JP2003236025A - Wood club head - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wood club head which has a mass adjusting mechanism for the accurate and efficient control of the inclination of the principal axes of inertia and allows the limiting of the process of mounting a mass adjusting part to the mass adjusting mechanism. <P>SOLUTION: In the wood club head 1, a head outer shell part 4 is formed so that the long axis C of a weight housing chamber 7 of the mass adjusting part 6 extends parallel along a back part side 1B of a head body 2 in order to make the inclination of the axis I<SB>1</SB>, the axis I<SB>2</SB>and the axis I<SB>3</SB>of the principal axes of inertia adjustable after a hollow part 3 of the head body 2 is sealed up. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention limits a mass adjusting mechanism for accurately and efficiently controlling the inclination of the principal axis of inertia of a wood club head, and a step of mounting a mass adjusting section on the mass adjusting mechanism. It concerns the wood club head.

[0002]

2. Description of the Related Art Recent studies on wood club heads have revealed that variations in the ball striking direction of wood club heads can be improved by tilting the principal axis of inertia of the head body.

However, in order to adjust the inclination of the principal axis of inertia to a position close to an ideal position, it is a fact that a heavy load must be added at an optimum position.

Therefore, Japanese Unexamined Patent Publication No. 6-2967 shown in FIG.
Head body 2 at the center of gravity or in any direction, such as No. 16
In order to adjust the moment of inertia of 0 A, the head body 2
A general case is the golf club head 20 in which the mass body 21 is disposed in the hollow portion 20B of 0A, and various methods such as welding, bonding, and press fitting are known as the fixing method.

Further, as in Japanese Unexamined Patent Publication No. 10-234902 shown in the enlarged cross-sectional view of the main part of FIG. 14, a thick portion 23 is provided in the sole portion 22, the backside portion, the toe portion, etc., and the thick portion 2
A golf club head 2 using a mass adjusting member 25 in which a female screw 24 is attached to the golf ball 3 and a mass body 25B made of a material having a large specific gravity is interposed inside and a male screw 25A is formed.
6 is also known.

In addition, Japanese Patent Publication No. 10-3 shown in FIG.
Like No. 6831, in the wood club head 27, the outer shell body 29 is integrally formed on the surface of the inner shell body 28, and the inner shell body 28 is exposed on the back side 30 of the outer shell body 29. And from the back side 30 to the face side 31 of the inner shell 28.
A wood club head 27 having a structure in which a hollow portion 32 is formed over the entire length and a mass adjusting body 33 is housed in the hollow portion 32 is also known.

Further, the registered utility model No. 3029 shown in FIG.
Like No. 422, the iron club head 34 has a perforation portion 37 formed in the direction from the toe portion 35 to the heel portion 36. The perforation portion 37 accommodates the mass adjusting member 38 and the plug 3
Iron club head 3 that can be contained by 9
4 is also known.

[0008]

Further, as shown in FIGS. 13 and 14, the long axis of the mass adjusting body is arranged perpendicular to the wall surface. However, in the wood club head, With the increase in length and size, the allowable mass of the head main body of the wood club head is close to the limit. Therefore, it is necessary to efficiently control the inclination of the inertial spindle with a small mass.

On the other hand, most of the conventionally known mass adjusting structures for heads of wood club heads have a housing portion for housing a weight adjusting member formed on the sole member by welding, bonding, press fitting, fitting, or the like. In addition, in the case of adding a weight body to the inside of the head, a mass body is added at the stage of parts of the head, and then each part is integrated by welding or the like to form a head.

As described above, a weight greater than the weight adjustment is inevitably added due to the welding beat generated when the respective parts are integrated, and as a result, the inclination of the inertial spindle of the head varies, and the design As a matter of fact, there is a problem that the inclination of the principal axis of inertia cannot be controlled accurately.

In order to solve this problem, it is necessary to add mass after forming the closed space of the head.

As a mass adding means corresponding to this, holes or screw parts are provided in the toe part, the sole part and the back side part, and the mass is increased from these parts toward the hollow part of the head corresponding to the center of gravity of the head. Generally, a structure in which an accommodation portion for adjusting weight members is projected or a method for forming an accommodation portion for mass adjustment from the back side portion toward the face portion have been generally adopted.

However, particularly in the conventional structure for adjusting the mass arranged on the side wall, as shown in FIG. 15, the major axis of the mass adjusting body 33 is close to vertical to the side wall, so that mass is added. The center of gravity of the mass adjusting body 33 becomes closer to the center of gravity of the head, and the effect of adjusting the principal axis of inertia remarkably decreases.

[0014]

SUMMARY OF THE INVENTION The present invention is a wood club head having a hollow portion, in order to efficiently control the main spindle of inertia of the head main body with a small mass.
The direction of the long axis C of the weight storage chamber that stores the weight member for mass adjustment in the position most effective for adjusting the inertial spindle is
The head outer shell is arranged so as to be parallel to the side surface of the head shell, and the structure in which the mass body can be added and fixed after the hollow portion of the head is formed is adopted.
It is possible to supply a wood club head having a structure in which the tilt angles of the _1- axis, the I ₂ -axis, and the I ₃ -axis can be adjusted as designed.

[0015]

According to the first aspect of the present invention, in order to accurately control the inertial spindle according to the purpose, a columnar weight member can be mounted after the hollow portion of the head is formed,
In order to increase the efficiency of adjustment, a wood club head is arranged so that the direction of the long axis C of the weight storage chamber that stores the weight member for mass adjustment is parallel to the side surface shape of the head outer shell. is there.

That is, according to claim 1 of the present invention, in the wood club head 1 having the hollow portion 3 provided with the mass adjusting portion 6, the mass adjusting portion 6 is arranged on the side surface 1B of the back portion of the head body 2. In addition, the weight storage chamber 7 of the mass adjusting portion 6 is arranged substantially parallel to the back portion side surface 1B, and the weight member 8 is detachably attached to the wood club head 1.

According to the second aspect of the present invention, the mass adjusting section 6 is provided.
Is located at a position where the head side surface portion 5 intersects a plane including the center of gravity G of the head, including a straight line perpendicular to the ground, and having an angle in the range of 23 degrees to 57 degrees with respect to the tangent line A of the face surface 1A. The wood club head 1 is characterized by the above.

