JP6537562B2 - Golf club heads and golf clubs - Google Patents

Description

  The present invention relates to a golf club head and a golf club.

In order to improve the initial velocity of the ball when hitting a ball with a golf club head and to improve the flight distance, it is important how to secure the deflection amount of the face portion.
In Patent Document 1, a bulging portion is formed in a crown portion, a first connection angle α of the bulging portion to the face portion, a second connection angle β of the bulging portion to the crown portion, and a height of the bulging portion A golf club head has been proposed in which the width H of the bulging portion is defined as H.
According to this golf club head, by securing the amount of deformation of the bulging portion, the amount of deflection of the face portion is secured, the initial velocity of the ball is improved, and the flight distance is improved.

Patent No. 5882522

However, since the above-mentioned golf club head has a bulging portion that protrudes upward in the crown portion, the shape of the bulging portion tends to be noticeable. Therefore, some golfers may feel uncomfortable when holding the face surface of the golf club head toward the target point.
Therefore, when the golfer holds the golf club, the direction of the face surface of the golf club head with respect to the ball varies, and as a result, there is a concern that the direction of the ball launched by the golf club head is not stable.
The present invention has been made in view of such circumstances, and an object thereof is to provide a golf club head which is advantageous in suppressing variation in the direction of a ball which is easily launched while improving initial velocity and flight distance. And to provide golf clubs.

In order to achieve the above object, the invention according to claim 1 is characterized in that a face portion having upper and lower heights and extending left and right, and a thickness smaller than the face portion from the top of the face portion to the rear Between the toe side edge and the heel side edge of the face portion between the crown portion and the sole portion extending rearward from the lower portion of the face portion A golf club head comprising a head body including side portions extending therethrough, wherein the inside surrounded by the face portion, the crown portion, the sole portion and the side portions is a hollow portion, the golf club head comprising In a reference state set according to lie angles and loft angles predetermined with respect to a horizontal plane, the head body is broken in a plane including a normal line passing through the center point of the face surface and orthogonal to the horizontal plane A cross section is taken as a face center reference cross section, a plane parallel to the face center reference cross section and separated by 10 mm from the face center reference cross section in the toe direction is taken as a first plane, and is parallel to the face center reference cross section from the face center reference cross section A plane separated by 10 mm in a direction is taken as a second plane, and a cross section obtained by breaking the head body at an arbitrary plane parallel to the face center reference cross section within the range from the first plane to the second plane is taken as a face reference cross section. A boundary point between an upper end of the face surface and a front end of the crown surface is a first boundary point K1 in the face reference cross section, and a plane including the first boundary point K1 and parallel to the horizontal surface in the face reference cross section And a straight line perpendicular to the horizontal plane passing through a point 5 mm away from the first boundary point K1 in the face-back direction and the crown Where the flange angle θ1 is 15 ° or more, where a first intersection point P1 is the first intersection point P1 and a straight line connecting the first boundary point K1 and the first intersection point P1 is the flange angle θ1. An inflection point H is formed at a location of the crown surface which is 50 ° or less and which is separated from the first intersection point P1 in the face back direction in the face reference cross section, and the inflection point H in the face reference cross section. The radius of curvature of the inflection point H is located between the first intersection point P1 and the inflection point H, where the radius of curvature of the portion of the crown surface that is included is the radius of curvature of the inflection point H. The value is smaller than the radius of curvature of the crown surface, and when the head main body is viewed in plan in the reference state, the inflection point H continues in the toe heel direction, and the crown surface is in the toe heel direction. An existing ridge line is formed so as to be visible, and in the reference state, on the plane including the inflection point H and parallel to the horizontal plane in the face reference cross section, a point 15 mm away from the inflection point H in the faceback direction The length along the face reference cross section of the crown portion from the first boundary point K1 to the inflection point H, where the point of intersection between the straight line orthogonal to the horizontal plane and the crown plane passes through the first boundary point K1 to the inflection point H Said crown portion weighted along the face reference cross section of the crown portion from the inflection point H to the fourth intersection point P4. And the inflection point H from the inflection point H on the plane including the inflection point H in the face reference cross section in the reference state. Let a straight line perpendicular to the horizontal plane passing through a point 5 mm away in the sback direction, and the crown plane be the second cross point P2, and a straight line connecting the inflection point H and the second cross point P2 and the horizontal plane The inflection point angle θ2 is 1 ° or more and 15 ° or less when the inflection point angle is θ2, and in the face reference cross section, from the center point of the face surface toward the crown portion at an interval of 1 mm. An operation of defining three measurement points and measuring a radius of curvature R of an arc passing through the three measurement points while displacing the three measurement points toward the crown by 1 mm. The radius of curvature R (R = R1, R2, R3, ... Rn-1, Rn, Rn + 1, ...) is sequentially measured by repeating, and the radius of curvature Rn measured immediately before that is measured. When the value divided by n-1 is less than 0.3, the middle measurement point of the three measurement points is taken as the face-side first specified point, and the center is 1 mm more than the face-side first specified point. The measurement point closer to the point is a face-side second predetermined point, and the measurement point closer to the center point by 1 mm than the face-side second predetermined point is a face-side third predetermined point. The face-side first predetermined point, the face A curved line extending toward the crown side from an arc passing through the side second specified point and the face-side third specified point is defined as a first specified line, and in the face reference cross section, a distance of 1 mm from the crown to the face Define the three measurement points and measure the radius of curvature R of the arc passing through the three measurement points, and move the measurement of the radius of curvature toward the direction toward the face portion by The radius of curvature R (R = R1, R2, R3, ... Rn-1, Rn, Rn + 1, ...) was sequentially measured by repeating the operation described above, and the measured radius of curvature Rn was measured immediately before that. When the value divided by the curvature radius Rn-1 is less than 0.4, the middle measurement point of the three measurement points is taken as the crown side first specified point, and 1 mm from the crown side first specified point. The measurement point closer to the faceback is the crown side second defined point, and the measurement point closer to the faceback by 1 mm than the crown side second defined point is the crown side third defined point, the crown side first defined point, the crown The first boundary point K1 corresponds to the first defined line and the first defined line when the second defined line is a curved line extending toward the face side with an arc passing through the side second defined point and the crown-side third defined point. It is characterized by the point of intersection with two prescribed lines I assume.
The invention according to claim 2 is that, in the reference state, on the plane including the inflection point H and parallel to the horizontal plane in the face reference cross section, a point 1 mm away from the inflection point H toward the face portion The ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0, where the intersection of the straight line orthogonal to the horizontal plane and the crown surface is the third intersection point P3. .04 or more and 0.35 or less.
In the invention according to claim 3, when the head body is viewed in plan in the reference state, a boundary between the upper end of the face surface and the front end of the crown surface is formed by the appearance finish of the head body. The ridge line extends substantially parallel to the boundary line, and in the reference state, the heel side located 22.23 mm above the horizontal surface when the head main body is viewed from the front of the face surface When the dimension of the distance from the portion of the head to the end closest to the toe side is projected to the horizontal plane as the head length HL in the toe heel direction, the ridgeline when the head main body is viewed in plan in the reference state And the face center reference cross section, and the size of the ridge line obtained by projecting the ridge line on the horizontal surface is 20% or more of the head length HL.
According to the fourth aspect of the present invention, in the reference state, when a dimension obtained by projecting the distance from the leading edge of the head body to the rear end of the head body in the horizontal plane is the head width HW. The distance from the first boundary point K1 to the inflection point H when projecting the first boundary point K1 and the inflection point H on the horizontal plane is 5% or more and 15% or less of the head width HW. It is characterized by
The invention according to claim 5 is a golf club having the golf club head according to any one of claims 1 to 4.

According to the first and fifth aspects of the invention, the flange angle θ1 of the crown portion is 15 ° or more and 50 ° or less, and the face reference cross section is bent at a point on the crown surface away from the first intersection point P1 in the faceback direction. The point H is formed, and the radius of curvature RA of the inflection point H is set to a value smaller than the radius of curvature of the crown surface located between the first intersection point P1 and the inflection point H, and the head body is viewed in plan in the standard state. Then, when the inflection point H continues in the toe-heel direction, a ridge line extending in the toe-heel direction is made visible on the crown surface.
Therefore, when the ball is hit, stress concentrates on the portion of the crown including the inflection point H (ridge line) so that a large amount of deformation of the crown near the face can be secured, and the amount of deflection of the face increases. And the launch angle can be increased, which is advantageous for improving the initial speed and the flight distance.
In addition, since ridgelines extending in the toe-heel direction are visually recognized on the crown surface, there is no sense of discomfort when holding the face surface of the golf club head toward the target point, and therefore variations in the direction of the hit balls can be made. It is advantageous in suppressing.
According to the invention of claims 2 to 4, it is advantageous to enhance the effect of claim 1.

It is the front view which looked at the golf club head concerning an embodiment from the front of a face side. It is an A arrow line view of FIG. It is B arrow line view of FIG. It is C arrow line view of FIG. It is a first explanatory view showing a method of defining a center point Pc of the face surface. It is a 2nd explanatory view showing a method of defining center point Pc of a face side. It is a 3rd explanatory view showing a method of defining center point Pc of a face side. It is a 4th explanatory view showing a method of defining center point Pc of a face side. FIG. 6 is a cross-sectional view of the golf club head showing the relationship between the center of gravity G0 of the golf club head and the center of gravity FG on the face surface. It is a front view of a golf club head explaining the definition of the outline I of a face surface. FIG. 5 is a cross-sectional view of a golf club head illustrating the definition of the contour line I of the face surface. It is a front view of a golf club head explaining the definition of center point Pc of a face side. FIG. 2A is a cross-sectional view of the face center reference cross section Pfc taken along plane X of FIG. 1, depicting the top of the face portion and the front of the crown portion. It is explanatory drawing of the measuring method of the curvature radius R for defining the 1st boundary point K1. It is the top view which planarly considered the golf club head to which this invention was applied as a reference state, (A) is a driver, (B) is fairway wood, (C) shows utility. It is sectional drawing of face center reference | standard reference cross section Pfc of the golf club head to which this invention was applied, (A) is a driver, (B) is fairway wood, (C) shows utility. It is sectional drawing of face center reference cross section Pfc which shows the change of the shape of a golf club head before and behind a hit, (A) is a general golf club head, (B) shows the golf club head of this invention. It is a sectional view of face central reference section Pfc of a golf club head to which the present invention is applied, (A) shows a state before hitting, and (B) shows a state after hitting. It is a figure which shows the evaluation result of the experiment example regarding the driver in condition 1. FIG. FIG. 10 is a diagram showing evaluation results of an experimental example regarding a driver under condition 2. It is a figure which shows the evaluation result of the experiment example regarding the driver in condition 3. FIG. FIG. 18 is a diagram showing evaluation results of an experimental example regarding a driver under condition 4. It is a figure which shows the evaluation result of the experiment example regarding the utility in condition 1. FIG. FIG. 16 is a diagram showing the evaluation results of an experimental example regarding the utility under condition 2. It is a figure which shows the evaluation result of the experiment example regarding the utility in condition 3. FIG. FIG. 18 is a diagram showing the evaluation results of an experimental example regarding the utility under condition 4;

Next, an embodiment of the present invention will be described.
As shown in FIGS. 1 to 4 and 13, in the present embodiment, the golf club head 10 is a hollow wood golf club head (driver), and includes a head body 12.
The head body 12 is mainly made of a metal material.
As said metal material, 1 type (s) or 2 or more types, such as stainless steel, maraging steel, pure titanium, a titanium alloy, or an aluminum alloy, are used, for example.
The head main body 12 includes a face portion 14, a crown portion 16, a sole portion 18 and a side portion 20.
The face portion 14 has left and right height and extends to the left and right.
The crown portion 16 extends rearward from the top of the face portion 14 with a smaller thickness than the face portion 14.
For example, the thickness of the crown portion 16 is 0.4 mm to 1.2 mm, the thickness of the face portion 14 is 2.0 mm to 4.5 mm, and the thickness of the sole portion 18 is 0.6 mm to It is 1.5 mm.
The sole portion 18 extends rearward from the lower portion of the face portion 14.
The side portion 20 extends through the faceback 26 between the crown portion 16 and the sole portion 18 and between the toe 22 side edge of the face portion 14 and the heel 24 side edge.
The head main body 12 has a hollow structure in which the inside surrounded by the face portion 14, the crown portion 16, the sole portion 18 and the side portion 20 is a hollow portion 28.
The surface exposed to the outside of the face portion 14 is a face surface 14A that strikes a ball, and the back surface of the face portion 14 facing the hollow portion 28 is a face back surface 14B.
The surface exposed to the outside of the crown portion 16 is a crown surface 16A.
The crown portion 16 is provided with a hosel 30 connected to the shaft S at a position closer to the heel 24 on the face surface 14A side, and the golf club 100 according to the present invention is configured by the shaft S being connected to the hosel 30. Ru.
The surface exposed to the outside of the sole portion 18 is a sole surface 18A, and the back surface of the sole portion 18 facing the hollow portion 28 is a sole back surface 18B.
In the figure, reference numeral 19 denotes a leading edge.

Next, a method of defining the center point Pc of the face surface 14A will be described.
The center point Pc of the face surface 14A is the geometric center of the face surface 14A, and various methods of defining the center point Pc may be known in the prior art including the first and second methods of definition as exemplified below. The method is adoptable.

[A] First Method of Defining Center Point Pc of Face Surface 14A:
When the boundary between the face surface 14A and the portion of the other golf club head 10 is clear, in other words, the method of defining the center point Pc in the case where the periphery of the face surface 14A is specified by a ridge line. In this case, the face surface 14A is clearly defined.
5 to 8 are explanatory views showing a method of defining the center point Pc of the face surface 14A.

(1) First, as shown in FIG. 5, the golf club head 10 is placed on the horizontal surface HP so that the lie angle and the face angle become the specified values. The state of the golf club head 10 at this time is taken as a reference state. The setting values of the lie angle and the face angle are, for example, values described in a product catalog.

(2) Next, a temporary center point c0 in the direction connecting the crown portion 16 and the sole portion 18 is determined.
That is, as shown in FIG. 5, a perpendicular line f0 is drawn which intersects the approximate center point of a line (hereinafter referred to as a horizontal line) parallel to the horizontal plane HP connecting the toe 22 and the heel 24.
A middle point of a0 point where the perpendicular f0 intersects with the upper edge of the face surface 14A and a b0 point where the perpendicular f0 intersects with the lower edge of the face surface 14A is a temporary center point c0.

(3) Next, as shown in FIG. 6, a horizontal line g0 passing through the temporary center point c0 is drawn.
(4) Next, as shown in FIG. 7, at point e0 at which the horizontal line g0 intersects the edge on the toe 22 side of the face surface 14A and at point e0 at which the horizontal line g0 intersects the edge on the heel 24 side of the face surface 14A. The middle point is taken as a temporary center point c1.

