JP6255306B2 - Club for ground golf - Google Patents

Description

  The present invention relates to a club for ground golf.

  Ground golf is a sport that anyone can enjoy easily and safely, and plays by hitting a ball in a predetermined club. 2. Description of the Related Art Conventionally, clubs for ground golf that have a small diameter portion provided on a shaft have been provided (see, for example, Patent Document 1).

  Such a club for ground golf includes a wooden columnar shaft and a head provided at one end of the shaft, and the shaft has a small diameter smaller than that of other portions in the middle of its length. The part is formed with a predetermined length.

  The small diameter portion is formed at a position corresponding to the antinode of the primary vibration mode of the shaft when the ball is hit by the head. For this reason, the shaft easily excites the primary vibration mode, and stress concentration hardly occurs at the end of the shaft on the head side. Therefore, the club for the ground golf is difficult to break the shaft.

JP 2009-178276 A

  By the way, in recent years, the ground golf has become popular as a lifelong sport mainly for elderly people. Considering that the majority of the competition population is elderly, there is a need for a club for ground golf that is lightweight yet capable of improving player performance.

  The club for ground golf having the above-described configuration has a small-diameter portion having a diameter smaller than that of the other portion having a predetermined length, so that the weight of the shaft is reduced compared to a shaft having no small-diameter portion. be able to. Therefore, the ground golf club having the above-described configuration can reduce the weight of the club. If the club becomes lighter, the swing speed can be increased even for elderly people.

  However, the club for ground golf having the above configuration has a problem that the swing speed is increased while the rebound speed of the ball is not increased.

  In addition, the ground golf club having the above-described configuration has a problem in that the impact on the hand holding the grip is great when hitting, and the player's hand is easily numb.

  Accordingly, in view of the above problems, the present invention provides a club for ground golf that can reduce the numbness of a player's hand at the time of striking while reducing the weight of the club and relatively improving the rebound speed of the ball. This is the issue.

A club for ground golf according to the present invention is a club for ground golf provided with a rod-shaped shaft, a grip provided at one end of the shaft, and a club head provided at the other end of the shaft. The shaft is formed with a large diameter portion having a constant diameter, a diameter smaller than the large diameter portion, and at least a diameter smaller than a portion corresponding to the antinode of the primary vibration mode of its own shaft. One small-diameter portion is provided, and the antinode of the primary vibration mode is formed in the large-diameter portion, and the small-diameter portion is located on the grip side of the antinode of the primary vibration mode of the shaft.

  According to this configuration, the shaft is formed with a small-diameter portion having a smaller diameter than the portion corresponding to the antinode of the primary vibration mode of the shaft. By forming the small-diameter portion, the shaft can be made lighter compared to a shaft in which the small-diameter portion is not formed. Therefore, the club can be lightened. As a result, the swing speed at the time of hitting can be improved.

  Further, the small diameter portion is located on the grip side with respect to the antinode of the primary vibration mode of the shaft. If the small-diameter portion that contributes to weight reduction is located on the grip side, the grip side tends to be lightweight, so the center of gravity of the club is relatively shifted to the head side. As a result, the rebound speed of the ball is superior to the club in which the small diameter portion is positioned corresponding to the antinode of the primary vibration mode of the shaft. Therefore, the club having the above configuration is relatively excellent in the rebound speed of the ball while reducing the weight of the club.

  Moreover, since the small diameter portion is formed to have a smaller diameter than the portion corresponding to the antinode of the primary vibration mode of the shaft, the small diameter portion is lower in rigidity than the portion and is easily bent. And the said small diameter part is located avoiding the antinode of the primary vibration mode which is the most curved part in a shaft. Therefore, a portion having higher rigidity than the small diameter portion corresponds to the antinode of the primary vibration mode. As a result, in the club according to the present invention, when the primary vibration mode is excited, the shaft amplitude can be suppressed as compared with the club in which the small-diameter portion is located on the antinode of the primary vibration mode. Accordingly, the amplitude of the grip can be suppressed. Therefore, it is possible to reduce the impact applied to the hand holding the grip during hitting, and to make the player's hand less likely to be numb.

A club for ground golf according to the present invention is a club for ground golf provided with a rod-shaped shaft, a grip provided at one end of the shaft, and a club head provided at the other end of the shaft. The shaft includes at least one small-diameter portion having a smaller diameter than a portion corresponding to the antinode of the primary vibration mode of the shaft, and the small-diameter portion grips more than the antinode of the primary vibration mode of the shaft. located on the side, that have the large-diameter portion and projecting radially outward.

