JP7153964B1 - Golf ball - Google Patents

Abstract

A golf ball is provided which, when hit with a pole, can increase the flight distance compared to when hit with other methods. SOLUTION: In a golf ball 10, a second H total volume is larger than each of a first H total volume and a third H total volume, and a second V total volume is smaller than each of a first V total volume and a third V total volume. and a relationship in which the second H total volume is smaller than each of the first H total volume and the third H total volume, and the second V total volume is larger than each of the first V total volume and the third V total volume It holds. [Selection drawing] Fig. 3

Description

The present invention relates to a golf ball provided with a parting line.

Golf balls are known that are formed using a set of molds each having a hemispherical cavity. In this type of golf ball, parting lines (also called seams) are provided at portions corresponding to mating surfaces of a pair of molds. For this reason, dimples are generally not arranged on the parting line.

As described above, a golf ball without dimples on the parting line tends to produce a difference in flight distance when hit with a pole and when hit with a seam. Pole hitting is a hitting method in which the axis of the golf ball passing through the parting line is the central axis of backspin rotation. Seam hitting is a hitting method in which the axis of the golf ball perpendicular to the parting line is the central axis of backspin rotation. Specifically, when a golf ball is seam-hit, the flight distance tends to be shorter than when it is pole-hit because it is difficult to obtain the effect of the dimples.

Therefore, for example, Patent Document 1 proposes adjusting the dimple pattern provided on the surface of a golf ball to make the flight distance when hit with a seam closer to the flight distance when hit with a pole. That is, in this golf ball, the dimple pattern is adjusted so that the flight distance is constant regardless of the hitting position.

JP-A-2000-93556

However, many amateur players tend to desire a golf ball capable of achieving a longer flight distance, even if the flight distance is limited to pole shots. In other words, there is a demand for a golf ball that provides excellent flight distance specifically for pole shots, rather than making the flight distance for seam shots closer to the flight distance for pole shots.

SUMMARY OF THE INVENTION An object of the present invention is to provide a golf ball which, when hit with a pole, can travel a longer distance than when hit with other methods.

According to one aspect of the present invention, there is provided a golf ball formed by a pair of molds each having a hemispherical cavity and having a parting line provided in a portion corresponding to the mating surfaces of the pair of molds, The surface of the golf ball has a dimple pattern formed of a plurality of dimples, and the direction parallel to the parting line in the circumferential direction of the golf ball is defined as a first circumferential direction and is perpendicular to the parting line. Assuming that the direction is the second circumferential direction, the dimple pattern has a plurality of dimple rows in the second circumferential direction, each of which is composed of a plurality of the dimples arranged in the first circumferential direction. The pattern has dimple groups equally divided in the first circumferential direction, and each of the dimple groups is divided into three in the second circumferential direction to form a first H area, a second H area, and a third H area. and the second H region is arranged between the first H region and the third H region, the parting line is arranged in the second H region, and the When the ratio of the number of dimple rows is 1, the ratio of the number of dimple rows included in each of the first H region and the third H region is 0.6 to 4.0, and each of the dimple groups is , by being divided into three in the first circumferential direction, it is partitioned into a first V region, a second V region, and a third V region, and the second V region is between the first V region and the third V region When the ratio of the total open area of the dimples included in the second V region is 1, the ratio of the total open area of the dimples included in each of the first V region and the third V region is 0.5. 85 to 1.15, the total volume of the dimples belonging to the 1H region is defined as the 1H total volume, the total volume of the dimples belonging to the 2H region is defined as the 2H total volume, and the total volume of the dimples belonging to the 2H region is defined as the 3H region. The total volume of the dimples is defined as a 3H total volume, the total volume of the dimples belonging to the first V region is defined as a first V total volume, the total volume of the dimples belonging to the second V region is defined as a second V total volume, and the Assuming that the total volume of the dimples belonging to the 3V region is the third V total volume, the second H total volume is larger than each of the first H total volume and the third H total volume, and the first V total volume and the third V total volume are larger than the first V total volume and the third V total volume. The second V total volume is smaller than each of the 3V total volumes, and the second H total volume is smaller than each of the first H total volume and the third H total volume. and that the second V total volume is larger than each of the first V total volume and the third V total volume.

