JP6910266B2 - Golf club head - Google Patents

Description

The present invention relates to a golf club head.

In order to improve the initial speed of the golf ball when hitting the golf ball with the golf club head and improve the flight distance, it is important how to secure the amount of deflection of the face part, and how to make the sweet area. It is important to expand it.
As a structure of a golf club head, there is a structure including a head body having an opening in the face portion and a face member joined to the opening by welding.
In such a structure, a bead portion having high rigidity is formed on the face portion along the entire circumference of the face member, which is disadvantageous in securing the amount of deflection of the face portion and expanding the sweet area.
On the other hand, a flange portion forming a part of the crown portion or a part of the sole portion is provided extending from the edge portion of the face member in the face back direction, and a face member (cup face) having such a flange portion is provided. A golf club head having a so-called cup face structure, which is welded to the opening of the head body, has been proposed (see Patent Document 1).

JP-A-2002-17913

According to a golf club having such a cup face structure, a part of the bead portion is formed on the crown portion or the sole portion, so that the amount of the bead portion formed on the face portion is reduced.
Therefore, although there is a certain effect in suppressing the rigidity of the face portion, securing the amount of deflection of the face portion, and expanding the sweet area, in order to secure the amount of deflection of the face portion and expand the sweet area. There is room for improvement.
The present invention has been made in view of such circumstances, and an object of the present invention is advantageous in securing the amount of deflection of the face portion, expanding the sweet area, and improving the initial velocity and flight distance of the ball. The purpose is to provide a golf club head having a cup face structure.

In order to achieve the above object, the present invention includes a head body having a hollow structure and an opening provided on the face portion side, and a face member joined to the opening by welding, and the face member is the face. A main body plate portion constituting the portion and a flange portion side flange extending from the upper portion of the main body plate portion to the crown portion side to form a part of the crown portion and being joined to the front edge of the crown portion of the head main body. A deformation-inducing portion that induces deformation when a golf ball is hit is formed extending along the toe heel direction on the crown portion-side flange, and the head body and the crown portion side are formed at the opening. A bead portion protruding inside the golf club head is formed so as to extend over the entire circumference of the portion where the flange is joined by welding, and the crown portion side flange has a front edge connected to the face portion and the said A first inclined surface that rises from the front edge toward the face back and whose end on the face back side is the highest in the crown portion, and a trailing edge joined to the front edge of the crown portion of the head body. It has a second inclined surface that rises from the trailing edge toward the face portion and intersects the first inclined surface, and a ridge line formed at a portion where the first inclined surface and the second inclined surface intersect. The deformation inducing portion is characterized by including the first inclined surface, the second inclined surface, and the ridge line .
Further, the present invention includes a head body having a hollow structure and an opening provided on the face portion side, and a face member joined to the opening by welding, and the face member is a main body plate constituting the face portion. A golf club head including a portion and a flange on the crown portion side extending from the upper portion of the main body plate portion to the crown portion side to form a part of the crown portion and being joined to the front edge of the crown portion of the head main body. A deformation-inducing portion that induces deformation when the golf ball is hit is formed extending along the toe-heel direction on the crown-side flange, and the head body and the crown-side flange are joined by welding at the opening. A bead portion protruding inside the golf club head is formed so as to extend over the entire circumference of the portion to be welded, and the crown portion side flange is formed with a front edge connected to the face portion and in the face back direction from the front edge. A first inclined surface that rises as it reaches and its end on the face back side becomes the highest position in the crown portion, a second inclined surface that descends from the rear end of the first inclined surface toward the face back, and the above. The deformation-inducing portion has a lower surface that extends from the lower end of the second inclined surface in the face-back direction and is joined to the front edge of the crown portion of the head body to form a continuous surface with the crown portion of the head body. , The first inclined surface, the second inclined surface, and the lower surface are included.
Further, the present invention includes a head body having a hollow structure and an opening provided on the face portion side, and a face member joined to the opening by welding, and the face member is a main body plate constituting the face portion. A golf club head including a portion and a flange on the crown portion side extending from the upper portion of the main body plate portion to the crown portion side to form a part of the crown portion and being joined to the front edge of the crown portion of the head main body. A deformation-inducing portion that induces deformation when the golf ball is hit is formed extending along the toe-heel direction on the crown-side flange, and the head body and the crown-side flange are joined by welding at the opening. A bead portion protruding inside the golf club head is formed so as to extend over the entire circumference of the portion to be welded, and the crown portion side flange is formed with a front edge connected to the face portion and in the face back direction from the front edge. A first inclined surface that rises as it reaches and the end portion on the face back side becomes the highest position in the crown portion, a recess connected to the end portion on the face back side of the first inclined surface and recessed toward the sole portion, and the above. It has a rear surface extending from the trailing edge of the concave portion away from the first inclined surface in the face back direction and joined to the front edge of the crown portion of the head body, and the deformation inducing portion is the first inclined surface. It is characterized in that it is configured to include the recess and the rear surface.

According to the present invention, when a golf ball is hit, stress is concentrated on the deformation-inducing portion, so that a large amount of deformation of the crown portion near the face portion can be secured.
Further, since the highly rigid bead portion inevitably generated during the manufacture of the cup face structure is located behind the deformation inducing portion, stress can be reliably concentrated on the deformation inducing portion when hitting a golf ball. , It is more advantageous to secure a large amount of deformation of the crown portion near the face portion.
Further, since the bead portion that is inevitably generated during the manufacture of the cup face structure is located at the front end of the crown portion of the head body, the head behind the bead portion that contributes less to the deflection of the face portion. It is advantageous in suppressing unnecessary deformation of the crown portion of the main body.
Therefore, in a golf club head having a cup face structure, by effectively utilizing the bead portion that is inevitably generated during the manufacture of the cup face structure, the amount of deflection of the face portion can be further increased, the sweet area can be further expanded, and the coefficient of restitution can be increased. Can be made higher and the launch angle can be made larger, which is more advantageous in improving the initial velocity and the flight distance.
Further, as compared with the conventional golf club head in which the deformation-inducing portion is provided on the crown portion of the golf club head which does not have the cup face structure, in the present invention, the bead portion which is inevitably generated during the manufacture of the cup face structure is effectively used. Therefore, it is not necessary to newly provide a reinforcing bead portion, and the stress can be reliably concentrated on the deformation inducing portion by a simple structure. Therefore, compared to a conventional golf club head in which a deformation-inducing portion is provided on the crown portion of the golf club head which does not have a cup face structure, the sweet area can be expanded by a simple structure, the coefficient of restitution is increased, and the launch angle is increased. Is possible, which is advantageous in improving the initial velocity and flight distance.

It is a front view which looked at the golf club head which concerns on 1st Embodiment from the front of the face surface. It is a top view of the golf club head which concerns on 1st Embodiment. FIG. 1 is a cross-sectional view taken along the line AA of FIG. (A) is a front view of the head body, (B) is a view of arrow B of (A), and (C) is a view of arrow C of (A). It is a front view of a face member. It is a front view which made the golf club head which concerns on 1st Embodiment a reference state. It is a view of arrow A of FIG. It is a B arrow view of FIG. It is a C arrow view of FIG. It is a 1st explanatory view which shows the method of defining the center point Pc of a face surface. It is a 2nd explanatory view which shows the method of defining the center point Pc of a face surface. It is a 3rd explanatory view which shows the method of defining the center point Pc of a face surface. It is a 4th explanatory view which shows the method of defining the center point Pc of a face surface. It is sectional drawing of the golf club head which shows the relationship between the center of gravity point G0 of a golf club head and the center of gravity point FG on a face surface. It is a front view of the golf club head explaining the definition of the contour line I of a face surface. It is sectional drawing of the golf club head explaining the definition of the contour line I of a face surface. It is a front view of the golf club head explaining the definition of the center point Pc of a face surface. It is sectional drawing of the face center reference cross section Pfc or the face reference cross section Pf of the golf club head which concerns on 1st Embodiment, and the regulation of each part is explained. It is sectional drawing of the face center reference cross section Pfc or the face reference cross section Pf of the golf club head which concerns on 1st Embodiment, and the definition of the flange angle θ1 is explained. It is sectional drawing of the face center reference cross section Pfc of the golf club head which concerns on 1st Embodiment, (A) shows the state before hitting a golf ball, and (B) shows the state after hitting a golf ball. FIG. 5 is a cross-sectional view of a face center reference cross section Pfc showing a change in the shape of a general golf club head before and after hitting a golf ball. It is a top view of the golf club head which concerns on 2nd Embodiment. It is sectional drawing of the face center reference cross section Pfc or the face reference cross section Pf of the golf club head which concerns on 2nd Embodiment, and the regulation of each part is explained. It is sectional drawing of the face center reference cross section Pfc of the golf club head which concerns on 2nd Embodiment, (A) shows the state before hitting a golf ball, and (B) shows the state after hitting a golf ball. It is a top view of the golf club head which concerns on 3rd Embodiment. It is sectional drawing of the face center reference cross section Pfc or the face reference cross section Pf of the golf club head which concerns on 3rd Embodiment, and the regulation of each part is explained. It is sectional drawing of the face center reference cross section Pfc of the golf club head which concerns on 3rd Embodiment, (A) shows the state before hitting a golf ball, and (B) shows the state after hitting a golf ball. It is a figure which shows the evaluation result of the experimental example in 1st Embodiment. It is a figure which shows the evaluation result of the experimental example in 1st Embodiment. It is a figure which shows the evaluation result of the experimental example in 1st Embodiment. It is a figure which shows the evaluation result of the experimental example in 2nd Embodiment. It is a figure which shows the evaluation result of the experimental example in 2nd Embodiment. It is a figure which shows the evaluation result of the experimental example in 2nd Embodiment. It is a figure which shows the evaluation result of the experimental example in 3rd Embodiment. It is a figure which shows the evaluation result of the experimental example in 3rd Embodiment. It is a figure which shows the evaluation result of the experimental example in 3rd Embodiment.

(First Embodiment)
Next, an embodiment of the present invention will be described.
As shown in FIGS. 1 to 5, in the present embodiment, the golf club head 10 is a hollow wood type golf club head (driver) and has a cup face structure.
That is, the golf club head 10 includes a head body 12 and a face member (cup face) 14.
As shown in FIGS. 4A to 4C, the head body 12 has a hollow structure and is provided with an opening 16 on the face portion 26 side.
In the opening 16 of the head body 12, the portions corresponding to the crown portion side flange 20 and the sole portion side flange 22 form recesses 1602 and 1604 recessed in the face back 38 direction, respectively, and the portion corresponding to the face portion 26 is a toe heel. Recesses 1606 and 1608 that are recessed in the direction are formed.

As shown in FIGS. 1, 2 and 3, the face member 14 is joined to the portion of the head body 12 around the opening 16 by welding with the opening 16 closed, whereby the golf club head 10 is formed. NS.
As shown in FIGS. 3 and 5, the face member 14 includes a main body plate portion 18, a crown portion side flange 20, and a sole portion side flange 22.

The main body plate portion 18 constitutes most of the face portion 26 described later.
As shown in FIGS. 1 and 5, the main body plate portion 18 has a toe side edge portion 1802 joined to a recess 1606 which is a toe side portion of the opening 16 of the head main body 12 and a heel side of the opening 16 of the head main body 12. It has a heel side edge 1804 that is joined to the recess 1608 that is a portion.

As shown in FIGS. 2 and 3, the crown portion side flange 20 extends from the upper portion of the main body plate portion 18 toward the face back 38 in the toe heel direction, and constitutes a portion of the crown portion 28 closer to the face portion 26, which will be described later. do.
The crown portion side flange 20 has a front edge 2002 connected to the face portion 26, a trailing edge 2004 joined to the bottom of the recess 1602 which is the front edge of the crown portion 28, and a side joined to both side portions of the recess 1602. It has an edge 2006 and forms a part of the crown portion 28.
Further, the flange length of the crown portion side flange 20 along the front-rear direction connecting the face portion 26 and the face back 38, that is, the distance between the leading edge 2002 and the trailing edge 2004 is 4 mm or more and 30 mm or less.
A deformation inducing portion 46, which will be described later, is provided on the crown portion side flange 26.

As shown in FIGS. 1, 2, and 3, the flange portion 22 on the sole portion extends from the lower portion of the main body plate portion 18 toward the toe heel toward the face back 38, and constitutes a part of the sole portion 30, which will be described later. ..
The sole portion side flange 22 has a leading edge 2202 connected to the face portion 26, a trailing edge 2204 joined to the bottom of the recess 1604 which is the front edge of the sole portion 30, and a side joined to both side portions of the recess 1604. It has an edge of 2206.
The flange portion may extend in the face back 38 direction from the entire circumference of the main body plate portion 18. In that case, the face member 14 constitutes the entire face portion 26, and the flange portion of the face member 14 constitutes the crown portion 28, the sole portion 30, and the side portion 32 described later, which is closer to the face portion 26. Become.
In the present invention, the face member 14 may have at least the crown portion side flange 20 and may not have the sole portion side flange 22.