  According to such a configuration, the small diameter portion has the enlarged diameter portion protruding outward in the radial direction. The enlarged diameter portion is formed in a convex shape so as to protrude outward in the radial direction. That is, a highly rigid portion is formed in the small diameter portion. Therefore, the rigidity of the small diameter portion is higher than that of the small diameter portion not having the enlarged diameter portion, and the rigidity of the shaft is also increased. As a result, when the primary vibration mode is excited, the amplitude of the shaft can be suppressed compared to a shaft in which the small diameter portion does not have the enlarged diameter portion. Accordingly, the amplitude of the grip can be suppressed. Therefore, it is possible to reduce the impact applied to the hand holding the grip during hitting, and to make the player's hand less likely to be numb.

  As one aspect of the present invention, the enlarged diameter portion may be disposed at a position corresponding to the antinode of the secondary vibration mode of the shaft.

  According to such a configuration, the enlarged diameter portion is disposed at a position corresponding to the antinode of the secondary vibration mode of the shaft. That is, the diameter-enlarged portion, which is a portion having high rigidity in the small-diameter portion, is disposed at a position corresponding to the antinode of the secondary vibration mode that is a curved portion of the shaft. Therefore, even when the secondary vibration mode is excited, the amplitude of the shaft can be suppressed as compared with a shaft in which the diameter-expanded portion is not disposed at a position corresponding to the antinode of the secondary vibration mode. Accordingly, the amplitude of the grip can be suppressed. Therefore, it is possible to further reduce the impact applied to the hand holding the grip at the time of hitting, and to make the player's hand less likely to be numb.

A club for ground golf according to the present invention is a club for ground golf provided with a rod-shaped shaft, a grip provided at one end of the shaft, and a club head provided at the other end of the shaft. The shaft includes at least two small-diameter portions having a smaller diameter than a portion corresponding to the antinode of the primary vibration mode of the shaft, and the small-diameter portion grips the antinode of the primary vibration mode of the shaft. located on the side, the portion between the small diameter portion adjacent to the that are located at positions corresponding to the antinodes of the secondary vibration mode of said shaft.

  According to this configuration, the shaft includes at least two small diameter portions. Since the diameter of the part between adjacent small diameter parts is larger than the diameter of each small diameter part, the part between adjacent small diameter parts has higher rigidity than each small diameter part. Therefore, the rigidity of the shaft is higher than that of a shaft in which one small diameter portion is continuously formed, and the amplitude of the shaft can be suppressed.

  The part between adjacent small diameter parts is arrange | positioned in the position corresponding to the antinode of the secondary vibration mode of a shaft. That is, a portion having higher rigidity than each small-diameter portion is disposed on the antinode of the secondary vibration mode, which is a portion that is largely curved in the shaft.

  According to such a configuration, the amplitude of the shaft can be suppressed compared to a shaft in which a portion between adjacent small diameter portions is not disposed at a position corresponding to the antinode of the secondary vibration mode. Accordingly, the amplitude of the grip can be suppressed. Therefore, it is possible to reduce the impact applied to the hand holding the grip during hitting, and to make the player's hand less likely to be numb.

  According to the club for ground golf according to one aspect of the present invention, it is possible to reduce the numbness of the player's hand at the time of hitting while being relatively excellent in the rebound speed of the ball while reducing the weight of the club. There is an effect.

FIG. 1 is a side view of a club for ground golf according to a first embodiment of the present invention. FIG. 2 is a conceptual diagram showing a state in which the primary vibration mode of the embodiment is excited. FIG. 3 is a side view of a club for ground golf according to the second embodiment of the present invention. FIG. 4 is a conceptual diagram showing a state in which the secondary vibration mode of the embodiment is excited. FIG. 5 is a side view of a club for ground golf according to a third embodiment of the present invention. FIG. 6 is a conceptual diagram illustrating the influence of the positional relationship between the small diameter portion and the antinode of the primary vibration mode on the amplitude of the grip. FIG. 7 is a conceptual diagram for explaining the influence of the positional relationship between the small diameter portion and the antinode of the secondary vibration mode on the amplitude of the grip. FIG. 8 is an enlarged side view showing a modification of the small diameter portion. FIG. 9 is a side view of a conventional club for ground golf.

(First embodiment)
Hereinafter, a club for ground golf (hereinafter, simply referred to as “club”) according to an embodiment (first embodiment) of the present invention will be described with reference to the accompanying drawings.

