JP7174282B2 - golf club head - Google Patents

Description

The present invention relates to golf club heads.

Conventionally, techniques for lowering the center of gravity of a golf club head have been proposed for the purpose of improving the flight distance.
Patent Document 1 discloses a hollow golf club head in which a concave portion is formed in a crown portion, a constraining member that connects a portion of the concave portion closer to the face-back side to a sole portion, and a constraining member that is connected to the constraining member. A technique is disclosed for providing a cantilever member extending substantially the entire length in the front-to-rear direction.
According to this technique, while the center of gravity is lowered by the concave portion, the rigidity of the crown portion is strengthened by the restraint member and the cantilever member, thereby improving the hitting sound.
Further, in Patent Document 2, although it does not aim to lower the center of gravity, in order to improve hitting sound, a hollow golf club head has a plurality of ribs extending from the crown through the side to the sole. Techniques for providing are disclosed.

Japanese Patent No. 5378806 Japanese Patent No. 5260110

However, in the technique of Patent Document 1, since the cantilever member is provided over substantially the entire length of the concave portion of the crown portion in the front-to-rear direction connecting the face portion and the face-back, the center of gravity is raised, thereby reducing the effect of lowering the center of gravity. there is a disadvantage to
In addition, in the technique of Patent Document 2, although there is a certain effect in improving the hitting sound by increasing the rigidity of the golf club head with the ribs, since a plurality of ribs are provided in the crown portion, the above-cited As in Document 1, the center of gravity becomes high, so there is a disadvantage that the effect of lowering the center of gravity is reduced.
SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and an object of the present invention is to provide a golf club head that is advantageous in achieving both a lower center of gravity and an improved hitting sound.

To achieve the above object, one embodiment of the present invention provides a golf club head having a crown portion and a sole portion and having a hollow interior, wherein the crown portion has an upwardly convex curved surface. and a low region connected to the high region and formed of a flat surface or a curved surface recessed downward, the lower region being lower than the high region, and connecting the face portion and the face back in the front-rear direction. The length of the high region in is formed with a dimension larger than the length of the low region, and in a reference state in which the golf club head is installed at a predetermined lie angle and loft angle with respect to a horizontal plane, the face surface When the face center reference cross section is a cross section obtained by cutting the golf club head along a plane including the normal line passing through the center of the face and perpendicular to the horizontal plane, the crown portion is cut along a first plane parallel to the face center reference cross section. In the resulting fracture surface, a boundary portion between the high-level region and the low-level region is positioned, and an inflection point is formed at the boundary portion, and the inflection point is 1 mm in the extending direction of the crown surface on the fracture surface. When a plurality of measurement points are set at an interval, the measurement points when the variation of the intersection angle θ at which the tangent lines passing through the adjacent measurement points intersect is 10° or more, and the measurement points are opposed to each other in the vertical direction. A rib is provided to connect the lower region and the sole portion.
Further, one embodiment of the present invention is a golf club head having a crown portion and a sole portion and having a hollow interior, wherein the crown portion is a high region formed with an upwardly convex curved surface. and a lower region connected to the higher region and formed of a flat surface or a curved surface recessed downward and having a lower height than the higher region, the higher region extending in the toe-heel direction near the face portion. and a second high region extending from an intermediate portion of the first high region in the toe-heel direction toward the face-back, wherein the low region extends from the side of the second high region on the toe side. A first low region extending in the toe direction and a second low region extending in the heel direction from a heel-side side portion of the second high region, wherein the golf club head is positioned with respect to a horizontal plane. A face center reference cross section is obtained by cutting the golf club head along a plane including a normal line passing through the center point of the face surface and orthogonal to the horizontal plane in a reference state in which the lie angle and loft angle are set in advance. When the crown portion is fractured on a first plane parallel to the face center reference cross section, and on a fracture surface obtained by fracture of the crown portion on a second plane perpendicular to the face center reference cross section and the horizontal plane. , a boundary portion between the high-level region and the low-level region is located, and an inflection point is formed in the boundary portion, and the inflection points are plural at intervals of 1 mm in the extending direction of the crown surface on the fracture surface. When setting the measurement point, the measurement point when the amount of change in the intersection angle θ at which the tangent lines passing through the adjacent measurement points intersect is 10 ° or more, and the lower regions facing each other in the vertical direction A rib is provided to connect the portion and the portion of the sole portion.

According to one embodiment of the present invention, the provision of the low region in the crown portion is advantageous in lowering the center of gravity of the golf club head. Since the amount can be reduced, it is advantageous in securing a large flight distance of the hit ball.
Furthermore, by connecting the low-level region and the sole portion with ribs, the rigidity of the low-level region can be increased, and the natural frequency of the vibration mode appearing in the low-level region can be increased. In spite of the provision of the .
Therefore, it is advantageous in achieving both a lower center of gravity and an improved hammering sound.