(5) Next, as shown in FIG. 8, a perpendicular line f1 passing through the temporary center point c1 is drawn, and the perpendicular line f1 intersects the upper edge of the face surface 14A, the perpendicular line f1 and the lower edge of the face surface 14A The middle point of the b1 points where the points intersect is taken as a temporary center point c2.
Here, if the temporary center points c1 and c2 coincide with each other, that point is defined as the center point Pc of the face surface 14A.
If the tentative center points c1 and c2 do not match, the procedure of (2) to (5) is repeated.
Since the face surface 14A has a curved surface, the midpoint of the horizontal line g0, the length of the horizontal line g0 when obtaining the midpoint between the perpendiculars f0 and f1, and the lengths of the perpendiculars f0 and f1 are the curved surfaces of the face surface 14A. The length along the line shall be used.
The face center line CL is defined by a straight line passing through the center point Pc and extending in the direction perpendicular to the toe 22-heel 24 direction.

[B] Second method of defining center point Pc of face surface 14A:
Next, the definition of the center point Pc in the case where the periphery of the face surface 14A and the portion of the other golf club head 10 are connected by a curved surface and the face surface 14A can not be clearly defined will be described.

As shown in FIG. 9, the golf club head 10 is hollow, the code G0 indicates the center of gravity of the golf club head 10, the code Lp is a straight line connecting the center of gravity G0 and the center of gravity FG on the face surface. The straight line Lp is a perpendicular line of the face surface 14A passing through the center of gravity G0.
That is, the point obtained by projecting the center of gravity G0 of the golf club head 10 onto the face surface 14A is the center of gravity FG on the face.
Here, as shown in FIG. 10, a large number of planes H1, H2, H3,..., Hn including a straight line Lp connecting the gravity center point G0 and the gravity center point FG on the face surface are considered.

As shown in FIG. 11, the curvature radius r0 of the outer surface of the golf club head 10 is measured in a cross section when the golf club head 10 is broken along the planes H1, H2, H3,.
When measuring the radius of curvature r0, it is treated as if there is no face line, punch mark, etc. on the face surface 14A.
The radius of curvature r0 is continuously measured outward (upward and downward in FIG. 11) from the center point Pc of the face surface 14A.
Then, a portion where the curvature radius r0 first becomes equal to or less than a predetermined value in measurement is defined as an outline I representing the periphery of the face surface 14A.
The predetermined value is, for example, 200 mm.
An area surrounded by the outline I determined based on the large number of planes H1, H2, H3,..., Hn is defined as a face surface 14A as shown in FIGS.

Next, as shown in FIG. 12, the golf club head 10 is placed on a horizontal ground (horizontal plane HP) so that the lie angle and the face angle become prescribed values.
The straight line LT passes through the toe side point PT of the face surface 14A and extends in the vertical direction.
The straight line LH passes through the heel side point PH of the face surface 14A 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.
The symbol Pu indicates the upper point of the face surface 14A, and the symbol Pd is the lower point of the face surface 14A. The upper point Pu and the lower point Pd are both intersections of the straight line LC and the contour line I.
The central point Pc is defined by the middle point of a line connecting the upper point Pu and the lower point Pd.

Next, the definition of each part of the golf club head 10 will be described in detail.
As shown in FIGS. 1 to 4, the golf club head 10 is set in a reference state in which the golf club head 10 is installed at a lie angle and a loft angle predetermined with respect to the horizontal plane HP.
As shown in FIGS. 1 and 13, in the reference state, a cross section obtained by breaking the head body 12 at a plane X including a normal passing through the center point Pc of the face surface 14A and orthogonal to the horizontal plane HP Do. In other words, the face center reference cross section Pfc is a cross section in which the head body 12 is broken at a plane X that includes the face center line CL and is orthogonal to the horizontal plane HP in the reference state.
Furthermore, as shown in FIGS. 1, 3 and 4, a plane parallel to the face center reference cross section Pfc and separated from the face center reference cross section Pfc by 10 mm in the toe direction is taken as a first plane Pt.
A plane parallel to the face center reference cross section Pfc and separated from the face center reference cross section Pfc by 10 mm in the heel direction is taken as a second plane Ph.
A cross section obtained by breaking the head main body at an arbitrary plane parallel to the face center reference cross section Pfc within the range from the first plane Pt to the second plane Ph is taken as a face reference cross section Pf. Therefore, the face reference cross section Pf includes the face center reference cross section Pfc.

(First boundary point K1)
As shown in FIG. 13, the first boundary point K1 is a boundary point between the upper end of the face surface 14A and the front end of the crown surface 16A in the face reference cross section Pf.
In the present embodiment, the first boundary point K1 is defined by the following method.
As shown in FIG. 14, in the face reference cross section Pf, three measurement points p are defined at intervals of 1 mm from the center point Pc toward the crown portion 16 and the curvature radius R of the arc passing through the three measurement points p is measured. The radius of curvature R (R = R1, R2, R3,..., Rn-1) is repeated by repeating this measurement of the radius of curvature while displacing the three measurement points p toward the crown portion 16 by 1 mm. , Rn, Rn + 1,...
When the value obtained by dividing the measured radius of curvature Rn by the radius of curvature Rn-1 measured immediately before that becomes less than 0.3, the middle measurement point p of the three measurement points p is the face side 1 Designated as A1.
A measurement point p closer to the center point Pc by 1 mm than the face-side first defined point A1 is taken as a face-side second defined point A2.
A measurement point p closer to the center point Pc by 1 mm than the face-side second defined point A2 is taken as a face-side third defined point A3.
A curved line (arc) extending toward the crown portion 16 side is taken as a first defined line α, which is an arc passing through the face-side first defined point A1, the face-side second defined point A2 and the face-side third defined point A3.
The distance along the first definition line α from the face side second definition point A2 to the measurement point p closest to the center point Pc of the face surface 14A among the plurality of measurement points p defining the first definition line α Is about 3 mm to 15 mm. In an actual hollow golf club head, the radius of curvature R of the face surface 14A is substantially constant in the range of about 3 mm to 15 mm in the face reference cross section Pf.

In the face reference cross section Pf, three measurement points p are defined at intervals of 1 mm from the crown portion 16 to the face portion 14 and the curvature radius R of the arc passing through the three measurement points p is measured. The radius of curvature R (R = R1, R2, R3,..., Rn-1, Rn, Rn + 1,...) Is repeated by repeatedly performing the operation while displacing the three measurement points p toward the face portion 14 by 1 mm. ) In order.
The starting point of the measurement point p of the crown portion 16 is preferably defined as follows.
That is, in the face reference cross section Pf, a straight line L10 that is orthogonal to the horizontal plane HP through a point parallel to the horizontal plane HP and including the face side first prescribed point A1 and separated by 30 mm in the faceback direction A point of intersection P10 where the crown face 16A intersects is set as a start point, or a point closer to the face portion 14 than the point of intersection P10 is set as a start point of the measurement point p of the crown portion 16.

When the value obtained by dividing the measured radius of curvature Rn by the radius of curvature Rn-1 measured immediately before that becomes less than 0.4, the middle measurement point p of the three measurement points p is set to the crown side It is assumed that 1 stipulation point B1.
A measurement point p closer to the face back by 1 mm than the crown side first specified point B1 is taken as a crown side second specified point B2.
A measurement point p closer to the face back by 1 mm than the crown side second specified point B2 is taken as a crown side third specified point B3.
A curved line (arc) extending toward the face portion 14 is an arc passing through the crown side first specified point B1, the crown side second specified point B2, and the crown side third specified point B3 as a second specified line β.
In addition, among the plurality of measurement points p defining the second defined line β, the distance along the second defined line β from the crown side second defined point B2 to the measurement point p farthest from the center point Pc of the face surface 14A. Is about 3 to 15 mm. In an actual hollow golf club head, the radius of curvature of the crown surface 16A is substantially constant in the range of about 3 mm to 15 mm in the face reference cross section Pf.

An intersection point of the first defining line α and the second defining line β is referred to as a first boundary point K1.
Accordingly, as shown in FIG. 14, the first boundary point K1 is located at a position slightly away outward from the outer surface of the golf club head 10.
In the present embodiment, since the first boundary point K1 is defined by the above-described procedure, it is advantageous for simply and reliably determining the first boundary point K1.
The data preparation method for measuring each radius of curvature for defining the first boundary point K1 is to prepare CAD data (external surface data) by measuring the dimension of the golf club head 10 using a laser scan or the like. And the radius of curvature may be measured.
As shown in FIG. 3, when the head main body 12 is viewed in plan in the reference state, a boundary line Lfc between the upper end of the face surface 14A and the front end of the crown surface 16A is formed.
That is, the boundary line Lfc between the upper end of the face surface 14A and the front end of the crown surface 16A that the golfer actually recognizes at the time of addressing is located at a position between the face side first defined point A1 and the crown side first defined point B1. Do. In addition, it is possible to change the position of the boundary Lfc depending on the appearance finish, in particular, the position of the coating of the crown portion 16.

(Flange angle θ1)
As shown in FIG. 13, in the reference state, in the face reference cross section Pf, it passes through a point which is 5 mm away from the first boundary point K1 in the faceback direction on a plane HP ′ parallel to the horizontal plane HP including the first boundary point K1. An intersection point of a straight line L1 orthogonal to the horizontal plane HP and the crown surface 16A is taken as a first intersection point P1.
The flange angle θ1 is an angle formed by a straight line L20 connecting the first boundary point K1 and the first intersection point P1 with respect to the horizontal plane HP (HP ′).

(Inflection point H, radius of curvature RA, ridge line RL)
As shown in FIG. 13, the inflection point H is formed in the face reference cross section Pf at a position of the crown surface 16A which is separated from the first intersection point P1 in the face back direction.
The curvature radius RA is a curvature radius of the inflection point H in the face reference cross section Pf, and the curvature radius RA is smaller than the curvature radius of the crown surface 16A located between the first intersection point P1 and the inflection point H It is.
As shown in FIG. 3, when the head main body 12 is viewed in plan in the reference state, the ridge line RL extending in the toe heel direction on the crown surface 16A is visible when the inflection point H continues in the toe heel direction. It is formed.
In the reference state, when the head body 12 is viewed in plan, most of the ridge line RL extends substantially parallel to the boundary line Lfc.

That is, as shown in FIGS. 3 and 13, on the crown portion 16 near the face portion 14, a first inclined surface 1602 extending rearward while being displaced upward from the upper portion of the face portion 14, and a first inclined surface A second inclined surface 1604 extending rearward while being displaced downward following the rear end of the 1602 is formed in the toe heel direction at the location of the boundary between the first inclined surface 1602 and the second inclined surface 1604. An extending ridge line RL is formed.
As shown in FIG. 13, in the face reference cross section Pf, the first inclined surface 1602 extends between the first intersection point P1 and the inflection point H, and the second inclined surface 1604 faces from the inflection point H It extends in the back direction.

(Inflection point angle θ2)
As shown in FIG. 13, in the reference state, in the face reference cross section Pf, it passes through a point on the plane HP ′ ′ including the inflection point H and parallel to the horizontal plane HP and separated by 5 mm from the inflection point H in the faceback direction An intersection point of a straight line L2 orthogonal to the above and the crown surface 16A is taken as a second intersection point P2.
The inflection point angle θ2 is an angle formed by a straight line L22 connecting the inflection point H and the second intersection point P2 with the horizontal plane HP (HP ′ ′).

(Curvature radius RB of third intersection point P3)
As shown in FIG. 13, in the reference state, in the face reference cross section Pf, it passes through a point on the plane HP ′ ′ including the inflection point H and parallel to the horizontal plane HP and separated by 1 mm from the inflection point H toward the face portion 14 An intersection point of a straight line L3 orthogonal to HP and the crown surface 16A is taken as a third intersection point P3.
The radius of curvature of the third intersection point P3 is taken as RB.

(Head length HL)
As shown in FIGS. 1 and 3, in the reference state, when the head main body 12 is viewed from the front of the face surface 14A, the point on the heel 24 side located 22.23 mm above with respect to the horizontal plane HP Let the dimension which projected the distance to the located end part to the horizontal surface HP be head length HL of a toe heel direction.

(Head width HW)
As shown in FIG. 3, in the reference state, in the face reference cross section Pf, a dimension obtained by projecting the distance from the leading edge 19 of the head body 12 to the rear end of the head body 12 on a horizontal plane HP is taken as the head width HW.

In the present embodiment, the crown portion 16 has a thickness smaller than that of the face portion 14 and extends rearward from the top of the face portion 14, and the flange angle θ1 is a value of 15 ° or more and 50 ° or less. In Pf, an inflection point H is formed at a position of the crown surface 16A separated from the first intersection point P1 in the faceback direction, and the radius of curvature RA of the inflection point H is between the first intersection point P1 and the inflection point H The value is smaller than the radius of curvature of the crown surface 16A located therebetween.
The flange angle θ1 and the curvature radius RA strictly change slightly depending on the distance of the face reference cross section Pf from the face center reference cross section Pfc, in other words, changes within a certain range.
Therefore, when the ball is hit, stress concentrates on the portion of the crown portion 16 including the inflection point H (ridge line RL), and a large amount of deformation of the portion of the crown portion 16 near the face portion 14 can be secured. Since the amount of deflection increases, the coefficient of restitution can be increased and the launch angle can be increased, which is advantageous in improving the initial speed and the flight distance.
If the flange angle θ1 is less than 15 °, it is disadvantageous in securing the amount of deformation of the portion of the crown portion 16 including the inflection point H (ridge line RL) when hitting a ball.
If the flange angle θ1 is larger than 50 °, the golfer tends to feel uncomfortable with the shape of the golf club head, making it difficult to swing, lowering the head speed, which is disadvantageous in securing the flight distance. In particular, it becomes too deep to make you feel uncomfortable when addressing. In addition, if the flange angle θ1 is larger than 50 °, the strength of the portion of the head main body 12 corresponding to the first boundary point K1 (the boundary between the face surface 14A and the crown surface 16A) decreases, and therefore the durability of the golf club head The effect of securing
The flange angle θ1 is more preferably 20 ° or more and 40 ° or less, and still more preferably 25 ° or more and 35 ° or less.

In addition, if the bulging portion is formed in the crown portion 16 as in the prior art, the shape of the bulging portion is easily noticeable, and the user feels discomfort when holding the face surface 14A of the golf club head 10 toward the target point. Therefore, depending on the golfer, when holding the golf club 100, the direction of the face surface 14A of the golf club head 10 with respect to the ball may vary, and as a result, the direction of the ball launched by the golf club head 10 may not be stable.
On the other hand, in the present embodiment, when the head body 12 is viewed in a plan view in the reference state, the ridge line RL extending in the toe heel direction on the crown surface 16A by the inflection point H continuing in the toe heel direction. It is formed to be visible.
Therefore, since two lines of the boundary line Lfc and the ridge line RL parallel to each other at intervals in the front-rear direction are visually recognized, it looks like the portion (thickness) of the top blade of the iron type golf club head. Become.
Therefore, when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to feel discomfort and it is advantageous to suppress the variation in the direction of the hit ball.
In the reference state, when the head body 12 is viewed in plan, since the ridge line RL is parallel to the boundary line Lfc, when holding the face surface 14A of the golf club head 10 toward the target point, It becomes easier to hold the hand and is more advantageous in suppressing the variation in the direction of the hit ball.