The head body 12 is mainly made of a metal material.
As the metal material, for example, one kind or two or more kinds such as stainless steel, maraging steel, pure titanium, titanium alloy or aluminum alloy are used.
The face member 14 is made of a metal material, and in the present embodiment, the Young's modulus may be 60 GPa or more and 130 GPa or less. More preferably, it is formed by bending a cold-rolled β-titanium plate and has a Young's modulus of 60 GPa or more and 90 GPa or less.
The processing temperature during this bending process is 100 to 300 ° C. or less.
By setting the processing temperature within the above range, bending processing is possible while suppressing an increase in Young's modulus (hardening) of the β titanium plate, which is advantageous in ensuring the deflection of the face member 14.

As shown in FIGS. 6 to 9, the golf club head 10 includes a face portion 26, a crown portion 28, a sole portion 30, and a side portion 32.
The face portion 26 has a vertical height and extends to the left and right.
The crown portion 28 has a wall thickness smaller than that of the face portion 26 and extends rearward from the upper portion of the face portion 26.
The sole portion 30 extends rearward from the lower portion of the face portion 26.
The side portion 32 extends between the crown portion 28 and the sole portion 30 through the face back 38 between the toe side edge and the heel side edge of the face portion 26.
As shown in FIG. 3, the golf club head 10 has a hollow structure in which the inside surrounded by the face portion 26, the crown portion 28, the sole portion 30, and the side portion 32 is a hollow portion 40.
The surface exposed to the outside of the face portion 26 is the face surface 26A for hitting the golf ball, and the back surface of the face portion 26 facing the hollow portion 40 is the face back surface 26B.
The surface exposed to the outside of the crown portion 28 is the crown surface 28A, and the back surface of the crown portion 28 facing the hollow portion 40 is the crown back surface 28B.
As shown in FIGS. 6 and 7, the crown portion 28 is provided with a hosel 42 connected to the shaft on the face surface 26A side and at a position closer to the heel 36, and the shaft is connected to the hosel 42 to connect the golf club. Is configured.
The surface exposed to the outside of the sole portion 30 is the sole surface 30A, and the back surface of the sole portion 30 facing the hollow portion 40 is the sole back surface 30B.
In the figure, reference numeral 44 indicates a leading edge.

Next, prior to the description of the deformation inducing portion 46, the center point Pc of the face surface 26A, the face center reference cross section Pfc, and the face reference cross section Pf will be described.

(Definition of center point Pc of face surface 26A)
First, a method of defining the center point Pc of the face surface 26A will be described.
The center point Pc of the face surface 26A is the geometric center of the face surface 26A, and various conventionally known methods of defining the center point Pc include the first defining method and the second defining method exemplified below. The method can be adopted.

[A] First method for defining the center point Pc of the face surface 26A:
When the boundary between the face surface 26A and the portion of the other golf club head 10 is clear, in other words, it is a method of defining the center point Pc when the peripheral edge of the face surface 26A is specified by the ridge line. In this case, the face surface 26A is clearly defined.
10 to 13 are explanatory views showing a method of defining the center point Pc of the face surface 26A.

(1) First, as shown in FIG. 10, the golf club head 10 is placed on the horizontal surface HP so that the lie angle and the face angle become specified values. The state of the golf club head 10 at this time is used as the reference state. The set values of the lie angle and the face angle are, for example, the values described in the product catalog.

(2) Next, the temporary center point c0 in the direction connecting the crown portion 28 and the sole portion 30 is obtained.
That is, as shown in FIG. 10, a perpendicular line f0 that intersects the approximate center point of a line parallel to the horizontal plane HP connecting the toe 34 and the heel 36 (hereinafter referred to as a horizontal line) is drawn.
The midpoint between the a0 point where the perpendicular line f0 and the upper edge of the face surface 26A intersect and the b0 point where the perpendicular line f0 and the lower edge of the face surface 26A intersect is defined as a temporary center point c0.

(3) Next, as shown in FIG. 11, a horizontal line g0 passing through the temporary center point c0 is drawn.
(4) Next, as shown in FIG. 12, at the d0 point where the horizontal line g0 and the edge of the face surface 26A on the toe 34 side intersect, and at the e0 point where the horizontal line g0 and the edge of the face surface 26A on the heel 36 side intersect. Let the midpoint be the temporary center point c1.

(5) Next, as shown in FIG. 13, a perpendicular line f1 passing through the temporary center point c1 is drawn, and the perpendicular line f1 and the upper edge of the face surface 26A intersect with the a1 point, and the perpendicular line f1 and the lower edge of the face surface 26A. Let the midpoint of the b1 point where the two intersect is the temporary center point c2.
Here, if the temporary center points c1 and c2 match, that point is defined as the center point Pc of the face surface 26A.
If the temporary center points c1 and c2 do not match, the steps (2) to (5) are repeated.
Since the face surface 26A has a curved surface, the length of the horizontal line g0 and the lengths of the perpendicular lines f0 and f1 when the midpoint of the horizontal line g0 and the midpoint of the perpendicular lines f0 and f1 are obtained is the curved surface of the face surface 26A. Along the length shall be used.
The face center line CL is defined by a straight line that passes through the center point Pc and extends in a direction orthogonal to the toe 34-heel 36 direction.

[B] A second method for defining the center point Pc of the face surface 26A:
Next, the definition of the center point Pc when the peripheral edge of the face surface 26A and the portion of the other golf club head 10 are connected by a curved surface and the face surface 26A cannot be clearly defined will be described.

As shown in FIG. 14, the golf club head 10 is hollow, the reference numeral G0 indicates the center of gravity point of the golf club head 10, and the reference numeral Lp is a straight line connecting the center of gravity point G0 and the center of gravity point FG on the face surface, in other words. The straight line Lp is a perpendicular line of the face surface 26A passing through the center of gravity point G0.
That is, the point where the center of gravity point G0 of the golf club head 10 is projected onto the face surface 26A is the center of gravity point FG on the face surface.
Here, as shown in FIG. 15, a large number of planes H1, H2, H3, ..., Hn including a straight line Lp connecting the center of gravity point G0 and the center of gravity point FG on the face surface are considered.

As shown in FIG. 16, the radius of curvature r0 of the outer surface of the golf club head 10 is measured in the cross section when the golf club head 10 is broken along the planes H1, H2, H3, ..., Hn.
When measuring the radius of curvature r0, it is treated as if there is no face line, punch mark, etc. on the face surface 26A.
The radius of curvature r0 is continuously measured from the center point Pc of the face surface 26A in the outward direction (upward and downward in FIG. 16).
Then, in the measurement, the portion where the radius of curvature r0 is first or less than a predetermined value is defined as the contour line I representing the peripheral edge of the face surface 26A.
The predetermined value is, for example, 200 mm.
A region surrounded by contour lines I determined based on a number of planes H1, H2, H3, ..., Hn is defined as the face surface 26A, as shown in FIGS. 15 and 16.

Next, as shown in FIG. 17, the golf club head 10 is placed on a horizontal ground (horizontal plane HP) so that the lie angle and the face angle become specified values.
The straight line LT passes through the toe side point PT of the face surface 26A and extends in the vertical direction.
The straight line LH passes through the heel side point PH of the face surface 26A and extends in the vertical direction.
The straight line LC is parallel to the straight line LT and the straight line LH. The distance between the straight line LC and the straight line LT is equal to the distance between the straight line LC and the straight line LH.
Reference numeral Pu indicates an upper point of the face surface 26A, and reference numeral Pd is a lower point of the face surface 26A. The upper point Pu and the lower point Pd are both intersections of the straight line LC and the contour line I.
The center point Pc is defined by the midpoint of the line segment connecting the upper point Pu and the lower point Pd.

(Definition of face center reference cross section Pfc and face reference cross section Pf)
Next, the face center reference cross section Pfc will be described.
As shown in FIGS. 6 to 9, the golf club head 10 is set in a reference state in which the golf club head 10 is installed according to a predetermined lie angle and loft angle with respect to the horizontal plane HP.
As shown in FIGS. 6, 8 and 9, in the reference state, the face center is a cross section obtained by breaking the golf club head 10 on a plane X including a normal line passing through the center point Pc of the face surface 26A and orthogonal to the horizontal plane HP. The reference cross section is Pfc.
In other words, the face center reference cross section Pfc is a cross section obtained by breaking the golf club head 10 on a plane X including the face center line CL and orthogonal to the horizontal plane HP in the reference state.
Further, a cross section obtained by breaking the golf club head 10 on an arbitrary plane parallel to the face center reference cross section Pfc is referred to as a face reference cross section Pf. Therefore, the face reference cross section Pf includes the face center reference cross section Pfc.

As described above, since the face member 14 is joined to the head body 12 by welding, as shown in FIG. 3, the bead portion by welding is formed along the entire circumference of the portion where the face member 14 and the head body 12 are joined. 48 is formed.
The portion of the bead portion 48 located on the outer surface of the golf club head 10 is removed by polishing, but the bead portion 48 protruding toward the hollow portion 40 is present on the inner surface of the golf club head 10 facing the hollow portion 40. It will be.
Therefore, in the crown portion 28, a bead portion 48 is formed along the toe heel direction on the inner surface facing the hollow portion 40 at the portion where the trailing edge 2004 of the crown portion side flange 20 and the recess 1602 of the crown portion 28 are joined. Will be done.
Therefore, the bead portion 48 is formed along the trailing edge 2004 of the crown portion side flange 20.
The portion of the crown portion 28 in which the bead portion 48 is formed has higher rigidity than the portion in which the bead portion 48 is not formed.

Next, the deformation inducing unit 46 will be described.
The deformation inducing portion 46 is formed extending along the toe heel direction between the leading edge 2002 and the trailing edge 2004 of the crown portion side flange 20, and the deformation inducing portion 46 is induced to be deformed when the golf ball is hit. It is a part.
As shown in FIGS. 2, 3 and 8, the crown portion side flange 20 has a front inclined surface 2010, a rear inclined surface 2012, and a ridge line 2014.
The front inclined surface 2010 rises from the front edge 2002 of the crown side flange 20 toward the face back 38.
The rear inclined surface 2012 rises from the trailing edge 2004 of the crown portion side flange 20 toward the face portion 26.
The ridge line 2014 is formed at a portion where the front inclined surface 2010 and the rear inclined surface 2012 intersect.
The deformation inducing portion 46 includes a front inclined surface 2010, a rear inclined surface 2012, and a ridge line 2014.

Next, the definition of the positional relationship of the ridge line 2014 on the crown portion side flange 20 and the regulation of the wall thickness on the crown portion side flange 20 will be described.
As shown in FIG. 18, in the present embodiment, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 on the horizontal plane HP is 4 mm to 20 mm. Is.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the deformation-inducing front portion to the trailing edge 2004 on the horizontal plane HP is 5 mm to 20 mm.
When the first distance L1 is within the above range, the stress concentrated on the deformation inducing portion 46 at the time of hitting the ball is increased, the deformation inducing portion 46 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion side. This is advantageous in ensuring the amount of deflection of the flange 20.
When the first distance L1 is less than the above range, the stress concentrated on the deformation inducing portion 46 is reduced, the deformation inducing portion 46 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion side flange 20 are deformed. The effect of securing the amount of deflection (particularly the flange on the crown portion side 20) is reduced.
When the first distance L1 exceeds the above range, the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown portion side flange 20 and the ridge line 2014, so that the deformation inducing portion 46 is greatly above the other portions. The effect of ensuring the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced.
Further, when the second distance L2 is within the above range, the deformation amount of the deformation inducing portion 46 can be secured at the time of hitting the ball, which is advantageous in securing the deflection amount of the face portion 26 and the crown portion side flange 20.
When the second distance L2 is less than the above range, the distance from the deformation inducing portion to the welded portion (brazing is also possible) is too short, so that the deformation inducing portion 46 is deformed to the upper side more than the other portions and the face portion. The effect of securing the amount of deflection of the 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.
If the second distance L2 exceeds the above range, the distance from the deformation inducing portion to the welded portion (brazing is also possible) is too long, so even if the ball and the head come into contact with each other and are separated from each other, the face portion 26 The deformation of the face portion 26, which is 40 mm or more away from the surface, remains, resulting in energy loss. In particular, the effect of securing the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.

Further, in the present embodiment, the wall thickness t1 from the leading edge 2002 connected to the face portion to the deformation-inducing front portion is the wall thickness t2 of the trailing edge 2004 joined to the front edge of the face portion 26 from the deformation-inducing rear portion. It is supposed to be larger than.
When the condition of wall thickness t1> wall thickness t2 is satisfied, the stress concentrated on the deformation inducing portion 46 is increased, the deformation inducing portion 46 is deformed to the upper side more than other portions, and the face portion 26 and the crown portion side flange 20 are formed. It is advantageous in securing the amount of deflection, and the sweet area can be expanded. Further, in terms of strength, the large deformed portion 20 is thick and the small deformed portion is thin, which is advantageous.
When the condition of wall thickness t1> wall thickness t2 is not satisfied, the stress concentrated on the deformation inducing portion 46 is increased, the deformation inducing portion 46 is deformed to the upper side more than other portions, and the face portion 26 and the crown portion side flange 20 are formed. It is disadvantageous in securing the amount of deflection, and the sweet area cannot be expanded. (The deformable area of the crown flange becomes too small.) Further, in terms of strength, the large deformed portion 20 is thin and the small deformed portion is thick, which is disadvantageous.

