JP2000157651A - Golf club - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve stability of drive distance and direction by setting the ratio of the inertia moment in the toe heel direction to that in top sole direction about the center of gravity of a wood type club head to a specified range. SOLUTION: The ratio of inertia moment in the toe heel direction to that in the top sole direction about the center of gravity of a wood type club head is set within the range of 6.0:4.0 to 5.0:5.0. This ratio is calculated from the toe heel direction inertia moment value Ax, the top sole direction inertia moment value Ay and 10.Ax/(Ax+Ay):10.Ay/(Ax+Ay). When the toe heel direction inertia moment value Ax is too low, the flying distance and direction are made unstable, and when it is too high, it is difficult to keep the top sole direction inertia moment. When the top sole direction inertia moment value Ay is too low, the flying distance and trajectory become unstable, and when it is too high, it is difficult to keep the toe heel direction inertia moment. Thus, the flying distance and direction are stabilized.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a golf club, and more particularly, to a golf club having a head with improved balance.

[0002]

2. Description of the Related Art In general, golf players have demands for golf clubs such as 1) flight distance, 2) stability of flight distance,
3) Although three items of directional stability are important, it is difficult to simultaneously achieve these three requirements.

Therefore, as a conventional countermeasure, it has been practiced to increase the moment of inertia of the head so as to suppress the movement of the head when hitting a ball, thereby improving the directional stability. In other words, by setting a large moment of inertia, it is possible to make the head hard to rotate around the center of gravity, and even if the sweet spot (intersection point when the perpendicular is dropped from the center of gravity to the face) is removed when hitting the ball, The rotation is suppressed, and the head is less likely to shake, thereby improving the directional stability.

[0004]

However, the prior art head focuses on increasing the moment of inertia in the left-right (toe-heel) direction so as to reduce the variation in the lateral direction of the hit ball. It is not configured to achieve the above three requirements in a well-balanced manner. That is, the rotational moment in the vertical direction (top and sole) around the center of gravity (the moment of inertia in which the face rotates upward or downward when the head rotates around the center of gravity) is directional. Is not taken into account because it does not affect For this reason, when the ball is hit with the sweet spot removed, the head shakes up and down, and the ball is no longer hit at the specified loft angle,
It causes variation in flight distance. In the conventional head, neither the wood type nor the iron type is designed to provide a well-balanced rotational moment about the center of gravity in the horizontal direction and the vertical direction.

The inventor of the present invention has tried to strike a number of golfers with respect to the balance of the moment of inertia at present by using a generally used driver (a driver having a club length of 45 inches and a so-called large head having a head capacity of 220 cc). Then, a hit point survey was performed to measure the amount of variation (the center is a sweet spot) in the left-right direction and the up-down direction in the face portion at the time of hitting the ball. As a result, the ratio of the variation in the horizontal direction and the vertical direction of the face is about 5.6: 4.4 on average, and half of the test hitters are 5.4: 4.6 to 5.5. 8: 4.2. In addition, 70% of the test hitters centered on the average value and 5.2:
4.8-6.0: 4.0. Similarly, an iron club (37.5 inches in total club length and a loft angle of 2
When a hitting point survey was also conducted on a so-called general 5 iron at 8 °, the ratio of variation in the horizontal direction and the vertical direction of the face was about 6.8: 3.2 on average.
Half of the test hitters center on the average, 6.5: 3.5-7.5.
0: 3.0. Also, 70% of the test hitters ranged from 6.0: 4.0 to 7.2: 2.8 around the average value.

As apparent from this hitting point survey, the extent to which the golfer misses the sweet spot when hitting the ball is slightly more in the left-right direction than in the up-down direction. There is no.

Conventionally, wood-type and iron-type golf clubs that are generally commercially available have a moment of inertia in the left-right direction set to be much larger than a moment of inertia in the vertical direction. That is, in the wood type golf club, when the ratio of the moment of inertia in the left-right direction to the moment of inertia in the vertical direction was measured, the ratio was about 6.5: 3.5 on average, and the moment of inertia in the vertical direction was set to be the largest. It is about 6.1: 3.9. The average of the iron type golf clubs is about 8.0: 2.0, and the average of the moments of inertia in the vertical direction is about 7.5: 2.5.