Further, in the present embodiment, since the inflection point angle θ2 is 1 ° or more and 15 ° or less, the ridge line RL is easy to be visually recognized, ensuring ease of holding, and the direction of the ball launched by the golf club head 10 It is more advantageous in securing the stability of the
Strictly, the inflection point angle θ2 slightly changes depending on the distance of the face reference cross section Pf from the face center reference cross section Pfc, in other words, changes within a certain range.
When the inflection point angle θ2 is less than 1 °, the effect of securing the visibility of the ridge line RL is reduced.
When the inflection point angle θ2 is larger than 15 °, the height difference of the crown surface is too large before and after the ridge line RL, so the effect of securing the ease of holding is reduced, and the direction of the ball launched by the golf club head 10 is stabilized. The effect of securing
More preferably, the inflection point angle θ2 is 2 ° or more and 10 ° or less.

Further, in the present embodiment, since the ratio RA / RB of the curvature radius RA of the inflection point H to the curvature radius RB of the third intersection point P3 is 0.04 or more and 0.35 or less, the ridge line RL is easily visible. Therefore, it is more advantageous in securing the ease of holding and suppressing the variation in the direction of the ball launched by the golf club head 10.
The ratio RA / RB strictly changes slightly depending on the distance of the face reference cross section Pf from the face center reference cross section Pfc, in other words, changes within a certain range.
If the ratio RA / RB is less than 0.04, the shape of the inflection point H changes too rapidly, so the stress is concentrated too much, and the effect of securing the durability of the golf club head is reduced. In addition, the effect of preventing the user from feeling a sense of discomfort when the golf club head 10 is viewed is also reduced.
When the ratio RA / RB is larger than 0.35, the effect of securing the visibility of the ridge line RL is reduced.
More preferably, the ratio RA / RB is 0.04 or more and 0.25 or less.

Further, in the present embodiment, as shown in FIG. 3, when the head main body 12 is viewed in plan in the reference state, the ridge line RL intersects the face center reference cross section Pfc and the ridge line RL is projected on the horizontal plane HP. The dimension D1 of the ridge line RL is set to 20% or more of the head length HL.
Therefore, since it becomes easy to visually recognize ridgeline RL, it becomes more advantageous in ensuring the ease of holding and suppressing the dispersion | variation in the direction of the ball | bowl which started with the golf club head 10. FIG.
In addition, if the dimension D1 of the ridge line RL is less than 20% of the head length HL, the effect of concentrating stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting is reduced. The amount of deformation of the portion of the crown portion 16 closer to the portion 14 decreases, and the amount of deflection of the face portion 14 decreases, so the effect of improving the initial speed and the flight distance decreases.
The dimension D1 of the ridge line RL is preferably 30% or more of the head length HL, and more preferably 40% or more.

Further, in the present embodiment, as shown in FIG. 13, in the reference state, in the face reference cross section Pf, from the first boundary point K1 when the first boundary point K1 and the inflection point H are projected onto the horizontal plane HP. The distance D2 to the inflection point H is 5% or more and 15% or less of the head width HW (see FIG. 3).
The distance D2 strictly varies slightly depending on the distance of the face reference cross section Pf from the face center reference cross section Pfc, in other words, changes within a certain range.
Therefore, when the golf club head 10 is viewed in plan at the address time, the ratio of the distance D2 between the boundary line Lfc and the ridge line RL to the head width HW is a range that does not make the golfer feel uncomfortable. In other words, the balance between the distance D2 and the head width HW is a range that does not make the golfer feel discomfort.
Therefore, it is easy for the golfer to feel discomfort when holding the face surface 14A of the golf club head 10 toward the target point, so it is easy to hold the golf club 100, and the effect of suppressing variation in the direction of the hit balls is enhanced. It is more advantageous.

15 (A) to 15 (C) are plan views of the golf club head to which the present invention is applied as a reference state, (A) shows a driver, (B) shows a fairway wood, (C) shows a utility. ing.
16 (A) to 16 (C) are cross-sectional views of the face center reference cross section Pfc of each golf club head described above, where (A) shows a driver, (B) shows a fairway wood, and (C) shows a utility. . 16A to 16C show only the outlines of the face surface 14A and the crown surface 16A.
By setting the distance D2 to 5% or more and 15% or less of the head width HW, it is understood that it is difficult for the golfer to feel discomfort regardless of the type of the head.

If the distance D2 is less than 5% of the head width HW, the distance D2 between the boundary line Lfc and the ridge line RL is too small for the head width HW, that is, the ridge line RL is too close to the face portion 14 The effect of not giving the golfer a sense of discomfort is reduced.
If the distance D2 from the first boundary point K1 to the inflection point H is larger than 15% of the head width HW, the distance D2 between the boundary line Lfc and the ridge line RL is too large for the head width HW, ie, the ridge line RL Is too far from the face portion 14, so that the effect of making the golfer not feel uncomfortable is reduced, and the effect of concentrating stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting is also reduced. As a result, the amount of deformation of the portion of the crown portion 16 closer to the face portion 14 is reduced, and the amount of deflection of the face portion 14 is reduced, so that the effect of improving the initial speed and the flight distance is reduced.
The distance D2 is preferably 7% or more and 12% or less of the head width HW.
Further, even if the distance D2 is 5 mm or more and 25 mm or less, the same effect as described above is exhibited.

Further, in the present embodiment, as shown in FIG. 13, in the reference state, in the face center reference cross section, in the faceback direction from the inflection point H on the plane HP ′ ′ including the inflection point H and parallel to the horizontal plane HP. The weighted average of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H when the intersection point of the straight line L4 passing through the point 15 mm apart and orthogonal to the horizontal plane HP and the crown surface 16A is the fourth intersection point P4. The value Δd1 is a value larger than the weighted average value Δd2 of the thickness of the crown portion 16 from the inflection point H to the fourth intersection point P4.
The weighted average value Δd1 and the weighted average value Δd2 strictly change slightly depending on the distance of the face reference cross section Pf from the face center reference cross section Pfc, in other words, change within a certain range.
Here, the weighted average value of the thickness of the crown portion 16 is indicated by the weighted average of the thickness of the crown portion 16 weighted by the length of the face reference cross section Pf.
Therefore, in addition to the crown portion 16 having a smaller thickness than the face portion 14 and extending rearward from the top of the face portion 14, the weighted average value Δd1 is larger than the weighted average value Δd2, This is advantageous in improving durability while securing the effect of concentration of stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting a ball.
The weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is less than or equal to the weighted average value Δd2 of the thickness of the crown portion 16 from the inflection point H to the fourth intersection point P4. In addition, the effect of concentration of stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting a ball is reduced, which is disadvantageous in improving the durability.
The thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 0.7 mm to 2.0 mm, and more preferably 0.7 mm to 1.4 mm.
The thickness of the crown portion 16 from the inflection point H to the fourth intersection point P4 is 0.4 mm to 1.2 mm, and more preferably 0.4 mm to 0.8 mm.

As described above, according to the golf club head 10 of the present embodiment, the flange angle θ1 of the crown portion 16 is 15 ° to 50 °, and the face reference cross section Pf is separated from the first intersection point P1 in the faceback direction. The inflection point H is formed at the crown surface 16A, and the radius of curvature RA of the inflection point H is smaller than the radius of curvature of the crown surface 16A located between the first intersection point P1 and the inflection point H. In the reference state, when the head main body 12 is viewed in a plan view, the ridge line RL extending in the toe heel direction is visibly formed on the crown surface 16A by continuing the inflection point H in the toe heel direction. .
Therefore, when the ball is hit, stress concentrates on the portion of the crown portion 16 including the inflection point H (ridge line RL), so that a large amount of deformation of the crown portion 16 near the face portion 14 can be secured, and the deflection amount of the face portion 14 increases. Thus, the coefficient of restitution can be increased and the launch angle can be increased, which is advantageous in improving the initial speed and the flight distance.
In addition, since ridge line RL extending in the toe-heel direction is visually recognized on crown surface 16A, there is no sense of discomfort when holding face surface 14A of golf club head 10 toward the target point, and golf club 100 can be held easily. This is advantageous in suppressing variations in the ball direction.

FIG. 17 is a cross-sectional view of a face center reference cross section Pfc showing changes in the shape of the golf club head 10 before and after hitting a ball, in which (A) shows a general golf club head 10 'and (B) shows the present invention. A golf club head 10 is shown.
In FIGS. 17A and 17B, a solid line indicates a state before hitting a ball and a two-dot chain line indicates a deformed state after hitting a ball, and a two-dot chain line indicates an enlarged amount of actual deformation.
Further, Dx1 and Dx2 indicate the range in which the crown portion 16 is deformed by hitting a ball.
As apparent from FIGS. 17A and 17B, the deformation range Dx2 of the golf club head 10 of the present invention is narrower than the deformation range Dx1 of the general golf club head 10 '.
That is, the degree of stress concentration on the portion of the crown portion 16 near the face portion 14 including the inflection point H at the time of hitting a golf club head 10 according to the present invention in comparison with the general golf club head 10 '. Is greater.
That is, in the golf club head 10 of the present invention, the deformation is concentrated in a narrow area near the face portion 14 of the crown portion 16, and the deformation contributes to the deflection of the face portion 14 at a high degree.
As a result, the amount of deflection of the face portion 14 is increased, so that the coefficient of restitution can be increased and the launch angle can be increased, which is advantageous in improving the initial speed and the flight distance.

On the other hand, in a general golf club head 10 ', in addition to the portion near the face portion 14 of the crown portion 16, deformation also occurs in the portion of the crown portion 16 separated from the face portion 14 in the faceback direction. That is, deformation occurs in a wide range.
Therefore, although the deformation of the crown portion 16 closer to the face portion 14 contributes to the deflection of the face portion 14, the deformation of the portion of the crown portion 16 separated from the face portion 14 in the face back direction hardly contributes to the deflection of the face portion 14 . Therefore, the deflection amount of the face portion 14 is smaller than that of the present invention, and the initial velocity and the flying distance are smaller than those of the present invention.

The deformation of the crown portion 16 at the time of hitting is further described.
FIGS. 18A and 18B are cross-sectional views of the face center reference cross section Pfc showing changes in the shape of the golf club head 10 of the present invention before and after hitting a ball, showing an actual amount of deformation enlarged. 18B shows the shape of the golf club head 10 before hitting a ball.
As shown in FIG. 18B, it can be seen that the deformation of the crown portion 16 at the time of hitting the ball B is concentrated toward the face portion 14 and the deformation of the crown portion 16 other than the face portion 14 is extremely small. .
For example, in the case where the deformation amount (displacement amount) of the crown portion 16 at the time of hitting is 0.1 mm or more in the face center reference cross section Pfc of the golf club head 10 in the reference state, the deformation range of the crown portion 16 is A ratio D1 ′ / HW obtained by dividing the length D1 ′ of the deformation range obtained by projecting the range on the horizontal plane HP by the head width HW is 10% to 25% closer to the face portion 14 of the crown portion 16.
Specifically, when the head width HW is 110 mm, the deformation range of the crown portion 16 is 11 mm to 27.5 mm closer to the face portion 14 of the crown portion 16.
Therefore, it can be seen that the deformation of the crown portion 16 at the time of hitting is concentrated closer to the face portion 14.
As described above, since the amount of deformation in a narrow range near the face portion 14 in the crown portion 16 is large, the degree of the contribution of the deformation to the deflection of the face portion 14 is high.
On the other hand, the portion of the crown portion 16 excluding the portion near the face portion 14 has a small amount of deformation, so unnecessary deformation that contributes little to the deflection of the face portion 14 is suppressed, and the amount of deflection of the face portion 14 increases Since the coefficient of restitution can be increased and the launch angle can be increased, it is advantageous in improving the initial speed and the flight distance.

Hereinafter, experimental examples of the present invention will be described.
FIG. 19 is a diagram showing experimental results of the golf club head 10 according to the present invention.
A golf club head 10 serving as a sample was prepared for each experimental example, and the following four evaluation items were measured to determine an index (evaluation point), and a total score of the four indices was determined.

(1) Initial Speed A golf club equipped with the golf club head 10 was installed on a swing robot, and a hit test was conducted under the following conditions to evaluate the average value of the initial speed at 9 points with 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 speed and the better the evaluation.
Head speed: 40 m / s
Ball: Pro Gear Inc. Pro Gear TR Spin (trade name)
The hit point position was a total of 9 hit points below, and the ball was hit five times at each hit point.
A center point Pc of the face surface 14A, and a point which is 7 mm away from the center point Pc in the toe direction on a straight line passing the center point Pc and orthogonal to the face center line CL and a point 7 mm apart in the heel direction.
A point 5 mm apart from the center point Pc in the direction of the crown 16 on the face center line CL, and a point 7 mm apart in the toe direction from the above point on an upper 5 mm line passing through this point and orthogonal to the face center line CL; 3 bout points 7 mm apart in the heel direction.
A point 5 mm apart from the center point Pc in the direction of the sole portion 18 on the face center line CL, and a point 7 mm apart in the toe direction from the above point on the lower 5 mm line passing through this point and orthogonal to the face center line CL; 3 bout points 7 mm apart in the heel direction.

(2) Directionality The directionality when actually hitting a golf ball with the golf club head 10 was evaluated using an index. The index of the experimental example corresponding to the comparative example is 100, and the larger the index is, the better the directionality is.
Here, the directionality is determined as follows.
That is, a target point is set in the hitting field, and the golfer hits the target point. Then, the straight line connecting the hit point and the target point and the distance to the point where the hit ball stops is recorded as the direction shake width (yard). These were performed five balls at a time on one golf club, and the average value of the standard deviations of the directional shake widths was obtained as evaluation data of directionality.
Here, evaluation data of directionality was determined for each of twenty test subjects using the golf clubs of each experimental example, and an average value of evaluation data of directionality of 20 persons was determined for each golf club. The average value of the evaluation data of the experimental example corresponding to the comparative example is 100, and the experimental example other than the comparative example has an index (((average value of evaluation data of experimental example corresponding to comparative example / experimental example other than comparative example Average value of evaluation data) × 100). That is, the higher the index, the better the directionality.

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

(4) Durability A 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 impacts required to cause deformation or breakage of the face portion 14 is measured. Was indexed. The ball speed was 50 m / s. The hit point position is 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 indicated by an index of 100. The larger the index, the better the evaluation.

(5) Total points The sum of the four indexes of initial velocity, directionality, flight distance, and durability described above was taken as the total point.
The total score of the experimental example corresponding to the comparative example is 400, and the larger the total score, the better the evaluation.