1 is a perspective view of a golf club head according to a first embodiment as seen from the face-back side; FIG. 1 is a front view of the golf club head according to the first embodiment as seen from the front of the face surface; FIG. FIG. 3 is a view in the direction of arrow A in FIG. 2; FIG. 3 is a view in the direction of arrow B in FIG. 2; FIG. 3 is a cross-sectional view of a face center reference cross section Pfc taken along a plane X in FIG. 2; (A) is an explanatory diagram showing the positional relationship between a rib joint portion and a boundary portion connecting a high level area and a low level area, and (B) is an explanatory diagram of an inflection point. FIG. 4 is a first explanatory diagram showing a method of defining a center point Pc of the face surface; FIG. 11 is a second explanatory diagram showing a method of defining the center point Pc of the face surface; FIG. 11 is a third explanatory diagram showing a method of defining the center point Pc of the face surface; FIG. 11 is a fourth explanatory diagram showing a method of defining the center point Pc of the face surface; FIG. 3 is a cross-sectional view of a 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. 1 is a front view of a golf club head explaining the definition of a contour line I of a face surface; FIG. 1 is a cross-sectional view of a golf club head explaining the definition of a contour line I of a face surface; FIG. 1 is a front view of a golf club head explaining the definition of a center point Pc of a face surface; FIG. FIG. 4 is a plan view of the golf club head showing the relationship between ribs and a first reference circle (second reference circle); (A) is an explanatory diagram showing the positional relationship between a rib joint portion and a boundary portion connecting a high level area and a low level area, and (B) is an explanatory diagram of an inflection point. FIG. 5 is a cross-sectional view of a face center reference cross-section Pfc of a golf club head showing a modified example of ribs. It is a perspective view of the golf club head of the second embodiment as seen from the face-back side. FIG. 10 is a plan view of a golf club head according to a second embodiment; (A) is a cross-sectional view taken along line XX of FIG. 19, and (B) is an explanatory diagram of an inflection point. FIG. 5 is a diagram showing evaluation results of an experimental example of the golf club head of the embodiment;

(First embodiment)
Next, an embodiment of the present invention will be described.
As shown in FIGS. 1 to 5, in this embodiment, a golf club head 10A is a hollow fairway wood and includes a head body 12. As shown in FIG.
The head body 12 is mainly made of a metal material.
As the metal material, for example, one or more of stainless steel, maraging steel, pure titanium, titanium alloy, aluminum alloy and the like are used.
The head body 12 has a face portion 14 , a crown portion 16 , a sole portion 18 and side portions 20 .
As shown in FIG. 5, the head body 12 has a hollow structure with a hollow portion 28 surrounded by the face portion 14, the crown portion 16, the sole portion 18, and the side portions 20. As shown in FIG.
The face portion 14 has vertical height and extends left and right.
The crown portion 16 has a thickness smaller than that of the face portion 14 and extends rearward from the upper portion of the face portion 14 .
For example, the thickness of the crown portion 16 is 0.4 mm-1.2 mm, the thickness of the face portion 14 is 1.8 mm-4.5 mm, and the thickness of the sole portion 18 is 0.5 mm-1.2 mm. 1.5 mm.
As shown in FIG. 5, the surface exposed to the outside of the face portion 14 is a face surface 14A for striking 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 the crown surface 16A, and the back surface of the crown portion 16 facing the hollow portion 28 is the crown back surface 16B.
As shown in FIG. 1, the crown portion 16 is provided with a hosel 30 connected to the shaft S at a position on the side of the face surface 14A and closer to the heel 24, and the shaft S is connected to the hosel 30, whereby the golf club 100 is configured.
As shown in FIG. 5, the sole portion 18 extends rearward from the lower portion of the face portion 14 .
The surface exposed to the outside of the sole portion 18 is the sole surface 18A, and the back surface of the sole portion 18 facing the hollow portion 28 is the sole back surface 18B.
As shown in FIGS. 2 and 3, the side portions 20 extend through the faceback 26 between the toe 22 and heel 24 side edges of the face portion 14 between the crown portion 16 and the sole portion 18. Therefore, the side portion 20 is where the crown portion 16 and the sole portion 18 are connected.
The surface exposed to the outside of the side portion 20 is the side surface 20A, and the back surface of the side portion 20 facing the hollow portion 28 is the side back surface 20B (FIG. 5).
In the figure, reference numeral 19 indicates a leading edge.

(Center point Pc of face surface 14A)
Next, a method for 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 conventionally known methods including the following first and second defining methods can be used to define the center point Pc. method can be adopted.

[A] A first method of defining the center point Pc of the face surface 14A:
This is a method of defining the center point Pc when the boundary between the face surface 14A and other parts of the golf club head 10A is clear, in other words, when the periphery of the face surface 14A is specified by a ridgeline. In this case, the face surface 14A is clearly defined. 7 to 10 are explanatory diagrams showing how to define the center point Pc of the face surface 14A.

(1) First, as shown in FIG. 7, the golf club head 10A is placed on the horizontal plane HP so that the lie angle and the face angle are at specified values. The state of the golf club head 10A at this time is taken as a reference state. The set values of the lie angle and the face angle are the values described in the product catalog, for example.

(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. 7, a perpendicular line f0 is drawn that intersects the approximate center point of a line parallel to the horizontal plane HP connecting the toe 22 and the heel 24 (hereinafter referred to as a horizontal line).
The middle point of point a0 where the perpendicular f0 intersects the upper edge of the face 14A and point b0 where the perpendicular f0 intersects the lower edge of the face 14A is assumed to be the temporary center point c0.

(3) Next, as shown in FIG. 8, draw a horizontal line g0 passing through the temporary center point c0.
(4) Next, as shown in FIG. 9, point d0 at which the horizontal line g0 intersects the edge of the face surface 14A on the toe 22 side, and 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 assumed to be a provisional center point c1.

(5) Next, as shown in FIG. 10, a perpendicular f1 passing through the temporary center point c1 is drawn. The midpoint of the point b1 at which .
Here, if the temporary center points c1 and c2 match, that point is defined as the center point Pc of the face surface 14A.
If the temporary center points c1 and c2 do not match, the steps (2) to (5) are repeated.
Since the face surface 14A has a curved surface, the length of the horizontal line g0 and the lengths of the perpendicular lines f0 and f1 when obtaining the midpoint of the horizontal line g0 and the midpoints of the vertical lines f0 and f1 are determined by the curved surface of the face surface 14A. shall be used.
A face centerline CL is defined by a straight line passing through the center point Pc and extending in a direction perpendicular to the toe-heel direction.