As is clear from the results of the above-described investigation of the hitting points of the wood club and the iron club, the conventional golf clubs generally used are different from golf clubs in actual hitting pitch in the horizontal direction. The moment of inertia tends to be larger than the moment of inertia in the vertical direction. That is, at present, the head of the conventional golf club is formed without sufficiently considering the variation at the time of actual hitting with respect to the moment of inertia in the left-right direction and the moment of inertia in the vertical direction centering on the center of gravity. However, it is not configured to satisfy the above three requirements in a well-balanced manner.

The present invention has been made by finding out that the golf clubs actually used have a poor balance of the moment of inertia as a result of conducting the above-described hitting point investigation. . That is, the present invention optimizes the balance (ratio) of the values of the moments of inertia in the left-right (toe-heel) direction around the center of gravity and in the up-down (top-sole) direction. The objective is to achieve the three requirements of stability and direction stability in a well-balanced manner.

[0010]

In order to solve the above-mentioned problems, a golf club according to the present invention has a wood type. In the case of a wood type, a moment of inertia in the toe-heel direction and a moment of inertia in the top-sole direction around the center of gravity of the head. (Lx: Ly) from 6.0: 4.0 to 5.0: 5.0.
Is set in the range of. Further, in the iron type, the ratio (Lx: Ly) of the moment of inertia in the toe-heel direction to the moment of inertia in the top-sole direction around the center of gravity of the head is calculated from 7.4: 2.6.
It is characterized in that the ratio of y is increased.

The ratio between Lx and Ly described above is derived based on the above-described hitting point survey. The ratio of the moment of inertia in the toe-heel direction and the top-sole direction of the head is calculated from the actual lateral direction of the hit ball. In addition, the flight distance and the direction can be efficiently stabilized by coping with variations in the vertical direction.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS [Wood type] From the above-mentioned hitting point investigation, the head has a ratio of Lx to Ly preferably in the range of 6.0: 4.0 to 5.0: 5.0. And from 5.8: 4.2 to 5.
It is preferable to form them so as to be in the range of 4: 4.6.
The ratio (Lx: Ly) is 1 when a specific value of the moment of inertia in the toe-heel direction is Ax and a specific value of the moment of inertia in the top-sole direction is Ay.
0 · Ax / (Ax + Ay): 10 · Ay / (Ax + A
y).

When the head is formed such that the ratio of the moment of inertia is within the above range, if the value of the moment of inertia in the toe-heel direction is too low, the flying distance and direction are not affected by variations in the toe-heel direction. It becomes stable, and if it is too high, it becomes difficult to maintain the moment of inertia in the top-sole direction to some extent, so the lower limit is 1500 g · cm 2,
The upper limit is 3700 g · cm 2, preferably 2000 g
・ It is good to be within the range of cm 2 to 3500 g · cm 2. Also, if the value of the moment of inertia in the top sole direction is too low, the flight distance and trajectory will be unstable with respect to the variation of hit points in the vertical direction, and if it is too high, the moment of inertia in the toe-heel direction will be maintained to some extent. Because it becomes difficult, the lower limit is 1500 g · cm 2 and the upper limit is 2700 g
Cm2, preferably from 2000 gcm2 to 25
It is better to be within the range of 00 g · cm 2.

The shape of the face portion of the head is obtained by calculating the ratio of the length in the left-right direction to the length in the vertical direction with respect to the sweet spot position, based on the ratio of the moment of inertia set in the above range. It is preferable to make it large. As a result, it is possible to hit the ball without feeling uncomfortable with the head shape of the conventional image. Specifically, it is preferable to set the left-right length: up-down length in the range of 6: 4 to 7: 3. The shape and size of the head are not limited as long as the condition of the moment of inertia is satisfied, but is preferably 220 cc or more in consideration of ease of hitting.

[Iron type] From the above-described hitting point investigation, it is preferable that the ratio of Lx to Ly in the head is larger than that of 7.4: 2.6, and the ratio of Ly is preferably larger. 7.2: 2.8 to 6.0: 4.0
, And further from 7.0: 3.0 to 6.5: 3.5.
It is preferable to form them so as to fall within the range described above.