According to claim 3 of the present invention, the mass adjusting portion 6 is provided.
Is located at a position where the head side surface portion 5 intersects with a plane including the center of gravity G of the head, including a straight line perpendicular to the ground, and having an angle in the range of 28 degrees or more and 52 degrees or less with respect to the tangent line A of the face surface 1A. The wood club head 1 is characterized by the above.

According to claim 4 of the present invention, the mass adjusting portion 6 is provided.
Of the three principal axes of inertia of the wood club head 1 in which
Any one of the ₁ axis, the I ₂ axis, and the I ₃ axis is the wood club head 1 having an angle of −10 degrees or more and 9 degrees or less with respect to the tangent line A of the face surface 1A.

[0020]

EXAMPLES Next, specific examples of the present invention will be described. In the embodiment shown in FIGS. 1 to 3, after closing the hollow portion 3 of the head main body 2, the inertial principal axes I ₁ axis, I ₂ axis, I
_The head outer shell portion 4 is formed so that the major axis C of the weight storage chamber 7 of the mass adjusting portion 6 extends in parallel along the back surface 1B of the head body 2 so that the inclination of the _three axes can be adjusted. It is a characteristic wood club head 1.

The tip 7B of the weight storage chamber 7 is closed and the weight member 8 is stored in the weight storage chamber 7,
Although the insertion opening side 7A may be fixed by adhesion, in the present invention, the hexagon socket head cap screw 8B in which the threaded portion 8A is formed on the weight member 8 is used to enable fine adjustment in the weight storage chamber 7. It is desirable to use the hexagon socket head cap bolt 8B in order to prevent the golfer from seeing the crown of the screw portion 8A when holding the wood club head 1. After the hexagon socket head cap screw 8B is screwed on, it is desirable to fix it with a rubber adhesive or an instant adhesive to prevent loosening.

In addition, in order to improve the durability of the hexagon socket head cap screw 8B when the wood club head 1 is repeatedly loaded, the weight member 8 should be short. Therefore, it is desirable that the weight member 8 is made of a material that is heavier than the material that forms the head body 2, and if possible, the weight member 8 should have a specific gravity of 7 or more.

The weight member 8 to be used is preferably made of iron, lead, cobalt, tungsten, beryllium-nickel alloy, or the like. Some of the above materials have poor workability and are not suitable for forming a screw by themselves.

Therefore, as shown in FIG. 4A, the screw tip portion 8C is formed of a metal material having good workability and high hardness, and the weight member 8 is formed of a metal having a high specific gravity. Hexagon socket head cap bolt 8B in a form in which the portion 8C and the weight member 8 are pressure-welded and joined together as an inclined material.
It is also possible to produce and use. At this time, it is possible to form the threaded portion 8A on the weight member 8. In this way, the screw tip portion 8 is made of a metal material having high hardness.
By forming C, the durability of the screw portion is improved, and the weight member 8 can be taken in and out any number of times.
The weight member 8 can be adjusted according to the condition of the golfer at that time.

In addition, as shown in FIG. 4B, it is possible to process the metal such as tungsten by powder metallurgy to integrally form the screw portion 8A and use it as the weight member 8.

FIG. 3 shows another embodiment. The weight storage chamber 7 is provided not in the center of the back side surface 1B but in the heel portion 1D.

Here, as shown in FIG. 5, I of the principal axis of inertia is
_{The 1-} axis, the I _2- axis, and the I ₃ -axis represent the moment of inertia of the wood club head 1 by an ellipsoid of inertia E around the center of gravity G of the head, and the inertia of the three principal axes of inertia orthogonal to the ellipsoid of inertia E. I is the axis showing the maximum value of the moment of inertia around the main axis.
₁ axis, the axis showing the minimum value is the I ₃ axis, and the axis showing the intermediate value between the maximum value and the minimum value is the I ₂ axis. However, the I ₁ axis is perpendicular to the drawing and includes the center of gravity G of the head.

Although the inclination of the principal axis of inertia of the wood club head is slightly different depending on the shape and thickness design, as shown in FIG.
Due to the mass of the hosel portion 1F, in general, the I ₃ axis often falls within the range of −15 degrees to −25 degrees with respect to the tangent line A of the face surface 1A. In FIG. 6, it is described as a plane B that is perpendicular to the ground through the center of gravity G of the head and is parallel to the tangent line A of the face surface 1A for easy description.

By adjusting this inclination, the I ₃ axis is the face surface 1
The directionality of the hit ball is improved by making it close to the tangent line A of A. Here, the tangent line A of the face surface 1A is
In a plane perpendicular to the target point of the trajectory, parallel to the ground,
Further, it is a straight line which passes through the center of gravity G of the head and is in contact with a portion called a sweet spot SS which is an intersection point perpendicular to the face surface 1A.

Even in a wood club head having a hook face whose face angle is directed to the left with respect to the target point or an open face whose face angle is directed to the right, the tangent line A of the face surface 1A is in a plane perpendicular to the target point of the trajectory. The posture is fixed.

When the I ₃ axis is parallel to the tangent line A of the face surface, neither slice spin nor hook spin occurs at the hitting point above or below the sweet spot SS.

However, in the general head as described above whose I ₃ axis is not parallel to the tangent line A of the face surface, when the hit point is above the sweet spot SS, the head rotates in the direction in which the loft increases during a collision. The rotation axis of the head is not parallel to the tangent line A of the face surface and is close to the direction of the I ₃ axis having the smallest moment of inertia, so that the hitting point of the head is not only on the upper side, Although it slightly moves to the heel portion 1D side, as a result, slice spin occurs due to the gear effect.

Here, the gear effect means that at the impact point other than the sweet spot SS, the rotational direction of the head and the rotational direction of the ball at the time of impact seem to rotate in the opposite directions due to the meshing of gears (gears). So it is what is called the gear effect.

The larger the angle of the I ₃ axis with the tangent line A of the face surface, the larger the slice amount.

On the other hand, in the case of a hit point below the sweet spot SS, the head starts to rotate in a direction in which the loft becomes smaller during a collision, but its rotation axis is also a rotation axis close to the direction of the I ₃ axis. As a result, the hitting portion of the head moves not only to the lower side but also to the heel portion 1D side slightly, and as a result, slice spin occurs due to the gear effect. Therefore, if the I ₃ axis is closer to parallel to the tangent line of the face surface, slice spin is less likely to occur and the directionality of the hit ball can be improved.

