L530) as the part provided with. Thereby, the crown part 30y shown in FIG.6 (b) is formed. The crown portion 30y has a thin portion 200y on which chemical milling has been performed and an edge portion 100 on which chemical milling has not been performed. Since the edge portion 100 is not subjected to chemical milling, it has a thickness L100 similar to that shown in FIG.

  Subsequently, in the third step, the worker performs chemical milling on a part of the thin portion 200y until the thickness becomes L300. At this time, the portion where the chemical milling is not performed becomes a rib 500z having a height L530. In FIG.6 (c), the crown part 30z which has the thin part 200z in which the rib 500z was provided in the 3rd process is shown. Then, in the fourth step, the worker performs chemical milling on the portion included in the regions C4, C5, and C8 shown in FIG. 4 in the thin portion 200z, and sets the thickness of this portion. Make it small overall. Thereby, as shown in FIG.6 (d), the crown part 30 which has the 1st thin part 300 and the 2nd thin part 400 is formed. That is, the second thin portion 400 shown in FIG. 6D is a portion where chemical milling has been performed in the fourth step. Finally, in the fifth step, the operator welds the crown part 30 and the separately formed face part 20, sole part 40, and hosel part 50 to join each other. In this way, the golf club head 10 is assembled.

When the golf club head 10 hits the ball, the golf club head 10 is deformed by an impact received from the ball.
FIG. 7 is a view showing an example of the shape of the golf club head 10 deformed at the time of hitting. 7, the shape of the outer periphery of the golf club head 10 shown in FIG. 3 is indicated by a two-dot chain line, and portions corresponding to the first thin portion 300 and the second thin portion 400 are shown on the outer periphery. Moreover, in FIG. 7, the shape of the outer periphery after a deformation | transformation is shown as the continuous line. When the ball collides with the golf club head 10, the face portion 20 moves rearward as a whole while the portion where the ball collided is depressed toward the hollow space B1. The crown portion 30 and the sole portion 40 are deformed so as to warp to the outside space side by a force applied from the face portion 20 that has moved to the rear side.

  As described above, the sole portion 40 has the same thickness as the edge portion 100 of the crown portion 30. On the other hand, the crown portion 30 is provided with a first thin portion 300 and a second thin portion 400 that are thinner than the edge portion 100. The sole portion 40 is formed of titanium as a material like the crown portion. For this reason, the crown portion 30 has a larger amount of deformation during hitting than the sole portion 40. As a result, the face portion 20 moves more largely on the crown side to the rear side than on the sole side. By deforming the face portion 20, the crown portion 30, and the sole portion 40 in this way, the effect of increasing the loft angle and the launch angle becomes larger than before the deformation, and the backspin amount of the launched ball is reduced. The effect is produced. The greater the deformation of the crown portion 30 compared to the sole portion 40, the greater the degree of these effects. Further, the crown portion 30 is deformed at the time of hitting and a force (hereinafter referred to as “repulsive force”) for returning to the original shape is transmitted to the ball through the face portion 20, thereby producing an effect of improving the initial velocity of the ball. Let This repulsive force increases as the thickness of the crown portion decreases.

However, if the thickness of the crown portion is too small, the rigidity becomes too small and excessive vibration occurs in the crown portion. Then, energy is consumed by the vibration, the repulsive force is reduced, and the initial speed is also reduced.
FIG. 8 is a diagram illustrating an example of the relationship between the thickness of the crown portion and the flight distance of the ball. FIG. 8 shows a graph in which the vertical axis represents the flight distance of the ball and the horizontal axis represents the thickness of the crown portion. The thickness of the crown portion referred to here is the thickness of the thin portion 200 in the case of the crown portion 30, and in this example, a crown portion having a uniform thickness is used. Further, the flight distance here includes both carry (distance to fly before the ball falls) and run (distance to roll after the ball falls). In this example, when the thickness of the crown portion is 0.50 mm or more and 0.60 mm or less, the flight distance becomes maximum (the thickness at this time is referred to as “optimum thickness”), and the thickness becomes larger than that. Even if it gets smaller, the flight distance is decreasing. In other words, in the crown portion where the thickness is the optimum thickness, the improvement in the above repulsive force and the suppression of excessive vibration improve the initial velocity of the ball compared to other thicknesses. Therefore, the balance is more suitable. In addition, when the thickness of the crown portion is 0.20 mm or less, the degree to which the flight distance decreases rapidly increases. The flight distance in this example is generally proportional to the initial velocity of the ball. In other words, the initial velocity of the ball is also maximized when the thickness of the crown portion is the optimum thickness (the initial velocity at this time is referred to as “maximum initial velocity”), and decreases as the thickness changes from there.