When the head is formed such that the ratio of the moment of inertia is within the above range, if the value of the moment of inertia in the toe-heel direction is too low, the flying distance and the direction will vary with the variation of the hit points in the toe-heel direction. Both are unstable, and if too high, it is difficult to maintain the moment of inertia in the top-sole direction to some extent, so the lower limit is 1500 g · c.
m2, the upper limit being 3800 g.cm2, preferably 23
It is preferable to be within the range of 00 g · cm 2 to 3500 g · cm 2. Also, if the value of the moment of inertia in the top sole direction is too low, the flight distance and trajectory will be unstable with respect to the variation of hit points in the vertical direction, and if it is too high, the moment of inertia in the toe-heel direction will be maintained to some extent. Because it becomes difficult, the lower limit is 700 g · cm 2 and the upper limit is 1500
g · cm 2, preferably 850 g · cm 2 to 13
It is better to be within the range of 00 g · cm 2.

As in the case of the wood type, the shape of the face portion of the head is such that, based on the sweet spot position, the ratio of the left-right length to the up-down length is determined by the ratio of the moment of inertia set in the above range. It is preferred that the length ratio be made large. As a result, it is possible to hit the ball without feeling uncomfortable with the head shape of the conventional image. The face part is not limited to such a shape, but it is also possible to form a larger proportion in the up and down direction, and it is also possible to make the shape more emphasized and appeal the characteristics to the player It is. As described above, if the condition of the moment of inertia is satisfied, the shape and size are not limited.

Further, various materials can be used for the materials constituting the above-mentioned types of heads. For example, as a hard material having a relatively low specific gravity, for example, a titanium alloy (6Al-4V, 15Mo-5Zr-3Al, 1
It is possible to use a titanium-based material such as 5V-3Cr-3Sn-3Al) or pure titanium, an amorphous alloy, or FRP. As means for adjusting the moment of inertia, a weight body having a relatively large specific gravity, such as a tungsten copper alloy or a nickel tungsten alloy, is appropriately attached or incorporated, or a predetermined position of a head portion is cut, or a thin-walled body is formed. It is possible to realize this. Note that the configuration and material of the neck portion into which the shaft is inserted can also be used as a means for adjusting the moment of inertia.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a head having the above-described structure will be described below with reference to the accompanying drawings. 1 and 2 show a first embodiment of a wood type. FIG. 1 (a) is a front view, FIG. 1 (b) is a bottom view, and FIG. 2 (a) is A in FIG. 1 (a). FIG. 2B is a sectional view taken along the line A, and FIG.
It is sectional drawing along the BB line of (a). A-A
The line corresponds to half the maximum height H of the head.

The head 1 includes a head body 3 formed in a hollow shape and a neck 5 into which a shaft is inserted. The head body 3 is formed into a hollow shape by forming outer shell portions such as a face portion 3a, a crown portion 3b, a sole portion 3c, a toe portion, a heel portion 3d, and a back portion 3e into members of an arbitrary shape and welding them. Have been. in this case,
Titanium alloy (6Al-4V) as the material constituting each part
Is used.

In the above configuration, the thickness ta of the face portion 3a is 3.0 mm, and the thickness tb of the crown portion 3b is 1.3.
And the thickness tc of the sole portion 3c is 1.4 to 1.
7 mm, thickness td of toe portion and heel portion 3d is 0.7
~ 1.2mm, thickness te of back part 3e is 1.5mm
The thickness of the toe-heel portion, which contributes to the increase of the moment of inertia in the toe-heel direction, is reduced to td <tb, tc. The thickness ratio of Ly in Lx: Ly can be increased, and further, as shown in FIG. 2A, between the face portion and the crown portion, and between the crown portion and the back portion. And a thick portion between the sole portion and the face portion. These thick portions are those in which the mass is efficiently dispersed at a position farther from the center of gravity G, and the moment of inertia in the vertical direction can be efficiently increased. The thickness tg of the thick portion between the crown portion and the back portion is set to 5.0 mm, and the other thick portions are formed to have substantially the same thickness.

The overall shape of the head is such that its maximum height H is 60 mm, its width W is 86 mm, and its longitudinal length L is 85 mm.
It is configured so that the difference between the maximum height and the width is smaller than that of the conventional type (in the conventional type, H is about 49 mm and W is about 98 mm). That is, by decreasing the width W and increasing the height H, it is possible to increase the ratio of Ly in Lx: Ly described above.

[0023] By forming the head as described above, the moment of inertia of the lateral direction 2470g · cm ^2, the moment of inertia in the vertical direction is 2100 g · cm ² becomes, L
x: Ly is 5.4: 4.6.

FIGS. 3A and 3B show a second embodiment of the wood type. FIG. 3A is a front view, FIG. 3B is a bottom view, and FIG. 3C is along a line CC passing through the center of gravity of FIG. FIG.