Here, in order to adjust the inclination of the I ₃ axis,
Describe the calculation formula for obtaining the most efficient position of the weight member. As shown in FIG. 5, assuming that the I ₃ axis and the I ₂ axis coincide with the x axis and the y axis on the xy plane, respectively, the inertia tensor is as shown in Equation 1 below.

[0037]

## EQU1 ## When the masses of m / 2 and m / 2 are added to the position of the distance r from the center of gravity G of the head at the angle of the x-axis and .theta., The inertia tensor becomes as shown in the following Expression 2.

[0038]

Where α is the I ₃ axis after the weight member is attached and x
The inclination angle with respect to the axis is used, and from this formula, α is as shown in the following formula 3, formula 4, formula 5, formula 6, and formula 7.

[0039]

[Equation 3]

[Equation 4]

[Equation 5]

[Equation 6]

From Equation 7, the tilt angle α of the I ₃ axis with respect to the x axis after the weight member is attached can be obtained.

However, in a wood club head having a large head volume in recent years, the weight adjusting weight member can secure only a limited mass of 0.1 kg or the like in consideration of the strength, so As described above, it is difficult for the I ₃ axis to be in the range of −15 degrees to −25 degrees to be larger than 0 degrees due to the weight of the weight member.
Therefore, if the condition that maximizes α is the optimum condition, and θ at that time is θ ₁ , then the following formula 8 is obtained.

[0041]

If the [number 8] _k 1> 1 and, θ _1, the following equation (9), is as shown in Equation 10.

[0042]

[Equation 9]

The most efficient angle of the weight member can be obtained by the following equation. From this equation, it can be seen that the efficient angle varies depending on the values of the principal moments of inertia I ₃ and I ₂ of the head before mounting the weight member, the mass m of the weight member, and the value of the distance r. Actually, m = 0.1 to 0.2 (kg) r = 0.03 to 0.04 (m) I ₃ = 0.00015 to 0.00018 (kg · m ² ) I ₂ = 0.00022 to When 0.00025 (kg · m ² ) is input to the formula, the results shown in Table 1 are obtained.

Incidentally, in FIG. 6, because of the symmetry, -1
Since 80 to -90 degrees corresponds to 0 to 90 degrees and -90 to 0 degrees corresponds to 90 to 180 degrees, in Table 1, the weight member indicates α at an angle of 0 to 180 degrees.

Therefore, θ ₁ is in the range of 48 to 72 degrees. However, as described above, in general, the wood club head may have the I ₃ axis within the range of −15 to −25 degrees with respect to the tangent line A of the face surface, as shown in FIG. Many, if you add this as an average of -20 degrees,
If the weight member is in the range of 28 to 52 degrees shown in FIG. 7, it is possible to most efficiently bring the I ₃ axis close to the tangent line of the face. Rather than -20 ° average, if considering a 15 to 25 degrees, parallel if there is weight member in the range of 23 to 57 degrees, in a variety of wood club head, most efficiently, the I ₃ axis and the tangent of the face It is possible to approach. At that time, from α in Table 1, the I ₃ axis rotates on the xy plane by ₃ to 27 degrees.

[0045]

[Table 1] Table 1 θ ₁ and α for m, r, I ₂ and I ₃

Although the case where the number of weight members having a mass of m / 2 is two is simulated, as is clear from the process of calculation, the calculation is also performed when the number of weight members 8 having a mass of m is one. The results are exactly the same. However, the center of gravity G of the head moves, and other characteristics of the head change, such as the distance between the center of gravity G of the head and the axis of the shaft, which is commonly called the distance of the center of gravity. When the weight members 8 are two, depending on the angle, when the weight members 8 are on the face surface 1A side, the distance r of the weight members 8 cannot be increased to about 0.2 m at the maximum, so in actual design. It is possible to control the I ₃ axis more efficiently in the case of one.

As an example, No. 1 in Table 1 is used. In case of 16,
FIG. 8 illustrates the inclination angle α of the I ₃ axis with respect to the x axis depending on the arrangement angle θ of the weight member 8.

As can be seen from FIG. 8, when the arrangement angle θ of the weight member 8 is 59 degrees and the maximum inclination angle α, the I ₃ axis of the wood club head before the arrangement of the weight member is relative to the tangent line A of the face surface 1A. When the arrangement angle θ of the weight member is 39 degrees, that is, in the case of one weight member, it simply corresponds to the intermediate position between the heel portion and the back portion of the wood club head 1. To do.

Although it has been described that the rotation axis is close to the I ₃ axis when hitting the point above or below the sweet spot SS, in reality, from the center of gravity G of the head in FIG.
The rotation is started with a vector to a point A that is in contact with the inertial ellipsoid as a perpendicular line of the X axis, as a rotation axis. However, the I ₃ axis and the rotation axis are in a substantially proportional relationship, and if the I ₃ axis has a large angle with respect to the tangent line of the face, the rotation axis also has a large angle with respect to the tangent line of the face. The most efficient position of the weight member was determined based on the _three axes.

When the most efficient position for adjusting the inclination of the main axis is obtained, the position including the center of gravity G of the head, perpendicular to the ground, and 2 with respect to the tangent A of the face 1A is determined.
The efficiency is improved at the position where it intersects with a plane having an angle of 3 degrees or more and 57 degrees or less and the head side surface, and the position having a plane having an angle of 28 degrees or more and 52 degrees or less and the intersection line of the head side surface portion intersects. It was found to peak when placed in.

When the wood head is normally assembled, the head contains an error in the inclination of the principal axis of inertia due to variations in parts and welding. Therefore, if the inertial spindle is adjusted in a process closer to the final process, the variation in the final product can be reduced. Therefore, as in the invention of the present application, by positioning, adjusting and fixing the mass adjusting body after forming the hollow portion, the accuracy of the inclination angle of the inertial spindle can be extremely improved.

In this way, the I of the wood club head is
_By setting the _three axes at an angle of -10 degrees or more and 9 degrees or less with respect to the tangent line A of the face surface 1A, it is possible to provide the wood club head 1 having good directionality.

To explain the present invention more clearly,
A general conventionally known golf club head 50 has a principal axis of inertia as shown in FIG.

The principal axis of inertia is the tangent line A of the face surface 1A.
Has a tilt angle of at least −15 ° to −25 °.

In the present invention, the angle between the principal axis of inertia and the contact surface is 0 ° (90 °) as shown in FIG.
It is desirable to be in the vicinity.