  In the crown portion 30 of the golf club head 10 in the present embodiment, as described above, the edge portion 100, the first thin portion 300, and the second thin portion 400 have thicknesses (thickness without adding ribs) of 0.75 mm, 0.55 mm and 0.35 mm. 0.35 mm is the thickness when the initial speed is smaller than the maximum initial speed due to the influence of excessive vibration as described above. However, in the crown portion 30, the first thin portion 300 having a larger thickness is provided around the second thin portion 400. For this reason, in the 2nd thin part 400, the excessive vibration in the 2nd thin part 400 is suppressed compared with the crown part with a thickness of 0.35 mm shown by the example of FIG. That is, in the crown portion 30, the repulsive force is improved by the second thin portion 400 having a smaller thickness than the first thin portion 300 having the optimum thickness shown in FIG. 8, while the thickness is reduced. Therefore, excessive vibration generated by the above is suppressed. In the crown portion 30, the second thin portion 400 is provided so that the degree of improving the repulsive force is greater than the degree of suppressing excessive vibration. This will be described with reference to FIG.

  FIG. 9 is a diagram illustrating an example of the relationship between the position where the second thin portion is provided and the initial velocity of the ball. Here, the second thin portion is a portion having a smaller thickness among the thin portions having a smaller thickness than the edge portion in the crown portion, and the second thin portion 400 is an example thereof. In addition, the thin portion excluding the second thin portion is the first thin portion. In the example of FIG. 9, the initial speed of the ball when the head is hit at the center of the face surface 21 at a head speed of 43.5 m / s (meters per second) is shown on the vertical axis. On the horizontal axis, “C4”, “C5”, “C8”, “C5, 8”, “C4, 5, 8” and “uniform thickness” representing the shapes of the first and second thin portions are shown. The name is shown. Among these, the name including “C” indicates a region where the second thin portion is provided among the thin portions.

  For example, “C4” indicates that the crown portion provided with the second thin portion is used in a location included in the region C4 shown in FIG. 4 among the thin portions. That is, the crown part 30 of this embodiment is represented by the name “C4, 5, 8”. The name “uniform thickness” represents a case where a crown portion in which the thickness of the thin portion is uniform, that is, a crown portion having only the first thin portion is used. In this “thickness uniform”, a crown portion formed so as to have a maximum flight distance is used among the crown portions in which the thickness of the thin portion is uniform.

  In the example of FIG. 9, the initial velocity of the ball is higher in all cases where the second thin portion is provided than in the case of “uniform thickness” where the second thin portion is not provided. In particular, the initial velocity of the ball is large in the case of “C5, 8” and “C4, 5, 8”, and the initial velocity of the ball is maximum in the case of “C4, 5, 8”. Thus, according to the present embodiment, in the golf club head having a crown portion with a part of the thickness being reduced, compared to a golf club head that does not have the second thin portion, that is, only the first thin portion, The initial speed of the ball can be improved. Furthermore, the golf club head 10 in the present embodiment can further improve the initial velocity of the ball as compared with other golf club heads provided with the second thin portion.

  FIG. 10 is a diagram showing the ball flight distance in the same case as FIG. In FIG. 10, the vertical axis represents the ball flight distance. The flight distance here includes both carry and run. The flight distance of the ball is affected not only by the initial velocity of the ball but also by the ball launch angle and the backspin amount. Therefore, although the result is different from the initial speed shown in FIG. 9, in FIG. 10, the flying distance is increased in all cases where the second thin portion is provided, compared to the case of “uniform thickness”. Yes. Thus, according to the present embodiment, in the golf club head having a crown portion with a part of the thickness being reduced, the flight distance of the ball can be improved as compared with a golf club head that does not have the second thin portion. .