[B] Second method of defining center point Pc of face surface 14A:
Next, the definition of the center point Pc when the peripheral edge of the face surface 14A and other parts of the golf club head 10A are connected by a curved surface and the face surface 14A cannot be clearly defined will be described.

As shown in FIG. 11, the golf club head 10A is hollow, the symbol G0 indicates the center of gravity of the golf club head 10A, and the symbol 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 to 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 10A onto the face surface 14A is the center of gravity FG on the face surface.
Here, as shown in FIG. 12, consider a large number of planes H1, H2, H3, .

As shown in FIG. 13, the radius of curvature r0 of the outer surface of the golf club head 10A is measured in cross sections of the golf club head 10A taken along the planes H1, H2, H3, . . . , Hn.
When measuring the radius of curvature r0, it is assumed that there are no face lines, punch marks, etc. on the face surface 14A.
The curvature radius r0 is continuously measured from the center point Pc of the face surface 14A outward (upward and downward in FIG. 13).
Then, the portion where the radius of curvature r0 first becomes less than or equal to a predetermined value in the measurement is defined as the contour line I representing the periphery of the face surface 14A.
A predetermined value is, for example, 200 mm.
A region surrounded by contour lines I determined based on a number of planes H1, H2, H3, . . . , Hn is defined as face surface 14A, as shown in FIGS.

Next, as shown in FIG. 14, the golf club head 10A is placed on the horizontal ground (horizontal plane HP) so that the lie angle and the face angle are at specified values.
The straight line LT passes through the toe 22 side point PT of the face surface 14A and extends in the vertical direction.
The straight line LH passes through the heel 24 side point PH of the face surface 14A and extends in the vertical direction.
Straight line LC is parallel to straight lines LT and LH. The distance between straight lines LC and LT is equal to the distance between straight lines LC and LH.
Reference character Pu indicates an upper point of the face surface 14A, and reference character Pd indicates a lower point of the face surface 14A. Both the upper point Pu and the lower point Pd are intersections of the straight line LC and the contour line I.
The center point Pc is defined as the midpoint of a line segment connecting the upper point Pu and the lower point Pd.

Next, the definition of each part of the golf club head 10A will be described in detail.
As shown in FIGS. 2 and 3, it is assumed that the golf club head 10A is installed at a predetermined lie angle and loft angle with respect to the horizontal plane HP. Note that the reference state of the golf club head 10A is hereinafter simply referred to as the “reference state”.
As shown in FIGS. 2 and 5, in the reference state, a face center reference cross section Pfc is a cross section of the head body 12 taken along a plane X which includes a normal line passing through the center point Pc of the face surface 14A and which is orthogonal to the horizontal plane HP. do. In other words, the face center reference cross section Pfc is a cross section obtained by cutting the head body 12 along a plane X that includes the face center line CL and is orthogonal to the horizontal plane HP in the reference state.
A face reference cross section Pf is a cross section obtained by cutting the head body 12 along an arbitrary plane parallel to the face center reference cross section Pfc. Therefore, the face reference cross section Pf includes the face center reference cross section Pfc.

(higher area, lower area)
As shown in FIGS. 1, 3, 4, and 5, the crown portion 16 includes a high-level region 32 that is formed by a curved surface that is convex upward, and a flat surface that is connected to the high-level region 32 and a curved surface that is recessed downward. and a lower region 34 that is formed and has a lower height than the higher region 32 .
In the first embodiment, the high-level region 32 is connected to a first high-level region 32A positioned closer to the face portion 14 and a portion of the first high-level region 32A closer to the faceback 26, and the height increases toward the faceback 26. and a second higher region 32B where the
The low-level region 34 is connected to a portion of the second high-level region 32B near the faceback 26 and extends toward the faceback 26 .
Since the first and second high-level regions 32A and 32B are formed of upwardly convex curved surfaces, they have high rigidity.
On the other hand, since the low region 34 is composed of a flat surface or a curved surface that is depressed downward, the rigidity is low, and the vibration frequency at the time of hitting the ball tends to be low, which causes the frequency of the hitting sound to decrease. there is
In other words, since the crown of a typical golf club head is almost always composed of a single upwardly convex curved surface, the rigidity of the crown is high, and the frequency of the hitting sound is While a constant height is maintained, providing the low region 34 in the crown portion 16 as described above lowers the frequency of the hitting sound compared to the general golf club head 10A. .
Further, when the eigenvalue analysis of the head body 12 is performed, the low-level region 34 is composed of a flat surface or a curved surface that is depressed downward, and thus has low rigidity. Vibrational modes with the lowest (largest amplitude) natural frequencies tend to appear in the low region 34, which significantly affect the frequency of .

More specifically, in the standard state of the golf club head 10A, the crown portion 16 located behind the hosel 30 in the front-rear direction connecting the face portion 14 and the face back 26 has first and second high-level regions 32A and 32B. area 34.
The height of the low-level region 34 from the horizontal plane HP is smaller than the height of the first and second high-level regions 32A, 32B from the horizontal plane HP.
The crown portion 16 located behind the hosel 30 is, as shown in FIG. The portion of the crown portion 16 located on the face back 26 side from the passing third plane PL3.
As shown in FIG. 6A, in the first embodiment, when the crown portion 16 is broken in the first plane PL1 parallel to the face center reference cross section Pfc in the reference state, in the first embodiment, , a boundary portion 36 between the high region 32 and the low region 34 adjacent to each other on the crown face 16A is positioned at the fracture surface, and an inflection point Ph is formed at the boundary portion 36. As shown in FIG.
In other words, as shown in FIG. 6B, the high level area 32 (second high level area 32B) and the low level area 34 are connected by a boundary portion 36, and the boundary portion 36 includes an inflection point Ph. there is
Here, the inflection point Ph is defined.
As shown in FIG. 6(B), a plurality of measurement points P1, P2, P3, . set.
Draw a tangent T1...Tn to the crown surface 16A at each measurement point P1...Pn.
The intersection angle θ1 at which the tangent line T1 intersects with the adjacent tangent line T2, the intersection angle θ2 at which the tangent line T2 and the adjacent tangent line T3 intersect, and the intersection angle θ3 at which the tangent line T3 and the adjacent tangent line T4 intersect are used in this order. Angle θ is measured sequentially.
Then, the amount of change between a certain crossing angle θx1 and the next crossing angle θx2 is sequentially measured.
A measurement point Px (for example, P5) when the amount of change in the intersection angle θ is 10° or more is defined as an inflection point Ph.