Explaining another embodiment of the present invention shown in FIG. 9, the mass of the weight member 80 for adjusting the inertial spindle inclination used is 20 g. As can be seen from this example, in order to effectively tilt the principal axis of inertia, the weight member 80 needs to have a mass of 7% to 15% of the total mass of the head.

If all of this mass is arranged on the wall surface of the heel portion, the position of the center of gravity of the head will move to the side of the weight member for adjustment, which may impair the action and effect.

In order to avoid this, a weight member for adjustment can be arranged on the side surface of the toe portion with the center of gravity of the head as a target point.

FIG. 12 is a graph showing the inclination angle α of the I ₃ axis and the left and right positions of the falling point of the hit ball. That is, in a 44-inch-long club, a head having a mass of 190 g was mounted with various weights of lead, which is a weight member, of 30 g, on various side wall portions of the head body with a double-sided tape, and a robot test was conducted.

Before assembling the head to the shaft, the tilt angle α of the I ₃ axis was measured with the weight members mounted at various positions.

In the robot test, FIG. 12 shows the result of measuring the left and right positions of the fall point of the carry while changing the position of the weight member while swinging the grip and swinging the grip. As shown in FIG. 12, it has been found that the larger the inclination angle α of the I ₃ axis is, the more rightward the falling point of the hit ball is.

If all of this mass is placed on the heel wall,
The position of the center of gravity of the head may move to the side of the weight member for adjustment, which may impair the action and effect. In order to avoid this, it is possible to deal with this by disposing an adjusting weight on the side surface on the toe portion side with the center of gravity of the head as the target point.

Depending on the form of the head, the position of the weight member on the toe side may touch the face. Providing a weight member on the ball striking face affects the flight distance performance and strength. In this case, therefore, it is desirable to provide it on the side wall on the toe portion side near the face or on the sole portion on the toe portion side.

The size of the golf club head, the size of the inertia ellipse, and the inclination of the principal axis of inertia are determined substantially uniquely by the shape, mass, and mass distribution of the head.

[0065]

As described above, according to the invention of the present application, the weight of the weight adjusting chamber is arranged in the outer shell of the head so that the major axes of the weight accommodating chambers extend in parallel along the side wall of the head body. Can efficiently adjust the principal axis of inertia and improve the directionality.

Further, it becomes possible to finely adjust the position of the mass body by providing screws to finely adjust the inclination of the inertial spindle.

Further, in order to reduce the length of the weight storage chamber in the long axis direction, a heavy metal having a specific gravity of 7 or more is used, or a weight member in which an easily workable material and a difficultly workable heavy metal material are integrally joined. By utilizing, it is possible to improve the durability of the weight member.

Further, by specifying the position where the arrangement position of the weight member can be adjusted most effectively, the inertial spindle can be adjusted with a small mass so that the head is not enlarged or thinned. can do.

Further, since the adjusting weight member can be fixed to an arbitrary position near the final step of the head, the inertial spindle can be adjusted in consideration of variations in manufacturing of the head, and variations in the inertial spindle of individual heads can be prevented. Can make recommendations.

As a result of the adjustment as described above, the I ₃ axis of the principal axis of inertia becomes perpendicular to the tangent to the face surface, so that the directionality of the hit ball of the wood club head can be improved.

[0071]

[Brief description of drawings]

FIG. 1 is a perspective view showing a wood club head of the present invention.

FIG. 2 is a perspective view showing a situation in which a weight member is attached to the wood club head of the present invention.

FIG. 3 is an enlarged sectional view of an essential part of the wood club head of the present invention.

FIG. 4 is a perspective view showing a weight member used in the wood club head of the present invention.

FIG. 5 is a graph of an inertial ellipsoid of a wood club head.
I of the principal axis of inertia_TwoAxis, I _ThreeThe schematic diagram which shows the inclination angle of a shaft.

FIG. 6 is a schematic diagram showing a range of inclination angles of the I ₃ axis of the principal axis of inertia of a conventionally known wood club head.

FIG. 7 is a schematic diagram showing the range of the inclination angle of the I ₃ axis of the principal axis of inertia of the wood club head of the present invention.

FIG. 8 is a graph showing a position where a weight member is arranged and an inclination angle of a principal axis of inertia of a wood club head.

FIG. 9 is a perspective view showing another embodiment of the wood club head of the present invention.

FIG. 10 is a perspective view showing tilt angles of I ₁ axis, I ₂ axis, and I ₃ axis of inertia principal axes of a conventionally known wood club head.

FIG. 11 is a wood club head of the present invention.
Of the principal axis of inertia at ₁Axis, I_TwoAxis, I_ThreeAxis tilt angle
FIG.

FIG. 12 is a graph showing the inclination angle of the I ₃ axis of the principal axis of inertia of the wood club head of the present invention and the directionality of a hit ball.

FIG. 13 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

FIG. 14 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

FIG. 15 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

FIG. 16 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

[Explanation of symbols]

1 Wood club head 1A face surface 1B Back side 1C toe section 1D heel part 1E Crown part 1F Hosel part 2 head body 3 Hollow part 4 head outer shell 5 Head side part 6 Mass adjustment section 7 weight storage room 7A insertion port side 7B Tip side 8 weight members 8A screw part 8B Hexagon socket head cap screw 8C screw tip 20 head body 20A head body 20B hollow part 21 mass 22 Sole part 23 Thick part 24 female screw 25 Mass adjustment member 25A male screw 25B mass 26 golf club heads 27 Wood Club Head 28 Inner shell 29 outer shell 30 back side 31 Face side 32 cavity 33 Mass adjuster 34 Iron Club Head 35 Toe Division 36 Heel part 37 Perforated part 38 Mass adjustment member 39 stopper 80 Weight member A tangent B A plane parallel to the tangent to the face surface C long axis G head center of gravity G

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[Procedure amendment]

[Submission date] October 10, 2002 (2002.10.
10)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title of invention Wood club head

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention limits a mass adjusting mechanism for accurately and efficiently controlling the inclination of the principal axis of inertia of a wood club head, and a step of mounting a mass adjusting section on the mass adjusting mechanism. It concerns the wood club head.

[0002]

2. Description of the Related Art Recent studies on wood club heads have revealed that variations in the ball striking direction of wood club heads can be improved by tilting the principal axis of inertia of the head body.

However, in order to adjust the inclination of the principal axis of inertia to a position close to an ideal position, it is a fact that a heavy load must be added at an optimum position.