With this golf ball, the dimple pattern is adjusted as described above, so that when the ball is hit with a pole, the effect of the dimples can be obtained better than when the golf ball is hit with other methods. Therefore, with this golf ball, when the ball is hit with a pole, it is possible to particularly effectively reduce the air resistance and increase the lift, thereby improving the flight distance.

FIG. 1 is an external view of a golf ball according to an embodiment of the invention. FIG. 2 shows the diameter of each dimple belonging to the dimple group, the diameter of the first polar dimple, and the diameter of the second polar dimple, for the golf balls of Examples 1 and 2, in relation to the arrangement of the dimples. It is explanatory drawing shown correspondingly. FIG. 3 shows the volume of each dimple belonging to the dimple group, the volume of the first polar dimple, and the volume of the second polar dimple in the golf ball of Example 1, corresponding to the arrangement of the respective dimples. It is an explanatory diagram. FIG. 4 shows the volume of each dimple belonging to the dimple group, the volume of the first polar dimple, and the volume of the second polar dimple in the golf ball of Example 2, corresponding to the arrangement of the respective dimples. It is an explanatory diagram. FIG. 5 is a chart showing the dimple diameter, dimple depth, dimple volume, number of dimples, and number ratio for each of the 1st H region, the 2nd H region, and the 3rd H region of Example 1. FIG. FIG. 6 is a chart showing the dimple diameter, dimple depth, dimple volume, number of dimples, and number ratio for each of the 1st H region, the 2nd H region, and the 3rd H region of Example 2. FIG. FIG. 7 shows the diameter of each dimple belonging to the dimple group, the diameter of the first polar dimple, and the diameter of the second polar dimple in the golf ball of the comparative example, corresponding to the arrangement of the respective dimples. It is an explanatory diagram. FIG. 8 shows the volume of each dimple belonging to the dimple group, the volume of the first polar dimple, and the volume of the second polar dimple, corresponding to the arrangement of the respective dimples, for the golf ball of the comparative example. It is an explanatory diagram. FIG. 9A is a chart showing the results of a first hitting test of the golf balls of Example 1 and Comparative Example. 9B is a chart showing the results of a second hitting test on the golf balls of Examples 1 and 2. FIG. FIG. 10A is a graph showing the drag coefficient CD of the golf ball of Example 1 when the number of revolutions is changed at a plurality of flight speeds when hitting with a pole and when hitting with a seam. FIG. 10B is a graph showing the lift coefficient CL of the golf ball of Example 1 when the number of revolutions is changed at a plurality of flight speeds in pole shot and seam shot. FIG. 11A is a graph showing the drag coefficient CD of the golf ball of Example 2 when the number of revolutions is changed at a plurality of flight speeds when hitting with a pole and when hitting with a seam. FIG. 11B is a graph showing the lift coefficient CL of the golf ball of Example 2 when the number of revolutions is changed at a plurality of flight speeds in pole shot and seam shot.

The golf ball 10 according to the present embodiment shown in FIG. 1 is formed by a set of molds (not shown). Each of the set of molds has a hemispherical cavity. Therefore, when a set of molds is closed, a spherical cavity is formed. A spherical golf ball 10 is formed by this spherical cavity.

The golf ball 10 formed as described above is provided with a parting line PL in a portion corresponding to the mating surfaces of a pair of molds. The parting line PL is also called a seam. Golf ball 10 has two hemispheres that sandwich parting line PL. One of these two hemispheres is hereinafter also referred to as the first hemisphere 12 and the other is also referred to as the second hemisphere 14 . Also, the apex of the first hemisphere 12 is also called a first polar point 16 , and the apex of the second hemisphere 14 is also called a second polar point 18 .

Of the circumferential directions of the golf ball 10, the direction parallel to the parting line PL is defined as a first circumferential direction, and the direction orthogonal to the parting line PL is defined as a second circumferential direction. The surface of golf ball 10 has a dimple pattern 22 formed from a plurality of dimples 20 . The dimple pattern 22 has a plurality of dimple rows 24 arranged in the second circumferential direction.