Moreover, as an experimental example is shown below, it experimented on the following four types of conditions about each of a driver and a fairway wood.
(Condition 1) The thickness of the crown portion 16 is made uniform and constant, the volume and weight of the head body 12 are made constant, and the respective numerical values (numerical values defined in claim 1) are changed.
However, an experiment example satisfying only the definition of claim 1 and not satisfying the definition of claims 2, 3 and 4 is compared with an experiment example not satisfying all the definitions of claims 1-4.
(Condition 2) The thickness of the crown portion 16 is made uniform and constant, the volume and weight of the head body 12 are made constant, and the respective numerical values (numerical values defined in claims 1 to 4) are changed.
(Condition 3) The volume of the head main body 12 is fixed, the numerical value other than the thickness of the crown portion 16 (numerical value defined in claims 1 to 4) is fixed, and the thickness of the crown portion 16 is changed.
Therefore, the weight of the head body 12 changes within a certain range.
(Condition 4) The thickness of the crown portion 16 is made uniform, the numerical value other than the thickness of the crown portion 16 (numerical values defined in claims 1 to 4) is made constant, and the volume of the head main body 12 is changed.
Therefore, the weight of the head body 12 changes within a certain range.
For the convenience of the experiment, the experimental examples under the conditions 1, 2 and 4 do not satisfy the definition of the weighted average value of the thickness of the crown portion 16 in claim 1, and the experimental example under the condition 3 Among the claim 1 of the present invention, there are those which satisfy the requirements of the weighted average value of the thickness of the crown portion 16 and those which do not.
Therefore, for the conditions 1, 2 and 4, the experimental example satisfying the definition of claim 1 does not satisfy the definition of the weighted average value of the thickness of the crown portion 16 in claim 1.
In addition, with regard to condition 3, the experimental example satisfying the definition of claim 1 satisfies all the provisions of claim 1 including the definition of the weighted average value of the thickness of the crown portion 16.

(Driver: Condition 1)
Next, an experimental example of the driver under condition 1 will be described.
As shown in FIG. 19, in Experimental Examples 1 to 7, experiments were performed under condition 1, and the thickness of the crown portion 16 and the volume and weight of the head main body 12 are made constant, and each numerical value is changed.
That is, the volume of the head body 12 was 460 ± 2 cc, the weight was 198 ± 1 g, and the loft angle was 10 degrees in any of the experimental examples.
Further, in any of the experimental examples, the shape of the crown portion 16 closer to the face portion 14 is different as described in detail below, and the shape of the crown portion 16 in other places and the shape other than the crown portion 16 are the same shape. It has become.
The material of the head body 12 is 6AL-4V titanium alloy, the thickness of the face portion 14 is 3.2 ± 0.05 mm uniform thickness, and the other thickness is 1.0 ± 0.1 mm uniform thickness including the crown portion 16 I made it.

  Experimental Example 1 is the same as the prior art (Japanese Patent No. 5882522) in which the crown portion 16 is provided with the bulging portion and corresponds to the comparative example, and the inflection point specified in the present invention H, has no ridge line RL, and therefore does not satisfy the definition of claim 1 of the present invention.

Experimental examples 2, 3, 6, 7 do not satisfy all the requirements of claims 1 to 4.
Examples 2 and 3 do not satisfy the definition of claim 1 in that there is no ridge line RL, and examples 6 and 7 have a ridge line RL but do not satisfy the definition of claim 1.
Experimental Examples 4 and 5 satisfy the definition of claim 1 and do not satisfy the definitions of claims 2, 3 and 4.
The definitions of claims 2, 3 and 4 in experimental examples 4, 5, 6, 7 are as follows.
The ratio RA / RB of the radius of curvature RA is 0.44, and the ratio RA / RB of claim 2 exceeds the range of 0.04 or more and 0.35 or less.
In the reference state, the size of the ridgeline obtained by projecting the ridgeline RL to the horizontal plane HP is 15% of the head length HL, which is less than 20% of the third aspect.
When the first boundary point K1 and the inflection point H are projected on a horizontal plane, the distance from the first boundary point K1 to the inflection point H is 16% of the head width HW. It exceeds the range below%.

In Experimental Example 2, the flange angle θ1 is 15 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL does not exist, so the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 101, the directivity 95, the flight distance 102, and the durability 100 are 398 in total, the initial velocity and the flight distance are improved compared to those of Experimental Example 1, but the directivity is lower than that of Experimental Example 1.
This is because the ridge line RL is not visible, and when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to hold the ball, and variations in the direction of the hit balls increase.

In the experimental example 3, the flange angle θ1 is 50 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL does not exist, so the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 102, the directivity 95, the flight distance 102, and the durability 90 are a total of 389, although the initial velocity and the flight distance are improved compared to Experimental Example 1, the directivity and durability are lower than that of Experimental Example 1. .
This is because the ridge line RL is not visible, and when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to hold the ball, and variations in the direction of the hit balls increase.
In addition, since the flange angle θ1 is 50 °, which is the upper limit value, the strength of the portion of the head main body 12 (the boundary between the face surface 14A and the crown surface 16A) corresponding to the first boundary point K1 is slightly reduced. .

In Experimental Example 4, the flange angle θ1 is 15 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL is visible, and the definition of claim 1 is satisfied. ing.
Therefore, the initial velocity 108, the directionality 108, the flight distance 106, and the durability 100 are a total of 422, and the evaluation of the initial velocity, the directionality, and the flight distance exceeds that of the experimental example 1.

In Experimental Example 5, the flange angle θ1 is 50 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL is visible, and the definition of claim 1 is satisfied. ing.
Therefore, the initial velocity 104, the directivity 108, the flight distance 103, and the durability 106 are 421 in all, and all the evaluations exceed the experimental example 1.

In the experimental example 6, the flange angle θ1 is 10 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° in the definition of claim 1, the ridge line RL exists, but the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 101, the directivity 102, the flight distance 102, the durability 100, a total of 405, the evaluation of the initial velocity, directionality and flight distance is improved compared to the experimental example 1, the evaluation of the initial velocity and flight distance is an experiment Low compared to Examples 4 and 5.
This is disadvantageous in securing deformation of the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting the ball, although the inflection point H (ridge line RL) exists but the flange angle θ1 is small. It is for.

In the experimental example 7, the flange angle θ1 is 55 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° in the definition of claim 1, there is a ridge line RL, but the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 102, the directionality 102, the flight distance 101, and the durability 89 are a total of 394 and the evaluation of the initial velocity, directionality and flight distance is improved compared to Experimental Example 1, the evaluation of the initial velocity and flight distance is an experiment Compared with Examples 4 and 5, the durability is lower than that of Example 1.
This is because if the flange angle θ1 is larger than 50 °, the strength of the portion of the head main body 12 corresponding to the first boundary point K1 (the boundary between the face surface 14A and the crown surface 16A) decreases. This is because the effect of securing the durability is reduced. If the flange angle θ1 is larger than 50 °, the golfer tends to feel uncomfortable with the shape of the golf club head 10, making it difficult to swing and lowering the head speed, which is disadvantageous in securing the flight distance. It is.

Each evaluation item is discussed below.
(1) Initial Speed The experimental examples 4 and 5 satisfying the definition of claim 1 but not satisfying claims 2 to 4 have an initial speed of 108 and 104, and the initial speed is the best.
In the second, third, sixth, and seventh experimental examples which do not satisfy all of the definitions of claims 1 to 4, the initial speed is 101 to 102.
Therefore, the one satisfying the definition of claim 1 is excellent in the effect of improving the initial speed with respect to the one not satisfying the claim 1.

(2) Directionality Although Experimental Examples 4 and 5 which satisfy the definition of Claim 1, but do not satisfy Claims 2-4, directivity is 108 and 108 and directivity is the most excellent.
Experimental examples 2, 3, 6, 7 which do not satisfy all of the definitions of claims 1 to 4 have a directionality of 95 to 102.
Therefore, those satisfying the requirements of claim 1 are excellent in the effect of improving the directionality with respect to those not satisfying claim 1.

(3) Flying Distance The flying distances are 103 and 106 in Experimental Examples 4 and 5 satisfying the definition of claim 1 but not satisfying claims 2 to 4, and the flying distance is most excellent.
In Experimental Examples 2, 3, 6, 7 which do not satisfy all of the definitions of Claims 1-4, a flight distance is 101-102.
Therefore, those that satisfy the definition of claim 1 are superior in the effect of improving the flight distance to those that do not satisfy claim 1.

(4) Durability Although the requirements of claim 1 are satisfied, experimental examples 4 and 5 which do not satisfy claims 2 to 4 have a durability of 100 and 106, and the durability is most excellent.
Experimental examples 2, 3, 6, 7 which do not satisfy all of the definitions of claims 1 to 4 have a durability of 89 to 100.
Therefore, those that satisfy the requirements of claim 1 are more effective in improving the durability than those that do not satisfy claim 1.

(5) Total points The experimental examples 4 and 5 satisfying the definition of claim 1 but not satisfying claims 2 to 4 have a total point of 422 and 421, and the total point is the best.
In the experimental examples 2, 3, 6, 7 which do not satisfy all of the definitions of claims 1 to 4, the total score is 389 to 405.
Therefore, those that satisfy the requirements of claim 1 are excellent in the effect of improving the total score with respect to those that do not satisfy claim 1.

(Driver: Condition 2)
Next, an experimental example of the driver under condition 2 will be described.
In addition, the number of the example of an experiment shown below is attached from experiment example 12 for convenience.
As shown in FIG. 20, in Experimental Examples 12 to 28, experiments were performed under condition 2, and the thickness of the crown portion 16 and the volume and weight of the head main body 12 are made constant, and each numerical value is changed.
That is, the volume of the head body 12 was 460 ± 2 cc, the weight was 198 ± 1 g, and the loft angle was 10 degrees in any of the experimental examples.
Further, in any of the experimental examples, the shape of the crown portion 16 is different as described in detail below, and the shapes other than the crown portion 16 are the same.
The material of the head body 12 is 6AL-4V titanium alloy, the thickness of the face portion 14 is 3.2 ± 0.05 mm uniform thickness, and the other thickness is 1.0 ± 0.1 mm uniform thickness including the crown portion 16 I made it.

Experimental Example 1 is the same as Experimental Example 1 of FIG.
Experimental Examples 12, 13, 16, 17, 20, 23, 24, 27, 28 satisfy all of the definitions of claims 1 to 4.
Experimental Example 19 meets the requirements of claims 1, 2 and 4, but does not meet the requirement of claim 3.
Experimental Examples 21 and 22 satisfy the requirements of claims 1 and 2 but do not satisfy the requirements of claim 4.
Experimental Examples 25 and 26 satisfy the definition of claims 1, 3 and 4 but do not satisfy the definition of claim 2.
The experimental examples 14 and 15 have the inflection point H and the ridge line RL, but do not satisfy the definition of claim 1.
Experimental Example 18 has an inflection point H, but does not satisfy the requirements of claims 1 and 2.

Experimental Example 12 satisfies all the requirements of Claims 1-4.
Therefore, the initial velocity 119, the directivity 139, the flight distance 130, the durability 133, and the total score 521 are obtained, and all the evaluations are superior to those of the experimental example 1.

Experimental Example 13 satisfies all of the definitions of Claims 1 to 4.
Therefore, the initial velocity 123, the directivity 135, the flight distance 134, the durability 125, and the total point 517 are obtained. As compared with Experimental Example 2, the durability is slightly reduced.

In the experimental example 14, the flange angle θ1 is 12 °, and within the definition of claim 1, it falls below the range of 15 ° ≦ θ1 ≦ 50 °.
Therefore, the initial velocity 101, the directionality 102, the flight distance 101, and the durability 120 are totaled 424, and the evaluation excluding the durability remains at the same level as the experimental example 1.
This is disadvantageous in securing deformation of the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting the ball, although the inflection point H (ridge line RL) exists but the flange angle θ1 is small. It is for.

In the experimental example 15, the flange angle θ1 is 54 °, and in the definition of claim 1, it exceeds the range of 15 ° ≦ θ1 ≦ 50 °.
Accordingly, the initial velocity 105, the directivity 102, the flight distance 101, the durability 96, and the total are 404, and although the initial velocity and flight distance slightly exceed Experimental Example 1, the directivity is similar to Experimental Example 1 The sex is below experimental example 1.
This is because if the flange angle θ1 is larger than 50 °, the strength of the portion of the head main body 12 corresponding to the first boundary point K1 (the boundary between the face surface 14A and the crown surface 16A) decreases. This is because the effect of securing the durability is reduced. If the flange angle θ1 is larger than 50 °, the golfer tends to feel uncomfortable with the shape of the golf club head 10, making it difficult to swing and lowering the head speed, which is disadvantageous in securing the flight distance. It is.

Experimental example 16 satisfies all of the definitions of claims 1 to 4, the flange angle θ1 is 17 °, and within the definition of claim 1, it is in the vicinity of the lower limit value of the range of 15 ° ≦ θ1 ≦ 50 °. is there.
Therefore, the initial velocity 114, the directivity 122, the flight distance 117, and the durability 125 are 478 in total, and all the evaluations are superior to those of the experimental example 1.

Experimental example 17 satisfies all of the definitions of claims 1 to 4, the flange angle θ1 is 48 °, and within the definition of claim 1, it is in the vicinity of the upper limit value of the range of 15 ° ≦ θ1 ≦ 50 °. is there.
Therefore, the initial velocity 120, the directionality 116, the flight distance 131, and the durability 110 are 477 in total, and all the evaluations are superior to those of Experimental Example 1.

Experimental example 18 satisfies claims 3 and 4, but the ridge line RL can not be visually recognized and does not satisfy the requirements of claims 1 and 2. Further, the inflection point angle θ2 is 0.4 °, which is less than the range of 1 ° ≦ θ2 ≦ 15 ° in claim 2, and the ratio RA / RB of the curvature radius is 0.80, Item 2 exceeds the range of 0.04 ≦ ratio RA / RB ≦ 0.35.
Therefore, the initial velocity 102, the directionality 92, the flight distance 102, and the durability 125 are a total of 421, and the directionality is lower than that of the experimental example 1. This is because the ridge line RL is not visible, and when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to hold the ball, and variations in the direction of the hit balls increase.

Experimental example 19 satisfies claims 1, 2 and 4, but the length D1 of the ridge line RL is 18% of the head length HL and is less than the regulation of 20% or more of claim 2. .
Therefore, although the initial velocity 104, the directionality 110, the flight distance 104, and the durability 122 are 440 in all, and all the evaluations are superior as compared with the experimental example 1, the evaluation is lower compared to the experimental examples 12 and 13. It has become.
This is because, since the dimension D1 of the ridge line RL is less than 20% of the head length HL, the effect of concentration of stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting is reduced. The amount of deformation of the crown portion 16 closer to the face portion 14 is reduced, and the amount of deflection of the face portion 14 is reduced, so that the effect of improving the initial speed and the flight distance is reduced.