Therefore, Japanese Unexamined Patent Publication No. 6-2967 shown in FIG.
Head body 2 at the center of gravity or in any direction, such as No. 16
In order to adjust the moment of inertia of 0 A, the head body 2
A general case is the golf club head 20 in which the mass body 21 is disposed in the hollow portion 20B of 0A, and various methods such as welding, bonding, and press fitting are known as the fixing method.

Further, as in Japanese Unexamined Patent Publication No. 10-234902 shown in the enlarged cross-sectional view of the main part of FIG. 14, a thick portion 23 is provided in the sole portion 22, the backside portion, the toe portion, etc., and the thick portion 2
A golf club head 2 using a mass adjusting member 25 in which a female screw 24 is attached to the golf ball 3 and a mass body 25B made of a material having a large specific gravity is interposed inside and a male screw 25A is formed.
6 is also known.

In addition, Japanese Patent Publication No. 10-3 shown in FIG.
Like No. 6831, in the wood club head 27, the outer shell body 29 is integrally formed on the surface of the inner shell body 28, and the inner shell body 28 is exposed on the back side 30 of the outer shell body 29. And from the back side 30 to the face side 31 of the inner shell 28.
A wood club head 27 having a structure in which a hollow portion 32 is formed over the entire length and a mass adjusting body 33 is housed in the hollow portion 32 is also known.

Further, the registered utility model No. 3029 shown in FIG.
Like No. 422, the iron club head 34 has a perforation portion 37 formed in the direction from the toe portion 35 to the heel portion 36. The perforation portion 37 accommodates the mass adjusting member 38 and the plug 3
Iron club head 3 that can be contained by 9
4 is also known.

[0008]

Further, as shown in FIGS. 13 and 14, the long axis of the mass adjusting body is arranged perpendicular to the wall surface. However, in the wood club head, With the increase in length and size, the allowable mass of the head main body of the wood club head is close to the limit. Therefore, it is necessary to efficiently control the inclination of the inertial spindle with a small mass.

On the other hand, most of the conventionally known mass adjusting structures for heads of wood club heads have a housing portion for housing a weight adjusting member formed on the sole member by welding, bonding, press fitting, fitting, or the like. In addition, in the case of adding a weight body to the inside of the head, a mass body is added at the stage of parts of the head, and then each part is integrated by welding or the like to form a head.

As described above, a weight greater than the weight adjustment is inevitably added due to the welding beat generated when the respective parts are integrated, and as a result, the inclination of the inertial spindle of the head varies, and the design As a matter of fact, there is a problem that the inclination of the principal axis of inertia cannot be controlled accurately.

In order to solve this problem, it is necessary to add mass after forming the closed space of the head.

As a mass adding means corresponding to this, holes or screw parts are provided in the toe part, the sole part and the back side part, and the mass is increased from these parts toward the hollow part of the head corresponding to the center of gravity of the head. Generally, a structure in which an accommodation portion for adjusting weight members is projected or a method for forming an accommodation portion for mass adjustment from the back side portion toward the face portion have been generally adopted.

However, particularly in the conventional structure for adjusting the mass arranged on the side wall, as shown in FIG. 15, the major axis of the mass adjusting body 33 is close to vertical to the side wall, so that mass is added. The center of gravity of the mass adjusting body 33 becomes closer to the center of gravity of the head, and the effect of adjusting the principal axis of inertia remarkably decreases.

[0014]

SUMMARY OF THE INVENTION The present invention is a wood club head having a hollow portion, in order to efficiently control the main spindle of inertia of the head main body with a small mass.
The direction of the long axis C of the weight storage chamber that stores the weight member for mass adjustment in the position most effective for adjusting the inertial spindle is
The head outer shell is arranged so as to be parallel to the side surface of the head shell, and the structure in which the mass body can be added and fixed after the hollow portion of the head is formed is adopted.
It is possible to supply a wood club head having a structure in which the tilt angles of the _1- axis, the I ₂ -axis, and the I ₃ -axis can be adjusted as designed.

[0015]

According to the first aspect of the present invention, in order to accurately control the inertial spindle according to the purpose, a columnar weight member can be mounted after the hollow portion of the head is formed,
In order to increase the efficiency of adjustment, a wood club head is arranged so that the direction of the long axis C of the weight storage chamber that stores the weight member for mass adjustment is parallel to the side surface shape of the head outer shell. is there.

That is, according to claim 1 of the present invention, in the wood club head 1 having the hollow portion 3 provided with the mass adjusting portion 6, the mass adjusting portion 6 is arranged on the side surface 1B of the back portion of the head body 2. In addition, the weight storage chamber 7 of the mass adjusting portion 6 is arranged substantially parallel to the back portion side surface 1B, and the weight member 8 is detachably attached to the wood club head 1.

According to the second aspect of the present invention, the mass adjusting section 6 is provided.
Is located at a position where the head side surface portion 5 intersects a plane including the center of gravity G of the head, including a straight line perpendicular to the ground, and having an angle in the range of 23 degrees to 57 degrees with respect to the tangent line A of the face surface 1A. The wood club head 1 is characterized by the above.

According to claim 3 of the present invention, the mass adjusting portion 6 is provided.
Is located at a position where the head side surface portion 5 intersects with a plane including the center of gravity G of the head, including a straight line perpendicular to the ground, and having an angle in the range of 28 degrees or more and 52 degrees or less with respect to the tangent line A of the face surface 1A. The wood club head 1 is characterized by the above.

According to claim 4 of the present invention, the mass adjusting portion 6 is provided.
Of the three principal axes of inertia of the wood club head 1 in which
Any one of the ₁ axis, the I ₂ axis, and the I ₃ axis is the wood club head 1 having an angle of −10 degrees or more and 9 degrees or less with respect to the tangent line A of the face surface 1A.

[0020]

EXAMPLES Next, specific examples of the present invention will be described. In the embodiment shown in FIGS. 1 to 3, after closing the hollow portion 3 of the head main body 2, the inertial principal axes I ₁ axis, I ₂ axis, I
_The head outer shell portion 4 is formed so that the major axis C of the weight storage chamber 7 of the mass adjusting portion 6 extends in parallel along the back surface 1B of the head body 2 so that the inclination of the _three axes can be adjusted. It is a characteristic wood club head 1.