An example in which the dimple patterns 22 of Examples 1 and 2 are provided on the golf ball 10 according to the present embodiment will be described below. In Examples 1 and 2, the dimple pattern 22 is formed from a total of 372 dimples 20 . It should be noted that the dimple pattern 22 provided on the golf ball 10 is not limited to those of the first and second embodiments. Details of the dimple patterns 22 of Examples 1 and 2 will be described later, but as shown in FIG. 2, the arrangement and diameter of the dimples 20 of Examples 1 and 2 are the same. On the other hand, as shown in FIGS. 3 and 4, the volumes (depths) of the dimples 20 of Example 1 and Example 2 are different from each other.

As shown in FIG. 1, each dimple row 24 is formed from a plurality of dimples 20 arranged in the first circumferential direction. In the second circumferential direction, the dimple row 24 located near the parting line PL is the dimple row 24 located near the first pole point 16 and the dimple row 24 located near the second pole point 18. are formed from a larger number of dimples 20 than each of the .

As shown in FIG. 2, in Examples 1 and 2, dimples 20 are also arranged at each of the first pole point 16 and the second pole point 18 of FIG. The dimple 20 arranged at the first polar point 16 is also called a first polar dimple 26a. The dimple 20 arranged at the second polar point 18 is also called a second polar dimple 26b. Further, when the first polar dimples 26a and the second polar dimples 26b are not distinguished from each other, they are collectively referred to as the polar dimples 26 as well. In this embodiment, the dimple pattern 22 has polar dimples 26 .

In Examples 1 and 2, nine dimple rows 24 are arranged between the parting line PL and the first polar dimples 26a. Nine dimple rows 24 are arranged between the parting line PL and the second polar dimples 26b. Each of these dimple rows 24 has a number of dimples 20 that is a multiple of five. Therefore, the dimple pattern 22 excluding the polar dimples 26 can be equally divided into five in the first circumferential direction.

That is, the dimple pattern 22 has five dimple groups obtained by equally dividing the dimple pattern 22, excluding the polar dimples 26, into five in the first circumferential direction. As shown in FIG. 1 , the dividing line D that divides the dimple groups extends along the outer periphery of the dimple 20 without crossing the dimple 20 . As shown in FIG. 2, in Examples 1 and 2, the dividing line D extends along the outer circumference of the dimple 20, except for the first polar dimple 26a and the second polar dimple 26b.

Each of the dimple groups is divided into three in the second circumferential direction to be divided into a first H area, a second H area, and a third H area. In FIGS. 2 to 4, each of the 1st H region, the 2nd H region, and the 3rd H region is indicated by a dashed line.

The second H region is arranged between the first H region and the third H region. A parting line PL is arranged in the second H region. When the ratio of the number of dimple rows 24 included in the 2nd H region is 1, the ratio of the number of dimple rows 24 included in each of the 1st H region and the 3rd H region is 0.6 to 4.0. More preferably, the ratio is 1.7 to 2.0.

In Examples 1 and 2, the second H region is composed of four dimple rows 24 in total. Specifically, the second H region consists of two dimple rows 24 sandwiching the parting line PL and two dimple rows 24 adjacent to each of these dimple rows 24 on the opposite side of the parting line PL. have Therefore, the second H region is arranged across the first hemisphere 12 and the second hemisphere 14 .

A first H region is provided in the first hemisphere 12 . The first H region is composed of a total of seven dimple rows 24 from the dimple row 24 adjacent to the second H region to the dimple row 24 adjacent to the first polar dimple 26a. A third H region is provided in the second hemisphere 14 . The 3rd H region is composed of a total of 7 dimple rows 24 from the dimple row 24 adjacent to the 2nd H region to the dimple row 24 adjacent to the second polar dimple 26b.

Therefore, in Examples 1 and 2, when the ratio of the number of dimple rows 24 in the 2nd H region is 1, the ratio of the number of dimple rows 24 in each of the 1st H region and the 3rd H region is 1.75. .