Further, in the present embodiment, the weighted average ΔT1 of the wall thickness from the leading edge 2002 connected to the face portion to the deformation-inducing front portion is 0.6 mm to 1.4 mm, and the deformation-inducing rear portion to the face portion 26 The weighted average ΔT2 of the wall thickness up to the trailing edge 2004 joined to the leading edge is 0.4 mm to 1.0 mm.
The weighted average wall thickness is determined as a weighted average in which the wall thickness t of some measurement points in the specified area in the face reference cross section is weighted by the length.
When the weighted average ΔT1 and the weighted average ΔT2 are within the above ranges, the stress concentrated on the deformation inducing portion 46 is increased, the deformation inducing portion 46 is deformed more upward than the other portions, and the face portion 26 and the crown portion side flange are formed. It is advantageous in securing the amount of deflection of 20, and the sweet area can be expanded. Further, in terms of strength, the large deformed portion 20 is thick and the small deformed portion is thin, which is advantageous.
When the weighted average ΔT1 and the weighted average ΔT2 are less than the above ranges, the wall thickness of the crown portion side flange 20 is too thin, so that the effect of ensuring the durability of the deformation inducing portion 46 is reduced.
When the weighted average ΔT1 and the weighted average ΔT2 exceed the above ranges, the wall thickness of the crown side flange 20 is too thick, so that the amount of deformation of the crown part side flange 20 located on the face part 26 side of the ridge line 2014 at the time of hitting the ball. Therefore, the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting the ball is reduced, and the effect of securing a large amount of deflection of the face portion 26 and the sweet area is reduced.

Next, the definition of the flange angle θ1 will be described.
As shown in FIG. 19, the intersection of the face reference cross section Pf and the front edge of the crown portion side flange 20 is defined as the first boundary point K1.
In the face reference cross section Pf, a straight line L1 and a crown side flange that pass through a point 5 mm away from the first boundary point K1 in the face back direction on the plane HP'that includes the first boundary point K1 and are parallel to the horizontal plane HP and are orthogonal to the horizontal plane. The intersection with the surface of 20 is defined as the first intersection P1.
The angle formed by the straight line L2 connecting the first boundary point K1 and the first intersection P1 with respect to the horizontal plane HP is defined as the flange angle θ1.
In this embodiment, the flange angle θ1 is set to 15 ° or more and 50 ° or less.
When the flange angle θ1 is within the above range, the golfer does not feel a sense of discomfort in the shape of the golf club head 10 while ensuring the amount of deformation of the deformation inducing portion 46 at the time of hitting the ball, and it is easy to swing and the head speed is not easily reduced. , It is advantageous in securing the flight distance.
When the flange angle θ1 is less than the above range, the effect of securing the amount of deformation of the deformation inducing portion 46 at the time of hitting the ball is reduced, and the effect of securing the flight distance is reduced.
When the flange angle θ1 exceeds the above range, the golfer tends to feel a sense of discomfort in the shape of the golf club head 10, the swing becomes difficult, the head speed decreases, and the effect of securing the flight distance decreases. Further, since the strength of the boundary between the face surface 26A and the crown surface 28A corresponding to the first boundary point K1 is reduced, the effect of ensuring the durability of the golf club head 10 is reduced.

Next, the action and effect will be described.
In the present embodiment, a deformation-inducing portion 46, which induces deformation when a golf ball is hit, is formed extending along the toe-heel direction on the crown portion-side flange 20.
By providing such a deformation-inducing portion 46, the deformation-inducing portion 46 is deformed more than the other portions of the crown portion 28 when the golf ball is hit.
Further, since the bead portion 48 having high rigidity inevitably generated during the manufacture of the cup face structure is located at the rear end of the deformation inducing portion 46, the stress is surely concentrated on the deformation inducing portion 46 when the golf ball is hit. This is more advantageous in ensuring a large amount of deformation of the deformation-inducing portion 46, that is, a large amount of deformation of the crown portion 28 near the face portion 26.
Further, since the bead portion 48 having high rigidity inevitably generated during the manufacture of the cup face structure is located at the front end of the crown portion 28 portion of the head body 12, the degree of contribution to the deflection of the face portion 26 is small. This is advantageous in suppressing unnecessary deformation of the crown portion 28 of the head body 12 behind the bead portion 48.
Therefore, in a golf club head having a cup face structure, by effectively utilizing the bead portion 48 that is inevitably generated during the manufacture of the cup face structure, stress can be reliably concentrated on the deformation inducing portion 46 when the golf ball is hit. This makes it possible to secure a large amount of deformation of the crown portion 28 near the face portion 26. Therefore, the amount of deflection of the face portion 26 can be increased, the sweet area can be expanded, the coefficient of restitution can be increased, the sweet area can be widened, and the launch angle can be increased, which is advantageous in improving the initial velocity and the flight distance. Become.
Further, as compared with the conventional golf club head in which the deformation inducing portion is provided on the crown portion of the golf club head having no cup face structure, the golf club head 10 of the present embodiment is inevitably manufactured at the time of manufacturing the cup face structure. Since the generated bead portion 48 is effectively used, it is not necessary to newly provide a reinforcing bead portion, and the simple structure allows the stress to be reliably concentrated on the deformation inducing portion 46, and the deformation inducing portion 46 is made large. It can be deformed by the amount of deformation. Therefore, compared to a conventional golf club head in which a deformation-inducing portion is provided on the crown portion of the golf club head which does not have a cup face structure, the sweet area can be expanded by a simple structure, the coefficient of restitution is increased, and the launch angle is increased. Is possible, which is advantageous in improving the initial velocity and flight distance.

The deformation of the crown portion 28 when hitting a golf ball will be further described.
20 (A) and 20 (B) are cross-sectional views of a face center reference cross section Pfc showing a change in the shape of the golf club head 10 of the present invention before and after hitting a golf ball, and the actual amount of deformation is enlarged and shown. ..
FIG. 21 is a cross-sectional view of a face center reference cross section Pfc showing a change in the shape of a general golf club head 10'before and after hitting a golf ball.
In FIGS. 20 and 21, the solid line shows the state before hitting the golf ball, the alternate long and short dash line shows the deformed state after hitting the golf ball, and the alternate long and short dash line shows the actual amount of deformation enlarged.
As is clear from FIGS. 20B and 21, in the golf club head 10 of the present embodiment, the crown portion 28 is deformed when the golf ball B is hit, as compared with the general golf club head 10'. Is concentrated near the face portion 26 (the flange on the crown portion 28 side), and it can be seen that the deformation of the crown portion 28 other than the face portion 26 is extremely small.
Therefore, it can be seen that the deformation of the crown portion 28 at the time of hitting the golf ball is concentrated near the face portion 26.
As described above, since the amount of deformation in the narrow range of the crown portion 28 near the face portion 26 is large, the degree of the deformation contributing to the deflection of the face portion 26 is high.
On the other hand, the portion of the crown portion 28 excluding the portion closer to the face portion 26 has a small amount of deformation, and therefore, unnecessary deformation having a small degree of contributing to the deflection of the face portion 26 is suppressed, and the amount of deflection of the face portion 26 increases. Since the coefficient of restitution can be increased and the launch angle can be increased, it is advantageous in improving the initial velocity and the flight distance.

(Second Embodiment)
Next, the second embodiment will be described with reference to FIGS. 22, 23, 24 (A), and (B).
In the following embodiments, the same parts and members as those in the first embodiment are designated by the same reference numerals as those in the first embodiment, and the description thereof will be omitted.
Also in the second embodiment, the deformation inducing portion 50, which induces deformation when the golf ball is hit, is formed extending along the toe heel direction between the leading edge 2002 and the trailing edge 2004 of the crown portion side flange 20. ing.
In the second embodiment, the configuration of the deformation inducing unit 50 is different from that in the first embodiment.
In the second embodiment, the crown portion side flange 20 has an upper surface 2020, an inclined surface 2022, and a lower surface 2024.
The upper surface 2020 extends in the toe heel direction and extends from the upper edge of the face portion 26 in the face back 38 direction.
The inclined surface 2022 extends in the toe heel direction and extends in the sole portion 30 direction from the rear end of the upper surface 2020 located at the intermediate portion between the leading edge 2002 and the trailing edge 2004 of the crown portion side flange 20.
The lower surface 2024 extends in the toe heel direction, extends from the lower end of the inclined surface 2022 toward the face back 38, and is joined to the front edge of the crown portion 28 to form a continuous surface with the front portion of the crown portion 28 (crown surface 28A). is doing.
The deformation inducing portion 50 includes an upper surface 2020, an inclined surface 2022, and a lower surface 2024.

Next, with reference to FIG. 23, the provisions of the upper surface 2020, the inclined surface 2022, and the lower surface 2024 of the crown portion side flange 20 will be described.
In the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP is 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 5 mm to 20 mm.
Further, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the upper end 2022A (rear end 2020A of the upper surface 2020) of the inclined surface 2022 to the lower end 2022B on the vertical plane orthogonal to the face reference cross section Pf is 1 mm or more. It is 7 mm or less.
When the first distance L1 is within the above range, the stress concentrated on the deformation inducing portion 50 at the time of hitting the ball is increased, the deformation inducing portion 50 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion side are formed. This is advantageous in ensuring the amount of deflection of the flange 20.
When the first distance L1 is less than the above range, the stress concentrated on the deformation inducing portion 50 is reduced, the deformation inducing portion 50 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion side flange 20 are deformed. The effect of securing the amount of deflection (particularly the flange on the crown portion side 20) is reduced.
When the first distance L1 exceeds the above range, the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown side flange 20 and the upper end 2022A of the inclined surface 2022. The effect of ensuring the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced by deforming the face portion 26 and the crown portion side flange 20 more upward than the above.
Further, when the second distance L2 is within the above range, the deformation amount of the deformation inducing portion 50 can be secured at the time of hitting the ball, which is advantageous in securing the deflection amount of the face portion 26 and the crown portion side flange 20.
When the second distance L2 is less than the above range, the distance from the upper end 2022A of the inclined surface 2022 to the welded portion (brazing is also possible) is too short, so that the deformation inducing portion 50 is deformed to the upper side more than the other portions. , The effect of securing the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.
If the second distance L2 exceeds the above range, the distance from the upper end 2022A of the inclined surface 2022 to the welded portion (brazing is also possible) is too long, so that even if the ball and the head come into contact with each other and are separated from each other, The deformation of the crown portion away from the face portion 26 remains, resulting in energy loss, and the deformation inducing portion 46 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 ( In particular, the effect of securing the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.
When the third distance L3 is within the above range, the deformation inducing portion 50 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced. The effect of securing is improved, and the effect of securing the sweet area is improved.
When the third distance L3 is less than the above range, the distance of the inclined surface 2022 is too short, so that the deformation inducing portion 50 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 is increased. The effect of securing (particularly the flange 20 on the crown portion side) is reduced, and the effect of securing the sweet area is reduced.
When the third distance L3 exceeds the above range, the distance of the inclined surface 2022 is too long, so that the stress at the time of hitting is dispersed between the front edge 2002 of the crown side flange 20 and the rear end 2022B of the inclined surface 2022. Therefore, the effect of deforming the deformation inducing portion 50 to the upper side more than the other portions and securing the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced.
Further, since the definition of the flange angle θ1 is the same as the content described with reference to FIG. 19 in the first embodiment, the description thereof will be omitted.

According to such a second embodiment, the same effect as that of the first embodiment can be obtained.
As shown in FIG. 24 (B), when the golf ball is hit, the deformation inducing portion 50 is deformed more than the other portions of the crown portion 28.
Further, since the bead portion 48 having high rigidity inevitably generated during the manufacture of the cup face structure is located at the rear end of the deformation inducing portion 50, the stress is surely concentrated on the deformation inducing portion 50 when the golf ball is hit. This is more advantageous in ensuring a large amount of deformation of the deformation-inducing portion 50, that is, a large amount of deformation of the crown portion 28 near the face portion 26.
Further, since the bead portion 48 having high rigidity inevitably generated during the manufacture of the cup face structure is located at the front end of the crown portion 28 portion of the head body 12, the degree of contribution to the deflection of the face portion 26 is small. This is advantageous in suppressing unnecessary deformation of the crown portion 28 of the head body 12 behind the bead portion 48.
Therefore, in a golf club head having a cup face structure, by effectively utilizing the bead portion 48 that is inevitably generated during the manufacture of the cup face structure, it is possible to reliably concentrate the stress on the deformation inducing portion 50 when the golf ball is hit. This makes it possible to secure a large amount of deformation of the crown portion 28 near the face portion 26. Therefore, the amount of deflection of the face portion 26 can be increased, the sweet area can be expanded, the coefficient of restitution can be increased, and the launch angle can be increased, which is advantageous in improving the initial velocity and the flight distance.
Further, as compared with the conventional golf club head in which the deformation inducing portion is provided on the crown portion of the golf club head having no cup face structure, the golf club head 10 of the present embodiment is inevitably manufactured at the time of manufacturing the cup face structure. Since the generated bead portion 48 is effectively used, it is not necessary to newly provide a reinforcing bead portion, stress can be reliably concentrated on the deformation inducing portion 50 by a simple structure, and the deformation inducing portion 50 is made large. It can be deformed by the amount of deformation. Therefore, compared to a conventional golf club head in which a deformation-inducing portion is provided on the crown portion of the golf club head which does not have a cup face structure, the sweet area can be expanded by a simple structure, the coefficient of restitution is increased, and the launch angle is increased. Is possible, which is advantageous in improving the initial velocity and flight distance.