  As shown in FIG. 1, the club 1 includes a shaft 2, a grip 6 provided at one end of the shaft 2, and a head 3 provided at the other end of the shaft 2. The shaft 2 is made of, for example, wood and has a substantially cylindrical shape. The shaft 2 is formed, for example, by cutting solid wood into a cylindrical shape, or formed by cutting out a wooden laminated material or laminated material composed of a plurality of layers into a cylindrical shape. The head 3 includes a wooden head main body 4 and a synthetic resin face portion 5 fixed to the head main body 4. The grip 6 is a grip portion provided at one end of the shaft, and generally, another member such as a rubber is often attached to the grip portion.

  As shown in FIG. 1, one end portion of the shaft 2 is inserted from the upper surface 4 a of the head main body 4, and the face portion 5 is superimposed on the front surface 4 b of the head main body 4. A metal reinforcing member (not shown) is provided on the lower surface (hereinafter referred to as “sole surface”) 4 c of the head 3. The face portion 5 is formed with a striking surface 7 for hitting a ball. The striking surface 7 is a flat surface, and an angle (loft angle) formed with the sole surface 4c is about 90 °.

  The shaft 2 includes a small-diameter portion 8 formed so as to have a smaller diameter than a portion corresponding to the antinode Z1 of the primary vibration mode of the shaft 2 and to be bound radially inward. That is, the shaft 2 includes a small diameter portion 8 and a large diameter portion 9 having a diameter larger than that of the small diameter portion 8. The large diameter portion 9 includes a first large diameter portion 10 formed at the end portion on the head 3 side and a second large diameter portion 11 formed at the end portion on the grip 6 side. A part of the first large diameter portion 10 corresponds to the antinode Z1 of the primary vibration mode of the shaft 2. In other words, the antinode Z1 in the primary vibration mode of the shaft 2 is located in the first large diameter portion 10. As shown in FIG. 1, the small diameter portion 8 is formed between the first large diameter portion 10 and the second large diameter portion 11. More specifically, the small diameter portion 8 is formed between a boundary portion 8 a between the small diameter portion 8 and the first large diameter portion 10 and a boundary portion 8 b between the small diameter portion 8 and the second large diameter portion 11. Yes.

  The diameter D11 of the first large diameter portion 10 and the diameter D12 of the second large diameter portion 11 are preferably about 18 mm or more and about 30 mm or less. The diameter D2 of the small diameter portion 8 is preferably about 14 mm to about 27 mm.

  The club 1 according to the present embodiment includes the small-diameter portion 8, so that the total weight can be reduced by about 25 g to about 50 g compared to the club before the small-diameter portion 8 is formed on the shaft 2.

  If the club is lightened, the swing speed is improved, while the rebound speed of the ball is reduced due to a decrease in the total weight of the club. In the club 1 according to the present embodiment, the center of gravity of the club 1 is shifted to the grip side by reducing the grip 6 side of the club 1. Therefore, the club 1 according to the present embodiment is relatively superior in the rebound speed of the ball as compared with the club in which the head side of the shaft is lightened.

  Since the small-diameter portion 8 is formed with a smaller diameter than the portion corresponding to the antinode Z1 of the primary vibration mode of the shaft 2, the small-diameter portion 8 has lower rigidity than the portion and is easily bent. As shown in FIG. 2, the small diameter portion 8 is formed closer to the grip 6 than the antinode Z1 in the primary vibration mode of the shaft 2. That is, the small diameter portion 8 is formed to avoid the antinode Z1 in the primary vibration mode that is the most curved portion in the shaft 2. Therefore, a portion having higher rigidity than the small diameter portion 8 corresponds to the antinode Z1 in the primary vibration mode. As a result, when the primary vibration mode is excited, the club 1 according to the present embodiment can suppress the amplitude of the shaft 2 as compared with a club in which a small diameter portion is formed on the antinode Z1 of the primary vibration mode. it can. Accordingly, the amplitude of the grip 6 can be suppressed. Therefore, the impact applied to the hand gripping the grip 6 at the time of hitting can be reduced, and the player's hand can be less likely to be numb.

  When the primary vibration mode is excited, the antinode Z1 of the primary vibration mode is formed in the shaft 2 within a range of about 210 mm to about 360 mm from the upper surface 4a of the head 3 body. The small diameter portion 8 of the shaft 2 is formed on the grip 6 side within a distance of about 135 mm from the antinode Z1 in the primary vibration mode to the edge on the antinode Z1 side in the primary vibration mode of the small diameter portion 8.