Each dimple group is partitioned into a first V region, a second V region, and a third V region by being divided into three in the first circumferential direction. 2 to 4, the first V region, the second V region, and the third V region are indicated by thick lines.

The second V region is arranged between the first V region and the third V region. When the ratio of the total open area of the dimples 20 included in the second V region is 1, the ratio of the total open area of the dimples 20 included in each of the first V region and the third V region is 0.85 to 1.15. . More preferably, the ratio is 0.9 to 1.0. When the ratio of the number of dimples 20 included in the second V region is 1, the ratio of the number of dimples 20 included in each of the first V region and the third V region is 0.85 to 1.15.

In Examples 1 and 2, the total opening area of the second V region (total value of opening areas of all dimples 20 in the second V region) is approximately 100.9πmm ² . The total open area of the first V region (total value of open areas of all the dimples 20 in the first V region) is approximately 98.3πmm ² . The total open area of the third V region (total value of open areas of all the dimples 20 in the third V region) is approximately 97.0πmm ² .

Therefore, in Examples 1 and 2, when the ratio of the total open area of the dimples 20 included in the second V region is 1, the ratio of the total open area of the dimples 20 included in the first V region is 0.97. The ratio of the total open area of the dimples 20 included in the third V region is 0.96.

In Examples 1 and 2, the total number of dimples 20 provided in the second V region is twenty-five. The total number of dimples 20 provided in the first V region is twenty-five. A total of 24 dimples 20 are provided in the third V region.

Therefore, in Examples 1 and 2, when the ratio of the number of dimples 20 included in the second V region is 1.0, the ratio of the number of dimples 20 included in the first V region is 1.0, and the ratio of the number of dimples 20 included in the third V region is 1.0. The ratio of the number of included dimples 20 is 0.96.

Hereinafter, the total volume, which is the sum of the volumes of the dimples 20 belonging to the 1H region, will be referred to as the 1H total volume. The volume of the dimple 20 here is the volume between the plane surrounded by the edges of the dimple 20 and the surface of the dimple 20 . Similarly, the total volume of the dimples 20 belonging to the 2H region is called the 2H total volume. A total volume of the dimples 20 belonging to the 3H region is called a 3H total volume. A total volume of the dimples 20 belonging to the first V region is called a first V total volume. A total volume of the dimples 20 belonging to the second V region is called a second V total volume. A total volume of the dimples 20 belonging to the third V region is called a third V total volume.

In Examples 1 and 2, there is a relationship that the 2nd H total volume is larger than each of the 1st H total volume and the 3rd H total volume, and the 2nd V total volume is smaller than each of the 1st V total volume and the 3rd V total volume. . In this case, in the second H region, the ratio of the number of dimples 20 having a diameter of 4.0 mm or more to the total number of dimples 20 is preferably 75% or more. In each of the first H region and the third H region, the ratio of the number of dimples 20 having a diameter of less than 4.0 mm to the total number of dimples 20 is preferably 60% or more.

As shown in FIG. 5, in the second H regions of Examples 1 and 2, the ratio of the number of dimples 20 having a diameter of 4.0 mm or more to the total number of dimples 20 is 83.3%. Further, in each of the first H region and the third H region, the ratio of the number of dimples 20 having a diameter of less than 4.0 mm to the total number of dimples 20 is 60.0%.

The dimple 20 preferably has a diameter of 3.0 to 5.0 mm. More preferably, the dimple 20 has a diameter of 3.2 to 4.6 mm. The depth of the dimples 20 is preferably 0.15-0.30 mm. The depth of the dimples 20 here is the depth from the phantom spherical surface (the spherical surface on which the surface of the golf ball 10 would exist if the dimples 20 were not present) to the deepest part of the dimples 20 . The total volume of the dimples 20 provided on the entire golf ball 10 is preferably 350-450 mm ³ .

Further, the second H total volume is preferably 10% or more greater than each of the first H total volume and the third H total volume. Preferably, each of the first V total volume and the third V total volume is at least 9.5% greater than the second V total volume.