In this embodiment, the overall shape of the head body is configured such that its maximum height H is 56 mm, its width W is 96 mm, and its front and rear length L is 95 mm. I have. For this reason, it becomes possible to use it without a sense of incongruity.

The thickness ta of the face portion 3a is 2.5
mm, the thickness tb of the crown portion 3b is 1.2 mm, the thickness tc of the sole portion 3c is 1.4 mm, the thickness td of the toe portion and the heel portion 3d is 0.6 to 1.1 mm, and the thickness of the back portion 3e. The thickness te is 1.5 mm, and is formed so that td <tb, tc. As for the material constituting each part, the face part 3a is made of a high-strength titanium alloy (15Mo-5Zr-3).
Al) and the other parts are high-strength titanium alloys (1
5V-3Cr-3Sn-3Al).

The weight body 10 is attached to the front end of the crown 3b, the front end of the sole 3c, and the back 3e. By attaching the weight body 10 to such a position, the mass can be efficiently dispersed and arranged at a position farther from the center of gravity G, and the moment of inertia in the vertical direction can be efficiently increased. As the material constituting the weight body, a material having a specific gravity of 12 or more such as tungsten or a tungsten alloy (tungsten copper alloy, nickel tungsten alloy, or the like) is used. As a method of attaching the weight body 10, press fitting, brazing, bonding, or the like is used for each part.

[0028] By forming the head as described above, the moment of inertia of the lateral direction 2700 g · cm ^2, the moment of inertia in the vertical direction is 2300 g · cm ² becomes, L
x: Ly is 5.4: 4.6.

FIGS. 4A and 4B show a third embodiment of the wood type, in which FIG. 4A is a front view, FIG. 4B is a bottom view, and FIG. 4C is along a DD line passing through the center of gravity of FIG. FIG.

In this embodiment, the overall shape of the head body is configured such that the maximum height H is 56 mm, the width W is 96 mm, and the front and rear length L is 95 mm. I have. For this reason, it becomes possible to use it without a sense of incongruity.

The thickness ta of the face portion 3a is 2.5
mm, the thickness tb of the crown portion 3b is 1.2 mm, the thickness tc of the sole portion 3c is 1.4 mm, the thickness td of the toe portion and the heel portion 3d is 0.6 to 1.1 mm, and the thickness of the back portion 3e. The thickness te is 1.5 mm, and is formed so that td <tb, tc. As for the material constituting each part, the face part 3a is made of a high-strength titanium alloy (15Mo-5Zr-3).
Al) and the other parts are high-strength titanium alloys (1
5V-3Cr-3Sn-3Al).

The weight body 20 is attached to the toe at the front end of the crown 3b, the front end of the sole 3c, and the back 3e. A cylindrical weight 25 is also attached to the uppermost region of the neck 5 so as to surround the neck 5. The cylindrical weight body 25 has a thickness ts of 1.
2 mm, length L1 is 30 mm, and it is press-fitted to the neck 5.

By attaching the weight body 25 to the neck as described above and attaching the weight body 20 to the toe at the front end side of the crown 3b, the weight is dispersed in the toe-heel direction,
The right and left moments of inertia can also be efficiently improved. In addition, each weight 2
By attaching 0 and 25, the mass can be efficiently dispersed and arranged at a position farther than the center of gravity G, and the moment of inertia in the vertical direction can be efficiently increased. The material constituting the weight body has a specific gravity of 12 such as tungsten or a tungsten alloy (tungsten copper alloy, nickel tungsten alloy, etc.) as described above.
The above materials are used. As a method of attaching the weight body 20, press fitting, brazing, bonding, or the like is used for each part.

By forming the head as described above, the moment of inertia in the horizontal direction is 2840 g · cm ² , the moment of inertia in the vertical direction is 2400 g · cm ² , and L
x: Ly is 5.42: 4.58.

FIGS. 5A and 5B show a first embodiment of the iron type. FIG. 5A is a rear view, and FIG. 5B is a cross-sectional view taken along the line EE passing through the center of gravity of FIG.