The tip 7B of the weight storage chamber 7 is closed and the weight member 8 is stored in the weight storage chamber 7,
Although the insertion opening side 7A may be fixed by adhesion, in the present invention, the hexagon socket head cap screw 8B in which the threaded portion 8A is formed on the weight member 8 is used to enable fine adjustment in the weight storage chamber 7. It is desirable to use the hexagon socket head cap bolt 8B in order to prevent the golfer from seeing the crown of the screw portion 8A when holding the wood club head 1. After the hexagon socket head cap screw 8B is screwed on, it is desirable to fix it with a rubber adhesive or an instant adhesive to prevent loosening.

In addition, in order to improve the durability of the hexagon socket head cap screw 8B when the wood club head 1 is repeatedly loaded, the weight member 8 should be short. Therefore, it is desirable that the weight member 8 is made of a material that is heavier than the material that forms the head body 2, and if possible, the weight member 8 should have a specific gravity of 7 or more.

The weight member 8 to be used is preferably made of iron, lead, cobalt, tungsten, beryllium-nickel alloy, or the like. Some of the above materials have poor workability and are not suitable for forming a screw by themselves.

Therefore, as shown in FIG. 4A, the screw tip portion 8C is formed of a metal material having good workability and high hardness, and the weight member 8 is formed of a metal having a high specific gravity. Hexagon socket head cap bolt 8B in a form in which the portion 8C and the weight member 8 are pressure-welded and joined together as an inclined material.
It is also possible to produce and use. At this time, it is possible to form the threaded portion 8A on the weight member 8. In this way, the screw tip portion 8 is made of a metal material having high hardness.
By forming C, the durability of the screw portion is improved, and the weight member 8 can be taken in and out any number of times.
The weight member 8 can be adjusted according to the condition of the golfer at that time.

In addition, as shown in FIG. 4B, it is possible to process the metal such as tungsten by powder metallurgy to integrally form the screw portion 8A and use it as the weight member 8.

FIG. 3 shows another embodiment. The weight storage chamber 7 is provided not in the center of the back side surface 1B but in the heel portion 1D.

Here, as shown in FIG. 5, I of the principal axis of inertia is
_{The 1-} axis, the I _2- axis, and the I ₃ -axis represent the moment of inertia of the wood club head 1 by an ellipsoid of inertia E around the center of gravity G of the head, and the inertia of the three principal axes of inertia orthogonal to the ellipsoid of inertia E. I is the axis showing the maximum value of the moment of inertia around the main axis.
₁ axis, the axis showing the minimum value is the I ₃ axis, and the axis showing the intermediate value between the maximum value and the minimum value is the I ₂ axis. However, the I ₁ axis is perpendicular to the drawing and includes the center of gravity G of the head.

Although the inclination of the principal axis of inertia of the wood club head is slightly different depending on the shape and thickness design, as shown in FIG.
Due to the mass of the hosel portion 1F, in general, the I ₃ axis often falls within the range of −15 degrees to −25 degrees with respect to the tangent line A of the face surface 1A. In FIG. 6, it is described as a plane B that is perpendicular to the ground through the center of gravity G of the head and is parallel to the tangent line A of the face surface 1A for easy description.

By adjusting this inclination, the I ₃ axis is the face surface 1
The directionality of the hit ball is improved by making it close to the tangent line A of A. Here, the tangent line A of the face surface 1A is
In a plane perpendicular to the target point of the trajectory, parallel to the ground,
Further, it is a straight line which passes through the center of gravity G of the head and is in contact with a portion called a sweet spot SS which is an intersection point perpendicular to the face surface 1A.

Even in a wood club head having a hook face whose face angle is directed to the left with respect to the target point or an open face whose face angle is directed to the right, the tangent line A of the face surface 1A is in a plane perpendicular to the target point of the trajectory. The posture is fixed.

When the I ₃ axis is parallel to the tangent line A of the face surface, neither slice spin nor hook spin occurs at the hitting point above or below the sweet spot SS.

However, in the general head as described above whose I ₃ axis is not parallel to the tangent line A of the face surface, when the hit point is above the sweet spot SS, the head rotates in the direction in which the loft increases during a collision. The rotation axis of the head is not parallel to the tangent line A of the face surface and is close to the direction of the I ₃ axis having the smallest moment of inertia, so that the hitting point of the head is not only on the upper side, Although it slightly moves to the heel portion 1D side, as a result, slice spin occurs due to the gear effect.

Here, the gear effect means that at the impact point other than the sweet spot SS, the rotational direction of the head and the rotational direction of the ball at the time of impact seem to rotate in the opposite directions due to the meshing of gears (gears). So it is what is called the gear effect.

The larger the angle of the I ₃ axis with the tangent line A of the face surface, the larger the slice amount.

On the other hand, in the case of a hit point below the sweet spot SS, the head starts to rotate in a direction in which the loft becomes smaller during a collision, but its rotation axis is also a rotation axis close to the direction of the I ₃ axis. As a result, the hitting portion of the head moves not only to the lower side but also to the heel portion 1D side slightly, and as a result, slice spin occurs due to the gear effect. Therefore, if the I ₃ axis is closer to parallel to the tangent line of the face surface, slice spin is less likely to occur and the directionality of the hit ball can be improved.

Here, in order to adjust the inclination of the I ₃ axis,
Describe the calculation formula for obtaining the most efficient position of the weight member. As shown in FIG. 5, assuming that the I ₃ axis and the I ₂ axis coincide with the x axis and the y axis on the xy plane, respectively, the inertia tensor is as shown in the following mathematical formula 1.

[0037]

[Equation 1] When the masses of m / 2 and m / 2 are added to the position of the distance r from the center of gravity G of the head and the angle of x-axis and θ, the inertia tensor becomes as shown in the following Expression 2.

[0038]

[Equation 2] Here, α is the inclination angle between the I ₃ axis and the x axis after the weight member is attached, and from this equation, α is as shown in the following formula 3, formula 4, formula 5, formula 6, and formula 7.

[0039]

[Equation 3]

[0040]

[Equation 4]

[0041]

[Equation 5]

[0042]

[Equation 6]

[0043]

[Equation 7] Thus, the inclination angle α of the I ₃ axis with respect to the x axis after the weight member is attached can be obtained.

However, since the weight adjusting weight member can secure only a limited mass of 0.1 kg or the like in a wood club head having a large head volume in recent years, in consideration of strength, As described above, it is difficult for the I ₃ axis to be in the range of −15 degrees to −25 degrees to be larger than 0 degrees due to the weight of the weight member.
Therefore, if the condition that maximizes α is the optimum condition, and θ at that time is θ ₁ , then the following formula 8 is obtained.