In Example 1, the 1st H total volume is 25.1628 mm ³ , the 2nd H total volume is 27.5318 mm ³ , and the 3rd H total volume is 25.2982 mm ³ . Also, the first V total volume is 27.1199 mm ³ , the second V total volume is 23.9657 mm ³ , and the third V total volume is 26.9072 mm ³ .

Thus, in Example 1, the second H total volume is 9.4% greater than the first H total volume. The 2nd H total volume is 8.8% greater than the 3rd H total volume. The first V total volume is 13.2% greater than the second V total volume. The third V total volume is 12.3% greater than the second V total volume.

In Example 2, the 1st H total volume is 23.2520 mm ³ , the 2nd H total volume is 27.5318 mm ³ , and the 3rd H total volume is 23.5668 mm ³ . Also, the first V total volume is 25.9941 mm ³ , the second V total volume is 22.5150 mm ³ , and the third V total volume is 25.8415 mm ³ .

Thus, in Example 2, the second H total volume is 18.4% greater than the first H total volume. The 2nd H total volume is 16.8% greater than the 3rd H total volume. The first V total volume is 15.5% greater than the second V total volume. The third V total volume is 14.8% greater than the second V total volume.

EXAMPLES Example 1, Example 2, and Comparative Example are shown below to explain the effects of the present invention. As shown in FIGS. 7 and 8, in the dimple pattern provided on the golf ball of the comparative example, the second H total volume is larger than each of the first H total volume and the third H total volume, and the first V total volume and the third H total volume are larger than the first V total volume and the third H total volume. A second V total volume is greater than each of the three V total volumes.

Specifically, in the comparative example, the 1st H total volume is 24.0422 mm ³ , the 2nd H total volume is 25.0038 mm ³ , and the 3rd H total volume is 23.8844 mm ³ . Also, the first V total volume is 22.9721 mm ³ , the second V total volume is 27.1847 mm ³ , and the third V total volume is 22.7736 mm ³ .

Therefore, in the comparative example, the 2nd H total volume is 4.0% greater than the 1st H total volume. The 2nd H total volume is 4.7% greater than the 3rd H total volume. The second V total volume is 18.3% greater than the first V total volume. The second V total volume is 19.4% greater than the third V total volume.

A first hitting test was conducted on each of the golf ball 10 having the dimple pattern 22 of Example 1 and the golf ball having the dimple pattern of Comparative Example. The first hitting test was conducted by a tester (a male amateur golfer) using a driver club (#1 wood). Specifically, the testers hit each of the golf balls 10 of Example 1 and the golf balls of Comparative Examples by both seam hitting and pole hitting. In the pole shot, the axis of the golf ball passing through the parting line PL is the central axis of backspin rotation. Seam hitting is a hitting method in which the axis of the golf ball perpendicular to the parting line PL is the central axis of backspin rotation.

In the first shot test, the golf ball's initial velocity, launch angle, number of spins, maximum reach, carry (distance from launch point to landing point), and total flight distance (distance from launch point to stationary point) were measured. . The head speed (HS) of the tester was 39 m/s. The first hitting test was performed five times under the same conditions for each of the golf balls 10 of Example 1 and the golf balls of the comparative examples. FIG. 9A shows the average value of the results obtained from the five first shot tests.

From FIG. 9A, in the first hitting test, the golf ball 10 of Example 1 had a carry ratio of 101.6% when hit with a pole to the carry when hit with a seam. In the golf ball 10 of Example 1, the ratio of the total flight distance when hit with a pole to the total flight distance when hit with a seam was 102.0%.

On the other hand, the golf ball of the comparative example had a carry ratio of 100.5% when pole-strike to the carry when seam-strike. Further, the golf balls of the comparative examples had a total flight distance of 101.3% of the total flight distance of seam-hit when pole-hit.

From these results, it can be said that the golf ball 10 of Example 1 can effectively extend the flight distance when hit with a pole more than when hit with a seam, as compared with the golf balls of Comparative Example. In other words, in the golf ball 10 according to the present embodiment, by adjusting the dimple pattern 22 as described above, the effect of the dimples 20 can be obtained better when hit with a pole than when hit in other ways. can be done.