(Third Embodiment)
Next, the third embodiment will be described with reference to FIGS. 25, 26, 27 (A), and 27 (B).
Also in the third embodiment, a deformation inducing portion 52 that induces deformation when the golf ball is hit is formed extending along the toe heel direction between the leading edge 2002 and the trailing edge 2004 of the crown portion side flange 20. ing.
In the third embodiment, the configuration of the deformation inducing unit 52 is different from that in the first and second embodiments.
The crown portion side flange 20 has a recess 2030 extending in the toe heel direction and recessing toward the sole portion 30 in the intermediate portion between the leading edge 2002 and the trailing edge 2004 of the crown portion side flange 20.
The deformation inducing portion 52 includes a front surface 2034 located between the leading edge 2002 of the crown portion side flange 20 and the leading edge 2032 of the recess 2030, and a trailing edge 2004 of the crown portion side flange 20 and a trailing edge 2036 of the recess 2030. It is configured to include a rear surface 2038 located between them and a recess 2030.

Next, with reference to FIG. 26, the definition of each portion of the crown portion side flange 20 will be described.
In the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP is 4 mm to 20 mm.
In the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 5 mm to 20 mm.
In the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 1 mm or more and 7 mm or less. Is.
In the face reference cross section Pf, the fourth distance L4 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 1 mm or more and 7 mm or less. Is.
When the first distance L1 is within the above range, the stress concentrated on the deformation inducing portion 52 at the time of hitting the ball is increased, the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion side are formed. This is advantageous in ensuring the amount of deflection of the flange 20.
When the first distance L1 is less than the above range, the stress concentrated on the deformation inducing portion 52 is reduced, the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion side flange 20 are deformed. The effect of securing the amount of deflection (particularly the flange on the crown portion side 20) is reduced.
When the first distance L1 exceeds the above range, the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown side flange 20 and the front edge 2032 of the recess 2030. The effect of ensuring the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced by deforming the face portion 26 and the crown portion side flange 20 more upward than the above.
Further, when the second distance L2 is within the above range, the deformation amount of the deformation inducing portion 52 can be secured at the time of hitting the ball, which is advantageous in securing the deflection amount of the face portion 26 and the crown portion side flange 20.
When the second distance L2 is less than the above range, the distance from the trailing edge 2036 of the recess 2030 to the welded portion (brazing is also possible) is too short, so that the deformation inducing portion 52 is deformed to the upper side more than the other portions. , The effect of securing the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.
If the second distance L2 exceeds the above range, the distance from the trailing edge 2036 of the recess 2030 to the welded portion (brazing is also possible) is too long, so that even if the ball and the head come into contact with each other and are separated from each other, The deformation of the crown portion away from the face portion 26 remains, resulting in energy loss, and the inducing portion 46 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly). The effect of securing the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.
When the third distance L3 is within the above range, the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced. The effect of securing is improved, and the effect of securing the sweet area is improved.
When the third distance L3 is less than the above range, the depth of the recess 2030 is too small, so that the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 is increased. The effect of securing (particularly the flange 20 on the crown portion side) is reduced, and the effect of securing the sweet area is reduced.
If the third distance L3 exceeds the above range, the depth of the recess 2030 is too large, and the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown side flange 20 and the lower end 2030A of the recess 2030. The effect of deforming the deformation-inducing portion 52 upward more than the other portions and securing the amount of deflection of the face portion 26 and the crown portion-side flange 20 is reduced.
When the fourth distance L4 is within the above range, the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced. The effect of securing is improved, and the effect of securing the sweet area is improved.
When the fourth distance L4 is less than the above range, the depth of the recess 2040 is too small, so that the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 is increased. The effect of securing (particularly the flange 20 on the crown portion side) is reduced, and the effect of securing the sweet area is reduced.
When the fourth distance L4 exceeds the above range, the depth of the recess 2040 is too large, and the stress at the time of hitting the ball is dispersed between the lower end 2040A of the recess 2040 and the trailing edge 2036 of the recess 2030, which induces deformation. The effect of deforming the portion 52 to the upper side more than the other portions and securing the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced.
Further, since the definition of the flange angle θ1 is the same as the content described with reference to FIG. 19 in the first embodiment, the description thereof will be omitted.

According to such a third embodiment, the same effect as that of the first embodiment can be obtained.
As shown in FIG. 27 (B), when the golf ball is hit, the deformation inducing portion 52 is deformed more than the other portions of the crown portion 28.
Further, since the bead portion 48 having high rigidity inevitably generated during the manufacture of the cup face structure is located at the rear end of the deformation inducing portion 52, the stress is surely concentrated on the deformation inducing portion 52 when the golf ball is hit. This is more advantageous in ensuring a large amount of deformation of the deformation-inducing portion 52, that is, a large amount of deformation of the crown portion 28 near the face portion 26.
Further, since the bead portion 48 having high rigidity inevitably generated during the manufacture of the cup face structure is located at the front end of the crown portion 28 portion of the head body 12, the degree of contribution to the deflection of the face portion 26 is small. This is advantageous in suppressing unnecessary deformation of the crown portion 28 of the head body 12 behind the bead portion 48.
Therefore, in a golf club head having a cup face structure, by effectively utilizing the bead portion 48 that is inevitably generated during the manufacture of the cup face structure, it is possible to reliably concentrate the stress on the deformation inducing portion 52 when the golf ball is hit. This makes it possible to secure a large amount of deformation of the crown portion 28 closer to the face portion 26. Therefore, the amount of deflection of the face portion 26 can be increased, the sweet area can be expanded, the coefficient of restitution can be increased, and the launch angle can be increased, which is advantageous in improving the initial velocity and the flight distance.
Further, as compared with the conventional golf club head in which the deformation inducing portion is provided on the crown portion of the golf club head having no cup face structure, the golf club head 10 of the present embodiment is inevitably manufactured at the time of manufacturing the cup face structure. Since the generated bead portion 48 is effectively used, it is not necessary to newly provide a reinforcing bead portion, stress can be reliably concentrated on the deformation inducing portion 52 by a simple structure, and the deformation inducing portion 52 is large. It can be deformed by the amount of deformation. Therefore, compared to a conventional golf club head in which a deformation-inducing portion is provided on the crown portion of the golf club head which does not have a cup face structure, the sweet area can be expanded by a simple structure, the coefficient of restitution is increased, and the launch angle is increased. Is possible, which is advantageous in improving the initial velocity and flight distance.

In each of the above-described embodiments, the deformation inducing portion 46 including the front inclined surface 2010, the rear inclined surface 2012, and the ridge line 2014, and the upper surface 2020, the inclined surface 2022, and the lower surface 2024 are included. The deformation-inducing portion 52 and the deformation-inducing portion 52 including the recess 2030 have been described. However, the deformation-inducing portion may have a structure in which stress is concentrated when the golf ball is hit to induce deformation, as described above. It is not limited to the structure of the embodiment. However, if the deformation-inducing portion is configured with the structure of the above-described embodiment, it is advantageous in easily and surely forming the deformation-inducing portion.

Hereinafter, experimental examples of the present invention will be described.
28 to 36 are diagrams showing the experimental results of the golf club head 10 according to the present invention.
A golf club head 10 as a sample was prepared for each experimental example, and the following four evaluation items were measured to obtain indexes (evaluation points), and the total points of the four indexes were obtained.
In the following experimental examples, the golf club heads of the first, second, and third embodiments were used as experimental targets.

(1) Initial speed A golf club equipped with a golf club head 10 was installed on a swing robot, and an actual hit test was conducted under the following conditions, and the average value of the initial speed at 9 RBIs was evaluated by an index. The index of the experimental example corresponding to the comparative example is set to 100, and the larger the index, the faster the initial velocity and the better the evaluation.
Head speed: 40m / s
Ball: Progear TR Spin (trade name) manufactured by Progear Co., Ltd.
The hitting positions were the following 9 hitting points in total, and the ball was hit 5 times at each hitting point.
Three hit points: a center point Pc of the face surface 14A, a point 7 mm away from the center point Pc in the toe direction on a straight line passing through the center point Pc and orthogonal to the face center line CL, and a point 7 mm away in the heel direction.
A point separated from the center point Pc by 5 mm in the crown portion 16 direction on the face center line CL, and a point separated from the above point by 7 mm in the toe direction on the upper 5 mm line passing through this point and orthogonal to the face center line CL. Three points separated by 7 mm in the heel direction.
A point separated from the center point Pc by 5 mm in the sole portion 18 direction on the face center line CL, and a point separated from the above point by 7 mm in the toe direction on the lower 5 mm line passing through this point and orthogonal to the face center line CL. Three points separated by 7 mm in the heel direction.

(2) Direction The direction when the golf ball is actually hit by the golf club head 10 is evaluated by an index. The index of the experimental example corresponding to the comparative example is set to 100, and the larger the index, the better the directionality.
Here, the directionality is obtained as follows.
That is, a target point is set in the hitting field and the golfer hits the ball toward the target point. Then, the distance between the straight line connecting the hitting point and the target point and the stopping point of the hit ball is recorded as the directional blur width (yard). These were performed for each golf club by 5 balls, and the average value of the standard deviations of the directional blur widths was obtained as directional evaluation data.
Here, the directional evaluation data was obtained for each of the 20 subjects using the golf clubs of each experimental example, and the average value of the directional evaluation data of 20 persons was obtained for each of the golf clubs. Then, the average value of the evaluation data of the experimental examples corresponding to the comparative examples is set to 100, and the experimental examples other than the comparative examples are indexed ((the average value of the evaluation data of the experimental examples corresponding to the comparative examples / the experimental examples other than the comparative examples). It was evaluated by the average value of the evaluation data) × 100). That is, the higher the index, the better the direction.

(3) Flying distance The flying distance obtained in the actual hitting test at the above hitting point position in the initial velocity test was measured.
The average value of the flight distance of a total of 9 RBIs is obtained, and the index of the experimental example corresponding to the comparative example is set to 100, and the larger the index, the longer the flight distance and the better the evaluation.

(4) Durability The golf ball is repeatedly hit on the face surface 14A of the golf club head 10 fixed to the shaft with an air cannon, and the number of hits required until the face portion 14 is deformed or damaged is measured and the number of hits is measured. Was indexed. The ball speed was 50 m / s. The hitting point position was the center point Pc of the face surface 14A.
In this case, the measurement result of the golf club head 10 of the experimental example corresponding to the comparative example is shown as an index of 100. The larger the index, the better the evaluation.

(5) Total score The total score was the sum of the four indices of initial velocity, directionality, flight distance, and durability described above.
The total score of the experimental examples corresponding to the comparative examples is set to 400, and the larger the total score, the better the evaluation.

In the following, experimental examples of golf club heads according to the first, second, and third embodiments will be described separately.

(Experimental example corresponding to the golf club of the first embodiment)
For the golf club of the first embodiment, an experiment was conducted under the following conditions.
(Condition 1)
Satisfy the provisions of claims 1 and 2, and change the conditions specified in claim 3.
However, in all the experimental examples, claims 4, 5 and 6 were set to constant conditions outside the specified range.
(Condition 2)
Satisfy the provisions of claims 1, 2 and 3, and change the conditions specified in claims 4, 5 and 6.
In the following Experimental Examples 2 to 14, the distances and wall thicknesses of the sole portion side flanges 22 specified in claims 3, 4 and 5 are different as described in detail below.
However, in Experimental Examples 2 to 14, the shape of the face member 14 excluding the sole portion side flange 22 and the shape of the head body 12 are all the same, and are composed of the head body 12 and the face member 14. The weight and volume of the golf club head 10 are all the same.

(Condition 1)
Next, an experimental example under condition 1 will be described with reference to FIG. 28.
In Experimental Examples 2 to 6, the wall thickness t1 of the crown side flange 20 located on the face portion 26 side of the ridge line 2014 and the wall thickness t2 of the crown portion side flange 20 located on the face back side of the ridge line 2014 are obtained. The constant value is 1.0 mm, which does not satisfy the provision of claim 4.
Further, in Experimental Examples 2 to 6, the weighted average values ΔT1 and ΔT2 of the wall thickness are 1.0 mm, but the provisions of claim 5 are not satisfied because they do not satisfy claim 4.
Further, in Experimental Examples 2 to 6, the flange angle θ1 is set to 52 °, which does not satisfy the provision of claim 6.

As shown in FIG. 28, Experimental Example 1 has a cup face structure but is configured in the same manner as the prior art (Japanese Patent Laid-Open No. 2002-17913) having no deformation-inducing portion, and corresponds to a comparative example. It does not satisfy all the provisions of claims 1 to 5 of the present invention.
In Experimental Example 1, the wall thickness of the crown side flange 20 was set to a constant value of 1.0 mm.

In Experimental Example 2, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 on the horizontal plane HP is 2.0 mm, and 4 mm to claim 3 It is below the range of 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 4.0 mm, which is 5 mm to 20 mm according to claim 3. It is below the range.
Therefore, the initial velocity is 105, the directionality is 104, the flight distance is 105, the durability is 105, and the total score is 419. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 4 satisfying the provision of claim 3. Compared to ~ 6, all evaluations are slightly lower.
This is because the first distance L1 is below the specified range, the stress concentrated on the deformation inducing portion 46 is reduced, the deformation inducing portion 46 is deformed more than the other portions, and the amount of deflection of the face portion 26 is reduced. In addition, since the second distance L2 is less than the specified range, the crown portion side flange 20 is too short, so that the amount of deflection of the crown portion 28 closer to the face portion 26 is reduced when hitting a ball. However, the amount of deflection of the face portion 26 and the effect of securing the sweet area are reduced.