Experimental example 20 satisfies claims 1, 2, 3 and 4. In addition, the length D1 of the ridge line RL is 100% of the head length HL, and the definition of 20% or more of claim 3 is satisfied.
Therefore, the initial velocity 122, the directivity 134, the flight distance 133, and the durability 121 are 510 in total, and the durability is about the same as that of the experimental example 19 and the remaining evaluation is superior to the experimental example 19. .
This is because, since the dimension D1 of the ridge line RL is 100% of the head length HL, the effect of concentration of stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting is secured. The deformation amount of the crown portion 16 closer to the face portion 14 is secured, and the deflection amount of the face portion 14 is secured, so that the effect of improving the initial speed and the flight distance can be achieved. Further, the evaluation of the directionality is better than that of Example 19 because the length D1 of the ridge line RL is long, so it is easy to hold the face surface 14A of the golf club head 10 toward the target point. This is because the variation in direction is somewhat suppressed.
However, with respect to the durability, the amount of deformation is a little larger than that of the experimental example 12 and is reduced due to the large stress.

Experimental example 21 satisfies claims 1, 2 and 3, but the distance D2 from the first boundary point K1 to the inflection point H is 4.2% of the head width HW, and 5% of claim 4 It is below the range of 15% or less.
Therefore, although the initial velocity 109, the directivity 120, the flight distance 115, and the durability 104 are 448 in total, and all the evaluations are superior as compared with the experimental example 1, the directions are compared with the experimental examples 12 and 13. It has a slightly low rating.
This is because the distance D2 between the boundary line Lfc and the ridge line RL is too small with respect to the head width HW, that is, the ridge line RL is too close to the face portion 14, and the effect of making the golfer not feel uncomfortable is reduced. .
In addition, since the distance D2 between the boundary line Lfc and the ridge line RL is too small, stress is likely to be concentrated in the vicinity of the ridge line RL, and it is difficult to perform appropriate deformation, and the initial speed has a slightly lower value compared to Experimental Example 12. The durability is low.

Experimental example 22 satisfies claims 1, 2 and 3, but the distance D2 from the first boundary point K1 to the inflection point H is 16.8% of the head width HW, and 5% of claim 4 It is above the range of 15% or less.
Therefore, although the initial velocity 106, the directionality 115, the flight distance 109, and the durability 125 are a total of 455, and all evaluations are superior as compared to Experimental Example 1, compared with Experimental Examples 12 and 13, It has low reputation.
This is because the distance D2 between the boundary line Lfc and the ridge line RL is too large for the head width HW, that is, the ridge line RL is too far from the face portion 14, and the effect of making the golfer not feel uncomfortable is reduced. .
In addition, since the distance D2 between the boundary line Lfc and the ridge line RL is too large, the stress is hard to concentrate in the vicinity of the ridge line RL, and it is difficult to perform appropriate deformation. .

Experimental example 23 satisfies claims 1, 2, 3 and 4, the distance D2 from the first boundary point K1 to the inflection point H is 6% of the head width HW, and 5% or more of claim 4 It is a value near the lower limit in the range of 15% or less.
Accordingly, the initial velocity 118, the directivity 122, the flight distance 118, and the durability 115 are all 473, and all the evaluations show that the distance D2 is less than the range of 5% to 15% of the head width HW. It is superior to.
This is because, since D2 is in the vicinity of the lower limit value in the appropriate range, appropriate stress is concentrated in the vicinity of the ridgeline RL, appropriate deformation is performed, and initial velocity, flight distance, durability, and directionality can be secured.

Experimental example 24 satisfies claims 1, 2, 3 and 4, the distance D2 from the first boundary point K1 to the inflection point H is 14% of the head width HW, and 5% or more of claim 4 It is a value near the upper limit in the range of 15% or less.
Therefore, the initial velocity 111, the directivity 120, the flight distance 114, and the durability 128 are all 473, and all evaluations show that the distance D2 exceeds the range of 5% to 15% of the head width HW. It is superior to.
This is because, since D2 is in the vicinity of the upper limit value in the appropriate range, appropriate stress is concentrated in the vicinity of the ridge line RL, appropriate deformation is performed, and initial velocity, flight distance, durability, and directionality can be secured.

Experimental example 25 satisfies claims 1, 3 and 4, but the inflection point angle θ2 is 0.7 °, and is less than the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2. ing. In addition, the ratio RA / RB of the curvature radius RA of the inflection point H to the curvature radius RB of the third intersection point P3 is 0.50, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 or less of claim 2. Exceeds.
Therefore, the initial velocity 107, the directionality 101, the flight distance 117, and the durability 120 total 445, and the evaluation of the directionality remains equivalent to that of the experimental example 1.
This is because the effect of securing the visibility of the ridge line RL decreases, and the effect of suppressing the variation in the direction of the ball launched by the golf club head 10 decreases.

Experimental example 26 satisfies claims 1, 3 and 4, but the inflection point angle θ2 is 17 °, and exceeds the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2. . Further, the ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.03, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 or less of claim 2. Below.
Therefore, the initial velocity 110, the directionality 100, the flight distance 111, and the durability 105, totaling 426, the evaluation of the directionality remains equivalent to that of the experimental example 1, and the remaining evaluation is superior to the experimental example 1.
This is because the inflection point angle θ2 is larger than 15 °, and the elevation difference of the crown surface 16A is too large before and after the ridge line RL, so the effect of securing the ease of holding decreases and the golf club head 10 This is because the effect of suppressing the variation in the direction of the ball is reduced.
Further, in the experimental example 26, since the ratio RA / RB is less than 0.04, the stress applied to the inflection point H is easily concentrated, so that the effect of ensuring the durability of the golf club head 10 is obtained by the experimental examples 12 and 13. It is lower than that.

Experimental example 27 satisfies claims 1, 2, 3 and 4, the inflection point angle θ2 is 1.2 °, and the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2 It is a value near the lower limit value. Further, the ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.14, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 in the second aspect. It is inside.
Therefore, the initial velocity 114, the directionality 129, the flight distance 120, and the durability 132 are a total of 495, and all the evaluations are superior to those of Experimental Example 1, and the definition of inflection point angle θ2 and ratio RA / The evaluation of the directionality is particularly excellent as compared to Experimental Examples 25 and 26 which do not satisfy the definition of RB.

Experimental example 28 satisfies claims 1, 2, 3 and 4, the inflection point angle θ2 is 14.8 °, and the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2 It is a value near the upper limit value. The ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.33, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 or less of claim 2. Of the upper limit value of.
Therefore, the initial velocity 116, the directivity 124, the flight distance 125, and the durability 129 are all 494, and all the evaluations are superior to those of the experimental example 1, and the definition of the inflection point angle θ2 and the ratio RA / The evaluation of the directionality is particularly excellent as compared to Experimental Examples 25 and 26 which do not satisfy the definition of RB.

Each evaluation item is discussed below.
(1) Initial Speed In Experimental Examples 12, 13, 16, 17, 20, 23, 24, 27, 28 satisfying all the requirements of Claims 1 to 4, the initial speed is 111 to 123, and the initial speed is the best.
The experimental example 19 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has an initial velocity of 104.
Examples 21 and 22 satisfying the requirements of claims 1 to 3 but not satisfying the requirement of claim 4 have initial velocities of 109 and 106, respectively.
Examples 25 and 26 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have an initial velocity of 107 and 110.
Therefore, those that satisfy all the requirements of claims 1 to 4 have an excellent effect of improving the initial speed with respect to those that do not satisfy any one of claims 2, 3 and 4.

(2) Directionality Experimental examples 12, 13, 16, 17, 20, 23, 24, 27 and 28 satisfying all the requirements of claims 1 to 4 have a directionality of 116 to 139 and are most excellent in directionality. ing.
Example 19 which meets the requirements of claims 1, 2 and 4 but does not meet the requirement of claim 3 has a directionality of 110.
Examples 21 and 22 satisfying the requirements of claims 1, 2 and 3 but not satisfying the requirement of claim 4 have directivity of 120 and 115.
Experimental examples 25 and 26 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have directionality of 101 and 100.
Therefore, those that satisfy all the requirements of claims 1 to 4 have an excellent effect of improving the directionality to those that do not satisfy any one of claims 2, 3 and 4. .

(3) Flying distance The experimental examples 12, 13, 16, 17, 20, 23, 24, 27 and 28 satisfying all the requirements of claims 1 to 4 have a flying distance of 114 to 134 and the best flight distance. ing.
In Example 19 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3, the flight distance is 104.
Experimental examples 21 and 22 satisfying the requirements of claims 1 to 3 but not fulfilling the requirements of claim 4 have flying distances of 115 and 109, respectively.
Experimental examples 25 and 26 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have a flight distance of 117 and 111.
Therefore, those that satisfy all the requirements of claims 1 to 4 have an excellent effect of improving the flight distance to those that do not satisfy any one of claims 2, 3 and 4. .

(4) Durability Experimental examples 12, 13, 16, 17, 20, 23, 24, 27 and 28 satisfying all the requirements of claims 1 to 4 have a durability of 110 to 133 and the highest durability. ing.
Experimental example 19 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has a durability of 122.
Examples 21 and 22 satisfying the requirements of claims 1 to 3 but not fulfilling the requirements of claim 4 have a durability of 104 and 125.
Experimental examples 25 and 26 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have a durability of 120 and 105, respectively.
Therefore, those satisfying all the requirements of claims 1 to 4 are excellent in the effect of improving the durability against those not satisfying any one of claims 2, 3 and 4. .

(5) Total points In Experimental Examples 12, 13, 16, 17, 20, 23, 24, 27, 28 satisfying all the requirements of claims 1 to 4, the total points are 473 to 521, and the total points are the best. ing.
The experimental example 19 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has a total score of 440.
In Examples 21 and 22 satisfying the requirements of claims 1 to 3 but not fulfilling the requirement of claim 4, the total points are 448 and 455.
Examples 25 and 26 satisfying the requirements of claims 1, 3 and 4 but not fulfilling the requirement of claim 2 have total points of 445 and 426.
Therefore, those which satisfy all the requirements of claims 1 to 4 are excellent in the effect of improving the total points with respect to those which do not satisfy any one of claims 2, 3 and 4. .

(Driver: Condition 3)
Next, an experimental example of the driver under condition 3 will be described.
As shown in FIG. 21, experimental examples 29 to 32 were conducted under the above-mentioned condition 3 and the volume of the head main body 12 is made the same as other numerical values, and the thickness of the crown portion 16 is changed. Therefore, the weight of the head body 12 changes within a certain range.
That is, the volume of the head body 12 was 460 ± 2 cc, the weight was 198 ± 2 g, and the loft angle was 10 degrees in any of the experimental examples.
Further, in any of the experimental examples, the shape and thickness of the crown portion 16 from the first boundary point K1 to the inflection point H and the shape and thickness of the crown portion 16 from the inflection point H to the fourth intersection point P4 are as follows: As will be described in detail, the shapes and thicknesses of the other portions of the crown portion 16 and portions other than the crown portion 16 have the same shape and the same value.
The material of the head body 12 is 6AL-4V titanium alloy, and the thickness of the face portion 14 is 3.2 mm ± 0.05 mm uniform thickness, and the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H Except for the thickness and the thickness of the crown portion 16 from the inflection point H to the fourth intersection point P4, it was manufactured with a uniform thickness of 1.0 mm ± 0.1 mm.
In addition, Experimental Example 12 which is a comparative example in FIG. 21 is Experimental Example 12 in FIG. 20, and the thickness of the crown portion 16 is uniform at 1.0 mm.
In FIG. 21, each evaluation point of this experimental example 12 is set to 100, and based on the evaluation point of this experimental example 12, evaluation of experimental examples 29 to 32 is performed.
Moreover, the following numerical values and configurations are the same in Experimental Examples 12, 29 to 32.
Flange angle θ1 = 30.0 °
There is a ridge line RL.
Edge length RL length D1 = 45.0%
Distance D2 from the first boundary point K1 to the inflection point H = 10.0%
Inflection point angle θ2 = 4.0 °
Radius of curvature ratio RA / RB = 0.20
Experimental Examples 29 to 31 satisfy all of the definitions of claims 1 to 4 including the definition of the weighted average value of the thickness of the crown portion 16.
Moreover, Experimental example 32 does not satisfy | fill the prescription | regulation of the weighted average value of the thickness of the crown part 16 among the prescription | regulations of Claim 1-4.

In Experimental Example 29, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 1.1 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is satisfied in which the weighted average value Δd2 of the thickness is 0.7 mm, and the weighted average value Δd1> the weighted average value Δd2.
Accordingly, the initial velocity 120, the directionality 110, the flight distance 124, and the durability 105 are 459 in total, and all the evaluations are superior to those of the experimental example 12.

In Experimental Example 30, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 1.8 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is satisfied in which the weighted average value Δd2 of the thickness is 1.2 mm, and the weighted average value Δd1> the weighted average value Δd2.
Accordingly, the initial velocity 105, the directionality 106, the flight distance 108, and the durability 110 are a total of 429. The initial velocity and flight distance are lower than those of Experimental Example 29, and the durability is improved compared to Experimental Example 29.
This is because the weighted average values Δd1 and Δd2 of the wall thickness are designed to be thicker than those of Example 29, so that the stress is concentrated on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting. However, the amount of deflection is slightly reduced, and the effect of improving the durability is ensured.

In the experimental example 31, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 0.8 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is satisfied in which the weighted average value Δd2 of the thickness is 0.5 mm, and the weighted average value Δd1> the weighted average value Δd2.
Therefore, the initial velocity 130, the directionality 104, the flight distance 129, and the durability 95 are a total of 458, and the initial velocity and flight distance are improved as compared with Experimental Example 29, and the durability is lowered.
This is because the weighted average values Δd1 and Δd2 of the wall thickness are designed to be thinner than those of Example 29, so that the stress is concentrated on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting. However, the deflection amount is slightly increased, and the effect of improving the durability is reduced.

In Experimental Example 32, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 0.7 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is not satisfied that the weighted average value Δd2 of the thickness is 1.1 mm, and the weighted average value Δd1> the weighted average value Δd2.
Therefore, the initial velocity 105, the directionality 103, the flight distance 104, and the durability 90 are a total of 402, and all evaluations are reduced compared to Experimental Examples 29 to 31.
Since this is not the weighted average value Δd1> the weighted average value Δd2, the stress is concentrated on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting a ball, and appropriate deflection can not be secured. In other words, this is because the deflection amount is excessive, and the effects of improving the initial speed and the durability decrease.

Each evaluation item is discussed below.
(1) Initial Speed In the test examples 29 to 31 satisfying all the requirements of claims 1 to 4, the initial speed is 105 to 130, and the initial speed is the best.
The experimental example 32 which does not satisfy the definition of claim 1 that the weighted average value Δd 1> the weighted average value Δd 2 among the definitions of claims 1 to 4 has an initial speed of 105.
Therefore, the effect of improving the initial speed is superior to the one not satisfying the definition of claim 1 in which the weighted average value Δd1> the weighted average value Δd2 is that satisfying all the requirements of claims 1 to 4 .

(2) Directionality Examples 29 to 31 satisfying all of the definitions of claims 1 to 4 have a directionality of 104 to 110 and are most excellent in directionality.
Among the definitions of claims 1 to 4, in the experimental example 32 not satisfying the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2, the directivity is 103.
Therefore, the effect of improving the directionality is superior to those that do not satisfy the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2 that satisfies all the requirements of claims 1 to 4 There is.