[0045]

[Equation 8] If k ₁ > 1, θ ₁ is given by the following formulas 9 and 10.

[0046]

[Equation 9]

[0047]

[Equation 10] Thus, the most efficient angle of the weight member can be obtained. From this equation, it can be seen that the efficient angle varies depending on the values of the principal moments of inertia I ₃ and I ₂ of the head before mounting the weight member, the mass m of the weight member, and the value of the distance r. Actually, m = 0.1 to 0.2 (kg) r = 0.03 to 0.04 (m) I ₃ = 0.00015 to 0.00018 (kg · m ² ) I ₂ = 0.00022 to When 0.00025 (kg · m ² ) is input to the formula, the results shown in Table 1 are obtained.

Incidentally, in FIG. 6, because of the symmetry, -1
Since 80 to -90 degrees corresponds to 0 to 90 degrees and -90 to 0 degrees corresponds to 90 to 180 degrees, in Table 1, the weight member indicates α at an angle of 0 to 180 degrees.

Therefore, θ ₁ is in the range of 48 to 72 degrees. However, as described above, in general, the wood club head may have the I ₃ axis within the range of −15 to −25 degrees with respect to the tangent line A of the face surface, as shown in FIG. Many, if you add this as an average of -20 degrees,
If the weight member is in the range of 28 to 52 degrees shown in FIG. 7, it is possible to most efficiently bring the I ₃ axis close to the tangent line of the face. Rather than -20 ° average, if considering a 15 to 25 degrees, parallel if there is weight member in the range of 23 to 57 degrees, in a variety of wood club head, most efficiently, the I ₃ axis and the tangent of the face It is possible to approach. At that time, from α in Table 1, the I ₃ axis rotates on the xy plane by ₃ to 27 degrees.

[0050]

[Table 1] Table 1 θ ₁ and α for m, r, I ₂ and I ₃

Although the case where the number of weight members having a mass of m / 2 is two is simulated, as is clear from the process of calculation, the calculation is also performed when the number of weight members 8 having a mass of m is one. The results are exactly the same. However, the center of gravity G of the head moves, and other characteristics of the head change, such as the distance between the center of gravity G of the head and the axis of the shaft, which is commonly called the distance of the center of gravity. When the weight members 8 are two, depending on the angle, when the weight members 8 are on the face surface 1A side, the distance r of the weight members 8 cannot be increased to about 0.2 m at the maximum, so in actual design. It is possible to control the I ₃ axis more efficiently in the case of one.

As an example, No. 1 in Table 1 is used. In case of 16,
FIG. 8 illustrates the inclination angle α of the I ₃ axis with respect to the x axis depending on the arrangement angle θ of the weight member 8.

As can be seen from FIG. 8, the weight member 8 has an arrangement angle θ of 59 degrees and has a maximum inclination angle α, and the I ₃ axis of the wood club head before the weight member is arranged is with respect to the tangent line A of the face surface 1A. When the arrangement angle θ of the weight member is 39 degrees, that is, in the case of one weight member, it simply corresponds to an intermediate position between the heel portion and the back portion of the wood club head 1. To do.

Although it has been described that the rotation axis is close to the I ₃ axis when hitting the spot above or below the sweet spot SS, in reality, from the center of gravity G of the head in FIG.
The rotation is started with a vector to a point A that is in contact with the inertial ellipsoid as a perpendicular line of the X axis, as a rotation axis. However, the I ₃ axis and the rotation axis are in a substantially proportional relationship, and if the I ₃ axis has a large angle with respect to the tangent line of the face, the rotation axis also has a large angle with respect to the tangent line of the face. The most efficient position of the weight member was determined based on the _three axes.

Here, the most efficient position for adjusting the inclination of the main axis was obtained. As a result, the position including the center of gravity G of the head, perpendicular to the ground, and tangential A of the face 1A was 2
The efficiency is improved at the position where it intersects with a plane having an angle of 3 degrees or more and 57 degrees or less and the head side surface, and the position having a plane having an angle of 28 degrees or more and 52 degrees or less and the intersection line of the head side surface portion intersects. It was found to peak when placed in.

When the wood head is normally assembled, the head has an error in the inclination of the principal axis of inertia due to variations in parts and welding. Therefore, if the inertial spindle is adjusted in a process closer to the final process, the variation in the final product can be reduced. Therefore, as in the invention of the present application, by positioning, adjusting and fixing the mass adjusting body after forming the hollow portion, the accuracy of the inclination angle of the inertial spindle can be extremely improved.

In this way, the I of the wood club head is
_By setting the _three axes at an angle of -10 degrees or more and 9 degrees or less with respect to the tangent line A of the face surface 1A, it is possible to provide the wood club head 1 having good directionality.

To explain the present invention more clearly,
A general conventionally known golf club head 50 has a principal axis of inertia as shown in FIG. The principal axis of inertia is at least −15 with respect to the tangent line A of the face surface 1A.
It has an inclination angle of ° to -25 °.

In the present invention, the angle between the principal axis of inertia and the contact surface is 0 ° (90 °) as shown in FIG.
It is desirable to be in the vicinity.

Explaining another embodiment of the present invention shown in FIG. 9, the mass of the weight member 80 for adjusting the inclination of the inertial spindle used is 20 g. As can be seen from this example, in order to effectively tilt the principal axis of inertia, the weight member 80 needs to have a mass of 7% to 15% of the total mass of the head. If all of this mass is placed on the wall surface of the heel portion, the position of the center of gravity of the head may move to the side of the weight member for adjustment, which may impair the action and effect. In order to avoid this, a weight member for adjustment can be arranged on the side surface of the toe portion with the center of gravity of the head as the target point.

FIG. 12 is a graph showing the inclination angle α of the I ₃ axis and the left and right positions of the falling point of the hit ball. That is, in a 44-inch-long club, a head having a mass of 190 g was mounted with various weights of lead, which is a weight member, of 30 g, on various side wall portions of the head body with a double-sided tape, and a robot test was conducted. Before assembling the head to the shaft,
The tilt angle α of the I ₃ axis was measured with the weight members attached to various positions.

In the robot test, the position of the weight member is changed, the swing is performed, and the left and right positions of the drop point of the carry are measured while the grip is being fixed. The results are shown in FIG. As shown in FIG. 12, it has been found that the larger the inclination angle α of the I ₃ axis is, the more rightward the falling point of the hit ball is.