  FIG. 11 is a diagram showing the hook spin amount of the ball in the same case as FIG. In FIG. 11, the vertical axis represents the hook spin amount of the ball. In FIG. 11, when the crown part provided with the second thin part is used in the place included in the region C8 shown in FIG. 4 ("C8", "C5, 8" and "C4, 5, 8" In the case), the hook spin amount is larger than in the case of “uniform thickness” in which the second thin portion is not provided. Therefore, according to the present embodiment (in the case of “C4, 5, 8”), the degree of hooking of the ball can be increased by increasing the hook spin amount as compared with the case where the second thin portion is not provided. .

  In the golf club head 10, the second thin portion 400 has the second rib 540. Since the second thin portion 400 has a smaller thickness than the edge portion 100 and the first thin portion 300, the second thin portion 400 has a smaller rigidity and a lower strength than these portions. The term “strength” as used herein refers to the magnitude of a force that can be withstood until the material does not return to its original shape (that is, breakage), such as tensile strength and yield strength. When the impact force received from the impacted ball is transmitted to the entire golf club head, a portion having a low strength in the golf club head may be damaged. In the crown portion 30, the second thin portion 400 having the smallest thickness is the portion that is most easily damaged. However, as described above, the second rib 540 has the strength compared to the case without the rib. Has improved and is less likely to break.

The golf club head 10 is vibrated by an impact force received from the ball at the time of hitting and generates a sound. The frequency of the sound having the largest amplitude (volume) among the sounds generated at this time is called a main sound frequency (for example, a frequency of about 4000 to 4100 Hz).
FIG. 12 is a diagram showing the magnitude (amplitude) of vibration at the main sound frequency of the golf club head 10 at the time of hitting. FIG. 12 shows the golf club head 10 viewed from the crown side. In FIG. 12, two-dot chain lines indicating the nine regions shown in FIG. The vibration at the main sound frequency is greatest in the portion of the crown portion included in the region C8. In the golf club head 10, the second thin portion 400 is provided in this portion.

  In a golf club head formed of titanium having a thickness of about 1 mm, the smaller the thickness, the larger the amplitude and the larger the generated sound. In the golf club head 10, since the second thin portion 400 having the smallest thickness is provided in the portion where the vibration at the main sound frequency is the largest as described above, the second thin portion 400 is not provided in this portion. The sound of the main frequency becomes louder than. As the sound of the main frequency increases, the sound of other frequencies becomes less noticeable and a clearer sound is generated. As described above, according to the present embodiment, it is possible to generate a clearer sound (a sound with a unified feeling) at the time of hitting, compared to a case where the second thin portion is not provided in the region C8.

[Modification]
The above-described embodiment is merely an example of implementation of the present invention, and may be modified as follows. Moreover, you may implement combining embodiment mentioned above and each modification shown below as needed.

(Modification 1)
The thicknesses L100, L300, and L400 of the edge portion 100, the first thin portion 300, and the second thin portion 400 may be different from the above-described embodiment. For example, L100 is 0.75 mm in the embodiment, but may be other values as long as it is 0.6 mm or more and 0.9 mm or less. Also, L300 was 0.55 mm, but other values may be used as long as it is 0.3 mm or more and 0.8 mm or less. L400 was 0.35 mm, but 0.1 mm or more and 0.00. Other values may be used as long as they are 6 mm or less. However, in either case, the magnitude relationship of L100>L300> L400 is established.

  Moreover, the thickness (L300 + L530 and L400 + L540) of the part in which the 1st rib 530 and the 2nd rib 540 are provided may also differ from embodiment. For example, L300 + L530 is 0.70 mm in the embodiment, but may be 0.4 mm or more and 0.9 mm or less, and L400 + L540 is 0.45 mm in the embodiment, but is 0.2 mm or more and 0.7 mm. The following is sufficient. However, these thicknesses are all set to L100 or less. In any case, the first thin portion and the second thin portion are formed to have a thickness having ribs (that is, the thickness is not set to L400 = L400 + L540). When L300 + L530 is equal to L100, the second step (chemical milling is performed on a part of the inner surface 31x of the crown portion 30x) is unnecessary among the steps shown in FIG.