(3) Flying Distance In Experimental Examples 29 to 31 satisfying all the requirements of Claims 1 to 4, the flying distance is 108 to 129 and the flying distance is most excellent.
In Example 32, the flight distance is 104, which does not satisfy the definition of claim 1 that the specified weighted average value Δd1> the weighted average value Δd2 of claims 1 to 4.
Therefore, the effect of improving the flight distance is superior to those not satisfying the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2 is one that satisfies all the requirements of claims 1 to 4. There is.

(4) Durability Experimental examples 29 to 31 satisfying all the requirements of claims 1 to 4 have a durability of 95 to 110 and are most excellent in durability.
The example 32 of the experimental example not satisfying the definition of the claim 1 satisfying the definition of the claims 1 to 4 but having the weighted average value Δd1> the weighted average value Δd 2 has a durability of 90.
Therefore, the effect of improving the durability is superior to those not satisfying the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2 is satisfied by all the requirements of claims 1 to 4. There is.

(5) Total points The experimental examples 29 to 31 satisfying all the definitions of claims 1 to 4 have a total point of 429 to 459, and the total point is the best.
The experimental example 32 satisfying the definition of claims 1 to 4 but not satisfying the definition of claim 1 having a weighted average value Δd1> weighted average value Δd 2 has a total point of 402.
Therefore, the effect of improving the total score is superior to those not satisfying the definition of claim 1 in which the weighted average value Δd1> the weighted average value Δd2 is one that satisfies all the requirements of claims 1 to 5 There is.

(Driver: Condition 4)
Next, an experimental example of the driver under condition 4 will be described.
As shown in FIG. 22, Experimental Examples 1, 12, 33 A, 33 B, 34 A, 34 B, 35 A, 35 B were conducted under the conditions 3 above, and the thickness of the crown portion 16 and each numerical value were the same. And the volume of the head body 12 is changed. Therefore, the weight of the head body 12 changes within a certain range. The loft angle was 10 degrees.
The material of the head body 12 is 6AL-4V titanium alloy, the thickness of the face portion 14 is 3.2 ± 0.05 mm uniform thickness, and the other thickness including the crown portion 16 is 1.0 ± 0.1 mm uniform thickness Made with.
Experimental Examples 33A, 34A, and 35A are Comparative Examples, and in the same manner as in Experimental Example 1, they are configured in the same manner as in the prior art (Japanese Patent No. 5882522) in which the crown portion 16 is provided with a bulged portion. Therefore, it does not have the inflection point H and the ridge line RL defined in the present invention, and therefore does not satisfy the definition of claim 1 of the present invention.
Further, Experimental Examples 33A, 34A, and 35A are different only in volume, and the other shape and thickness are the same as those of Experimental Example 1.
That is, Experimental Examples 33A, 34A, and 35A are comparative examples corresponding to Experimental Examples 33B, 34B, and 35B, respectively, and each evaluation point is set to 100. (It means that even if the volume changes a little, it is the same evaluation)
Experimental Example 1 and Experimental Example 12 shown in FIG. 22 are the same as Experimental Example 1 and Experimental Example 12 of FIG. 20 described above.
Further, the following numerical values and configurations are the same in Experimental Examples 12, 33B, 34B, and 35B.
Flange angle θ1 = 30.0 °
There is a ridge line RL.
Edge length RL length D1 = 45.0%
Distance D2 from the first boundary point K1 to the inflection point H = 10.0%
Inflection point angle θ2 = 4.0 °
Radius of curvature ratio RA / RB = 0.20
In addition, Experimental Examples 33B, 34B, and 35B satisfy all the requirements of Claims 1-4.

The experimental example 33B has a volume of 440 cc, an initial velocity 118, a directionality 139, a flight distance 130, a durability 133, and a total point 520.
The experimental example 34B has a volume of 450 cc, an initial velocity 118, a directionality 139, a flight distance 130, a durability 133, and a total point 520.
The experimental example 35B has a volume of 470 cc, an initial velocity 119, a directionality 139, a flight distance 131, a durability 133, and a total point 522.
Therefore, in Experimental Examples 33B, 34B, and 35B in which only the volume is changed, all evaluations are the same as those of Experimental Example 12 and it is possible to satisfy all the requirements of Claims 1-4 regardless of the volume It is clear that the same effect is exhibited.

(Fairway Wood: Condition 1)
Next, an experimental example of fairway wood # 3 under condition 1 will be described. (It will be appreciated by those skilled in the art that countless fairway woods and utilities will have similar results)
As shown in FIG. 23, in the experimental examples 41 to 47, experiments were performed under condition 1, and the thickness of the crown portion 16 and the volume and weight of the head main body 12 are made constant, and the respective numerical values are changed.
That is, the volume of the head body 12 was 165 ± 2 cc, the weight was 215 ± 1 g, and the loft angle was 15 degrees in any of the experimental examples.
Further, in any of the experimental examples, the shape of the crown portion 16 closer to the face portion 14 is different as described in detail below, and the shape of the crown portion 16 in other places and the shape other than the crown portion 16 are the same shape. It has become.
The material of the head body 12 is a SUS630 alloy, and the thickness of the face portion 14 is 2.4 ± 0.05 mm uniform thickness, and the other thicknesses including the crown portion 16 are 1.0 ± 0.1 mm uniform thickness.

  Experimental Example 41 is the same as the prior art (Japanese Patent No. 5882522) in which the crown portion 16 is provided with the bulging portion and corresponds to the comparative example, and the inflection point specified in the present invention H, has no ridge line RL, and therefore does not satisfy the definition of claim 1 of the present invention.

Experimental examples 42, 43, 46 and 47 do not satisfy all the requirements of claims 1 to 4.
Experimental examples 42 and 43 do not satisfy the definition of claim 1 in that there is no ridge line RL, and experimental examples 46 and 47 do not satisfy the definition of claim 1 although the ridge line RL exists.
Experimental Examples 44 and 45 satisfy the definition of claim 1 and do not satisfy the definitions of claims 2, 3 and 4.
In Experimental Examples 44, 45, 46 and 47, the definitions of Claims 2, 3 and 4 are as follows.
The ratio RA / RB of the radius of curvature RA is 0.44, and the ratio RA / RB of claim 2 exceeds the range of 0.04 or more and 0.35 or less.
In the reference state, the size of the ridgeline obtained by projecting the ridgeline RL to the horizontal plane HP is 15% of the head length HL, which is less than 20% of the third aspect.
When the first boundary point K1 and the inflection point H are projected on a horizontal plane, the distance from the first boundary point K1 to the inflection point H is 16% of the head width HW. It exceeds the range below%.

In the experimental example 42, although the flange angle θ1 is 15 ° and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL does not exist, so the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 102, the directivity 96, the flight distance 101, and the durability 100 are a total of 399, the initial velocity, the flight distance, and the durability are improved compared to those of Experiment 41, but the directivity is lower than that of Experiment 41. .
This is because the ridge line RL is not visible, and when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to hold the ball, and variations in the direction of the hit balls increase.

In Experimental Example 43, although the flange angle θ1 is 50 ° and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL does not exist, and therefore the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 102, the directivity 95, the flight distance 102, and the durability 90 are a total of 389, although the initial velocity and the flight distance are improved compared to the experimental example 41, the directivity and the durability are lower than the experimental example 41 .
This is because the ridge line RL is not visible, and when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to hold the ball, and variations in the direction of the hit balls increase.
In addition, since the flange angle θ1 is 50 °, which is the upper limit value, the strength of the portion of the head main body 12 (the boundary between the face surface 14A and the crown surface 16A) corresponding to the first boundary point K1 is slightly reduced. .

In the test example 44, the flange angle θ1 is 15 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL is visible, and the definition of claim 1 is satisfied. ing.
Therefore, the initial velocity 108, the directionality 108, the flight distance 107, and the durability 100 are a total of 423, and the evaluation of the initial velocity, the directionality, and the flight distance exceeds that of the experimental example 41.

In the experimental example 45, the flange angle θ1 is 50 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° of the definition of claim 1, the ridge line RL is visible, and the definition of claim 1 is satisfied. ing.
Therefore, the initial velocity 105, the directionality 108, the flight distance 102, and the durability 106 are all 421, and all the evaluations exceed the experimental example 41.

In the experimental example 46, the flange angle θ1 is 10 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° in the definition of claim 1, the ridge line RL exists, but the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 102, the directivity 102, the flight distance 101, and the durability 100 are a total of 405, although the evaluation of the initial velocity, directionality and flight distance is improved compared to Experimental Example 41, the evaluation of the initial velocity and flight distance is an experiment. Low compared to Examples 44 and 45.
This is disadvantageous in securing deformation of the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting the ball, although the inflection point H (ridge line RL) exists but the flange angle θ1 is small. It is for.

In the experimental example 47, the flange angle θ1 is 55 °, and within the range of 15 ° ≦ θ1 ≦ 50 ° in the definition of claim 1, the ridge line RL exists, but the definition of claim 1 is not satisfied. It is a thing.
Therefore, although the initial velocity 101, directionality 102, flight distance 101, durability 89, and a total of 393, the evaluation of initial velocity, directionality and flight distance is improved compared to Experimental Example 41, but evaluation of initial velocity and flight distance is experiment Compared with Examples 44 and 45, the durability is lower than that of Example 41.
This is because if the flange angle θ1 is larger than 50 °, the strength of the portion of the head main body 12 corresponding to the first boundary point K1 (the boundary between the face surface 14A and the crown surface 16A) decreases. This is because the effect of securing the durability is reduced. If the flange angle θ1 is larger than 50 °, the golfer tends to feel uncomfortable with the shape of the golf club head 10, making it difficult to swing and lowering the head speed, which is disadvantageous in securing the flight distance. It is.

Each evaluation item is discussed below.
(1) Initial Speed The experimental examples 44 and 45 satisfying the definition of claim 1 but not satisfying claims 2 to 4 have an initial speed of 108 and 105, and the initial speed is the best.
The experimental examples 42, 43, 46, 47 not satisfying all the requirements of claims 1 to 4 have an initial speed of 101 to 102.
Therefore, the one satisfying the definition of claim 1 is excellent in the effect of improving the initial speed with respect to the one not satisfying the claim 1.

(2) Directionality Examples 44 and 45 satisfying the definition of claim 1 but not satisfying claims 2 to 4 have directionality of 108 and 108 and are most excellent in directionality.
Experimental examples 42, 43, 46, 47 which do not satisfy all of the definitions of claims 1 to 4 have a directivity of 95 to 102.
Therefore, those satisfying the requirements of claim 1 are excellent in the effect of improving the directionality with respect to those not satisfying claim 1.

(3) Flying Distance In the experimental examples 44 and 45 satisfying the requirements of claim 1 but not satisfying claims 2 to 4, the flying distances are 107 and 102, and the flight distance is most excellent.
Experimental examples 42, 43, 46, 47 not satisfying all of the definitions of claims 1 to 4 have a flight distance of 101 to 102.
Therefore, those that satisfy the definition of claim 1 are superior in the effect of improving the flight distance to those that do not satisfy claim 1.

(4) Durability Although the test examples 44 and 45 satisfying the requirements of claim 1 but not claims 2 to 4 have a durability of 100 and 106, the durability is the most excellent.
Experimental examples 42, 43, 46 and 47 not satisfying all of the definitions of claims 1 to 4 have a durability of 89 to 100.
Therefore, those that satisfy the requirements of claim 1 are more effective in improving the durability than those that do not satisfy claim 1.

(5) Total points The experimental examples 44 and 45 satisfying the definition of claim 1 but not satisfying claims 2 to 4 have a total point of 422 and 423, and the total point is the best.
Experimental examples 42, 43, 46, 47 not satisfying all of the definitions of claims 1 to 4 have a total score of 389 to 405.
Therefore, those that satisfy the requirements of claim 1 are excellent in the effect of improving the total score with respect to those that do not satisfy claim 1.

(Fairway Wood: Condition 2)
Next, an example of fairway wood experiment under the condition 2 will be described.
In addition, the number of the example of an experiment shown below is attached from the example 52 of experiment for convenience.
As shown in FIG. 24, in the experimental examples 52 to 68, experiments were conducted under condition 2, and the thickness of the crown portion 16 and the volume and weight of the head main body 12 are made constant, and the respective numerical values are changed.
That is, the volume of the head body 12 was 165 ± 2 cc, the weight was 215 ± 1 g, and the loft angle was 15 degrees in any of the experimental examples.
Further, in any of the experimental examples, the shape of the crown portion 16 is different as described in detail below, and the shapes other than the crown portion 16 are the same.
The material of the head body 12 is a SUS630 alloy, and the thickness of the face portion 14 is 2.4 ± 0.05 mm uniform thickness, and the other thicknesses including the crown portion 16 are 1.0 ± 0.1 mm uniform thickness.

Experimental Example 41 is the same as Experimental Example 41 of FIG.
Experimental examples 52, 53, 56, 57, 60, 63, 64, 67, 68 satisfy all of the definitions of claims 1 to 4.
Experimental Example 59 meets the requirements of claims 1, 2 and 4, but does not fulfill the requirement of claim 3.
Experimental Examples 61 and 62 satisfy the requirements of claims 1 and 2 but do not satisfy the requirements of claim 4.
The experimental examples 65 and 66 satisfy the definition of claims 1, 3 and 4 but do not satisfy the definition of claim 2.
Although the experimental examples 54 and 55 have the inflection point H and the ridge line RL, they do not satisfy the definition of claim 1.
Experimental Example 58, although having an inflection point H, does not satisfy the requirements of claims 1 and 2.

Experimental example 52 satisfies all the definitions of claims 1 to 4.
Therefore, the initial speed 120, the directionality 138, the flight distance 129, the durability 133, and the total point 520 are obtained, and all the evaluations are superior to the experimental example 51.

Experimental example 53 satisfies all the definitions of claims 1 to 4.
Therefore, the initial velocity 122, the directivity 134, the flight distance 135, the durability 126, and the total point 517 are obtained. As compared with Experimental Example 52, the durability is slightly reduced.

In the experimental example 54, the flange angle θ1 is 12 °, and within the definition of claim 1, it falls below the range of 15 ° ≦ θ1 ≦ 50 °.
Therefore, the initial velocity 100, the directionality 101, the flight distance 101, and the durability 119 are a total of 421, and the evaluation excluding the durability remains at the same level as the experimental example 41.
This is disadvantageous in securing deformation of the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting the ball, although the inflection point H (ridge line RL) exists but the flange angle θ1 is small. It is for.

In the experimental example 55, the flange angle θ1 is 54 °, which exceeds the range of 15 ° ≦ θ1 ≦ 50 ° in the definition of claim 1.
Therefore, the initial velocity 104, the directivity 102, the flight distance 100, the durability 97, and the total are 403, and although the initial velocity and the flight distance slightly exceed the experimental example 41, the directivity is similar to the experimental example 41, Sex is lower than Experimental Example 41.
This is because if the flange angle θ1 is larger than 50 °, the strength of the portion of the head main body 12 corresponding to the first boundary point K1 (the boundary between the face surface 14A and the crown surface 16A) decreases. This is because the effect of securing the durability is reduced. If the flange angle θ1 is larger than 50 °, the golfer tends to feel uncomfortable with the shape of the golf club head 10, making it difficult to swing and lowering the head speed, which is disadvantageous in securing the flight distance. It is.