  Various standards for ground golf equipment are determined by the Japan Ground Golf Association, and the club 1 needs to be manufactured within a range of 500 mm to 1000 mm in total length. In the present embodiment, the small diameter portion 8 is preferably formed with a length L2 within a range of about 120 mm to about 255 mm. If it is in this range, weight reduction can be achieved, without reducing the rigidity of the small diameter part 8 extremely. The first large diameter portion 10 has a length L1 in the range of about 210 mm to about 360 mm, and the second large diameter portion 11 and the grip 6 have a total length L3 of about 355 mm to about 425 mm. Preferably, it is formed within the range.

(Second embodiment)
Hereinafter, a club 1 according to another embodiment (second embodiment) of the present invention will be described with reference to the accompanying drawings. In addition, about the structure which is common in said embodiment, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  As shown in FIG. 3, the small diameter portion 8 is formed with a large diameter portion 83 protruding outward in the radial direction. In order to protrude outward in the radial direction of the small diameter portion 8, the enlarged diameter portion 83 is formed in a convex shape. That is, a portion having high rigidity is formed in the small diameter portion 8. Therefore, the rigidity of the small diameter portion 8 is higher than that of the small diameter portion in which the enlarged diameter portion 83 is not formed, and the rigidity of the shaft 2 is also increased.

  The maximum diameter D3 of the expanded diameter portion 83 is smaller than the diameter of the portion corresponding to the antinode Z1 in the primary vibration mode, preferably 17 mm to 29 mm, and more preferably 20 mm to 25 mm.

  As shown in FIG. 4, the enlarged diameter portion 83 is formed at a position corresponding to the antinode Z <b> 2 of the secondary vibration mode of the shaft 2. Specifically, the enlarged diameter portion 83 is formed at a position corresponding to the antinode Z2 on the grip 6 side among the two antinodes Z2 in the secondary vibration mode of the shaft 2. That is, the diameter-enlarged portion 83 that is a portion having high rigidity in the small-diameter portion is formed on the antinode Z2 in the secondary vibration mode that is a portion that is easily bent in the shaft 2. In addition, about the preferable minimum diameter of the small diameter part 8, it is the same as 1st embodiment.

  As shown in FIG. 4, when the secondary vibration mode is excited, the node Z3 of the secondary vibration mode is formed at a position corresponding to the antinode Z1 of the primary vibration mode. Since the small-diameter portion 8 is formed closer to the grip 6 than the antinode Z1 in the primary vibration mode of the shaft 2, the enlarged-diameter portion 83 includes the antinode Z2 on the grip side of the antinode Z2 in the two secondary vibration modes. It is formed in the corresponding position. The antinode Z2 in the secondary vibration mode is formed within a range of about 400 mm to about 600 mm from the upper surface 4a of the head 3 main body.

  According to such a club 1, even when the secondary vibration mode is excited, the amplitude of the shaft 2 is larger than that of the shaft in which the diameter-expanded portion 83 is not formed at a position corresponding to the antinode Z2 of the secondary vibration mode. Can be suppressed. Accordingly, the amplitude of the grip 6 can be suppressed. Therefore, the impact applied to the hand gripping the grip 6 at the time of hitting can be reduced, and the player's hand can be less likely to be numb.

(Third embodiment)
In the club 1 according to another embodiment (third embodiment) of the present invention, as shown in FIG. 5, the shaft 2 includes at least two small diameter portions 8. Specifically, the shaft 2 includes a first small diameter portion 81 formed on the head 3 side and a second small diameter portion 82 formed on the grip 6 side.

  In the first small diameter portion 81, the boundary portion 8a between the first small diameter portion 81 and the first large diameter portion 10 and the diameter D22 thereof are the same as the diameter of the portion corresponding to the antinode Z1 of the primary vibration mode of the shaft 2. It is formed between the boundary portion 8c. In the second small diameter portion 82, the boundary portion 8b between the second small diameter portion 82 and the second large diameter portion 11 and the diameter D23 thereof are the same as the diameter of the portion corresponding to the antinode Z1 of the primary vibration mode of the shaft 2. It is formed between the boundary portion 8d. In addition, about the preferable minimum diameter of the small diameter part 8, it is the same as 1st embodiment.

  That is, the diameter D4 of the portion X between the first small diameter portion 81 and the second small diameter portion 82 is larger than the diameter D22 of the first small diameter portion 81 and the diameter D23 of the second small diameter portion 82. Therefore, the portion X between the first small diameter portion 81 and the second small diameter portion 82 has higher rigidity than the first small diameter portion 81 and the second small diameter portion 82. Accordingly, the rigidity of the shaft 2 is higher than that of the shaft 2 in which one small diameter portion 8 is continuously formed. In this case, the diameter D4 may be the same as that of the portion corresponding to the antinode Z1 of the primary vibration mode of the shaft 2, or may be larger than that.