(rib)
As shown in FIG. 5, a rib 38 is provided to connect the lower region 34 and the sole portion 18 that face each other in the vertical direction.
By providing such ribs 38, the rigidity of the low-level region 34 is increased, and the natural frequency of the vibration mode appearing in the low-level region 34 (among the multiple natural frequencies of the head body 12, the frequency of the hitting sound is significantly affected). The lowest (largest amplitude) natural frequency that gives ) can be changed to a higher frequency. .

Although the direction in which the ribs 38 extend is not limited, in the first embodiment, the ribs 38 extend in the front-rear direction connecting the face portion 14 and the faceback 26 as shown in FIG.
The rib 38 has a length along the extending direction, a height along the vertical direction connecting the crown portion 16 and the sole portion 18, and a thickness orthogonal to the length and height.
4 and 5, the rib 38 extends in a direction intersecting the extending direction of the boundary portion 36. are separated from the boundary 36 and are not joined to the boundary 36 .
Here, since the boundary portion 36 includes the inflection point Ph, the rigidity of the boundary portion 36 tends to locally decrease compared to other portions that do not include the inflection point Ph.
On the other hand, as shown in FIGS. 16A and 16B, when one end of the rib 38 in the extending direction is joined to the boundary portion 36, the inflection point Ph is included and the Since the rigidity of the boundary portion 36 can be increased, the rigidity of the low-level region 34 adjacent to the boundary portion 36 is also increased, which is more advantageous in increasing the natural frequency of the vibration mode appearing in the low-level region 34.

5 or 16A, the rib 38 joins the low region 34 and the sole portion 18, but the rib 38 is not joined to the side portion 20. As shown in FIG.
On the other hand, as shown in FIG. 17, the rib 38 is joined to the low region 34 and the sole portion 18, and further joined to the side portion 20 located between the low region 34 and the sole portion 18, The joint portion between the rib 38 and the low region 34, the joint portion between the rib 38 and the side portion 20, and the joint portion between the rib 38 and the sole portion 18 may be continuous.
In this way, the ribs 38 are joined not only to the low region 34 and the sole portion 18 but also to the side portions 20, which is more advantageous in increasing the rigidity of the low region 34 where the ribs 38 are joined. This is more advantageous in increasing the rigidity of the low-order region 34 and increasing the natural frequency of the vibration mode appearing in the low-order region 34 .
Further, as shown in FIG. 17, if the rib 38 is provided with a hole 40 penetrating in its thickness direction, the weight of the rib 38 can be reduced, which is advantageous in securing the degree of freedom in designing the golf club head 10A. Become.

Further, as shown in FIG. 4, in a reference state in which the golf club head 10A is installed at a predetermined lie angle and loft angle with respect to the horizontal plane HP, the low region 34 (crown When a circle having a radius of 10 mm centered on the normal to the surface 16A) is projected onto the lower region 34 along the normal, the first reference circle CA1 is defined as a rib when the golf club head 10A is viewed from above. At least part of the joint portion between 38 and low-level area 34 may be positioned inside the first reference circle CA1.
A portion having a large amplitude in the vibration mode appearing in the low level area 34 appears near the center of gravity GA where the rigidity is low in the low level area 34 .
Therefore, as shown in FIG. 4, if at least a portion of the joint portion between the rib 38 and the low-level region 34 is positioned inside the first reference circle CA1, at least the joint portion between the rib 38 and the low-level region 34 is The distance between the joint portion between the rib 38 and the low-level region 34 and the center of gravity GA of the low-level region 34 is shortened compared to the case where the portion is not located inside the first reference circle CA1.
Therefore, it is more advantageous in increasing the rigidity of the low-level region 34 to which the rib 38 is joined, and in increasing the natural frequency of the vibration mode appearing in the low-level region 34 .

Further, referring to FIG. 4, in a reference state in which the golf club head 10A is installed at a predetermined lie angle and loft angle with respect to the horizontal plane HP, the first reference circle CA1 is vertically aligned with the sole surface 18A. Assuming that the circle projected upward is a second reference circle CA2, at least a portion of the joint portion between the rib 38 and the sole portion 18 is located inside the second reference circle CA2 when the golf club head 10A is viewed from above. You may do so.
In this way, compared to the case where at least part of the joint portion between the rib 38 and the sole portion 18 is not positioned inside the second reference circle CA2, the joint portion between the rib 38 and the sole portion 18, The distance from the center of gravity GA of the low region 34 is shortened.
Therefore, in the standard state of the golf club head 10A, the rib 38 extends vertically along the normal line of the sole portion 18 (sole inner surface 18B) passing through the center of gravity GA of the low region 34. The angle between the extending direction and the sole portion 18 (sole inner surface 18B) approaches 90°, which is more advantageous for increasing the rigidity of the ribs 38 in the vertical direction and increasing the rigidity of the lower regions 34 to which the ribs 38 are joined, This is more advantageous in increasing the natural frequency of the vibration mode appearing in the low-order region 34 .