Experimental example 56 satisfies all of the definitions of claims 1 to 4, the flange angle θ1 is 17 °, and within the definition of claim 1, it is in the vicinity of the lower limit value of the range of 15 ° ≦ θ1 ≦ 50 °. is there.
Therefore, the initial velocity 113, the directivity 122, the flight distance 118, and the durability 124 are 477 in total, and all the evaluations are superior to the experimental example 41.

Experimental example 57 satisfies all of the definitions of claims 1 to 4, the flange angle θ1 is 48 °, and within the definition of claim 1, it is in the vicinity of the upper limit value of the range of 15 ° ≦ θ1 ≦ 50 °. is there.
Therefore, the initial velocity 121, the directivity 115, the flight distance 132, and the durability 111 are a total of 479, and all the evaluations are superior to the experimental example 41.

Experimental example 58 satisfies claims 3 and 4, but the ridge line RL can not be visually recognized and does not satisfy the definition of claim 1. Further, the inflection point angle θ2 is 0.4 °, which is less than the range of 1 ° ≦ θ2 ≦ 15 ° in claim 2, and the ratio RA / RB of the curvature radius is 0.80, Item 2 exceeds the range of 0.04 ≦ ratio RA / RB ≦ 0.35.
Therefore, the initial velocity 101, the directivity 92, the flight distance 103, and the durability 124 are 420 in total, and the directivity is lower than that of the experimental example 41. This is because the ridge line RL is not visible, and when holding the face surface 14A of the golf club head 10 toward the target point, it becomes difficult to hold the ball, and variations in the direction of the hit balls increase.

Experimental example 59 satisfies claims 1, 2 and 4, but the length D1 of the ridge line RL is 18% of the head length HL and is less than the definition of 20% or more of claim 2. .
Therefore, although the initial velocity 103, the directivity 111, the flight distance 103, and the durability 123 are a total of 440, and all the evaluations are superior to the experimental example 41, the evaluation is lower compared to the experimental examples 52 and 53. It has become.
This is because, since the dimension D1 of the ridge line RL is less than 20% of the head length HL, the effect of concentration of stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting is reduced. The amount of deformation of the crown portion 16 closer to the face portion 14 is reduced, and the amount of deflection of the face portion 14 is reduced, so that the effect of improving the initial speed and the flight distance is reduced.

Experimental example 60 satisfies claims 1, 2, 3 and 4. In addition, the length D1 of the ridge line RL is 100% of the head length HL, and the definition of 20% or more of claim 3 is satisfied.
Therefore, the initial velocity 122, the directionality 135, the flight distance 134, the durability 120, and a total of 511 are obtained. The durability is about the same as that of the experimental example 59, and the remaining evaluation is superior to the experimental example 59. .
This is because, since the dimension D1 of the ridge line RL is 100% of the head length HL, the effect of concentration of stress on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting is secured. The deformation amount of the crown portion 16 closer to the face portion 14 is secured, and the deflection amount of the face portion 14 is secured, so that the effect of improving the initial speed and the flight distance can be achieved. The evaluation of the directionality is better than that of Example 59 because the length D1 of the ridge line RL is long, so when holding the face surface 14A of the golf club head 10 toward the target point, it is easy to hold the ball. This is because the variation in direction is somewhat suppressed.
However, with respect to the durability, the amount of deformation is slightly larger than that of Example 52, and is reduced due to the large stress.

Experimental example 61 satisfies claims 1, 2 and 3, but the distance D2 from the first boundary point K1 to the inflection point H is 4.2% of the head width HW, and 5% of claim 4 It is below the range of 15% or less.
Therefore, although the initial velocity 110, the directivity 119, the flight distance 115, and the durability 104 are 448 in total, and all the evaluations are superior as compared to the experimental example 41, the directions are compared with the experimental examples 52 and 53. It has a slightly low rating.
This is because the distance D2 between the boundary line Lfc and the ridge line RL is too small with respect to the head width HW, that is, the ridge line RL is too close to the face portion 14, and the effect of making the golfer not feel uncomfortable is reduced. .
In addition, since the distance D2 between the boundary line Lfc and the ridge line RL is too small, stress is likely to be concentrated in the vicinity of the ridge line RL, and it is difficult to perform appropriate deformation, and the initial speed has a slightly lower value compared to Experimental Example 52. The durability is low.

Experimental example 62 satisfies claims 1, 2 and 3, but the distance D2 from the first boundary point K1 to the inflection point H is 16.8% of the head width HW, and 5% of claim 4 It is above the range of 15% or less.
Therefore, although the initial velocity 107, the directionality 115, the flight distance 111, and the durability 124 are 457 in total, all evaluations are superior compared to the experimental example 41, but the directions It has low reputation.
This is because the distance D2 between the boundary line Lfc and the ridge line RL is too large for the head width HW, that is, the ridge line RL is too far from the face portion 14, and the effect of making the golfer not feel uncomfortable is reduced. .
In addition, since the distance D2 between the boundary line Lfc and the ridge line RL is too large, the stress is hard to concentrate in the vicinity of the ridge line RL, and it is difficult to perform appropriate deformation. .

Experimental example 63 satisfies claims 1, 2, 3 and 4, the distance D2 from the first boundary point K1 to the inflection point H is 6% of the head width HW, and 5% or more of claim 4 It is a value near the lower limit in the range of 15% or less.
Therefore, the initial velocity 119, directionality 121, flight distance 119, durability 115, and a total of 474 are obtained, and all evaluations show that the distance D2 is less than the range of 5% to 15% of the head width HW. It is superior to.
This is because, since D2 is in the vicinity of the lower limit value in the appropriate range, appropriate stress is concentrated in the vicinity of the ridgeline RL, appropriate deformation is performed, and initial velocity, flight distance, durability, and directionality can be secured.

Experimental example 64 satisfies claims 1, 2, 3 and 4, the distance D2 from the first boundary point K1 to the inflection point H is 14% of the head width HW, and 5% or more of claim 4 It is a value near the upper limit in the range of 15% or less.
Therefore, the initial velocity 111, the directivity 119, the flight distance 115, and the durability 128 are all 473, and all the evaluations show that the distance D2 exceeds the range of 5% to 15% of the head width HW. It is superior to.
This is because, since D2 is in the vicinity of the upper limit value in the appropriate range, appropriate stress is concentrated in the vicinity of the ridge line RL, appropriate deformation is performed, and initial velocity, flight distance, durability, and directionality can be secured.

Experimental example 65 satisfies claims 1, 3 and 4, but the inflection point angle θ2 is 0.7 °, and it falls below the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2. ing. In addition, the ratio RA / RB of the curvature radius RA of the inflection point H to the curvature radius RB of the third intersection point P3 is 0.50, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 or less of claim 2. Exceeds.
Therefore, the initial velocity 108, the directivity 101, the flight distance 116, and the durability 119, totaling 444, the evaluation of the directivity remains the same as that of the experimental example 41.
This is because the effect of securing the visibility of the ridge line RL decreases, and the effect of suppressing the variation in the direction of the ball launched by the golf club head 10 decreases.

Experimental example 66 satisfies claims 1, 3 and 4, but the inflection point angle θ2 is 17 °, and exceeds the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2. . Further, the ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.03, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 or less of claim 2. Below.
Therefore, the initial velocity 110, the directionality 101, the flight distance 110, and the durability 105, which are a total of 426, the evaluation of the directionality remains equivalent to that of Example 41, and the remaining evaluation is superior to Example 41.
This is because the inflection point angle θ2 is larger than 15 °, and the elevation difference of the crown surface 16A is too large before and after the ridge line RL, so the effect of securing the ease of holding decreases and the golf club head 10 This is because the effect of suppressing the variation in the direction of the ball is reduced.
Further, in the experimental example 66, since the ratio RA / RB is less than 0.04, the stress applied to the inflection point H is easily concentrated, so that the effect of securing the durability of the golf club head 10 is obtained by the experimental examples 52, 53 It is lower than that.

Experimental example 67 satisfies claims 1, 2, 3 and 4, the inflection point angle θ2 is 1.2 °, and the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2 It is a value near the lower limit value. Further, the ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.14, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 in the second aspect. It is inside.
Therefore, the initial velocity 115, the directivity 128, the flight distance 121, and the durability 130 are all 494, and all the evaluations are superior to the experimental example 41, and the definition of the inflection point angle θ2 and the ratio RA / The evaluation of the directionality is particularly excellent as compared with Experimental Examples 65 and 66 which do not satisfy the definition of RB.

Experimental example 68 satisfies claims 1, 2, 3 and 4, the inflection point angle θ2 is 14.8 °, and the range of 1 ° ≦ inflection point angle θ2 ≦ 15 ° in claim 2 It is a value near the upper limit value. The ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.33, and the range of 0.04 ≦ ratio RA / RB ≦ 0.35 or less of claim 2. Of the upper limit value of.
Therefore, the initial velocity 116, the directionality 125, the flight distance 124, and the durability 130 are all 495, and all the evaluations are superior to those of the experimental example 41, and the definition of the inflection point angle θ2 and the ratio RA / The evaluation of the directionality is particularly excellent as compared with Experimental Examples 65 and 66 which do not satisfy the definition of RB.

Each evaluation item is discussed below.
(1) Initial Speed In Experimental Examples 52, 53, 56, 57, 60, 63, 64, 67, 68 satisfying all the requirements of Claims 1 to 4, the initial speed is 111 to 122, and the initial speed is most excellent.
The experimental example 59 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has an initial velocity of 103.
Examples 61 and 62 satisfying the requirements of claims 1 to 3 but not satisfying the requirement of claim 4 have initial velocities of 110 and 107, respectively.
Experimental examples 65 and 66 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have an initial velocity of 108.
Therefore, those that satisfy all the requirements of claims 1 to 4 have an excellent effect of improving the initial speed with respect to those that do not satisfy any one of claims 2, 3 and 4.

(2) Directionality Examples 52, 53, 56, 57, 60, 63, 64, 67, 68 satisfying all the requirements of claims 1 to 4 have directivity of 115 to 138, and the most excellent in directivity. ing.
Example 59 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has a directionality of 111.
Examples 61 and 62 satisfying the requirements of claims 1 to 3 but not fulfilling the requirements of claim 4 have directivity of 119 and 115.
Experimental examples 65 and 66 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have a directionality of 101.
Therefore, those that satisfy all the requirements of claims 1 to 4 have an excellent effect of improving the directionality to those that do not satisfy any one of claims 2, 3 and 4. .

(3) Flying distance The experimental examples 52, 53, 56, 57, 60, 63, 64, 67, 68 satisfying all the requirements of claims 1 to 4 have a flying distance of 115 to 135 and the best flight distance. ing.
In Example 59, the flight distance is 103, which satisfies the requirements of claims 1, 2 and 4, but does not satisfy the requirement of claim 3.
Examples 61 and 62 satisfying the requirements of claims 1 to 3 but not fulfilling the requirement of claim 4 have a flight distance of 115 and 111, respectively.
Experimental examples 65 and 66 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have a flight distance of 116 and 110.
Therefore, those that satisfy all the requirements of claims 1 to 4 have an excellent effect of improving the flight distance to those that do not satisfy any one of claims 2, 3 and 4. .

(4) Durability Experimental examples 52, 53, 56, 57, 60, 63, 64, 67, 68 satisfying all the requirements of claims 1 to 4 have a durability of 111 to 133 and the highest durability. ing.
Experimental example 59 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has a durability of 123.
Examples 61 and 62 satisfying the requirements of claims 1, 2 and 3 but not satisfying the requirement of claim 4 have a durability of 104 and 124.
Experimental examples 65 and 66 satisfying the requirements of claims 1, 3 and 4 but not satisfying the definition of claim 2 have a durability of 119 and 105.
Therefore, those satisfying all the requirements of claims 1 to 4 are excellent in the effect of improving the durability against those not satisfying any one of claims 2, 3 and 4. .

(5) Total points Experimental examples 52, 53, 56, 57, 60, 63, 64, 67, 68 satisfying all the requirements of claims 1 to 4 have a total point of 473 to 520 and the total point is the best. ing.
The experimental example 59 satisfying the requirements of claims 1, 2 and 4 but not satisfying the requirement of claim 3 has a total score of 440.
In Examples 61 and 62 satisfying the requirements of claims 1 to 3 but not fulfilling the requirement of claim 4, the total points are 448 and 457.
The experimental examples 65 and 66 satisfying the requirements of claims 1, 3 and 4 but not satisfying the requirement of claim 2 have a total score of 444 and 424.
Therefore, those which satisfy all the requirements of claims 1 to 4 are excellent in the effect of improving the total points with respect to those which do not satisfy any one of claims 2, 3 and 4. .

(Fairway Wood: Condition 3)
Next, an example of fairway wood experiment under the condition 3 will be described.
As shown in FIG. 25, experimental examples 69 to 72 were conducted under the above condition 3, and the volume of the head main body 12 is made the same as other numerical values, and the thickness of the crown portion 16 is changed. Therefore, the weight of the head body 12 changes within a certain range.
That is, the volume of the head body 12 was 165 ± 2 cc, the weight was 215 ± 2 g, and the loft angle was 15 degrees in any of the experimental examples.
Further, in any of the experimental examples, the shape and thickness of the crown portion 16 from the first boundary point K1 to the inflection point H and the shape and thickness of the crown portion 16 from the inflection point H to the fourth intersection point P4 are as follows: As will be described in detail, the shapes and thicknesses of the other portions of the crown portion 16 and portions other than the crown portion 16 have the same shape and the same value.
The material of the head body 12 is a SUS630 alloy, and the thickness of the face portion 14 is 2.4 mm ± 0.05 mm uniform thickness, and the thickness and deformation of the crown portion 16 from the first boundary point K1 to the inflection point H Except for the thickness of the crown portion 16 from the bending point H to the fourth intersection point P4, the uniform thickness of 1.0 mm ± 0.1 mm was used.
In addition, Experimental example 52 made into the comparative example in FIG. 25 is Experimental example 52 of FIG. 24, and the thickness of the crown part 16 is uniform at 1.0 mm.
In FIG. 25, each evaluation point of this experimental example 52 is set to 100, and based on the evaluation point of this experimental example 52, evaluation of experimental examples 69 to 72 is performed.
Further, the following numerical values and configurations are the same in Experimental Examples 52 and 69 to 72.
Flange angle θ1 = 30.0 °
There is a ridge line RL.
Edge length RL length D1 = 45.0%
Distance D2 from the first boundary point K1 to the inflection point H = 10.0%
Inflection point angle θ2 = 4.0 °
Radius of curvature ratio RA / RB = 0.20
Experimental Examples 69 to 71 satisfy all of the definitions of Claims 1-4 including the definition of the weighted average value of the thickness of the crown portion 16.
Moreover, Experimental example 72 does not satisfy | fill the prescription | regulation of the weighted average value of the thickness of the crown part 16 among the prescription | regulations of Claim 1-4.