  As described above, the thickness of the second thin portion is set to the optimum thickness (0.50 mm to 0.60 mm) or less (0.1 mm to 0.6 mm) shown in FIG. The effect of improving the repulsive force can be obtained when the thickness is reduced. Further, by providing the first thin portion having a thickness that suppresses excessive vibration in the second thin portion according to the thickness of the second thin portion, the degree of improving the repulsive force is suppressed to suppress excessive vibration. It can be greater than the degree. Thereby, compared with the case where a 2nd thin part is not provided, the initial velocity of a ball can be improved.

(Modification 2)
In the above-described embodiment, the second thin portion has the front region portion 410, the central region portion 420, and the toe side region portion 430 illustrated in FIG. 4, but is not limited thereto.
FIG. 13 is a diagram illustrating an example of a crown portion in the present modification. In FIGS. 13A and 13B, crown portions 30a and 30b viewed from the inner surface side are shown. In FIG. 13, the ribs are not shown to make the drawing easier to see, and the second thin portion 400 in the embodiment is indicated by a two-dot chain line for comparison. The crown portion 30a has a second thin portion 400a. The second thin portion 400a is provided so as to include the front region portion 410 and the central region portion 420 in FIG. The initial speed, flying distance, and hook spin amount of the ball when such a crown portion 30a is used are indicated by the names “C5, 8” in FIGS. As shown in these drawings, when the crown portion 30a is used, the initial velocity, the flight distance, and the hook spin amount of the ball are also compared to the case where the crown portion without the second thin portion is used, as in the embodiment. Can be improved. In addition, when the crown portion 30a is used, the initial velocity of the ball can be set to a size next to the golf club head 10 of the embodiment among other golf club heads provided with the second thin portion. Further, when the crown portion 30a is used, the flight distance of the ball can be maximized among other golf club heads provided with the second thin portion.

The crown portion 30b has a second thin portion 400b. The second thin portion 400b is provided so as to include only the front region 410 in FIG. The case where the crown portion 30b is used is indicated by the name “C8” in FIG. Even when the crown portion 30b is used, as shown in FIG. 9 and the like, the initial velocity, the flight distance, and the hook spin amount of the ball can be improved as compared with the case where the crown portion without the second thin portion is used. it can. Further, when the crown portion 30b is used, the hook spin amount can be set to a size next to the golf club head 10 of the embodiment among other golf club heads provided with the second thin portion.
As described above, the second thin portion may be provided including at least the front region portion 410.

(Modification 3)
In the above-described embodiment, the second thin portion has the front region portion 410 and the central region portion 420, the central region portion 420, and the toe side region portion 430 shown in FIG. However, they may be separated without being continuous.
FIG. 14 is a diagram illustrating an example of a crown portion in the present modification. 14A and 14B show crown portions 30c and 30d viewed from the inner surface side. Further, in FIG. 14, the ribs are not shown for easy understanding of the drawing. Moreover, in FIG.14 (b), the 2nd thin part 400 of embodiment is shown for the comparison. The crown portion 30c has a second thin portion 400c. The second thin portion 400c includes a front region portion 410c, a central region portion 420c, and a toe side region portion 430c. The front area 410c, the central area 420c, and the toe area 430c are areas included in the front area 410, the central area 420, and the toe area 430 shown in FIG. In addition, the front region portion 410c, the central region portion 420c, and the toe side region portion 430c are not continuous with each other, and a first thin portion is formed therebetween.

  The crown portion 30d has a second thin portion 400d. The second thin portion 400d includes a front region portion 410d, a central region portion 420d, and a toe side region portion 430d. The front side area 410d, the central area 420d, and the toe side area 430d are areas included in the front side area 410, the central area 420, and the toe side area 430 shown in FIG. Further, the front side region portion 410d, the central region portion 420d, and the toe side region portion 430d are not continuous with each other and are not in contact with the outer periphery of the second thin portion 400. That is, these region portions are provided not in the whole thin portion included in the regions C8, C5, and C4 but in a part thereof.