In Experimental Example 3, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 on the horizontal plane HP is 22.0 mm, and 4 mm to claim 3 It exceeds the range of 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 22.0 mm, which is 5 mm to 20 mm according to claim 3. It is out of range.
Therefore, the initial velocity is 106, the directionality is 105, the flight distance is 106, the durability is 105, and the total score is 422. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 4 satisfying the provision of claim 3. Compared to ~ 6, all evaluations are slightly lower.
This is because the first distance L1 exceeds the specified range, so that the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown side flange 20 and the ridge line 2014. Since the effect of securing the amount of deflection of the face portion 26 is reduced and the second distance L2 exceeds the specified range, the crown portion side flange 20 is too long when hitting a ball. Since the stress of the above is dispersed in the crown portion side flange 20, the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting the ball is reduced, and the effect of securing the amount of deflection of the face portion 26 and the sweet area is reduced. Is.

In Experimental Example 4, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 on the horizontal plane HP is 6.0 mm, and 4 mm to claim 3 It is within the range of 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 6.0 mm, which is 5 mm to 20 mm according to claim 3. It is within the range.
Therefore, the initial velocity is 111, the directionality is 113, the flight distance is 113, the durability is 110, and the total score is 447, and all the evaluations are improved as compared with Experimental Examples 1, 2 and 3.
This is because the first distance L1 is within the above range, so that the stress concentrated on the deformation inducing portion 46 at the time of hitting the ball is increased, the deformation inducing portion 46 is deformed more than other portions, and the amount of deflection of the face portion 26 is increased. Also, since the second distance L2 is within the above range, it is possible to secure the amount of deformation of the deformation inducing portion 46 at the time of hitting the ball, which is advantageous in securing the amount of deflection of the face portion 26. This is to become.

In Experimental Example 5, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 on the horizontal plane HP is 18.0 mm, and 4 mm to claim 3 It is within the range of 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 18.0 mm, which is 5 mm to 20 mm according to claim 3. It is within the range.
Therefore, the initial velocity is 112, the directionality is 113, the flight distance is 112, the durability is 110, and the total score is 447, and all the evaluations are improved as compared with Experimental Examples 1, 2 and 3.
This is for the same reason as in Experimental Example 4.

In Experimental Example 6, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 on the horizontal plane HP is 12.0 mm, and 4 mm to claim 3 It is within the range of 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 15.0 mm, which is 5 mm to 20 mm according to claim 3. It is within the range.
Therefore, the initial velocity is 115, the directionality is 113, the flight distance is 115, the durability is 110, and the total score is 453, and all the evaluations are improved as compared with Experimental Examples 1, 2 and 3.
This is for the same reason as in Experimental Example 4.

Therefore, Experimental Examples 2 and 3 that satisfy the provisions of Claims 1 and 2 and do not satisfy the provisions of Claims 3, 4, 5, and 6 are relative to Experimental Example 1 that does not satisfy all the provisions of Claims 1 to 6. The effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent.
Further, Experimental Examples 4, 5 and 6 satisfying the provisions of claims 1, 2 and 3 and not satisfying the provisions of claims 4, 5 and 6 satisfy the provisions of claims 1 and 2 and satisfy the provisions of claims 3 and 4. Compared to Experimental Examples 2 and 3 that do not satisfy the provisions of 5 and 6, the effect of improving the initial speed, directionality, flight distance, durability, and total score is excellent.

(Condition 2)
Next, an experimental example under condition 2 will be described with reference to FIG. 29.
As described above, condition 2 satisfies the provisions of claims 1, 2 and 3, does not satisfy the provision of claim 6, and changes the conditions specified in claims 4 and 5.
In Experimental Examples 7 to 14, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 on the horizontal plane HP is 12.0 mm, according to claim 3. It was assumed that the regulation of the range of 4 mm to 20 mm was satisfied.
Further, in Experimental Examples 7 to 14, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 12.0 mm, which is claimed. It is assumed that the provision of the item 3 within the range of 5 mm to 20 mm is satisfied.
Further, in Experimental Examples 7 to 14, the flange angle θ1 is set to 52 °, which does not satisfy the provision of claim 6.

In Experimental Example 7, it is assumed that the provision of the wall thickness t1> t2 in claim 4 is not satisfied, and the weighted average ΔT1 of the wall thickness of the crown portion side flange 20 located on the face portion 26 side of the ridge line 2014 is 0. The weighted average ΔT2 of the wall thickness of the crown portion side flange 20 located on the face back side of the ridge line 2014 at 4 mm was set to 0.7 mm, and the provision of claim 5 was not satisfied.
Therefore, the initial velocity is 116, the directionality is 113, the flight distance is 116, the durability is 105, and the total score is 450. Compared with Experimental Examples 9, 10, 13, and 14 that satisfy the regulations, all the evaluations are slightly lower.
This is because the condition of wall thickness t1> wall thickness t2 is not satisfied, and the effect of securing the amount of deformation of the crown portion side flange 20 located on the face portion 26 side of the ridge line 2014 at the time of hitting is reduced. This is because the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting the ball is secured, and the effect of securing a large amount of deflection of the face portion 26 and the sweet area is reduced.
Further, since the wall thickness t1 of the crown side flange 20 and the weighted average ΔT1 of the wall thickness are 0.4 mm, which is less than the range of 0.6 mm to 1.4 mm of claim 5, durability is ensured. The effect is slightly reduced.

Although Experimental Example 8 satisfies the provision of wall thickness t1> t2 in claim 4, the weighted average ΔT1 of the wall thickness of the crown side flange 20 from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 is 1.7 mm. The weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 0.7 mm, which exceeds the range of 0.6 mm to 1.4 mm of claim 5. It was set within the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 117, the directionality is 114, the flight distance is 116, the durability is 110, and the total score is 457. While all the evaluations are improved as compared with Experimental Example 7, the experiments satisfying the provisions of claims 4 and 5. Compared with Examples 9, 10, 13, and 14, the evaluations other than durability are slightly lower.
This is because the weighted average ΔT1 exceeds the above range and the wall thickness of the crown portion side flange 20 is thick, so that the amount of deformation of the crown portion side flange 20 located on the face portion 26 side of the ridge line 2014 at the time of hitting is secured. This is because the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting the ball is reduced, and the effect of securing a large amount of deflection of the face portion 26 and the sweet area is reduced.

Experimental Example 9 satisfies the provision of wall thickness t1> t2 in claim 4, and the weighted average ΔT1 of the wall thickness of the crown side flange 20 from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 is 0.8 mm. Yes, it is within the range of 0.6 mm to 1.4 mm of claim 5, and the weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 0.7 mm. It was set within the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 123, the directionality is 124, the flight distance is 124, the durability is 115, and the total score is 486, and all the evaluations are improved as compared with Experimental Example 7.
Since this satisfies the provisions of claims 4 and 5, the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting, the amount of deflection of the face portion 26, and a large amount of sweet area is ensured. Because.

Experimental Example 10 satisfies the provision of wall thickness t1> t2 in claim 4, and the weighted average ΔT1 of the wall thickness of the crown side flange 20 from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 is 1.3 mm. Yes, it is within the range of 0.6 mm to 1.4 mm of claim 5, and the weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 0.7 mm. It was set within the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 122, the directionality is 121, the flight distance is 120, the durability is 115, and the total score is 478, and all the evaluations are improved as compared with Experimental Example 7.
Since this satisfies the provisions of claims 4 and 5, the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting, the amount of deflection of the face portion 26, and a large amount of sweet area is ensured. Because.

Although Experimental Example 11 satisfies the provision of the wall thickness t1> t2 in claim 4, the weighted average ΔT1 of the wall thickness of the crown portion side flange 20 from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 is 1.1 mm. Although it is within the range of 0.6 mm to 1.4 mm of claim 5, the weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 0.3 mm. It is below the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 123, the directionality is 123, the flight distance is 123, the durability is 105, and the total score is 474. While all the evaluations are improved as compared with Experimental Example 7, the experiments satisfying the provisions of claims 4 and 5. Compared with Examples 9, 10, 13 and 14, the evaluation of durability is slightly lower.
This is because the wall thickness of the crown portion side flange 20 is thin, so that the effect of ensuring durability is reduced.

Although Experimental Example 12 satisfies the provision of wall thickness t1> t2 in claim 4, the weighted average ΔT1 of the wall thickness of the crown side flange 20 from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 is 1.1 mm. Although it is within the range of 0.6 mm to 1.4 mm of claim 5, the weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 1.2 mm. It exceeds the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 117, the directionality is 113, the flight distance is 115, the durability is 115, and the total score is 460. While all the evaluations are improved as compared with Experimental Example 7, the experiments satisfying the provisions of claims 4 and 5. Compared with Examples 9, 10, 13, and 14, the evaluations other than durability are slightly lower.
This is because the weighted average ΔT2 exceeds the above range, and the wall thickness of the crown portion side flange 20 is thick, so that the amount of deformation of the crown portion side flange 20 located on the face portion 26 side of the ridge line 2014 at the time of hitting is secured. This is because the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting the ball is reduced, and the effect of securing a large amount of deflection of the face portion 26 and the sweet area is reduced.

Experimental example 13 satisfies the provision of wall thickness t1> t2 in claim 4, and the weighted average ΔT1 of the wall thickness of the crown side flange 20 from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 is 1.1 mm. Yes, it is within the range of 0.6 mm to 1.4 mm of claim 5, and the weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 0.5 mm. It was set within the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 124, the directionality is 125, the flight distance is 123, the durability is 115, and the total score is 487, and all the evaluations are improved as compared with Experimental Example 7.
Since this satisfies the provisions of claims 4 and 5, the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting, the amount of deflection of the face portion 26, and a large amount of sweet area is ensured. Because.

Experimental example 14 satisfies the provision of wall thickness t1> t2 in claim 4, and the weighted average ΔT1 of the wall thickness of the crown side flange 20 from the front edge 2002 of the crown side flange 20 to the ridgeline 2014 is 1.1 mm. Yes, it is within the range of 0.6 mm to 1.4 mm of claim 5, and the weighted average ΔT2 of the wall thickness of the crown portion side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown portion side flange 20 is 0.9 mm. It was set within the range of 0.4 mm to 1.0 mm of claim 5.
Therefore, the initial velocity is 123, the directionality is 122, the flight distance is 122, the durability is 115, and the total score is 482, and all the evaluations are improved as compared with Experimental Example 7.
Since this satisfies the provisions of claims 4 and 5, the effect of securing the amount of deflection of the crown portion 28 closer to the face portion 26 at the time of hitting, the amount of deflection of the face portion 26, and a large amount of sweet area is ensured. Because.

Therefore, Experimental Examples 8, 11, and 12 satisfying the provisions of claims 1 to 4 but not satisfying the provisions of claims 5 and 6 satisfy the provisions of claims 1, 2, and 3, but claims 4, 5, and 6. Compared to Experimental Example 7 which does not satisfy the provision of 6, the effect of improving the initial speed, directionality, flight distance, durability, and total score is excellent.
Further, Experimental Examples 9, 10, 13, and 14 satisfying all the provisions of claims 1 to 5 and not satisfying the provisions of claim 6 satisfy the provisions of claims 1 to 4, but claim 5 and 6. The effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent as compared with Experimental Examples 7, 8, 11, and 12 that do not meet the regulations.

(Condition 3)
Next, an experimental example under condition 3 will be described with reference to FIG.
As described above, condition 3 satisfies the provisions of claims 1 to 5 and changes the condition specified in claim 6.
In Experimental Examples 15 to 18, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 on the horizontal plane HP is 12.0 mm, according to claim 3. It was assumed that the regulation of the range of 4 mm to 20 mm was satisfied.
Further, in Experimental Examples 15 to 18, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the leading edge 2002 to the trailing edge 2004 of the crown portion side flange 20 onto the horizontal plane HP is 12.0 mm, which is claimed. It is assumed that the provision of the item 3 within the range of 5 mm to 20 mm is satisfied.
Further, in Experimental Examples 15 to 18, the provision of the wall thickness t1> t2 in claim 4 is satisfied, and the weighted average ΔT1 of the wall thickness of the crown portion side flange 20 from the front edge 2002 of the crown portion side flange 20 to the ridge line 2014 is It is 0.8 mm, is within the range of 0.6 mm to 1.4 mm of claim 5, and is a weighted average ΔT2 of the wall thickness of the crown side flange 20 from the ridge line 2014 to the trailing edge 2004 of the crown side flange 20. Was 0.7 mm, which was within the range of 0.4 mm to 1.0 mm of claim 5.

In Experimental Example 15, the flange angle θ1 in claim 6 is set to 12 °, and the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6 is not satisfied.
Therefore, the initial velocity and the flight distance are slightly lower than those of Experimental Examples 16 and 17, which have an initial velocity of 122, a directionality of 122, a flight distance of 123, a durability of 114, and a total point of 481 and satisfy all the provisions of claims 1 to 6. ing.
This is because the flange angle θ1 is less than the above range, so that the effect of securing the amount of deformation of the deformation inducing portion 46 at the time of hitting the ball is reduced, and the effect of securing the flight distance is reduced.