In Experimental Example 69, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 1.1 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is satisfied in which the weighted average value Δd2 of the thickness is 0.7 mm, and the weighted average value Δd1> the weighted average value Δd2.
Therefore, the initial velocity 119, the directionality 112, the flight distance 125, and the durability 105 are a total of 461, and all the evaluations are superior to those of the experimental example 52.

In the experimental example 70, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 1.8 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is satisfied in which the weighted average value Δd2 of the thickness is 1.2 mm, and the weighted average value Δd1> the weighted average value Δd2.
Accordingly, the initial velocity 105, the directionality 107, the flight distance 109, and the durability 111 are a total of 432, the initial velocity and the flight distance are lower than those of Experimental Example 69, and the durability is improved compared to Experimental Example 69.
This is because the weighted average values Δd1 and Δd2 of the wall thickness are designed to be thicker than those of Example 69, so that the stress is concentrated on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting. However, the amount of deflection is slightly reduced, and the effect of improving the durability is ensured.

In the experimental example 71, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 0.8 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is satisfied in which the weighted average value Δd2 of the thickness is 0.5 mm, and the weighted average value Δd1> the weighted average value Δd2.
Therefore, the initial velocity 131, the directionality 103, the flight distance 130, and the durability 96 are a total of 460, and the initial velocity and the flight distance are improved as compared with the experimental example 69, and the durability is lowered.
This is because the weighted average values Δd1 and Δd2 of the wall thickness are designed to be thinner than those of Example 69, so that the stress is concentrated on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting However, the deflection amount is slightly increased, and the effect of improving the durability is reduced.

In Experimental Example 72, the weighted average value Δd1 of the thickness of the crown portion 16 from the first boundary point K1 to the inflection point H is 0.7 mm, and the crown portion 16 from the inflection point H to the fourth intersection point P4 is The definition of claim 1 is not satisfied that the weighted average value Δd2 of the thickness is 1.1 mm, and the weighted average value Δd1> the weighted average value Δd2.
Accordingly, the initial velocity 104, the directionality 104, the flight distance 103, and the durability 91 are a total of 402, and all the evaluations are reduced compared to the experimental examples 69 to 71.
Since this is not the weighted average value Δd1> the weighted average value Δd2, the stress is concentrated on the portion of the crown portion 16 including the inflection point H (ridge line RL) at the time of hitting a ball, and appropriate deflection can not be secured. In other words, this is because the deflection amount is excessive, and the effects of improving the initial speed and the durability decrease.

Each evaluation item is discussed below.
(1) Initial Speed In Experimental Examples 69 to 71 satisfying all the requirements of Claims 1 to 4, the initial speed is 105 to 131, and the initial speed is the best.
The experimental example 72 which does not satisfy the definition of claim 1 that the weighted average value Δd 1> the weighted average value Δd 2 among the definitions of claims 1 to 4 has an initial speed of 104.
Therefore, among those which satisfy all the requirements of claims 1 to 4, the effect of improving the initial speed is superior to those which do not satisfy the requirement of claim 1 of weighted average value Δd1> weighted average value Δd2. ing.

(2) Directionality Experimental examples 69 to 71 satisfying all of the definitions of claims 1 to 4 have a directionality of 103 to 112 and are most excellent in directionality.
Among the definitions of claims 1 to 4, the experimental example 72 which does not satisfy the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd 2 has a directivity of 104.
Therefore, the effect of improving the directionality is superior to those that do not satisfy the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2 that satisfies all the requirements of claims 1 to 4 There is.

(3) Flying Distance In Experimental Examples 69 to 71 satisfying all the requirements of Claims 1 to 4, the flying distance is 109 to 130 and the flying distance is most excellent.
In the experimental example 72 not satisfying the claim 1 that the weighted average value Δd1> the weighted average value Δd2 among the definitions of claims 1 to 4, the flight distance is 103.
Therefore, the effect of improving the flight distance is superior to those not satisfying the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2 is one that satisfies all the requirements of claims 1 to 4. There is.

(4) Durability Experimental examples 69 to 71 satisfying all the requirements of claims 1 to 4 have a durability of 96 to 111, and the durability is the most excellent.
Among the claims 1 to 4, the experimental example 72 not satisfying the definition of the claim 1 that the weighted average value Δd1> the weighted average value Δd 2 has a durability of 91.
Therefore, the effect of improving the durability is superior to those not satisfying the definition of claim 1 that the weighted average value Δd1> the weighted average value Δd2 is satisfied by all the requirements of claims 1 to 4. There is.

(5) Total points The experimental examples 69 to 71 satisfying all the requirements of claims 1 to 4 have a total point of 432 to 461, and the total point is the best.
The experimental example 72 not satisfying the definition of claim 1 in which the weighted average value Δd1> the weighted average value Δd2 has a total point of 402.
Therefore, the effect of improving the total score is superior to those not satisfying the definition of claim 1 in which the weighted average value Δd1> the weighted average value Δd2 is one satisfying all the requirements of claims 1 to 4. There is.

(Fairway Wood: Condition 4)
Next, an example of fairway wood experiment under the condition 4 will be described.
As shown in FIG. 26, the experimental examples 41, 52, 73A, 73B, 74A, 74B are experiments conducted under the above condition 3, and the thickness of the crown portion 16 and each numerical value are made the same, and the head body Change the volume of 12 Therefore, the weight of the head body 12 changes within a certain range. Also, the loft angle was 15 degrees.
The material of the head body 12 is a SUS630 alloy, the thickness of the face portion 14 is 2.4 ± 0.05 mm uniform thickness, and the other thickness including the crown portion 16 is 1.0 ± 0.1 mm uniform thickness .
Experimental examples 73A and 74A are comparative examples, and are configured in the same manner as the conventional art (Japanese Patent No. 5882522) in which the crown portion 16 is provided with a bulging portion as in the experimental example 41. It does not have the inflection point H and the ridgeline RL defined in the present invention, and therefore does not satisfy the definition of claim 1 of the present invention.
Further, Experimental Examples 73A and 74A are different only in volume, and the other shape and thickness are the same as those of Experimental Example 1.
That is, Experimental Examples 73A and 74A are comparative examples corresponding to Experimental Examples 73B and 74B, respectively, and each evaluation point is set to 100. (It means that even if the volume changes a little, it is the same evaluation)
Experimental Example 41 and Experimental Example 52 shown in FIG. 26 are the same as Experimental Examples 41 and 52 of FIG. 24 described above.
Further, the following numerical values and configurations are the same in Experimental Examples 52, 73B, and 74B.
Flange angle θ1 = 30.0 °
There is a ridge line RL.
Edge length RL length D1 = 45.0%
Distance D2 from the first boundary point K1 to the inflection point H = 10.0%
Inflection point angle θ2 = 4.0 °
Radius of curvature ratio RA / RB = 0.20
In addition, Experimental Examples 73B and 74B satisfy all the requirements of Claims 1-4.

Experimental Example 73B has a volume of 185 cc, an initial velocity 119, a directivity 141, a flight distance 131, a durability 133, and a total point 524.
Experimental Example 74B has a volume of 140 cc, an initial velocity 120, a directionality 140, a flight distance 129, a durability 132, and a total point 521.
Therefore, in the experimental examples 73B and 74B in which only the volume is changed, all evaluations are similar to those of the experimental example 52, and any ones satisfying the definition of claims 1 to 4 can be used similarly regardless of the volume. It is clear that the effects of

In addition, since the difference of a volume, a weight, and a shape does not change so much between a fairway wood and a utility, it thinks that the equivalent evaluation was made also about the utility by the experiment example of the fairway wood.
Further, it goes without saying that the present invention is applied to a golf club head having various hollow portions such as a driver having a hollow portion, a fairway wood having a hollow portion, and a utility having a hollow portion.
Furthermore, the present invention is applied to a golf club provided with such a golf club head 10.

100 golf club 10 golf club head 12 head main body 14 face portion 14A face surface 16 crown portion 16A crown surface 18 sole portion 20 side portion 22 toe 24 heel 26 face back 28 hollow portion HP horizontal surface Pc center point Pfc face center reference Section Pf Face reference section Pt First plane Ph Second plane P1 First intersection P2 Second intersection P3 Third intersection P4 Fourth intersection K1 First boundary point H Inflection point θ1 Flange angle θ2 Inflection point angle RA Inflection point Radius of curvature RB crown radius of curvature RL ridgeline Lfc boundary line HL head length HW head width

Claims (5)

A face portion having upper and lower heights and extending left and right, a crown portion extending rearward from the upper portion of the face portion with a smaller thickness than the face portion, and extending rearward from the lower portion of the face portion A head body including an existing sole portion, and a side portion extending between the crown portion and the sole portion between the toe side edge and the heel side edge of the face portion and extending through the face back; A golf club head in which the inside surrounded by the face portion, the crown portion, the sole portion and the side portion is a hollow portion,
In a reference state where the golf club head is installed at a lie angle and loft angle predetermined with respect to a horizontal plane, the head body is broken in a plane including a normal line passing through the center point of the face surface and orthogonal to the horizontal plane Cross section as the face center reference cross section,
A plane parallel to the face center reference cross section and separated by 10 mm in the toe direction from the face center reference cross section is taken as a first plane,
A plane parallel to the face center reference cross section and separated by 10 mm from the face center reference cross section in the heel direction is taken as a second plane,
A cross section obtained by breaking the head body at an arbitrary plane parallel to the face center reference cross section within the range from the first plane to the second plane is taken as a face reference cross section.
In the face reference cross section, a boundary point between the upper end of the face surface and the front end of the crown surface is taken as a first boundary point K1.
In the face reference cross-section, a straight line that is orthogonal to the horizontal plane, passing through a point parallel to the horizontal plane including the first boundary point K1 and separated from the first boundary point K1 by 5 mm in the faceback direction Let the intersection point of be the first intersection point P1,
When an angle formed by a straight line connecting the first boundary point K1 and the first intersection point P1 with respect to the horizontal plane is a flange angle θ1,
The flange angle θ1 is 15 ° or more and 50 ° or less,
In the face reference cross section, an inflection point H is formed at a position of the crown surface which is separated from the first intersection point P1 in the face back direction,
When the radius of curvature of the portion of the crown surface including the inflection point H in the face reference cross section is the radius of curvature of the inflection point H,
The radius of curvature of the inflection point H is a value smaller than the radius of curvature of the crown surface located between the first intersection point P1 and the inflection point H,
In the reference state, when the head main body is viewed in plan, the inflection point H continues in the toe heel direction, and a ridge line extending in the toe heel direction is visibly formed on the crown surface;
In the reference state, on the plane including the inflection point H and parallel to the horizontal plane in the face reference cross section, a straight line orthogonal to the horizontal plane passing a point 15 mm away from the inflection point H in the faceback direction Assuming that the intersection point with the crown surface is the fourth intersection point P4,
The weighted average value of the thickness of the crown portion weighted by the length along the face reference cross section of the crown portion from the first boundary point K1 to the inflection point H corresponds to the inflection point H from the inflection point H It is a value larger than the weighted average value of the thickness of the crown portion weighted by the length along the face reference cross section of the crown portion to the fourth intersection point P4,
In the reference state, on the plane including the inflection point H and parallel to the horizontal plane in the reference plane, a straight line perpendicular to the horizontal plane passing a point 5 mm away from the inflection point H in the faceback direction; Let an intersection with the crown surface be a second intersection P2,
When an angle formed by a straight line connecting the inflection point H and the second intersection point P2 and the horizontal plane is an inflection point angle θ2,
The inflection point angle θ2 is 1 ° or more and 15 ° or less,
In the face reference cross section, three measurement points are defined at intervals of 1 mm from the center point of the face surface toward the crown portion, and the curvature radius R of the arc passing through the three measurement points is measured and the curvature radius is measured The curvature radius R (R = R1, R2, R3,..., Rn-1, Rn, Rn + 1,...) Is repeated by repeating the operation while displacing the three measurement points by 1 mm toward the crown portion. Sequentially),
When the value obtained by dividing the measured radius of curvature Rn by the radius of curvature Rn-1 measured immediately before that becomes less than 0.3, the middle measurement point of the three measurement points is the face-side first As a regulation point,
A measurement point closer to the center point by 1 mm than the face-side first defined point is taken as a face-side second defined point,
A measurement point closer to the center point by 1 mm than the face-side second defined point is taken as a face-side third defined point,
A curved line extending toward the crown portion is an arc passing through the face-side first defined point, the face-side second defined point, and the face-side third defined point as a first defined line,
In the face reference cross section, three measurement points are defined at intervals of 1 mm from the crown portion to the face portion, and the curvature radius R of the arc passing through the three measurement points is measured. The radius of curvature R (R = R1, R2, R3,..., Rn-1, Rn, Rn + 1,...) Is sequentially sequentially by repeating the operation performed while displacing the measurement point toward the face portion by 1 mm. Measure
When the value obtained by dividing the measured radius of curvature Rn by the radius of curvature Rn-1 measured immediately before that is less than 0.4, the middle measurement point of the three measurement points is crown side first As a regulation point,
A measurement point closer to the face back by 1 mm than the crown side first specified point is taken as a crown side second specified point,
A measurement point closer to the face back by 1 mm than the crown side second specified point is taken as a crown side third specified point,
When a curved line extending toward the face portion is an arc passing through the crown side first specified point, the crown side second specified point, and the crown side third specified point as a second specified line,
The first boundary point K1 is an intersection point of the first defined line and the second defined line.
A golf club head characterized by In the reference state, on the plane including the inflection point H and parallel to the horizontal plane in the face reference cross section, a straight line perpendicular to the horizontal plane passing a point 1 mm away from the inflection point H toward the face portion When an intersection point with the crown surface is a third intersection point P3,
The ratio RA / RB of the radius of curvature RA of the inflection point H to the radius of curvature RB of the third intersection point P3 is 0.04 or more and 0.35 or less.
The golf club head according to claim 1, characterized in that: In the reference state, when the head main body is viewed in plan, a boundary between the upper end of the face surface and the front end of the crown is formed by the appearance finish of the head, and the ridge line is the boundary Extend substantially parallel to
In the reference state, when the head main body is viewed from the front of the face surface, the distance from the heel side located 22.23 mm above the horizontal plane to the end closest to the toe side is the horizontal plane When the projected dimension is the head length HL in the toe heel direction,
In the reference state, when the head main body is viewed in plan, the ridgeline intersects the face center reference cross section, and the ridgeline size obtained by projecting the ridgeline on the horizontal plane is 20 of the head length HL. % Or more,
The golf club head according to claim 1 or 2, characterized in that: In the reference state, when a dimension obtained by projecting the distance from the leading edge of the head body to the rear end of the head body in the horizontal plane in the face reference cross section is the head width HW,
The distance from the first boundary point K1 to the inflection point H when projecting the first boundary point K1 and the inflection point H on the horizontal plane is 5% or more and 15% or less of the head width HW. is there,
The golf club head according to any one of claims 1 to 3, characterized in that:   A golf club having the golf club head according to any one of claims 1 to 4.

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