  The second thin portions 400c and 400d have, for example, a smaller surface area facing the hollow space B1 than the second thin portion 400 of the embodiment. For this reason, when the crown portions 30c and 30d are used, the degree of improvement in the repulsive force is reduced by making the second thin portion thinner than the first thin portion as compared with the embodiment, and the second thin portion is excessive. The degree to which simple vibrations are suppressed increases. In this case, for example, the repulsive force may be improved by making the thickness of the second thin portion smaller than in the embodiment. In any case, if the second thin portions 400c and 400d are not made too small (for example, the distance between adjacent second thin portions is within 10 mm), the second thin portion is not provided. Compared to the initial speed of the ball can be improved. In this way, the second thin portion only needs to be provided in each region where the front region portion 410, the central region portion 420, and the toe side region portion 430 are formed in FIG.

(Modification 4)
In the above-described embodiment, the region C0 illustrated in FIG. 4 is a region having a rectangular shape that contacts the toe side, heel side, front side, and rear side ends of the inner surface 101 of the edge portion 100 as an outer periphery. Not exclusively. For example, the region C <b> 0 may be a region having a rectangular shape that contacts the toe side, heel side, front side, and rear side ends of the thin portion 200 as an outer periphery. Since this area is smaller than the area C0, the second thin portion is smaller than that shown in FIG. In this case, similarly to the third modification, the repulsive force may be improved by reducing the thickness of the second thin portion as compared with the embodiment. In any case, the second thin portion If the distance is not too small (for example, if the distance between the outer periphery of the second thin portion and the outer periphery of each region is within 5 mm), the initial velocity of the ball is improved compared to the case where the second thin portion is not provided. Can be made.

  Note that the region C0 may be a region having a quadrangle that contacts the toe side, heel side, front side, and rear side ends of the crown portion 30 itself as an outer periphery. In this case, since the second thin portion is larger than that in the embodiment, the above-described improvement in the repulsive force and the suppression of the influence of vibration are opposite to each other, but compared to the case where the second thin portion is not provided. This is the same as the embodiment in that the initial velocity of the ball can be improved.

(Modification 5)
In the embodiment described above, the areas C1 to C9 shown in FIG. 4 are areas obtained by dividing the area C0 into three parts at equal intervals in the toe / heel direction and dividing into three parts at equal intervals in the front-rear direction. Not limited to. For example, as shown in FIG. 4, the boundaries between the regions divided into three at equal intervals in the toe / heel direction and the front-rear direction may be shifted by a predetermined length (for example, ± 5 mm) in these directions.
FIG. 15 is a diagram illustrating an example of a crown portion in the present modification. 15A and 15B show crown portions 30m and 30n viewed from the inner surface side. Further, in FIG. 15, the ribs are not shown to make the drawing easier to see, and the regions C1 to C9 and the second thin portion 400 in the embodiment are shown for comparison. The crown portion 30m has a second thin portion 400m. In the example of FIG. 15A, the boundary of each region in the embodiment is a boundary that is shifted by a length L1 in the direction toward the center of the region C0. As a result, the width in the toe-heel direction of the region C5 changes from L2 to L3 smaller than that, and the width in the front-rear direction changes from L4 to L5 smaller than that. For this reason, the 2nd thin part 400m is small compared with the 2nd thin part 400 of embodiment like the modification 3 grade | etc.,. Therefore, also in this case, the repulsive force may be improved by making the thickness of the second thin portion smaller than in the embodiment.

  The crown portion 30n has a second thin portion 400n. In the example of FIG. 15B, the boundary of each region in the embodiment is a boundary that is shifted by a length L6 in a direction away from the center of the region C0. As a result, the width of the region C5 in the toe-heel direction changes from L2 to L7 larger than that, and the width in the front-rear direction changes from L4 to L8 larger than that. For this reason, the second thin portion 400n is larger than the second thin portion 400 of the embodiment. In this case, as compared with the embodiment, the degree of improvement of the repulsive force is increased by making the second thin part thinner than the first thin part, and the degree of suppression of excessive vibration of the second thin part is reduced. . Therefore, for example, the degree of suppression of excessive vibration of the second thin portion may be increased by increasing the thickness of the first thin portion or the second thin portion as compared with the embodiment. In this modification, compared to the second thin portion 400 of the embodiment, the side of the second thin portion along the boundary of each region is displaced by ± 5 mm at the maximum, and the second thin portion is not provided. In comparison, it is the same as the embodiment in that the initial velocity of the ball can be improved.