When all of this mass is placed on the heel wall surface,
The position of the center of gravity of the head may move to the side of the weight member for adjustment, which may impair the action and effect. In order to avoid this, it is possible to deal with this by disposing an adjusting weight on the side surface on the toe portion side with the center of gravity of the head as the target point.

The position of the weight member on the toe portion may be applied to the face depending on the form of the head. Providing a weight member on the ball striking face affects the flight distance performance and strength. In this case, therefore, it is desirable to provide it on the side wall on the toe portion side near the face or on the sole portion on the toe portion side.

The size and mass distribution of the head substantially uniquely determine the size of the inertia ellipse of the golf club head and the inclination of the principal axis of inertia.

[0066]

As described above, according to the invention of the present application, the weight of the weight adjusting chamber is arranged in the outer shell of the head so that the major axes of the weight accommodating chambers extend in parallel along the side wall of the head body. Can efficiently adjust the principal axis of inertia and improve the directionality.

Further, it becomes possible to finely adjust the position of the mass body by providing screws to finely adjust the inclination of the inertial spindle.

Further, in order to shorten the length of the weight storage chamber in the long axis direction, a heavy metal having a specific gravity of 7 or more is used, or a weight member in which an easily workable material and a difficultly workable heavy metal material are joined and integrated. By utilizing, it is possible to improve the durability of the weight member.

Further, by specifying the position where the position of the weight member can be adjusted most effectively, the inertial spindle can be adjusted with a small mass so that the head is not enlarged or thinned. can do.

Further, since the adjusting weight member can be fixed to an arbitrary position near the final step of the head, the inertial spindle can be adjusted in consideration of variations in manufacturing of the head, and variations in the inertial spindle of individual heads can be prevented. Can make recommendations.

As a result of such adjustment, the I ₃ axis of the principal axis of inertia becomes perpendicular to the tangent line of the face surface, so that the directionality of the hitting ball of the wood club head can be improved.

[Brief description of drawings]

FIG. 1 is a perspective view showing a wood club head of the present invention.

FIG. 2 is a perspective view showing a situation in which a weight member is attached to the wood club head of the present invention.

FIG. 3 is an enlarged sectional view of an essential part of the wood club head of the present invention.

FIG. 4 is a perspective view showing a weight member used in the wood club head of the present invention.

FIG. 5 is a graph of an inertial ellipsoid of a wood club head.
I of the principal axis of inertia_TwoAxis, I _ThreeThe schematic diagram which shows the inclination angle of a shaft.

FIG. 6 is a schematic diagram showing a range of inclination angles of the I ₃ axis of the principal axis of inertia of a conventionally known wood club head.

FIG. 7 is a schematic diagram showing the range of the inclination angle of the I ₃ axis of the principal axis of inertia of the wood club head of the present invention.

FIG. 8 is a graph showing a position where a weight member is arranged and an inclination angle of a principal axis of inertia of a wood club head.

FIG. 9 is a perspective view showing another embodiment of the wood club head of the present invention.

FIG. 10 is a perspective view showing tilt angles of I ₁ axis, I ₂ axis, and I ₃ axis of inertia principal axes of a conventionally known wood club head.

FIG. 11 is a wood club head of the present invention.
Of the principal axis of inertia at ₁Axis, I_TwoAxis, I_ThreeAxis tilt angle
FIG.

FIG. 12 is a graph showing the inclination angle of the I ₃ axis of the principal axis of inertia of the wood club head of the present invention and the directionality of a hit ball.

FIG. 13 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

FIG. 14 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

FIG. 15 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

FIG. 16 is an enlarged cross-sectional view of a main part of a conventionally known wood club head.

[Explanation of symbols] 1 Wood club head 1A face surface 1B Back side 1C toe section 1D heel part 1E Crown part 1F Hosel part 2 head body 3 Hollow part 4 head outer shell 5 Head side part 6 Mass adjustment section 7 weight storage room 7A insertion port side 7B Tip side 8 weight members 8A screw part 8B Hexagon socket head cap screw 8C screw tip 20 head body 20A head body 20B hollow part 21 mass 22 Sole part 23 Thick part 24 female screw 25 Mass adjustment member 25A male screw 25B mass 26 golf club heads 27 Wood Club Head 28 Inner shell 29 outer shell 30 back side 31 Face side 32 cavity 33 Mass adjuster 34 Iron Club Head 35 Toe Division 36 Heel part 37 Perforated part 38 Mass adjustment member 39 stopper 80 Weight member A tangent B A plane parallel to the tangent to the face surface C long axis G head center of gravity G

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Shoji Ono             3877-8 Takada, Yoro-cho, Yoro-gun, Gifu Mitsuno             Yoro Factory Co., Ltd. (72) Inventor Masayuki Takagi             3877-8 Takada, Yoro-cho, Yoro-gun, Gifu Mitsuno             Yoro Factory Co., Ltd. F-term (reference) 2C002 AA02 CH06 LL01 LL04 MM04                       MM05

Claims (4)

[Claims] 1. A wood club head (1) having a hollow part (3) provided with a mass adjusting part (6), wherein the mass adjusting part (6) is provided on a side surface (1B) of a back part of a head body (2). The weight storage chamber (7) of the mass adjusting section (6) is arranged substantially parallel to the side surface (1B) of the back section, and the weight member (8) is detachably attached. A wood club head (1) characterized by the above. 2. The mass adjusting part (6) includes a center of gravity (G) of the head, is perpendicular to the ground, and has a face surface (1A).
The wood club head according to claim 1, characterized in that the wood club head is arranged at a position where a plane having an angle of 23 degrees or more and 57 degrees or less with respect to the tangent line (A) intersects with the head side surface portion (5). (1). 3. The mass adjusting part (6) includes a center of gravity (G) of the head, is perpendicular to the ground, and has a face surface (1A).
The wood club head (1) according to claim 1, characterized in that the wood club head (1) is arranged at a position where a plane having an angle in the range of 28 degrees or more and 52 degrees or less with respect to the tangent of (4) intersects the head side surface portion (5). . 4. The three principal axes of inertia of the wood club head (1) in which the mass adjusting section (6) is arranged, I ₁ axis, I axis
_{One of the two} axes and the I ₃ axis is the face surface (1
The wood club head (1) according to claim 1, 2 or 3, wherein the angle is in the range of -10 degrees to 9 degrees with respect to the tangent line (B) of A).