It should be noted that the weight of the rib 38 is preferably 5 g or less from the viewpoint of securing the degree of freedom in designing the golf club head 10A.

As described above, according to the present embodiment, the crown portion 16 is formed of a high-level region 32 that is formed by a curved surface that is convex upward, and a flat surface that is connected to the high-level region 32 or a curved surface that is recessed downward. A rib 38 is provided to connect the portion of the low region 34 and the portion of the sole portion 18 that face each other in the vertical direction.
Therefore, the provision of the low region 34 in the crown portion 16 is advantageous in lowering the center of gravity of the golf club head 10A. It is advantageous in securing a large flight distance of the hit ball.
Furthermore, by connecting the low-level region 34 and the sole portion 18 with the rib 38, the rigidity of the low-level region 34 can be increased, and the natural frequency of the vibration mode appearing in the low-level region 34 can be increased. Therefore, even though the low region 34 is provided, the hitting sound can be prevented from being lowered, and a pleasant hitting sound can be obtained, which is advantageous in increasing the commercial value of the golf club head 10A.
That is, it is advantageous in achieving both a lower center of gravity and an improved hammering sound.

(Second embodiment)
Next, a second embodiment will be described.
In the following embodiments, parts and members that are the same as those in the first embodiment are denoted by the same reference numerals, and descriptions thereof are simplified, and different parts are mainly described.

As shown in FIGS. 18-20, the golf club head 10B of the second embodiment differs from the first embodiment in the positional relationship between the high region 42 and the low region 44 included in the crown portion 16. .
That is, the high-level region 42 includes a first high-level region 42A located near the face portion 14, and a second high-level region 42B extending from the middle portion of the first high-level region 42A in the toe-heel direction toward the face back 26. ing.
The low regions 44 extend toward the faceback 26 from both sides of the first high region 42A except for the intermediate portion, and extend away from both sides of the second high region 42B in the toe-heel direction. ing.
Therefore, the low regions 44 are composed of a first low region 44A extending from the toe 22 side of the second high region 42B and a second low region 44A extending from the heel 24 side of the second high region 42B. 44B.
The first and second high-level regions 42A and 42B are both formed with curved surfaces that are convex upward.
The first and second low-level regions 44A, 44B are formed with curved surfaces that are recessed downward, and are lower in height than the first and second high-level regions 42A, 42B.
As in the first embodiment, the high level area 42 and the low level area 44 are connected at the boundary portion 36 .
In the second embodiment as well, the high level region 42 is formed with an upwardly convex curved surface and thus has high rigidity, whereas the low level region 44 is configured with a downwardly concave curved surface. Therefore, the rigidity is lower than that of the high-order region 42, and the vibration frequency at the time of hitting the ball tends to be low, which causes the frequency of the hitting sound to decrease.

More specifically, as shown in FIG. 19, in the standard state of the golf club head 10B, the crown portion 16 located behind the hosel 30 in the front-rear direction connecting the face portion 14 and the face back 26 has a high region 42 and a low region. area 44.
In the second embodiment, as in the first embodiment, as shown in FIG. 19, in the reference state, when the crown portion 16 is broken along the first plane PL1 parallel to the face center reference section Pfc, In the fracture surface, the first high level area 42A and the first and second low level areas 44A, 44B adjacent to each other on the crown surface 16A are positioned at the boundary portions 36, and inflection points Ph1, Ph2 are formed at the respective boundary portions 36. It is
Further, as shown in FIGS. 19 and 20A, when the crown portion 16 is broken in the reference state at a second plane PL2 orthogonal to the face center reference section Pfc and the horizontal plane HP, the crown surface 16A Boundaries 36 of the second high-level area 42B and the first and second low-level areas 44A, 44B, which are adjacent to each other above, are located, and inflection points Ph1, Ph2 are formed at the boundaries 36, respectively.
The boundary 36 between the first high-level region 42A and the first and second low-level regions 44A and 44B and the inflection points Ph1 and Ph2 are the boundary 36 between the second high-level region 42B and the first and second low-level regions 44A and 44B and They are continuous with the inflection points Ph1 and Ph2, respectively.
In other words, as shown in FIG. 20B, the high level area 42 and the low level area 44 are connected by a boundary portion 36, and the boundary portion 36 includes inflection points Ph1 and Ph2.
Here, the definition of the inflection point is the same as in the first embodiment. The inflection point Ph2 of the region 44B can be obtained by the same procedure as in the first embodiment.
Further, the inflection point Ph1 of the second high level area 42A and the first low level area 44A can be obtained by the following procedure.
That is, as shown in FIG. 20(B), a plurality of measurement points P1, P2, P3, P3, . . . Pn are set, tangent lines T1 . Let the measurement point Px (for example, P5) at this time be the inflection point Ph1.
The inflection point Ph2 of the second high level area 42B and the second low level area 44B can also be obtained by the same procedure as described above.

Also in the second embodiment, as shown in FIG. 19, ribs 46 are provided to connect the lower region 44 and the sole portion 18 that face each other in the vertical direction.
That is, a first rib 46A connecting a portion of the first low region 44A and a portion of the sole portion 18 that face each other in the vertical direction, and a portion of the second low region 44B and the portion of the sole portion 18 that face each other in the vertical direction. A second rib 46B is provided to connect the .