The head 30 has a structure in which a neck 32 and a frame 35 having an opening are formed integrally, and a face portion 37 is attached so as to close the opening. May be used). The neck 32 and the frame 35 are integrally formed of soft iron, stainless steel, maraging steel, or the like, and the face portion 37 is formed of soft iron, stainless steel, maraging steel, armet, or the like. In this case, the toe portion 35a of the frame 35 has a height H of 60 mm and a width W of the sole of 80 mm, compared to a conventional type having a height H of 45 mm and a width W of 97 mm.
It is formed so that the difference between them is small (the measurement standard of the width is measured with reference to the position P at a radius height of 21.3 mm of the ball). Also, the top portion 35 of the frame 35
b has a length Lt of 10 mm and a thickness t3 of 3 to 8 mm
The sole portion 35c has a length Ls of 25 m.
m and thickness t4 are 6 to 12 mm, which are longer and thicker than the conventional type to improve the moment of inertia in the vertical direction.

The thickness t1 of the toe portion 35a of the frame 35
Is 3.0 mm, and the thickness t2 of the face portion 37 is 2.0 mm.
The thickness is reduced to reduce the mass, and the amount is dispersed in the top portion 35b and the sole portion 35c. In this way, by efficiently distributing the mass at a position farther than the center of gravity G, the moment of inertia in the vertical direction can be efficiently increased.

[0038] By forming the head as described above, the moment of inertia of the lateral direction 1700 g · cm ^2, the moment of inertia in the vertical direction is 850 g · cm ² becomes, L
x: Ly is 6.67: 3.33.

FIGS. 6A and 6B show a second embodiment of the iron type, in which FIG. 6A is a rear view, and FIG. 6B is a sectional view taken along line FF passing through the center of gravity of FIG.

The head 30 has a structure in which a neck 32 and a frame 35 having an opening are formed integrally, and a face portion 37 is attached so as to close the opening. The neck 32 and the frame body 35 are integrally formed of stainless steel, maraging steel, titanium alloy, or the like. The face portion 37 is made of a metal material having a high specific strength, such as a titanium alloy, pure titanium, or an amorphous alloy, FRM, or FRP. (If the neck, frame, and face are made of the same material, they may be integrally formed.) In this case, the toe portion 35a of the frame 35 has a height H of 55 mm and a width W of the sole of 9 mm.
5 mm, the width is wider than that of the embodiment shown in FIG. 5, and it is slightly closer to the conventional type, so that uncomfortable feeling during addressing and hitting is reduced. Also, the top portion 35b of the frame 35
Has a length Lt of 10 mm and a thickness t3 of 3 to 8 mm, and the sole 35 c has a length Ls of 22 m.
m and a thickness t4 of 6 to 12 mm, and a weight body 40 made of a material having a specific gravity of 12 or more such as tungsten or a tungsten alloy (tungsten copper alloy, nickel tungsten alloy, etc.) The directional moment of inertia is improved.

The thickness t1 of the toe portion 35a of the frame 35
Is 3.0 mm, and the thickness t2 of the face portion 37 is 2.6 mm.
The thickness is reduced to reduce the mass, and the amount is dispersed in the top portion 35b and the sole portion 35c. As described above, by efficiently distributing and arranging the mass at a position farther than the center of gravity G, the moment of inertia in the vertical direction can be increased more efficiently.

By forming the head as described above, the moment of inertia in the left-right direction is 2050 g · cm ² , the moment of inertia in the vertical direction is 920 g · cm ² , and L
x: Ly is 6.90: 3.10.

FIGS. 7A and 7B show a third embodiment of the iron type. FIG. 7A is a rear view, and FIG. 7B is a cross-sectional view taken along the line GG passing through the center of gravity of FIG.

The head 30 has a structure in which a neck 32 and a frame 35 having an opening are formed integrally, and a face portion 37 is attached so as to close the opening. The neck 32 and the frame body 35 are integrally formed of stainless steel, maraging steel, titanium alloy, or the like. The face portion 37 is made of a metal material having a high specific strength, such as a titanium alloy, pure titanium, or an amorphous alloy, FRM, or FRP. (If the neck, frame, and face are made of the same material, they may be integrally formed.) In this case, the toe portion 35a of the frame 35 has a height H of 55 mm and a width W of the sole of 9 mm.
5 mm (measured at the lower end position), which is wider than the embodiment shown in FIG. 5 and slightly closer to the conventional type, thereby reducing uncomfortable feeling when hitting a ball. The top portion 35b of the frame 35 has a length Lt of 10 mm and a thickness t3 of 3 mm.
The sole portion 35c has a length Ls
Is 22 mm and the thickness t4 is 6 to 13 mm, and tungsten or tungsten alloy (tungsten copper alloy, nickel tungsten alloy, etc.)
For example, the weight body 40 made of a material having a specific gravity of 12 or more is attached to improve the moment of inertia in the vertical direction. In this embodiment, similarly to the above-described third embodiment of the wood type (see FIG. 4), the top portion 35b is provided on the toe side.
The weight 40 is attached, and a cylindrical weight 45 is attached to the uppermost region of the neck 32. The cylindrical weight body 45 has a thickness of 1.2 m similarly to the configuration shown in FIG.
m, 30 mm in length, and press-fit to the neck 32.