Next, a second hitting test was conducted on each of the golf ball 10 having the dimple pattern 22 of Example 1 and the golf ball 10 having the dimple pattern 22 of Example 2. The second hitting test was conducted in the same manner as the first hitting test, except that the head speed of the tester was 40 m/s. The results are shown in FIG. 9B.

From FIG. 9B, in the second hitting test, the golf ball 10 of Example 1 had a carry ratio of 101.8% when hit with a pole to the carry when hit with a seam. In the golf ball 10 of Example 1, the ratio of the total flight distance when hit with a pole to the total flight distance when hit with a seam was 101.2%.

On the other hand, the golf ball 10 of Example 2 had a carry ratio of 104.8% when pole-strike to the carry when seam-strike. In the golf ball 10 of Example 2, the ratio of the total flight distance when hit with a pole to the total flight distance when hit with a seam was 105.5%.

From these, it can be said that the golf ball 10 of Example 2 can effectively increase the flight distance when hit with a pole as compared to the golf ball 10 of Example 1 when hit with a seam. Therefore, the 2nd H total volume is 10% or more greater than each of the 1st H total volume and the 3rd H total volume, and each of the 1st V total volume and the 3rd V total volume is 9.5% greater than the 2nd V total volume. % or more, it is possible to favorably extend the flight distance when hitting a pole.

Next, when the golf ball 10 of Example 1 was hit with a pole and when it was hit with a seam, drag coefficient CD and lift force were determined according to the ITR (Indoor Test Range) defined by the rules of the United States Golf Association (USGA). The coefficient CL was measured. In FIG. 10A, the solid line shows the measurement results of the drag coefficient CD when the golf ball 10 of Example 1 was hit with a pole, and the dashed line shows the measurement results of the drag coefficient CD when the golf ball 10 was hit with a seam. In FIG. 10B, the solid line indicates the measurement result of the lift coefficient CL when the golf ball 10 of Example 1 is hit with a pole, and the dashed line indicates the measurement result of the lift coefficient CL when the golf ball 10 is hit with a seam.

Similarly, the drag coefficient CD and the lift coefficient CL of the golf ball 10 of Example 2 were also measured. In FIG. 11A, the solid line shows the measurement results of the drag coefficient CD when the golf ball 10 of Example 2 was hit with a pole, and the dashed line shows the measurement results of the drag coefficient CD when the golf ball 10 was hit with a seam. In FIG. 11B, the solid line indicates the measurement result of the lift coefficient CL when the golf ball 10 of Example 2 is hit with a pole, and the dashed line indicates the measurement result of the lift coefficient CL when the golf ball 10 of Example 2 is hit with a seam. These drag coefficient CD and lift coefficient CL measurement results were obtained by changing the rotational speed in the range of 1740 to 2880 rpm at each of the plurality of flight speeds shown in FIGS. 10A to 11B. The number of revolutions is shown only in FIG. 10A, and the number of revolutions is omitted in FIGS. 10B to 11B. The measurement results obtained by

10A to 11B, both Example 1 and Example 2 have a lower drag coefficient CD when the golf ball 10 is hit with a pole than when it is hit with a seam when the speed of the golf ball 10 is about 40 m/s or higher. The lift coefficient CL is high. In other words, in Examples 1 and 2, when a female amateur golfer hits a ball at a head speed of about 30 m/s and in flight hits a ball hit by a male amateur golfer at a head speed of 40 m/s, low drag and high lift are achieved. You can get power traits. From this, it is considered that the flight distance can be longer when the ball is hit with a pole than when the ball is hit with a seam. In other words, with the golf ball 10 according to the present embodiment, it is possible to particularly effectively reduce the air resistance and increase the lift to improve the flight distance when the ball is hit with a pole.