  In the example of FIG. 15, the boundaries of the regions are all shifted by the same length, but the shift lengths may be different from each other, and the shift directions (the direction toward the center and the direction away from each other) are mixed. Also good. In short, the crown portion is at the center in the toe-heel direction and the front-rear direction and has a first width in the toe-heel direction (L2, L3, and L7 are examples thereof), and a second width (L4 in the front-rear direction). , L5 and L8 may include the central region portion 420 illustrated in FIG. 4 and the like in the central region (the region C5 is an example thereof). In addition, the crown portion has a front side region 410 in a front region (region C8 is an example thereof) on the front side of the central region, and a toe side region (region C4 is an example thereof) on the toe side of the central region. What is necessary is just to have the toe side area | region part 430. FIG.

(Modification 6)
In the above-described embodiment, the crown portion includes the second thin portion having a thickness smaller than that of the first thin portion 300 as the above-described low-rigidity portion (a portion having lower rigidity than portions other than the low-rigidity portion). Although the part 400 was provided, it is not restricted to this. For example, in the crown portion, instead of the second thin portion, a low-rigidity portion (hereinafter referred to as “low-rigidity material portion”) formed of a material (for example, carbon) having lower rigidity than the material (titanium) used in the embodiment. May be provided). In this case, even if the low rigidity portion is formed with the same thickness as the first thin portion, the rigidity of the low rigidity portion (that is, the low rigidity material portion) is lower than that of the first thin portion due to the difference in material. Thereby, similarly to the case where the second thin portion is provided, the initial velocity, the flight distance, and the hook spin amount of the ball can be improved as compared with the case where only the first thin portion is provided.

  The crown portion may be provided with a further reduced thickness of the whole or part of the low-rigidity material portion described above. The low-rigidity material portion having a reduced thickness (hereinafter referred to as “thin and low-rigidity material portion”) is a low-rigidity portion whose rigidity is smaller than that of the first thin portion, and other than itself (low-rigidity portion). This has a thin portion with a thickness smaller than that of the first portion (for example, the first thin portion). That is, the thin low-rigidity material portion is a low-rigidity portion in which both the material and the thickness are different from the first thin portion. Thus, the crown portion may be provided with a low-rigidity portion in which both or one of the material and thickness is different from the first thin portion. Further, the first, second and third low-rigidity portions have the same thickness as the low-rigidity portion made of titanium thin like the second thin-walled portion in the embodiment, and the first thin-walled portion made of carbon, for example. Any one of a low-rigidity part (the low-rigidity material part described above) and a low-rigidity part (thin low-rigidity material part) obtained by further reducing the thickness of the whole or a part of a part formed of, for example, carbon One or three may be combined. At that time, at least one of the first, second, and third low-rigidity portions is provided with a low-rigidity portion or a thin low-rigidity material portion that is thin like the second thin-walled portion. The low-rigidity part has a thin part with a smaller thickness than parts other than itself (low-rigidity part).

(Modification 7)
The shape of the rib which the thin part of a crown part has is not restricted to what is shown in FIG.
FIG. 16 is a diagram illustrating an example of a rib shape in the present modification. FIGS. 16A, 16B, and 16C show the inner surfaces of the crown portions 30e, 30f, and 30g, respectively. In FIG. 16, the boundary between the first thin portion and the second thin portion is not shown in order to make the drawing easy to see. The crown portions 30e, 30f, and 30g have ribs 500e, 500f, and 500g, respectively. The rib 500e is other than the rib extending in the toe-heel direction in the rib 500 shown in FIG. The rib 500f is a rib extending in the front-rear direction. The rib 500g is a rib extending in the toe-heel direction. In each of these examples, a plurality of ribs are provided at predetermined intervals on the inner surface of the thin portion. Thereby, the strength of each thin portion is improved as compared to the case where no rib is provided. In short, the strength of the thin part is smaller than the edge part, so the strength is also reduced, so by providing a rib on the inner surface, the strength will be improved compared to when no rib is provided. It only has to be. That is, various shapes of ribs may be provided on the thin portion.