In the second embodiment, as in the first embodiment, since the boundary portion 36 includes the inflection points Ph1 and Ph2, the rigidity of the boundary portion 36 does not include the inflection points Ph1 and Ph2. It tends to decrease locally compared to the part of .
As in the first embodiment, the extending direction of the ribs 46 is not limited, but as shown in FIG. If one end in the extending direction is joined to the boundary portion 36, the rigidity of the boundary portion 36, which is reduced by including the inflection points Ph1 and Ph2, can be increased. The rigidity of the region 44 is also increased, which is more advantageous for increasing the natural frequency of the vibration mode appearing in the low-order region 44 .

Further, as in the first embodiment, the ribs 46 are joined to the respective low-level regions 44 and the sole portion 18, and are also joined to the side portions 20 located between the low-level regions 44 and the sole portion 18. Alternatively, the joint portion between the rib 46 and each low region 44, the joint portion between the rib 46 and the side portion 20, and the joint portion between the rib 46 and the sole portion 18 may be continuous.

Further, as shown in FIG. 19, in a standard state in which the golf club head 10B is installed at a predetermined lie angle and loft angle with respect to the horizontal plane HP, the radius When the first reference circle CA1 of 10 mm is drawn on each of the low regions 44, at least a part of the joints between the ribs 46 and the low regions 44 in a plan view of the golf club head 10B is aligned with the first reference circle CA1. It may be positioned inside the circle CA1.
In the example of FIG. 19, the rib 46 extends across the diameter of the first reference circle CA1.
A portion having a large amplitude in the vibration mode appearing in each low-level region 44 appears near the center of gravity GA where the rigidity is low in each low-level region 44 .
Therefore, if at least a portion of the junction between each rib 46 and each low-level region 44 is positioned inside the first reference circle CA1, at least a portion of the junction between each rib 46 and each low-level region 44 will be Since the distance between the joint portion between each rib 46 and the low-level area 34 and the center of gravity GA of each low-level area 44 is shortened compared to the case where it is not located inside the first reference circle CA1, each rib This is more advantageous in increasing the rigidity of each low-level region 44 to which 46 is joined, and is more advantageous in increasing the natural frequency of the vibration mode appearing in each low-level region 44 .

Further, referring to FIG. 19, in a reference state in which the golf club head 10B is installed at a predetermined lie angle and loft angle with respect to the horizontal plane HP, the center of gravity GA of each low region 44 is the center. A first reference circle CA1 having a radius of 10 mm is drawn on each low region 44, and a second reference circle CA2 is formed by projecting each first reference circle CA1 onto the sole surface. At least a portion of the joint portion between each rib 46 and each sole portion 18 may be positioned inside the second reference circle CA2.
In the example of FIG. 19, the rib 46 extends across the diameter of the second reference circle CA2.
In this way, compared to the case where at least a part of the joint portion between each rib 46 and each sole portion 18 is not located inside the second reference circle CA2, the connection between each rib 46 and each sole portion 18 can be reduced. The distance between the joint portion and the center of gravity GA of each lower region 44 is shortened.
Therefore, in the standard state of the golf club head 10B, each rib 46 extends vertically along the normal line of the sole portion 18 (sole inner surface 18B) passing through the center of gravity GA of each low region 44. The angle formed by the rib 46 and each sole portion 18 (sole inner surface 18B) approaches 90°, increasing the rigidity of each rib 46 in the vertical direction and increasing the rigidity of each lower region 44 to which each rib 46 is joined. This is advantageous, and it is more advantageous to increase the natural frequency of the vibration mode appearing in each low-level region 44 .

According to the second embodiment, similarly to the first embodiment, the provision of the low region 44 in the crown portion 16 is advantageous in lowering the center of gravity of the golf club head 10B, which is advantageous for the flight distance of the hit ball. Of course, the provision of the ribs 46 prevents a drop in the hitting sound despite the provision of the low region 44, and a comfortable hitting sound can be obtained. This is advantageous in increasing the commercial value of the club head 10B.

Note that the numbers of the high-level regions 42 and the low-level regions 44 are not limited to those in the embodiment.

Experimental examples of the present invention will be described below.
FIG. 21 is a diagram showing experimental results of a golf club head according to the present invention.
A sample golf club head was prepared for each experimental example, and the following two evaluation items were measured to obtain an index (evaluation score), and the total score of the two indexes was obtained.

(1) Rib Weight The rib weight W was evaluated by an index Prw represented by the following formula (1).
Prw=(1−(W/W0))×100+100 (1)
W: rib weight of experimental example W0: rib weight of comparative example index Prw.
Therefore, the higher the index Prw, the lighter the rib 46 and the higher the evaluation.

(2) Natural Frequency For the natural frequency, the lowest natural frequency (Hz) among the appearing vibration modes was obtained by performing the eigenvalue analysis on the finite element model of the golf club head.
Then, the natural frequency of the experimental example was evaluated with an index Pf where the natural frequency of the comparative example is 100.
Therefore, the higher the index Pf, the higher the frequency (natural frequency), the better the hammering sound, and the better the evaluation.

(3) Total Score The sum of the index Pwr of the rib weight and the index Pf of the eigenvalue frequency was taken as the total score.
The total score of the experimental example corresponding to the comparative example (experimental example 1) is set to 200, and the higher the total score, the better the evaluation.

Hereinafter, the golf club head of the experimental example will be described with reference to FIG. 21 .
21, whether or not the conditions specified in each claim are satisfied, that is, whether or not there are ribs 38 and 46, whether or not there is a joint portion within the first and second reference circles CA1 and CA2, and whether or not the boundary portion 36 has a joint portion. Regarding whether or not the joint portion is joined and whether or not the joint portion extends over the side portion 20, the case where the conditions are satisfied is indicated by the symbol ◯, and the case where the conditions are not satisfied is indicated by the symbol x.
Moreover, except for Reference Example 1, the golf club heads of the experimental examples were fairway woods.
Experimental example 1 does not satisfy the provisions of claims 1 to 5 of the present invention, and in the golf club head 10A of the first embodiment, the high region 32 and the low region 34 of claim 1 are provided. On the other hand, the rib 38 is omitted.
The specifications of each part of Experimental Example 1 are as follows.
Material of head body 12: Ti-6Al-4V
Material of face part 14: Ti-6Al-4V
Loft angle 15°
Lie angle 58°
Head volume 160cc
Experimental Example 9 does not satisfy the provisions of claims 1 to 5 of the present invention, and the golf club head 10B of the second embodiment is provided with the high region 42 and the low region 44 of claim 1. On the other hand, the rib 46 is omitted.