  A portion X between the first small diameter portion 81 and the second small diameter portion 82 is formed at a position corresponding to the antinode Z2 of the secondary vibration mode of the shaft 2. Specifically, the portion X is formed at a position corresponding to the antinode Z2 on the grip 6 side among the two antinodes Z2 in the secondary vibration mode of the shaft 2. That is, a portion X having higher rigidity than the first small-diameter portion 81 and the second small-diameter portion 82 is formed in the antinode Z2 in the secondary vibration mode, which is a portion that is easily bent in the shaft 2. The diameter of the portion X is equal to or larger than the diameter of the portion corresponding to the antinode Z1 in the primary vibration mode, and is usually the same as the diameter of the portion corresponding to the antinode Z1.

  The length L21 of the first small diameter portion 81 and the length L22 of the second small diameter portion 82 are formed within a range of about 60 mm to about 195 mm. In the present embodiment, the length L21 of the first small diameter portion 81 is 130 mm, the length L22 of the second small diameter portion 82 is 70 mm, and the first small diameter portion 81 is formed longer than the second small diameter portion 82. ing.

  According to such a club 1, even when the secondary vibration mode is excited, two small diameter portions 8 are formed as compared with the shaft 2 in which one small diameter portion 8 is formed. The amplitude of the shaft 2 can be suppressed as compared with a shaft in which the portion X is not formed at a position corresponding to the vibration mode antinode Z2. Accordingly, the amplitude of the grip 6 can be suppressed. Therefore, the impact applied to the hand gripping the grip 6 at the time of hitting can be reduced, and the player's hand can be less likely to be numb.

  In addition, the club for ground golf which concerns on this invention is not restricted to said embodiment, A various deformation | transformation and change are possible.

  In the said 1st-3rd embodiment, although the full length of the club 1 presupposes that it manufactures in the range of 500 mm-1000 mm, this is based on the standard which the Japan Ground Golf Association currently defines, When this reference is changed, the length of the shaft 2 can be changed accordingly.

  In the first to third embodiments, the shaft 2 of the club 1 is made of wood. However, for the same reason as described above, the material and shape of the shaft 2 can be changed according to the change of the reference. .

  In the first to third embodiments described above, the total weight of the club is reduced by reducing the shaft diameter. However, the grip side may be further reduced by reducing the diameter of the shaft and using other methods. For example, the shaft may be reduced in diameter, and the weight may be further reduced by foaming the grip material or reducing the density of the grip rubber. Moreover, you may shorten the length of a rubber. Further, the shaft may be reduced in diameter and the weight may be reduced by using low specific gravity wood. In addition, the extended portion of the same material as the shaft may be used as a grip.

  In the second embodiment, the case where one small-diameter portion 83 is formed in the small-diameter portion 8 has been described. However, as shown in FIG. 8A, a plurality of large-diameter portions 83, 83. Also good. You may provide the some small diameter part 2 which has the enlarged diameter part 83. FIG.

  Further, as shown in FIG. 8B, the small diameter portion 8 includes a tapered portion in which the diameter D2 gradually decreases toward the center in the length direction, a straight portion having a constant diameter, and the length direction thereof. The shape may include a tapered portion in which the diameter D2 gradually increases as the distance from the center increases. Furthermore, as shown in FIG.8 (c), the small diameter part 8 may be provided with several enlarged diameter parts 83,83 ....

  In order to confirm the effects of the present invention, a test was performed to compare the performance of the club 1 according to the present invention and a conventional club.

<Test Example 1>
Test Example 1 confirms the influence of the club weight and the center of gravity position on the swing speed.

Table 1 shows the weight and the position of the center of gravity of the club used in Test Example 1. In this test, three types of club examples 1 (Smp1, Smp2, and Smp3) having different weights and gravity center positions were swung by six female users, and the swing speeds were compared. Here, Smp1 to Smp3 are as follows.
Smp1: A small-diameter portion 8 (full length 190 mm, minimum diameter 18 mm) configured such that the diameter gradually decreases toward the center in the length direction on the cylindrical shaft (diameter 21 mm) from the antinode Z1 in the primary vibration mode. It is formed 90mm away on the grip 6 side.
Smp2: 23 g of lead was pasted on the small diameter part of Smp1, and the center of gravity was moved 21 mm toward the grip.
Smp3: Smp1 with 80 g of lead attached to the small diameter part and the center of gravity moved to the grip side by 60 mm.

  As a result of Test Example 1, the swing speed was Smp1> Smp2> Smp3. From this result, it was confirmed that the swing speed was improved by reducing the weight of the club 1 on the grip 6 side.