In Experimental Example 16, the flange angle θ1 in claim 6 is 16 °, which satisfies the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 125, the directionality is 124, the flight distance is 128, the durability is 115, and the total points are 492. Compared with Experimental Examples 15 and 18 which do not satisfy the sixth aspect, the initial velocity and the flight distance are improved.
This is because since the flange angle θ1 is within the above range, the amount of deformation of the deformation inducing portion 46 can be secured at the time of hitting the ball, and the effect of securing the flight distance is improved.

In Experimental Example 17, the flange angle θ1 in claim 6 is 49 °, which satisfies the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 126, the directionality is 124, the flight distance is 127, the durability is 115, and the total points are 492. Compared with Experimental Examples 15 and 18 which do not satisfy the sixth aspect, the initial velocity and the flight distance are improved.
This is because since the flange angle θ1 is within the above range, the amount of deformation of the deformation inducing portion 46 can be secured at the time of hitting the ball, and the effect of securing the flight distance is improved.

In Experimental Example 18, the flange angle θ1 in claim 6 is 51 °, which does not satisfy the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 122, the directionality is 121, the flight distance is 124, the durability is 115, and the total points are 482. ing.
This is because the flange angle θ1 exceeds the above range, so that the golfer tends to feel a sense of discomfort in the shape of the golf club head, it becomes difficult to swing, the head speed decreases, and the effect of securing the flight distance decreases. Because.

Therefore, Experimental Examples 16 and 17 satisfying all the provisions of Claims 1 to 6 satisfy the initial speed and directionality with respect to Experimental Examples 15 and 18 satisfying the provisions of Claims 1 to 5, but do not satisfy the provisions of Claim 6. It has an excellent effect of improving flight distance, durability, and total score.

(Experimental example corresponding to the golf club of the second embodiment)
For the golf club of the second embodiment, an experiment was conducted under the following conditions.
(Condition 1)
Satisfy the provisions of claims 1 and 7, and change the conditions specified in claim 8.
However, in all the experimental examples, claims 9 and 10 were set to constant conditions outside the specified range.
(Condition 2)
Satisfy the provisions of claims 1, 7 and 8 and change the conditions specified in claim 9.
However, in all the experimental examples, claim 10 was set to a certain condition outside the specified range.
(Condition 3)
Satisfy the provisions of claims 1, 7, 8 and 9, and change the conditions specified in claim 10.
In the following Experimental Examples 20 to 32, the shape of the face member 14 excluding the sole portion side flange 22 and the shape of the head body 12 are all the same, and the shape of the face member 14 is the same. The wall thickness and the wall thickness of the head body 12 are all the same, and the weight and volume of the golf club head 10 composed of the head body 12 and the face member 14 are all the same.

(Condition 1)
Next, an experimental example under condition 1 will be described with reference to FIG. 31.
As described above, condition 1 satisfies the provisions of claims 1 and 7, and changes the condition specified in claim 8.
However, in all the experimental examples, claims 9 and 10 were set to constant conditions outside the specified range.
That is, in Experimental Examples 20 to 24, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the upper end to the lower end of the inclined surface onto the vertical surface orthogonal to the face reference cross section Pf is 8 mm, and is 1 mm or more and 7 mm. The following provisions of claim 9 are not satisfied.
Further, in Experimental Examples 20 to 24, the flange angle θ1 is set to 52 °, which does not satisfy the provision of claim 10.
As shown in FIG. 31, Experimental Example 1 is the same as Experimental Example 1 in the first embodiment, and thus the description thereof will be omitted.

In Experimental Example 20, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP is 2.0 mm, which is claimed. It is below the range of 4 mm to 20 mm in item 8.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 4.0 mm, according to claim 8. It is below the range of 5 mm to 20 mm.
Therefore, the initial velocity is 104, the directionality is 103, the flight distance is 104, the durability is 105, and the total score is 416. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 22 satisfying the provision of claim 8. Compared to ~ 24, all evaluations are slightly lower.
This is because the first distance L1 is below the specified range, the stress concentrated on the deformation inducing portion 52 is reduced, the deformation inducing portion 46 is deformed more than the other portions, and the amount of deflection of the face portion 26 is reduced. In addition, since the second distance L2 is less than the specified range, the crown portion side flange 20 is too short, so that the amount of deflection of the crown portion 28 closer to the face portion 26 is reduced when hitting a ball. However, the amount of deflection of the face portion 26 and the effect of securing the sweet area are reduced.

In Experimental Example 21, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP in the face reference cross section Pf is 22.0 mm, which is claimed. It exceeds the range of 4 mm to 20 mm in item 8.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 22.0 mm, according to claim 8. It exceeds the range of 5 mm to 20 mm.
Therefore, the initial velocity is 106, the directionality is 105, the flight distance is 107, the durability is 104, and the total score is 422. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 22 satisfying the provision of claim 8. Compared to ~ 24, all evaluations are slightly lower.
This is because the first distance L1 exceeds the specified range, so that the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown side flange 20 and the rear end 2020A of the upper surface 2020, which induces deformation. Since the portion 52 is deformed more than the other portions, the effect of securing the amount of deflection of the face portion 26 is reduced, and the second distance L2 exceeds the specified range, the crown portion side flange 20 is long. Since the stress at the time of hitting is dispersed to the crown side flange 20, the amount of deflection of the crown portion 28 near the face portion 26 at the time of hitting is reduced, which is effective in securing the amount of deflection of the face portion 26 and the sweet area. This is because

In Experimental Example 22, the distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP in the face reference cross section Pf is 6.0 mm, which is claimed. Item 8 is in the range of 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 6.0 mm, according to claim 8. It is in the range of 5 mm to 20 mm.
Therefore, the initial velocity is 112, the directionality is 112, the flight distance is 112, the durability is 111, and the total score is 447, and all the evaluations are improved as compared with Experimental Examples 1, 20, and 21.
This is because the first distance L1 is within the above range, so that the stress concentrated on the deformation inducing portion 52 at the time of hitting the ball is increased, the deformation inducing portion 52 is deformed more than other portions, and the amount of deflection of the face portion 26 is increased. Also, since the second distance L2 is within the above range, it is possible to secure the amount of deformation of the deformation inducing portion 52 at the time of hitting the ball, which is advantageous in securing the amount of deflection of the face portion 26. This is to become.

In Experimental Example 23, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP in the face reference cross section Pf is 18.0 mm. Item 8 is in the range of 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 18.0 mm, according to claim 8. It is in the range of 5 mm to 20 mm.
Therefore, the initial velocity is 113, the directionality is 112, the flight distance is 113, the durability is 110, and the total score is 448, and all the evaluations are improved as compared with Experimental Examples 1, 20, and 21.
This is for the same reason as in Experimental Example 22.

In Experimental Example 24, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP in the face reference cross section Pf is 12.0 mm. Item 8 is in the range of 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 15.0 mm, according to claim 8. It is in the range of 5 mm to 20 mm.
Therefore, the initial velocity is 114, the directionality is 114, the flight distance is 115, the durability is 110, and the total score is 453, and all the evaluations are improved as compared with Experimental Examples 1, 20, and 21.
This is for the same reason as in Experimental Example 22.

Therefore, Experimental Examples 20 and 21 satisfying the provisions of claims 1 and 7 and not satisfying the provisions of claims 8, 9 and 10 are experiments that do not satisfy all the provisions of claims 1, 7, 8, 9 and 10. Compared to Example 1, the effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent.
Further, Experimental Examples 22, 23, and 24, which satisfy the provisions of claims 1, 7, and 8 and do not satisfy the provisions of claims 9, and 10, satisfy the provisions of claims 1, 7, and claim 8, 9, and 10. The effects of improving the initial velocity, directionality, flight distance, durability, and total score are superior to those of Experimental Examples 20 and 21 that do not satisfy the above requirements.

(Condition 2)
Next, an experimental example under condition 2 will be described with reference to FIG.
As described above, condition 2 satisfies the provisions of claims 1, 7 and 8 and changes the condition specified in claim 9.
However, in all the experimental examples, claims 9 and 10 were set to constant conditions outside the specified range.
That is, in Experimental Examples 25 to 28, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP is 12.0 mm. It is within the range of 4 mm to 20 mm of claim 8.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 12.0 mm, according to claim 8. It is in the range of 5 mm to 20 mm.
Further, in Experimental Examples 22 to 25, the flange angle θ1 is set to 52 °, which does not satisfy the provision of claim 10.

In Experimental Example 25, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the upper end 2022A (rear end 2020A of the upper surface 2020) of the inclined surface 2022 to the lower end 2022B on the vertical plane orthogonal to the face reference cross section Pf is , 0.5 mm, which is less than the range of 1 mm or more and 7 mm or less of claim 9.
Therefore, the initial velocity is 112, the directionality is 113, the flight distance is 113, the durability is 110, and the total score is 448. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 27 satisfying the provision of claim 9. , 28, all evaluations are slightly lower.
This is because the third distance L3 is below the specified range, and the distance of the inclined surface 2022 is too short, so that the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the face portion 26 and the crown portion are formed. This is because the effect of securing the amount of deflection of the side flange 20 (particularly the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.

In Experimental Example 26, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the upper end 2022A (rear end 2020A of the upper surface 2020) of the inclined surface 2022 to the lower end 2022B on the vertical plane orthogonal to the face reference cross section Pf is , 7.5 mm, which exceeds the range of 1 mm or more and 7 mm or less of claim 9.
Therefore, the initial velocity is 114, the directionality is 114, the flight distance is 113, the durability is 110, and the total score is 451. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 27 satisfying the provision of claim 9. , 28, all evaluations are slightly lower.
This is because the third distance L3 exceeds the specified range, and the distance of the inclined surface 2022 is too long, so that the stress at the time of hitting the ball is from the front edge 2002 of the crown side flange 20 to the rear end 2022B of the inclined surface 2022. This is because the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the effect of securing the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced.

In Experimental Example 27, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the upper end 2022A (rear end 2020A of the upper surface 2020) of the inclined surface 2022 to the lower end 2022B on the vertical plane orthogonal to the face reference cross section Pf is , 2.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 9.
Therefore, the initial velocity is 116, the directionality is 115, the flight distance is 117, the durability is 111, and the total score is 459. All the evaluations are improved as compared with Experimental Examples 1, 25, and 26.
This is because the third distance L3 is within the above range, the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange). This is because the effect of securing 20) is improved and the effect of securing the sweet area is improved.

In Experimental Example 28, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the upper end 2022A (rear end 2020A of the upper surface 2020) of the inclined surface 2022 to the lower end 2022B on the vertical plane orthogonal to the face reference cross section Pf is , 6.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 9.
Therefore, the initial velocity is 118, the directionality is 115, the flight distance is 118, the durability is 111, and the total score is 463, and all the evaluations are improved as compared with Experimental Examples 1, 25, and 26.
This is for the same reason as in Experimental Example 27.

Therefore, Experimental Examples 25 and 26 that satisfy the provisions of claims 1, 7, and 8 and do not satisfy the provisions of claims 9 and 10 are experiments that do not satisfy all the provisions of claims 1, 7, 8, 9, and 10. Compared to Example 1, the effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent.
Further, Experimental Examples 27 and 28 satisfying the provisions of claims 1, 7, 8 and 9 and not satisfying the provisions of claim 10 satisfy the provisions of claims 1, 7 and 8 and satisfy the provisions of claims 9 and 10. The effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent as compared with Experimental Examples 25 and 26 which do not satisfy the above conditions.

(Condition 3)
Next, an experimental example under condition 3 will be described with reference to FIG. 33.
As described above, condition 3 satisfies the provisions of claims 1, 7, 8 and 9, and changes the condition specified in claim 10.
That is, in Experimental Examples 29 to 32, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the rear end 2020A of the upper surface 2020 on the horizontal plane HP is 12.0 mm. It is within the range of 4 mm to 20 mm of claim 8.
Further, in Experimental Examples 29 to 32, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the rear end 2020A of the upper surface 2020 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 12.0 mm. It is within the range of 5 mm to 20 mm of claim 8.
Further, in Experimental Examples 29 to 32, in the face reference cross section Pf, the distance from the upper end 2022A (rear end 2020A of the upper surface 2020) to the lower end 2022B of the inclined surface 2022 is projected onto the vertical surface orthogonal to the face reference cross section Pf. The distance L3 is 4.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 9.

In Experimental Example 29, the flange angle θ1 in claim 10 is set to 12 °, and the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 10 is not satisfied.
Therefore, the initial velocity is 117, the directionality is 114, the flight distance is 118, the durability is 112, and the total points are 461. The flight distance is slightly reduced.
This is because the flange angle θ1 is less than the above range, so that the effect of securing the amount of deformation of the deformation inducing portion 46 at the time of hitting the ball is reduced, and the effect of securing the flight distance is reduced.

In Experimental Example 30, the flange angle θ1 in claim 10 is 16 °, which satisfies the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 123, the directionality is 124, the flight distance is 127, the durability is 114, and the total points are 488. Compared with Experimental Examples 29 and 32 which do not satisfy the tenth aspect, the initial velocity and the flight distance are improved.
This is because since the flange angle θ1 is within the above range, the amount of deformation of the deformation inducing portion 46 can be secured at the time of hitting the ball, and the effect of securing the flight distance is improved.