Furthermore, the difference between the lift coefficient CL when the golf ball 10 is seam-hit and the lift coefficient CL when it is pole-hit is greater in the second embodiment than in the first embodiment. From this, it can be seen that the golf ball 10 of Example 2 can effectively increase the flight distance by pole hitting as compared to seam hitting. Also from this, the 2nd H total volume is made 10% or more larger than each of the 1st H total volume and the 3rd H total volume, and each of the 1st V total volume and the 3rd V total volume is made larger than the 2nd V total volume It can be said that by increasing the ball length by 9.5% or more, it is possible to more favorably extend the flight distance when the ball is hit with a pole.

It should be noted that the present invention is not limited to the above-described embodiments, and can take various configurations without departing from the gist of the present invention.

For example, in the embodiment described above, dimples 20 are also located at each of the first polar point 16 and the second polar point 18, and the dimple pattern 22 has polar dimples 26, as shown in FIG. However, the dimples 20 may not be arranged at the first pole point 16 and the second pole point 18 . That is, the dimple pattern 22 need not have the polar dimples 26 .

Further, in the above-described embodiment, the dimple pattern 22 has five dimple groups obtained by equally dividing the dimple pattern 22 excluding the polar dimples 26 into five in the first circumferential direction. That is, the polar dimple 26 is not included in the dimple group. However, the polar dimples 26 may be included in the dimple group. In this case, the polar dimples 26 are shared by five dimple groups. Therefore, the dividing line D that divides the dimple groups does not cross the polar dimple 26 but crosses around the polar dimple 26 .

Furthermore, in the above embodiment, the dimple groups are formed by equally dividing the dimple pattern 22 into five in the first circumferential direction, but the present invention is not particularly limited to this. The dimple groups may be formed by equally dividing the dimple pattern 22 in the first circumferential direction. That is, the dimple pattern 22 may have a plurality of dimple groups other than five.

Example 3 is a dimple pattern 22 similar to Example 1 except that the dimple group has a first polar dimple 26a and a second polar dimple 26b. In Example 3, the first H region is composed of a total of eight dimple rows 24 from the dimple row 24 adjacent to the second H region to the first polar dimple 26a. The 3rd H region is composed of a total of 8 dimple rows 24 from the dimple row 24 adjacent to the 2nd H region to the second polar dimple 26b.

Accordingly, in Example 3, when the ratio of the number of dimple rows 24 in the 2H region is 1, the ratio of the number of dimple rows 24 in each of the 1H region and the 3rd H region is 2.0.

In Example 3, the second V region includes a first polar dimple 26a and a second polar dimple 26b. Therefore, the total opening area of the second V region is approximately 106.1πmm ² . Therefore, in Example 3, when the ratio of the total open area of the dimples 20 included in the second V region is 1, the ratio of the total open area of the dimples 20 included in the first V region is 0.93, and the ratio of the total open area of the dimples 20 included in the first V region is 0.93. The ratio of the total open area of the dimples 20 included in the region is 0.91.

In Example 3, the total number of dimples 20 provided in the second V region is 27. As shown in FIG. Therefore, when the ratio of the number of dimples 20 included in the second V region is 1, the ratio of the number of dimples 20 included in the first V region is 0.93, and the ratio of the number of dimples 20 included in the third V region is 0.93. The percentage is 0.89.

In Example 3, the 1H total volume is 25.6861 mm ³ . The 3rd H total volume is 25.8215 mm ³ . The second V total volume is 25.0123 mm ³ . Therefore, in Example 3 as well, there is a relationship in which the second H total volume is larger than each of the first H total volume and the third H total volume, and the second V total volume is smaller than each of the first V total volume and the third V total volume. It holds. Therefore, the golf ball provided with the dimple pattern 22 of Example 3 can also obtain the same effects as the golf ball 10 having the dimple pattern 22 of Examples 1 and 2. FIG.

In Examples 1 to 3 above, the 2H total volume is larger than each of the 1H total volume and the 3H total volume, and the 2V total volume is smaller than each of the 1V total volume and the 3rd V total volume. holds. However, in the dimple pattern 22, instead of this relationship, the second H total volume is smaller than each of the first H total volume and the third H total volume, and the second V total volume is smaller than each of the first V total volume and the third V total volume. A relationship with a large volume may be established. Even in this case, the same effect as the golf ball 10 having the dimple pattern 22 of Examples 1-3 can be obtained.