<Test Example 2>
Test Example 2 confirms the influence of the weight and center of gravity of the club on the rebound characteristics of the club.

Table 3 shows the weight of the club used in Test Example 2, the weight difference from SmpB (reference), and the center of gravity of the club. Here, SmpA to SmpC are as follows.
SmpA: A small-diameter portion 8 (total length 190 mm, minimum diameter 18 mm) configured to gradually decrease in diameter toward the center in the length direction on a cylindrical shaft (diameter 21 mm) is an antinode Z1 in the primary vibration mode. It is formed at a corresponding position, and the center of gravity of the club is the same as SmpB, and is 51 g lighter than SmpB.
SmpB: A cylindrical shaft (diameter 21 mm) with no small diameter portion formed.
SmpC (Example 2): A small-diameter portion 8 (total length 190 mm, minimum diameter 18 mm) configured to gradually decrease in diameter toward the center in the length direction on a cylindrical shaft (diameter 21 mm) is a primary vibration. It is formed 90mm away from the antinode Z1 of the mode on the grip 6 side, and the center of gravity of the club is shifted to the head side by 20mm from SmpB, making it 65g lighter than SmpB.

  The rebound characteristics were compared using the above three types of clubs. In each club, a ground golf ball was made to collide with the center of gravity of the head, and the rebound speed was compared. There were two types of collision speeds of 15 m / s and 25 m / s.

  Table 4 shows the results of Test Example 2. In Test Example 2, the rebound speed increased in the order of SmpA <SmpB <SmpC at any collision speed (two types of 15 m / s and 25 m / s). From this result, it was found that the club according to one embodiment of the present invention was relatively excellent in the rebound speed of the ball as compared with a club whose weight was reduced on the head side and a club whose weight was not reduced. That is, it was confirmed that the resilience characteristics were improved by reducing the weight of the entire club while positioning the center of gravity of the club on the head side.

  From the results of Test Example 1 and Test Example 2, it was found that the club 1 was relatively excellent in swing speed and ball repulsion speed by making the grip 6 side lighter on the shaft 2.

Table 5 shows the weight of each part and the total weight of the clubs of the club No. 1 (Example 3) as an example of the present invention and the conventional clubs (No. 2, No. 3, No. 4). The total length of these clubs is almost the same. Here, no. 1-No. The four clubs are as follows.
No. 1 (Example 3): A small-diameter portion 8 (total length 190 mm, minimum diameter 18 mm) configured to gradually decrease in diameter toward the center in the length direction on a cylindrical shaft (diameter 21 mm) is a primary vibration. It is formed 90 mm away from the mode belly Z1 on the grip 6 side.
No. 2: A cylindrical shaft (21 mm in diameter) in which a small diameter portion is not formed.
No. 3: A cylindrical shaft (diameter 22 mm) in which a small diameter portion is not formed.
No. 4: A small diameter part (full length 190 mm, minimum diameter 18 mm) configured such that the diameter gradually decreases toward the center in the length direction on the cylindrical shaft (21 mm in diameter) corresponds to the antinode Z1 in the primary vibration mode. What is formed at the position.

  As can be seen from Table 5, no. In the first club (Example 3), although the total weight of the club is the smallest, the center of gravity of the club 1 is closest to the head 6.

  No. 2, no. In the club No. 3, the center of gravity is shifted to the head side by making the head heavier. However, the shaft is heavy and the total weight is around 650 g. The No. 4 club has a specification that the center of gravity shifts to the grip side because the head is light and the shaft is heavy. No. 2, no. In the structure in which the total weight is large and the center of gravity position is shifted to the head side as shown in FIG. 3, although the improvement of the resilience characteristics can be expected, the swing speed decreases. No. In No. 4, the total weight is small, so that the swing speed is improved. On the other hand, since the center of gravity is closer to the grip side, the rebound characteristics are inevitably lowered.

That is, no. The first club is No. 1. 2-No. Compared to the club according to No. 4, it can be said that the ball rebound speed is relatively excellent while the club is light.

  Next, the influence of the position of the antinode Z1 and the small diameter portion 8 in the primary vibration mode on the numbness was analyzed by eigenvalue analysis using a finite element method. The positional relationship between the antinode Z1 and the small diameter portion 8 in the primary vibration mode is shown in FIG. (A), (b), and (c) of FIG. 6 show the primary vibration mode excitation states of SmpA1, SmpB1, and SmpC1, respectively.