Thus, the weight body 45 is attached to the neck,
By attaching the weight body 40 to the toe portion side of the top portion 35b, the weight is dispersed in the toe-heel direction, and the right and left moments of inertia can be efficiently improved.

The thickness t1 of the toe portion 35a of the frame 35
Is 3.0 mm, and the thickness t2 of the face portion 37 is 2.6 mm.
The thickness is reduced to reduce the mass, and the amount is dispersed in the top portion 35b and the sole portion 35c. In this way, by efficiently distributing the mass at a position farther than the center of gravity G, the moment of inertia in the vertical direction can be efficiently increased.

Further, in this embodiment, the toe side and the heel side of the frame body 35 are notched in a concave shape as shown in the figure, and the mass in the same region as the center of gravity in the vertical direction is reduced, so that the inertia in the vertical direction is reduced. The moment is increased more efficiently.

[0048] By forming the head as described above, the moment of inertia of the lateral direction 2070 g · cm ^2, the moment of inertia in the vertical direction is 950 g · cm ² becomes, L
x: Ly is 6.85: 3.15.

As described above, the embodiments of the head portion used in the golf club of the present invention are shown as wood type and iron type, respectively. However, these are merely examples, and the overall structure of the head is shown in FIG. However, the shape is not limited to the shape shown in FIG. That is, if the ratio of the moment of inertia in the left-right direction and the moment of inertia in the vertical direction around the center of gravity of the head is formed so as to satisfy the above-described conditions, the overall shape and materials used should be variously changed. Is possible.

[0050]

As described above, according to the present invention, the balance (ratio) of the value of the moment of inertia in the left-right (toe-heel) direction and the up-down (top-sole) direction around the center of gravity is optimized. The three requirements of flight distance, flight distance stability, and direction stability are achieved in a well-balanced manner.

[Brief description of the drawings]

FIG. 1 shows a first embodiment of a wood type,
(A) is a front view, (b) is a bottom view.

2A is a sectional view taken along line AA in FIG. 1A, and FIG. 2B is a sectional view taken along line BB in FIG. 1A.

FIG. 3 shows a second embodiment of a wood type,
(A) is a front view, (b) is a bottom view, (c) is C in (a).
Sectional drawing along the -C line.

FIG. 4 shows a third embodiment of the wood type;
(A) is a front view, (b) is a bottom view, (c) is D in (a).
Sectional drawing along the -D line.

FIG. 5 shows a first embodiment of the iron type;
(A) is a rear view, (b) is a cross-sectional view along the line EE of (a).

FIG. 6 shows a second embodiment of the iron type;
(A) is a rear view, (b) is a cross-sectional view along the line FF passing through the center of gravity of (a).

FIG. 7 shows a third embodiment of the iron type;
(A) is a rear view, and (b) is a cross-sectional view taken along line GG passing through the center of gravity of (a).

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Head, 3 ... Head body, 5 ... Neck, 10, 2
0,25 ... weight body, 30 ... head, 32 ... neck, 35
... frame, 40, 45 ... weight.

Claims (4)

[Claims] 1. A wood type golf club,
The ratio (Lx: Ly) between the moment of inertia in the toe-heel direction and the moment of inertia in the top-sole direction around the center of gravity of the head is from 6.0: 4.0 to 5.0: 5.
A golf club characterized by being set to a range of 0. 2. The golf club according to claim 1, wherein the values of the moment of inertia in the toe-heel direction and the moment of inertia in the top-sole direction are each 1500 g · cm ² or more. 3. The golf club according to claim 1, wherein the head has a volume of 220 cc or more. 4. In an iron type golf club, the ratio (Lx: Ly) of the moment of inertia in the toe-heel direction to the moment of inertia in the top-sole direction around the center of gravity of the head is 7.4: 2.6. A golf club, wherein the proportion of Ly is increased.