Experimental example 2-8 satisfies the definition of claim 1, and the first and second high-level regions 32A and 32B, the low-level region 34, and the low-level region 34 are similar to those shown in the first embodiment. It has one rib 38 provided.
Experimental example 10 satisfies the definition of claim 1, and similarly to the second embodiment, first and second high-level regions 42A, 42B and first and second low-level regions 44A, 44B are provided with first and second ribs 46A and 46B, respectively.
The specifications of each part of Experimental Example 2-10 are the same as those of Experimental Example 1. FIG.

Reference Example 1 is equivalent to the golf club head described in Patent Document 1, and is a hollow driver. and the sole portion 18, and a cantilever member connected to the restraining member and extending substantially over the entire length of the recess in the front-rear direction.
The index Pwr of the weight W of the rib in Reference Example 1 was calculated by taking the weight W of the rib as the weight of the restraining member and the cantilever member.
Since it is necessary to evaluate the index Pwr of the weight W of the ribs 38 and 46 in each experimental example, Reference Example 1 is used as a comparative example for convenience, and the indices Pwr and Pf are each set to 100, and the total is set to 200. An index for each experimental example was calculated for the example.
The specifications of each part of Reference Example 1 are as follows.
Material of head body 12: Ti-6Al-4V
Material of face part 14: Ti-6Al-4V
Loft angle 10.5°
Lie angle 59°
Head volume 460cc
In FIG. 21, reference example 1 is different from the structure defined in claims 1 to 5 of the present invention, so the description of each definition is omitted.

Experimental example 1 corresponds to the first embodiment and includes first and second high-level regions 32A, 32B and low-level region 34, but does not have rib 38, and is outside the scope of the present invention. .
Since the rib 38 is not provided, the index Prw of the rib weight W is not shown.
Since the rib 38 is not provided, the natural frequency index Pf remains at 73.

Experimental Example 2-8 corresponds to the first embodiment, has first and second high-level regions 32A and 32B, low-level regions 34 and ribs 38, and satisfies the definition of claim 1. FIG.
As shown in FIG. 21, the positional relationship between the first reference circle CA1, the second reference circle CA2, and the joint portion of the rib 38 satisfies the conditions of claims 2 and 3 (yes/no). In addition, the shortest distance ΔL1 from the normal line passing through the center of gravity GA to the joint portion between the ribs 38, 46 and the lower regions 34, 44, and the joint portion between the ribs 38, 46 and the sole portion 18 from the normal line passing through the center of gravity GA. The shortest distance ΔL2 to the point is described in units of mm.

In Experimental Example 2, the index Prw of the rib weight W is 160 and the weight of the rib 38 is reduced. The natural frequency exponent Pf remains at 82 because the 38 junctions are spaced apart.

Experimental example 3 satisfies the stipulations of claim 2 and the joint portion of the rib 38 is positioned within the first reference circle CA1, and the shortest distance ΔL1 is 8 mm. Since the joint portions of the ribs 38 are spaced apart, the natural frequency index Pf is 87, which is improved compared to Experimental Example 2.

Experimental example 4 satisfies the stipulations of claim 2 and the joint portion of the rib 38 is positioned within the first reference circle CA1, and the shortest distance ΔL1 is 0 mm. Since the joint portions of the ribs 38 are spaced apart, the natural frequency index Pf is 91, which is improved compared to Experimental Example 3.

Experimental example 5 satisfies the definition of claim 2, in which the joint portion of the rib 38 is positioned within the first reference circle CA1 and the shortest distance ΔL1 is 0 mm, and the definition of claim 2 is satisfied, and the rib lies within the second reference circle CA2. 38 are located and the shortest distance ΔL2 is 8 mm, the natural frequency index Pf is 100, which is improved compared to Experimental Example 4.

Experimental example 6 satisfies the definition of claim 2, in which the joint portion of the rib 38 is positioned within the first reference circle CA1 and the shortest distance ΔL1 is 0 mm, and the definition of claim 3 is satisfied, and the rib lies within the second reference circle CA2. 38 are positioned and the shortest distance ΔL2 is 0 mm, the natural frequency index Pf is 119, which is improved compared to Experimental Example 5.

In Experimental Example 7, in addition to satisfying the same conditions as Experimental Example 6, the joint portion of the rib 38 is joined to the boundary portion 36 in addition to satisfying the definition of Claim 4, so the natural frequency index Pf is 126. , is improved compared to Experimental Example 6.

In Experimental Example 8, in addition to satisfying the same conditions as Experimental Example 7, the ribs 38 were joined to the lower regions 34, the side portions 20, and the sole portion 18, and the joint portions were connected. Therefore, the exponent Pf of the natural frequency is 138, which is improved compared to Experimental Example 7.

Experimental Example 9 corresponds to the second embodiment and includes first and second high-level regions 42A, 42B and first and second low-level regions 44A, 44B, but does not have ribs 46, It is outside the scope of the present invention.
Since the rib 46 is not provided, the index Prw of the rib weight W is not shown.
Since the rib 46 is not provided, the natural frequency index Pf remains at 71.