SmpA1 is a conventional club, and a cylindrical shaft (21 mm in diameter) has a small diameter portion (total length 190 mm, minimum diameter 18 mm) configured such that the diameter gradually decreases toward the center in the length direction. , Formed at a position corresponding to the antinode Z1 of the primary vibration mode. SmpB1 (Embodiment 4) and SmpC1 (Embodiment 5) are both clubs 1 according to an embodiment of the present invention, and the small diameter portion 8 is formed on the grip 6 side of the antinode Z1 in the primary vibration mode of the shaft 2. Yes. SmpB1 has a cylindrical shaft (diameter 21 mm) with a small diameter portion 8 (total length 190 mm, minimum diameter 18 mm) configured to gradually decrease in diameter toward the center in the length direction. It is formed 90 mm away from Z1 on the grip 6 side. SmpC1 is obtained by forming an enlarged diameter portion 83 (maximum diameter D3 is 20 mm) in the small diameter portion 8. Table 6 shows the diameter of the shaft 2 and the amplitude of the grip 6 in SmpA1, SmpB1, and SmpC1 used in this analysis. In this analysis, the diameter of the portion corresponding to the antinode Z1 of the primary vibration mode of the shaft 2 is the same as the diameter D11 of the first large diameter portion 10. 6 and Table 6, D11 indicates the diameter of the portion corresponding to the antinode Z1 in the primary vibration mode, D2 indicates the minimum diameter of the small diameter portion 8, and D3 indicates the maximum diameter of the expanded diameter portion 83.

In this analysis, the total length of the club was 870 mm and the head weight was 350 g in all samples. Further, as the elastic modulus of each member, the head 3 and the shaft 2 is 1000 kgf / mm ^2, the grip 6 was 300 kgf / mm ^2. The density of each member was 0.75 g / cc for the head 3 and the shaft 2 and 1.0 g / cc for the grip 6. The club 1 was in a completely free restraint state in which each member was not fixed at all. In addition, eigenvalue analysis was performed by the finite element method with 3334 elements and 5062 nodes. Under this analysis condition, a portion where the relative displacement in the direction in which the shaft 2 is curved has a minimum value is defined as an antinode Z1 in the primary vibration mode.

  As a result of the analysis, the amplitude A1 of the grip 6 was SmpA1> SmpB1> SmpC1. Specifically, when the amplitude A1 of the grip 6 in SmpA1 is 1, the amplitude A1 of the grip 6 in SmpB1 is 0.88. This is considered to be because, in SmpB1, the small-diameter portion 8 that is a portion having low rigidity is formed avoiding the antinode Z1 in the primary vibration mode of the shaft 2. From this analysis, it was found that SmpB1 can reduce hand numbness compared to SmpA1, which is a conventional club.

  Further, the amplitude of the grip 6 was smaller in SmpC1 (0.85) than in SmpB1 (0.88). This is considered to be because, in SmpC1, the enlarged diameter portion 83 having higher bending rigidity than the smaller diameter portion 8 is formed in the smaller diameter portion 8. From this analysis, it was found that SmpC1 can further reduce hand numbness compared to SmpB1.

  Next, the influence of the position of the portion X between the antinode Z2 in the secondary vibration mode and the adjacent small diameter portions on the numbness was analyzed by eigenvalue analysis using a finite element method. All the clubs are formed with the small-diameter portion 8 on the grip 6 side of the antinode Z1 in the primary vibration mode. The positional relationship between the antinode Z2 in the secondary vibration mode and the portion X is shown in FIG. (A), (b), and (c) of FIG. 7 show secondary vibration mode excitation states of SmpA2 (Example 6), SmpB2 (Example 7), and SmpC2 (Example 8), respectively.

  SmpA2 has one small diameter portion 8 formed on the shaft 2, and SmpB2 and SmpC2 both have two small diameter portions 8 formed on the shaft 2. SmpB2 is formed at a position where the portion X between both small diameter portions deviates from the antinode Z2 in the second vibration mode. In SmpC2, the portion X is formed at a position corresponding to the antinode Z2 in the second vibration mode. Table 7 shows the diameter of the shaft 2 and the amplitude of the grip 6 of SmpA2, SmpB2, and SmpC2 used in this analysis. 7 and Table 7, D11 indicates the diameter of the portion corresponding to the antinode Z1 in the primary vibration mode, D2 indicates the minimum diameter of the small diameter portion 8, and D4 indicates the maximum diameter of the portion X.

The portion X in SmpB2 is formed at a location 535 mm from the upper surface 4a of the head 3 body of the shaft 2, and the portion X in SmpC2 is formed at a location 475mm from the upper surface 4a of the head 3 body of the shaft 2. Yes.