(Modification 8)
In the above-described embodiment, the undulation caused by the step or rib between the second thin portion and the other portion (the edge portion or the first thin portion) is the inner surface of the crown portion (the surface facing the hollow space side of the golf club head). However, these undulations may be formed on the outer surface of the crown portion (the surface facing the space side outside the golf club head).
FIG. 17 is a diagram illustrating an example of a cross section of the crown portion in the present modification. In FIG. 17, only the end face of the crown portion is shown for easy viewing of the drawing. 17A, 17B, and 17C show the end faces of the crown portions 30h, 30j, and 30k, respectively. The crown portion 30h has an edge portion 100, a first thin portion 300h, and a second thin portion 400h. On the inner surface of the crown portion 30h, undulations due to a step between the second thin portion 400h and other portions are formed. On the other hand, undulations by ribs 500h are formed on the outer surface of the crown portion 30h.

  The crown portion 30j has an edge portion 100, a first thin portion 300j, and a second thin portion 400j. A rib 500j is provided on the outer surface of the crown portion 30j. On the outer surface of the crown portion 30j, undulations are formed by both the steps of the second thin portion 400j and other portions and the rib 500j. The crown portion 30k has an edge portion 100, a first thin portion 300k, and a second thin portion 400k. A rib 500k is provided on the inner surface of the crown portion 30k. On the inner surface of the crown portion 30k, undulations due to the ribs 500k are formed, while on the outer surface, undulations due to steps between the second thin portion 400k and the other portions are formed. Even when the crown portion shown in FIG. 17 is used, as in the embodiment, improvement of the repulsive force and suppression of excessive vibration are realized, and the initial velocity of the ball is reduced as compared with the case where the second thin portion is not provided. Can be improved. Further, by providing ribs in the thin portion, the strength of the thin portion is improved as compared with the case where no rib is provided.

  In any of these examples, the unevenness due to the above steps or ribs appears on the outer surface of the crown portion. The outer surface of the crown portion is a portion that the user sees together with the ball when the user holds the golf club 1. On the other hand, as described in the modified example 7, various shapes of ribs may be provided on the thin portion. For example, patterns, figures, characters, etc. that are desired to be shown to the user by the ribs provided on the outer surface of the crown portion. It is also possible to draw. In other words, by providing the first thin part, the second thin part, and the rib so that the undulations described above draw patterns, figures, characters, etc., for example, what is drawn compared to the case where they are drawn in other places It can be easily recognized by the user who is playing.

(Modification 9)
In the embodiment described above, the thin portion is formed on the crown portion by chemical milling. However, the crown portion may be formed by other methods. Another method is, for example, sandblasting using an abrasive. In the above-described embodiment, titanium is processed by forging to first form the crown portion 30x shown in FIG. 6A. For example, as shown in FIGS. 4 and 6D from the beginning by casting. You may form the crown part which has a thin part. In short, the crown portion may be processed by any method as long as it is formed in the shape shown in FIG.

DESCRIPTION OF SYMBOLS 1 ... Golf club, 10 ... Golf club head, 11 ... Shaft, 12 ... Grip, 20 ... Face part, 21 ... Face surface, 30 ... Crown part, 40 ... Sole part, 50 ... Hosel part, 100 ... Edge part, 200 ... thin part, 300 ... first thin part, 400 ... second thin part, 101, 301, 401 ... inner surface, 500 ... rib, 530 ... first rib, 540 ... second rib

Claims (2)

In a hollow golf club head having a face portion on the front side and a crown portion and a sole portion on the rear side of the face portion,
The crown portion includes a central region Ru center near of the crown portion a central region of the crown portion in the center of the nine divided regions divided into three respectively in the toe-heel direction and longitudinal direction, Among the divided regions, a front region adjacent to the front side of the central region, and a toe side region adjacent to the toe side of the central region of the divided regions are the central region, the front region, and the crown region. A golf club head characterized by having lower rigidity than a portion excluding a toe side region . In a hollow golf club head having a face portion on the front side and a crown portion and a sole portion on the rear side of the face portion,
Of the crown portion, a central region in the center of the nine divided regions obtained by dividing the crown portion into three in the toe / heel direction and the front-rear direction, and a central region in the center of the crown portion, Only in the front region that is the divided region adjacent to the front side of the central region is a low-rigidity portion that is less rigid than the other portions.
A golf club head characterized by that .

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