Experimental Example 10 corresponds to the second embodiment, includes first and second high level regions 42A and 42B, first and second low level regions 44A and 44B, and ribs 46, and includes the provisions of claims 1-5. fulfill all.
The index Prw of the rib weight W is 161, and the weight of the rib 46 is reduced.
Also, the natural frequency index Pf is improved to 137 in order to satisfy the provisions of claims 1-5.

It goes without saying that the present invention can be applied to golf club heads having various hollow portions 28, such as a fairway wood having a hollow portion 28, a driver having a hollow portion 28, a utility having a hollow portion 28, and the like. is.

10A, 10B Golf club head 12 Head main body 14 Face portion 14A Face surface 14B Face back surface 16 Crown portion 16A Crown surface 16B Crown back surface 18 Sole portion 18A Sole surface 18B Sole back surface 20 Side portion 20A Side surface 20B Side back surface 19 Leading edge 22 Toe 24 heel 26 face back 28 hollow portion 30 hosel 32 high region 32A first high region 32B second high region 34 low region 36 boundary 38 rib 40 hole 42 high region 42A first high region 42B second high region 44 low region 44A First low level area 44B Second low level area 46 Rib 46A First rib 46B Second rib PL1 First plane PL2 Second plane PL3 Third plane CA1 First reference circle CA2 Second reference circle Pfc Face center reference section HP Horizontal plane Ph , Ph1, Ph2 Inflection point

Claims (6)

A golf club head having a crown portion and a sole portion and having a hollow interior,
The crown portion includes a high-level region formed with an upwardly convex curved surface, and a low-level region connected to the high-level region and formed with a flat surface or a downwardly recessed curved surface that is lower than the high-level region. ,
The length of the high region in the front-rear direction connecting the face portion and the face-back is larger than the length of the low region,
In a reference state in which the golf club head is installed at a predetermined lie angle and loft angle with respect to a horizontal plane, the golf club head is broken on a plane including a normal line passing through the center point of the face surface and perpendicular to the horizontal plane. When the face center reference cross section is the face center reference cross section, a boundary portion between the high region and the low region is located on a fracture surface obtained by cutting the crown portion on a first plane parallel to the face center reference cross section, and the boundary portion An inflection point is formed at
The inflection point is the amount of change in the intersection angle θ at which tangent lines passing through the adjacent measurement points intersect when a plurality of measurement points are set at intervals of 1 mm in the extending direction of the crown surface on the fracture surface. is the measurement point when 10° or more occurs,
A rib is provided that connects a portion of the lower region and a portion of the sole portion that are opposed to each other in the vertical direction,
A golf club head characterized by: A golf club head having a crown portion and a sole portion and having a hollow interior,
The crown portion includes a high-level region formed with an upwardly convex curved surface, and a low-level region connected to the high-level region and formed with a flat surface or a downwardly recessed curved surface that is lower than the high-level region. ,
The high-level region includes a first high-level region extending in the toe-heel direction near the face portion, and a second high-level region extending from an intermediate portion of the first high-level region in the toe-heel direction toward the face-back,
The low region includes a first low region extending in the toe direction from the toe side of the second high region, and a heel side of the second high region extending in the heel direction. a second lower region;
In a reference state in which the golf club head is installed at a predetermined lie angle and loft angle with respect to a horizontal plane, the golf club head is broken on a plane including a normal line passing through the center point of the face surface and perpendicular to the horizontal plane. When the cut cross section is a face center reference cross section, a fracture surface obtained by breaking the crown portion on a first plane parallel to the face center reference cross section and a second plane perpendicular to the face center reference cross section and the horizontal plane. A boundary portion between the high-level region and the low-level region is positioned on a fracture surface obtained by cutting the crown portion, and an inflection point is formed at the boundary portion,
The inflection point is the amount of change in the intersection angle θ at which tangent lines passing through the adjacent measurement points intersect when a plurality of measurement points are set at intervals of 1 mm in the extending direction of the crown surface on the fracture surface. is the measurement point when 10° or more occurs,
A rib is provided that connects a portion of the lower region and a portion of the sole portion that are opposed to each other in the vertical direction,
A golf club head characterized by: In a reference state in which the golf club head is installed at a predetermined lie angle and loft angle with respect to the horizontal plane, a circle with a radius of 10 mm centered on the normal line of the low region passing through the center of gravity of the low region is When a circle projected onto the low-level area along the normal line is set as the first reference circle,
At least a portion of a joint portion between the rib and the low region is located inside the first reference circle when the golf club head is viewed from above,
3. The golf club head according to claim 1 , wherein: In a reference state in which the golf club head is installed at a predetermined lie angle and loft angle with respect to the horizontal plane, a circle with a radius of 10 mm centered on the normal line of the low region passing through the center of gravity of the low region is When a circle projected onto the lower area along the normal line is defined as a first reference circle, and a circle obtained by projecting the first reference circle onto the sole surface in the vertical direction is defined as a second reference circle,
At least a portion of a joint portion between the rib and the sole portion is located inside the second reference circle when the golf club head is viewed from above,
3. The golf club head according to claim 1 , wherein: the high-level region and the low-level region are connected at a boundary;
The rib extends in a direction intersecting the extending direction of the boundary portion, and one end of the rib extending direction is joined to the boundary portion.
5. The golf club head according to any one of claims 1 to 4 , characterized in that: The golf club head has a side portion connecting the crown portion and the sole portion,
The rib is joined to the low region and the sole portion, and is also joined to the side portion located between the low region and the sole portion,
A joint portion between the rib and the low region, a joint portion between the rib and the side portion, and a joint portion between the rib and the sole portion are connected,
6. The golf club head according to any one of claims 1 to 5 , characterized in that:

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