In Experimental Example 31, the flange angle θ1 in claim 10 is 49 °, which satisfies the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 128, the directionality is 125, the flight distance is 127, the durability is 114, and the total points are 494. Compared with Experimental Examples 29 and 32 which do not satisfy the tenth aspect, the initial velocity and the flight distance are improved.
This is because since the flange angle θ1 is within the above range, the amount of deformation of the deformation inducing portion 46 can be secured at the time of hitting the ball, and the effect of securing the flight distance is improved.

In Experimental Example 32, the flange angle θ1 in claim 10 is 51 °, which does not satisfy the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 116, the directionality is 115, the flight distance is 117, the durability is 111, and the total points are 459. The flight distance is slightly reduced.
This is because the flange angle θ1 exceeds the above range, so that the golfer tends to feel a sense of discomfort in the shape of the golf club head, it becomes difficult to swing, the head speed decreases, and the effect of securing the flight distance decreases. Because.

Therefore, Experimental Examples 30 and 31 satisfying all the provisions of claims 1, 7, 8, 9 and 10 satisfy the provisions of claims 1, 7, 8 and 9, but do not satisfy the provisions of claim 10. , 32 is excellent in the effect of improving the initial velocity, directionality, flight distance, durability, and total score.

(Experimental example corresponding to the golf club of the third embodiment)
For the golf club of the third embodiment, an experiment was conducted under the following conditions.
(Condition 1)
Satisfy the provisions of claims 1 and 11, and change the conditions specified in claim 12.
However, in all the experimental examples, claims 13, 14 and 15 are set to constant conditions outside the specified range.
(Condition 2)
Satisfy the provisions of claims 1, 11 and 12, and change the conditions specified in claim 13.
However, in all the experimental examples, claims 14 and 15 were set to constant conditions outside the specified range.
(Condition 3)
Satisfy the provisions of claims 1, 11, 12, and 13, and change the conditions specified in claim 14.
In the following Experimental Examples 33 to 46, the shape of the face member 14 excluding the sole portion side flange 22 and the shape of the head body 12 are all the same, and the shape of the face member 14 is the same. The wall thickness and the wall thickness of the head body 12 are all the same, and the weight and volume of the golf club head 10 composed of the head body 12 and the face member 14 are all the same.

(Condition 1)
Next, an experimental example under condition 1 will be described with reference to FIG. 34.
As described above, condition 1 satisfies the provisions of claims 1 and 11 and changes the condition specified in claim 12.
However, in all the experimental examples, claims 13 and 14 were set to constant conditions outside the specified range.
That is, in Experimental Examples 33 to 37, in the face reference cross section Pf, the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 is projected onto the vertical plane orthogonal to the face reference cross section Pf. The distance L3 is 8 mm, which does not satisfy the provision of claim 13 of 1 mm or more and 7 mm or less.
Further, in Experimental Examples 33 to 37, in the face reference cross section Pf, the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 is projected onto the vertical plane orthogonal to the face reference cross section Pf. The distance L4 is 8 mm, which does not satisfy the provision of claim 13 of 1 mm or more and 7 mm or less.
Further, in Experimental Examples 33 to 37, the flange angle θ1 is set to 52 °, which does not satisfy the provision of claim 14 of 15 ° or more and 50 ° or less.
As shown in FIG. 34, Experimental Example 1 is the same as Experimental Example 1 in the first embodiment, and thus the description thereof will be omitted.

In Experimental Example 33, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP in the face reference cross section Pf is 2.0 mm, which is claimed. It is below the range of 4 mm to 20 mm in Item 12.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 4.0 mm, according to claim 12. It is below the range of 5 mm to 20 mm.
Therefore, the initial velocity is 105, the directionality is 104, the flight distance is 104, the durability is 105, and the total score is 418. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 35 satisfying the provision of claim 12. Compared to ~ 37, all evaluations are slightly lower.
This is because the first distance L1 is below the specified range, the stress concentrated on the deformation inducing portion 52 is reduced, the deformation inducing portion 52 is deformed more than the other portions, and the amount of deflection of the face portion 26 is reduced. In addition, since the second distance L2 is less than the specified range, the crown portion side flange 20 is too short, so that the amount of deflection of the crown portion 28 closer to the face portion 26 is reduced when hitting a ball. However, the amount of deflection of the face portion 26 and the effect of securing the sweet area are reduced.

In Experimental Example 34, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP is 22.0 mm, which is claimed. It exceeds the range of 4 mm to 20 mm of Item 12.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 22.0 mm, according to claim 12. It exceeds the range of 5 mm to 20 mm.
Therefore, the initial velocity is 106, the directionality is 104, the flight distance is 106, the durability is 105, and the total score is 421. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 35 satisfying the provision of claim 12. Compared to ~ 37, all evaluations are slightly lower.
This is because the first distance L1 exceeds the specified range, so that the stress at the time of hitting the ball is dispersed between the front edge 2002 of the crown side flange 20 and the front edge 2032 of the recess 2030, which induces deformation. The effect of deforming the portion 52 more than the other portions to secure the amount of deflection of the face portion 26 is reduced, and since the second distance L2 exceeds the specified range, the crown portion side flange 20 is long. Since the stress at the time of hitting is dispersed to the crown side flange 20, the amount of deflection of the crown portion 28 near the face portion 26 at the time of hitting is reduced, which is effective in securing the amount of deflection of the face portion 26 and the sweet area. This is because

In Experimental Example 35, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP in the face reference cross section Pf is 6.0 mm, which is claimed. Item 12 is within the range of 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 6.0 mm, according to claim 12. It is in the range of 5 mm to 20 mm.
Therefore, the initial velocity is 113, the directionality is 113, the flight distance is 112, the durability is 111, and the total score is 449. is doing.
This is because the first distance L1 is within the above range, so that the stress concentrated on the deformation inducing portion 52 at the time of hitting the ball is increased, the deformation inducing portion 52 is deformed more than other portions, and the amount of deflection of the face portion 26 is increased. Also, since the second distance L2 is within the above range, it is possible to secure the amount of deformation of the deformation inducing portion 52 at the time of hitting the ball, which is advantageous in securing the amount of deflection of the face portion 26. This is to become.

In Experimental Example 36, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP in the face reference cross section Pf is 18.0 mm. Item 12 is within the range of 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 18.0 mm, according to claim 12. It is in the range of 5 mm to 20 mm.
Therefore, the initial velocity is 114, the directionality is 113, the flight distance is 114, the durability is 111, and the total score is 452. is doing.
This is for the same reason as in Experimental Example 35.

In Experimental Example 37, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP is 12.0 mm, which is claimed. Item 12 is within the range of 4 mm to 20 mm.
Further, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 15.0 mm, according to claim 12. It is in the range of 5 mm to 20 mm.
Therefore, the initial velocity is 115, the directionality is 114, the flight distance is 115, the durability is 111, and the total score is 455. is doing.
This is for the same reason as in Experimental Example 35.

Therefore, Experimental Examples 33 and 34 that satisfy the provisions of claims 1 and 11 and do not satisfy the provisions of claims 12, 13 and 14 do not satisfy all the provisions of claims 1, 11, 12, 13 and 14. Compared to Experimental Example 1, the effects of improving the initial velocity, directionality, flight distance, durability, and total score are excellent.
Further, Experimental Examples 35, 36 and 37 satisfying the provisions of claims 1, 11 and 12 and not satisfying the provisions of claims 13 and 14 satisfy the provisions of claims 1 and 11 and satisfy the provisions of claims 12 and 13. Compared to Experimental Examples 33 and 34 that do not satisfy the provisions of No. 14, the effects of improving the initial velocity, directionality, flight distance, durability, and total score are excellent.

(Condition 2)
Next, an experimental example under condition 2 will be described with reference to FIG. 35.
As described above, condition 2 satisfies the provisions of claims 1, 11 and 12, and changes the condition specified in claim 13.
However, in all the experimental examples, claim 14 was set to a certain condition outside the specified range.
That is, in Experimental Examples 38 to 42, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP is 12.0 mm. It is within the range of 4 mm to 20 mm of claim 12.
Further, in Experimental Examples 38 to 42, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 16.0 mm. It is within the range of 5 mm to 20 mm of claim 12.
Further, in Experimental Examples 38 to 42, the flange angle θ1 is set to 52 °, which does not satisfy the provision of claim 14.

In Experimental Example 38, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical plane orthogonal to the face reference cross section Pf is It is set to 0.5 mm, which is less than the range of 1 mm or more and 7 mm or less of claim 13.
Further, in the face reference cross section Pf, the fourth distance L4 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 0.5 mm. It is below the range of 1 mm or more and 7 mm or less of claim 13.
Therefore, the initial velocity is 116, the directionality is 113, the flight distance is 115, the durability is 111, and the total score is 455. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 40 satisfying the provision of claim 13. , 41, 42, all evaluations are slightly lower.
This is because the depth of the concave groove 2030 is too small because the third distance L3 and the fourth distance L4 are below the specified range, so that the deformation inducing portion 52 is deformed to the upper side more than the other portions. This is because the effect of securing the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is reduced, and the effect of securing the sweet area is reduced.

In Experimental Example 39, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical plane orthogonal to the face reference cross section Pf is It is set to 8.0 mm, which exceeds the range of 1 mm or more and 7 mm or less of claim 13.
Further, in the face reference cross section Pf, the fourth distance L4 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 8.0 mm. It exceeds the range of 1 mm or more and 7 mm or less of claim 13.
Therefore, the initial velocity is 117, the directionality is 114, the flight distance is 115, the durability is 112, and the total score is 458. While all the evaluations are improved as compared with Experimental Example 1, Experimental Example 40 satisfying the provision of claim 13. , 41, 42, all evaluations are slightly lower.
This is because the third distance L3 and the fourth distance L4 exceed the specified range, and the depth of the concave groove 2030 is too large, so that the stress at the time of hitting the ball is from the front edge 2002 of the crown side flange 20. Since it is dispersed between the lower end 2030A of the recess 2030, the deformation inducing portion 52 is deformed to the upper side more than the other portions, and the effect of securing the amount of deflection of the face portion 26 and the crown portion side flange 20 is reduced. Is.

In Experimental Example 40, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical plane orthogonal to the face reference cross section Pf is It is set to 1.0 mm and is within the range of 1 mm or more and 7 mm or less of claim 13.
Further, in the face reference cross section Pf, the fourth distance L4 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 1.0 mm. It is within the range of 1 mm or more and 7 mm or less of claim 13.
Therefore, the initial velocity is 122, the directionality is 119, the flight distance is 121, the durability is 115, and the total score is 477. is doing.
This is because the third distance L3 and the fourth distance L4 are within the above ranges, so that the effect of securing the amount of deflection of the face portion 26 and the crown portion side flange 20 (particularly the crown portion side flange 20) is improved. This is because the effect of securing the sweet area is improved.

In Experimental Example 41, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical plane orthogonal to the face reference cross section Pf is It is set to 7.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 13.
Further, in the face reference cross section Pf, the fourth distance L4 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 7.0 mm. It is within the range of 1 mm or more and 7 mm or less of claim 13.
Therefore, the initial velocity is 123, the directionality is 120, the flight distance is 122, the durability is 115, and the total score is 480. is doing.
This is for the same reason as in Experimental Example 40.

In Experimental Example 42, in the face reference cross section Pf, the third distance L3 obtained by projecting the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical plane orthogonal to the face reference cross section Pf is It is set to 4.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 13.
Further, in the face reference cross section Pf, the fourth distance L4 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 on the vertical surface orthogonal to the face reference cross section Pf is 4.0 mm. It is within the range of 1 mm or more and 7 mm or less of claim 13.
Therefore, the initial velocity is 125, the directionality is 122, the flight distance is 125, the durability is 116, and the total score is 488. is doing.
This is for the same reason as in Experimental Example 40.

Therefore, Experimental Examples 38 and 39 that satisfy the provisions of claims 1, 11 and 12 and do not satisfy the provisions of claims 13 and 14 are experiments that do not satisfy all the provisions of claims 1, 11, 12, 13 and 14. Compared to Example 1, the effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent.
Further, Experimental Examples 40, 41, and 42 satisfying the provisions of claims 1, 11, 12, and 13 and not satisfying the provisions of claim 14 satisfy the provisions of claims 1, 11, and 12, and claim 13, 14 The effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent as compared with Experimental Examples 38 and 39 that do not satisfy the above requirements.

(Condition 3)
Next, an experimental example under condition 3 will be described with reference to FIG.
As described above, condition 3 satisfies the provisions of claims 1, 11, 12, and 13, and changes the conditions specified in claim 14.
That is, in Experimental Examples 43 to 46, in the face reference cross section Pf, the first distance L1 obtained by projecting the distance from the front edge 2002 of the crown side flange 20 to the front edge 2032 of the recess 2030 onto the horizontal plane HP is 12.0 mm. It is within the range of 4 mm to 20 mm of claim 12.
Further, in Experimental Examples 43 to 46, in the face reference cross section Pf, the second distance L2 obtained by projecting the distance from the trailing edge 2036 of the recess 2030 to the trailing edge 2004 of the crown side flange 20 on the horizontal plane HP is 16.0 mm. It is within the range of 5 mm to 20 mm of claim 12.
Further, in Experimental Examples 43 to 46, in the face reference cross section Pf, the distance from the front edge 2032 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 is projected onto the vertical plane orthogonal to the face reference cross section Pf. The distance L3 is 4.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 13.
Further, in Experimental Examples 43 to 46, in the face reference cross section Pf, the distance from the trailing edge 2036 of the recess 2030 to the lower end 2030A located at the lowermost position of the recess 2030 is projected onto the vertical plane orthogonal to the face reference cross section Pf. The distance L4 is 4.0 mm, which is within the range of 1 mm or more and 7 mm or less of claim 13.