In this analysis, in all samples, the total length of the club was 870 mm and the head weight was 350 g. Further, as the elastic modulus of each member, the head and the shaft is 1000 kgf / mm ^2, the grip was 300 kgf / mm ^2. The density of each member was 0.75 g / cc for the head 3 and the shaft 2 and 1.0 g / cc for the grip 6. The club 1 was in a completely free restraint state in which each member was not fixed at all. In addition, eigenvalue analysis was performed by the finite element method with 3334 elements and 5062 nodes. Under this analysis condition, a portion where the relative displacement in the direction in which the shaft 2 is curved has a minimum value is defined as an antinode Z2 in the secondary vibration mode.

  As a result of the analysis, the amplitude A2 of the grip 6 was SmpA2> SmpB2> SmpC2. Specifically, when the amplitude A2 of the grip 6 in SmpA2 is 1, the amplitude A2 of the grip 6 in SmpB2 is 0.93. This is considered to be because, in SmpB, a portion X having higher bending rigidity than the small diameter portion 8 was formed between the small diameter portion and the small diameter portion. From this analysis, it was found that SmpB2 can reduce hand numbness compared to SmpA1.

  Further, the amplitude A2 of the grip 6 was smaller in SmpC2 (0.88) than in SmpB2 (0.93). This is considered to be because, in SmpC1, the portion X having higher rigidity than the small diameter portion 8 was formed at a position corresponding to the antinode Z2 in the second vibration mode. From this analysis, it was found that SmpC2 can further reduce hand numbness compared to SmpB2.

  From the above test and analysis results, the club 1 according to an embodiment of the present invention has a relatively high ball rebound speed while reducing the weight of the club, and reduces the numbness of the player's hand at the time of hitting. Can be said.

DESCRIPTION OF SYMBOLS 1 ... Club, 2 ... Shaft, 3 ... Head, 4 ... Head main body, 4a ... Upper surface of head main body, 4b ... Front surface of head main body, 4c ... Sole surface, 5 ... Face part, 6 ... Grip, 7 ... Hitting 8, small diameter portion, 81, first small diameter portion, 82, second small diameter portion, 83, enlarged diameter portion, 9, large diameter portion, 10, first large diameter portion, 11, second large diameter portion, L 1 ... length of the first large diameter part, L2 ... length of the small diameter part, L3 ... total length of the second large diameter part and the grip, A1 ... amplitude of the primary vibration mode, A2 ... amplitude of the secondary vibration mode, X ... A portion between adjacent small-diameter portions, Z1 ... node of primary vibration mode, Z2 ... node of secondary vibration mode, Z3 ... node of secondary vibration mode, D1 ... diameter of large-diameter portion, D11 ... first large Diameter of diameter part, D12: Diameter of second large diameter part, D2: Diameter of small diameter part, D22: Diameter of first small diameter part, D23: Diameter of second small diameter part D3 ... diameter of the enlarged diameter portion, D4 ... diameter of the portion between the small diameter portion between adjacent

Claims (4)

In a club for ground golf comprising a rod-shaped shaft, a grip provided at one end of the shaft, and a club head provided at the other end of the shaft, the shaft is formed with a constant diameter. A large diameter portion and at least one small diameter portion formed smaller in diameter than a portion corresponding to the antinode of the primary vibration mode of the own shaft, the primary vibration mode. The ground golf club is formed in the large-diameter portion, and the small-diameter portion is positioned on the grip side of the shaft in the primary vibration mode. In a club for ground golf including a rod-shaped shaft, a grip provided at one end of the shaft, and a club head provided at the other end of the shaft, the shaft is a primary vibration of its own shaft. At least one small-diameter portion formed smaller in diameter than the portion corresponding to the antinode of the mode, the small-diameter portion is located on the grip side of the antinode of the primary vibration mode of the shaft and radially outward Club for Heidelberg round golf have a projecting enlarged diameter portion.   The club for ground golf according to claim 2, wherein the enlarged diameter portion is disposed at a position corresponding to an antinode of a secondary vibration mode of the shaft. In a club for ground golf including a rod-shaped shaft, a grip provided at one end of the shaft, and a club head provided at the other end of the shaft, the shaft is a primary vibration of its own shaft. Comprising at least two small-diameter portions formed to have a smaller diameter than the portion corresponding to the antinode of the mode, the small-diameter portion being located on the grip side of the antinode of the primary vibration mode of the shaft, and adjacent small-diameter portions portion between the club for Heidelberg round golf are located in positions corresponding to the antinodes of the secondary vibration mode of said shaft.

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