DESCRIPTION OF SYMBOLS 10...Golf ball 12...First hemisphere 14...Second hemisphere 20...Dimple 22...Dimple pattern 24...Dimple row 26...Polar dimple D...Parting line PL...Parting line

Claims (5)

A golf ball formed by a pair of molds each having a hemispherical cavity and having a parting line provided in a portion corresponding to the mating surfaces of the pair of molds,
the surface of the golf ball has a dimple pattern formed of a plurality of dimples,
Of the circumferential directions of the golf ball, if the direction parallel to the parting line is defined as a first circumferential direction, and the direction perpendicular to the parting line is defined as a second circumferential direction,
The dimple pattern has a plurality of dimple rows in the second circumferential direction, each row being composed of a plurality of the dimples arranged in the first circumferential direction,
The dimple pattern has a plurality of dimple groups obtained by equally dividing the dimple pattern in the first circumferential direction,
Each of the dimple groups is partitioned into a first H area, a second H area, and a third H area by being divided into three in the second circumferential direction,
the second H region is arranged between the first H region and the third H region;
The parting line is arranged in the second H region,
When the ratio of the number of dimple rows included in the second H region is 1, the ratio of the number of dimple rows included in each of the first H region and the third H region is 0.6 to 4.0. can be,
Each of the dimple groups is partitioned into a first V region, a second V region, and a third V region by being divided into three in the first circumferential direction,
the second V region is arranged between the first V region and the third V region;
When the ratio of the total open area of the dimples included in the second V region is 1, the ratio of the total open area of the dimples included in each of the first V region and the third V region is 0.85 to 1.0. is 15;
The total volume of the dimples belonging to the 1H region is defined as a 1H total volume, the total volume of the dimples belonging to the 2H region is defined as a 2H total volume, and the total volume of the dimples belonging to the 3H region is defined as a 3H total volume. The total volume of the dimples belonging to the first V region is the first V total volume, the total volume of the dimples belonging to the second V region is the second V total volume, and the total volume of the dimples belonging to the third V region is If the volume is the 3rd V total volume,
a relationship in which the second H total volume is larger than each of the first H total volume and the third H total volume, and the second V total volume is smaller than each of the first V total volume and the third V total volume;
a relationship in which the second H total volume is smaller than each of the first H total volume and the third H total volume, and the second V total volume is larger than each of the first V total volume and the third V total volume; A golf ball in which one or the other is established. 3. The golf ball of claim 1, wherein
the parting line is positioned between a first hemisphere and a second hemisphere of the golf ball;
The golf ball, wherein the dimple pattern has polar dimples that are the dimples arranged at the vertices of the first hemisphere and the vertices of the second hemisphere, and the polar dimples are not included in the dimple group. 3. The golf ball of claim 1, wherein
The dimple group is formed by dividing the dimple pattern into five equal parts in the first circumferential direction,
Golf, wherein a relationship is established in which the 2nd H total volume is larger than each of the 1st H total volume and the 3rd H total volume, and the 2nd V total volume is smaller than each of the 1st V total volume and the 3rd V total volume ball. The golf ball according to any one of claims 1 to 3,
In the second H region, the ratio of the number of the dimples having a diameter of 4.0 mm or more to the total number of the dimples is 75% or more;
A golf ball, wherein in each of the first H region and the third H region, the ratio of the number of the dimples having a diameter of less than 4.0 mm to the total number of the dimples is 60% or more. 5. The golf ball of claim 4, wherein
The dimple has a diameter of 3.0 to 5.0 mm,
the depth from the phantom spherical surface of the golf ball to the deepest part of the dimple is 0.15 to 0.30 mm;
a total volume of the dimples provided on the entire golf ball is 350 to 450 mm ³ ;
the second H total volume is 10% or more greater than each of the first H total volume and the third H total volume;
A golf ball, wherein each of said first V total volume and said third V total volume is greater than said second V total volume by 9.5% or more.

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