In Experimental Example 43, the flange angle θ1 in claim 14 is set to 12 °, and the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 14 is not satisfied.
Therefore, the initial velocity is 122, the directionality is 123, the flight distance is 123, the durability is 114, and the total score is 482. The flight distance is slightly reduced.
This is because the flange angle θ1 is less than the above range, so that the effect of securing the amount of deformation of the deformation inducing portion 46 at the time of hitting the ball is reduced, and the effect of securing the flight distance is reduced.

In Experimental Example 44, the flange angle θ1 in claim 14 is 16 °, which satisfies the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 14.
Therefore, the initial velocity is 126, the directionality is 124, the flight distance is 129, the durability is 115, and the total points are 494. Compared with Experimental Examples 43 and 46, which do not satisfy the provision of claim 14, the initial velocity and flight distance are improved.
This is because since the flange angle θ1 is within the above range, the amount of deformation of the deformation inducing portion 46 can be secured at the time of hitting the ball, and the effect of securing the flight distance is improved.

In Experimental Example 45, the flange angle θ1 in claim 14 is 49 °, which satisfies the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 14.
Therefore, the initial velocity is 128, the directionality is 125, the flight distance is 128, the durability is 115, and the total score is 496. Compared with Experimental Examples 43 and 46 which do not satisfy the provision of claim 14, the initial velocity and flight distance are improved.
This is because since the flange angle θ1 is within the above range, the amount of deformation of the deformation inducing portion 46 can be secured at the time of hitting the ball, and the effect of securing the flight distance is improved.

In Experimental Example 46, the flange angle θ1 in claim 14 is 51 °, which does not satisfy the provision of 15 ° ≦ θ1 ≦ 50 ° in claim 6.
Therefore, the initial velocity is 121, the directionality is 121, the flight distance is 124, the durability is 114, and the total score is 480. The flight distance is slightly reduced.
This is because the flange angle θ1 exceeds the above range, so that the golfer tends to feel a sense of discomfort in the shape of the golf club head, it becomes difficult to swing, the head speed decreases, and the effect of securing the flight distance decreases. Because.

Therefore, Experimental Examples 44, 44 satisfying all the provisions of Claims 1, 11, 12, 13, and 14 satisfy the provisions of Claims 1, 11, 12, and 13, but do not satisfy the provisions of Claim 14. Compared to 43 and 46, the effect of improving the initial velocity, directionality, flight distance, durability, and total score is excellent.

The face member 14 includes a main body plate portion 18, a crown portion side flange 20, and a sole portion side flange 22 joined to the front edge of the sole portion 30 of the head main body 12. Although the case where the deformation inducing portions 46, 50 and 52 are provided on the crown portion side flange 20 has been described, the deformation inducing portions 46, 50 and 52 may be provided on the sole portion side flange 22. The same effect as the form of is produced. In this case, the deformation inducing portion 46 including the ridge line 2014, the upper surface 2020, the inclined surface 2022, the deformation inducing portion 50 including the lower surface 2024, and the deformation inducing portion 52 including the concave portion 2030 are provided in a convex shape above the sole portion 30. Will be.

10 Golf club head 12 Head body 14 Face member 16 Opening 18 Main body plate 20 Crown side flange 2002 Front edge 2004 Rear edge 2010 Front inclined surface 2012 Rear inclined surface 2014 Ridge line 2020 Top surface 2020A Rear end 2022 Inclined surface 2020 Bottom surface 2030 Recession 2030A Lower end 2032 Front edge 2034 Front edge 2036 Trailing edge 2038 Rear surface 26 Face part 26A Face surface 28 Crown part 28A Crown surface 30 Sole part 34 Toe 36 Heel 38 Face back 40 Hollow part 46 Deformation inducing part 48 Bead part 50 Deformation inducing part 52 Deformation induction Part B Golf ball L1 First distance L2 Second distance L3 Third distance L4 Fourth distance Pfc Face center reference cross section Pf Face reference cross section K1 First boundary point P1 First intersection θ1 Flange angle

Claims (13)

The head body, which has a hollow structure and has an opening on the face side,
The opening is provided with a face member to be joined by welding.
The face member extends from the upper part of the main body plate portion to the crown portion side with the main body plate portion constituting the face portion, forms a part of the crown portion, and is joined to the front edge of the crown portion of the head main body. A golf club head with a crown side flange.
A deformation-inducing portion, which induces deformation when a golf ball is hit, is formed extending along the toe-heel direction on the flange on the crown portion side.
At the opening, a bead portion protruding inside the golf club head is formed so as to extend over the entire circumference of a portion where the head body and the flange on the crown portion side are joined by welding.
The crown portion-side flange has a leading edge connected to the face portion and a first inclined surface that rises from the front edge toward the face back and whose end on the face back side is the highest position in the crown portion. A trailing edge joined to the leading edge of the crown portion of the head body, a second inclined surface that rises from the trailing edge toward the face portion and intersects the first inclined surface, and the first inclined surface. It has a ridge line formed at a portion where the second inclined surface intersects with the second inclined surface.
The deformation inducing portion includes the first inclined surface, the second inclined surface, and the ridgeline.
A golf club head that features that. The claim is characterized in that the wall thickness t1 of the crown side flange located on the face portion side of the ridge line is larger than the wall thickness t2 of the crown portion side flange located on the face back side of the ridge line. 1 The golf club head described. The weighted average ΔT1 of the wall thickness of the crown portion side flange from the front edge of the crown portion side flange to the ridgeline is 0.6 mm to 1.4 mm, and the weighted average ΔT1 from the ridgeline to the trailing edge of the crown portion side flange. The weighted average ΔT2 of the wall thickness of the crown side flange is 0.4 mm to 1.0 mm.
2. The golf club head according to claim 2. In a reference state in which the golf club head is installed according to a predetermined lie angle and loft angle with respect to the horizontal plane, the head body is broken at a plane including a normal passing through the center point of the face surface and orthogonal to the horizontal plane. Let the cross section be the face center reference cross section.
The cross section obtained by breaking the head body on an arbitrary plane parallel to the face center reference cross section is defined as the face reference cross section.
In the face reference cross section, the first distance L1 obtained by projecting the distance from the front edge of the crown portion side flange to the ridge line onto the horizontal plane is 4 mm to 20 mm.
In the face reference cross section, the second distance L2 obtained by projecting the distance from the ridgeline to the trailing edge of the crown side flange onto the horizontal plane is 5 mm to 20 mm.
The golf club head according to any one of claims 1 to 3. The intersection of the face reference cross section and the front edge of the crown side flange is set as the first boundary point K1.
In the face reference cross section, a straight line perpendicular to the horizontal plane and the crown portion side passing through a point 5 mm away from the first boundary point K1 in the face back direction on a plane including the first boundary point K1 and parallel to the horizontal plane. The intersection with the surface of the flange is set as the first intersection P1.
When the angle formed by the straight line connecting the first boundary point K1 and the first intersection P1 with respect to the horizontal plane is the flange angle θ1.
The flange angle θ1 is 15 ° or more and 50 ° or less.
The golf club head according to claim 4. The head body, which has a hollow structure and has an opening on the face side,
The opening is provided with a face member to be joined by welding.
The face member extends from the upper part of the main body plate portion to the crown portion side with the main body plate portion constituting the face portion, forms a part of the crown portion, and is joined to the front edge of the crown portion of the head main body. A golf club head with a crown side flange.
A deformation-inducing portion, which induces deformation when a golf ball is hit, is formed extending along the toe-heel direction on the flange on the crown portion side.
At the opening, a bead portion protruding inside the golf club head is formed so as to extend over the entire circumference of a portion where the head body and the flange on the crown portion side are joined by welding.
The crown portion-side flange has a front edge connected to the face portion and a first inclined surface that rises from the front edge toward the face back and the end portion on the face back side is the highest position in the crown portion. A second inclined surface that descends from the rear end of the first inclined surface toward the face back direction, and a front edge of the crown portion of the head body that extends from the lower end of the second inclined surface in the face back direction. It has a crown portion of the head body that is joined and a lower surface that forms a continuous surface.
The deformation inducing portion includes the first inclined portion, the second inclined surface, and the lower surface.
A golf club head that features that. In a reference state in which the golf club head is installed according to a predetermined lie angle and loft angle with respect to the horizontal plane, the head body is broken at a plane including a normal passing through the center point of the face surface and orthogonal to the horizontal plane. Let the cross section be the face center reference cross section.
The cross section obtained by breaking the head body on an arbitrary plane parallel to the face center reference cross section is defined as the face reference cross section.
In the face reference cross section, the first distance L1 obtained by projecting the distance from the front edge of the crown side flange to the rear end of the upper surface onto the horizontal plane is 4 mm to 20 mm.
In the face reference cross section, the second distance L2 obtained by projecting the distance from the rear end of the upper surface to the trailing edge of the flange on the crown portion side onto the horizontal plane is 5 mm to 20 mm.
The golf club head according to claim 6. In the face reference cross section, the third distance L3 obtained by projecting the distance from the upper end to the lower end of the inclined surface onto the vertical plane orthogonal to the face reference cross section is 1 mm or more and 7 mm or less.
7. The golf club head according to claim 7. The intersection of the face reference cross section and the front edge of the crown side flange is set as the first boundary point K1.
In the face reference cross section, a straight line perpendicular to the horizontal plane and the crown portion side passing through a point 5 mm away from the first boundary point K1 in the face back direction on a plane including the first boundary point K1 and parallel to the horizontal plane. The intersection with the surface of the flange is set as the first intersection P1.
When the angle formed by the straight line connecting the first boundary point K1 and the first intersection P1 with respect to the horizontal plane is the flange angle θ1.
The flange angle θ1 is 15 ° or more and 50 ° or less.
The golf club head according to claim 7 or 8. The head body, which has a hollow structure and has an opening on the face side,
The opening is provided with a face member to be joined by welding.
The face member extends from the upper part of the main body plate portion to the crown portion side with the main body plate portion constituting the face portion, forms a part of the crown portion, and is joined to the front edge of the crown portion of the head main body. A golf club head with a crown side flange.
A deformation-inducing portion, which induces deformation when a golf ball is hit, is formed extending along the toe-heel direction on the flange on the crown portion side.
At the opening, a bead portion protruding inside the golf club head is formed so as to extend over the entire circumference of a portion where the head body and the flange on the crown portion side are joined by welding.
The crown portion-side flange has a leading edge connected to the face portion and a first inclined surface that rises from the front edge toward the face back and whose end on the face back side is the highest position in the crown portion. And a recess connected to the end of the first inclined surface on the face back side and recessed toward the sole portion, and a recess extending in the face back direction from the trailing edge of the recess separated from the first inclined surface of the head body. Has a trailing surface that is joined to the leading edge of the crown
The deformation-inducing portion includes the first inclined surface, the recess, and the rear surface.
A golf club head that features that. In a reference state in which the golf club head is installed according to a predetermined lie angle and loft angle with respect to the horizontal plane, the head body is broken at a plane including a normal passing through the center point of the face surface and orthogonal to the horizontal plane. Let the cross section be the face center reference cross section.
The cross section obtained by breaking the head body on an arbitrary plane parallel to the face center reference cross section is defined as the face reference cross section.
In the face reference cross section, the first distance L1 obtained by projecting the distance from the front edge of the crown side flange to the front edge of the recess on the horizontal plane is 4 mm to 20 mm.
In the face reference cross section, the second distance L2 obtained by projecting the distance from the trailing edge of the recess to the trailing edge of the flange on the crown portion side onto the horizontal plane is 5 mm to 20 mm.
10. The golf club head according to claim 10. In the face reference cross section, the third distance L3 obtained by projecting the distance from the front edge of the recess to the lowermost lower end of the recess onto the vertical plane orthogonal to the face reference cross section is 1 mm or more and 7 mm or less. ,
In the face reference cross section, the fourth distance L4 obtained by projecting the distance from the trailing edge of the recess to the lowermost lower end of the recess on the vertical plane orthogonal to the face reference cross section is 1 mm or more and 7 mm or less. ,
11. The golf club head according to claim 11. The intersection of the face reference cross section and the front edge of the crown side flange is set as the first boundary point K1.
In the face reference cross section, a straight line perpendicular to the horizontal plane and the crown portion side passing through a point 5 mm away from the first boundary point K1 in the face back direction on a plane including the first boundary point K1 and parallel to the horizontal plane. The intersection with the surface of the flange is set as the first intersection P1.
When the angle formed by the straight line connecting the first boundary point K1 and the first intersection P1 with respect to the horizontal plane is the flange angle θ1.
The flange angle θ1 is 15 ° or more and 50 ° or less.
The golf club head according to claim 11 or 12.

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