The present application claims priority to Japanese Patent Application No. 2021-144880 filed on Sep. 6, 2021. The entire contents of this Japanese Patent Application are hereby incorporated by reference.
The present disclosure relates to a golf club head.
A golf club head in which a weight portion is provided on an inner surface of a sole portion with a view to lowering the center of gravity has been proposed. JP6645569B1 (US2020/0206586A1) discloses a hollow golf club head in which a weight portion extending along a leading edge is provided on an inner surface of a sole portion.
The inventors of the present disclosure have found that a new advantageous effect can be obtained by a novel structure relating to a weight portion provided on an inner surface of a sole portion.
The present disclosure provides a golf club head that includes a weight portion having a novel structure that exhibits a new advantageous effect.
In one aspect, a golf club head includes a face portion, a sole portion, and an internal weight portion that is provided on an inner surface of the sole portion and is located apart from the face portion. The internal weight portion includes a base portion, and a protruding portion that protrudes from the base portion toward a face side and that is located apart from the inner surface of the sole portion. The protruding portion is positioned on the face side with respect to a center of gravity of the head. A thickness of a toe-side part of the protruding portion and/or a thickness of a heel-side part of the protruding portion is greater than a thickness of a middle part of the protruding portion, or a middle position of the protruding portion in a toe-heel direction is absent.
Embodiments of the present disclosure will be described in detail below with reference to the drawings as necessary.
In the present disclosure, a reference state, a reference perpendicular plane, a toe-heel direction, a face-back direction, an up-down direction, and a face center are defined as follows.
The reference state is a state where a head is placed at a predetermined lie angle on a ground plane GP. As shown in
In the reference state, the orientation of a striking face is set so that a line normal to the striking face at the face center lies on a plane that is perpendicular to the reference perpendicular plane VP and is perpendicular to the ground plane GP. That is, in a planar view of the head as viewed from above, the line normal to the striking face at the face center is set to be perpendicular to the reference perpendicular plane VP.
In the present disclosure, the toe-heel direction is the direction of an intersection line NL between the reference perpendicular plane VP and the ground plane GP (see
In the present disclosure, the face-back direction is a direction that is perpendicular to the toe-heel direction and is parallel to the ground plane GP.
In the present disclosure, the up-down direction is a direction that is perpendicular to the toe-heel direction and is perpendicular to the face-back direction. In other words, the up-down direction in the present disclosure is a direction perpendicular to the ground plane GP.
In the present disclosure, the face center Fc is determined in the following manner. First, a point Pr is selected roughly at the center of a striking face in the up-down direction and the toe-heel direction. Next, a plane that passes through the point Pr, extends in the direction of a line normal to the striking face at the point Pr, and is parallel to the toe-heel direction is determined. An intersection line between this plane and the striking face is drawn, and a midpoint Px of this intersection line is determined. Next, a plane that passes through the midpoint Px, extends in the direction of a line normal to the striking face at the midpoint Px, and is parallel to the up-down direction is determined. An intersection line between this plane and the striking face is drawn, and a midpoint Py of this intersection line is determined. Next, a plane that passes through the midpoint Py, extends in the direction of a line normal to the striking face at the midpoint Py, and is parallel to the toe-heel direction is determined. An intersection line between this plane and the striking face is drawn, and a midpoint Px of this intersection line is newly determined. Next, a plane that passes through this newly-determined midpoint Px, extends in the direction of a line normal to the striking face at this midpoint Px, and is parallel to the up-down direction is determined. An intersection line between this plane and the striking face is drawn, and a midpoint Py of this intersection line is newly determined. By repeating the above-described steps, points Px and Py are sequentially determined. In the course of repeating these steps, when the distance between a newly-determined midpoint Py and a midpoint Py determined in the immediately preceding step first becomes less than or equal to 0.5 mm, the newly-determined midpoint Py (the midpoint Py determined last) is defined as the face center Fc.
The head 100 includes a face portion 104, a crown portion 106, a sole portion 108, and a hosel portion 110. The sole portion 108 includes an outer surface 108a and an inner surface 108b. The hosel portion 110 includes an exposed part 110a exposed to outside of the head 100, and an inner extending part 110b positioned inside the head 100. The hosel portion 110 also has a hosel hole 112. The hosel hole 112 has an opening at an upper end of the exposed part 110a, and continuously extends from the exposed part 110a to the inner extending part 110b. The face portion 104 includes a striking face 104a. The striking face 104a is the outer surface of the face portion 104. The head 100 may include a skirt portion (side portion) that extends between the crown portion 106 and the sole portion 108. The striking face is also simply referred to as a face.
The head 100 is a hollow head. The head 100 is a wood type head. The head 100 is a fairway wood type head. The head 100 may be a hybrid type head. The head 100 may be a driver head.
From the viewpoint of components, the head 100 includes a face member 100a and the body member 100b. The face member 100a is welded to the body member 100b. In the head 100 which has been subjected to finishing polishing and coating, a boundary between the face member 100a and the body member 100b is not visually recognized. In
In the cross-sectional views of
The face member 100a is made of a metal. Examples of the metal include stainless steel, maraging steel, a titanium alloy, an aluminum alloy, and a magnesium alloy. A part or an entirety of the face member 100a may be made of a non-metal material. For example, a part or the entirety of the face member 100a may be made of a carbon fiber reinforced resin.
The body member 100b is made of a metal. Examples of the metal include stainless steel, maraging steel, a titanium alloy, an aluminum alloy, and a magnesium alloy. A part or an entirety of the body member 100b may be made of a non-metal material. For example, a part or the entirety of the body member 100b may be made of a carbon fiber reinforced resin.
The head 100 includes an internal weight portion 120. The body member 100b includes the internal weight portion 120. The internal weight portion 120 is provided on the inner side of the sole portion 108. The internal weight portion 120 is provided on the inner surface 108b of the sole portion 108.
The internal weight portion 120 is integrated with the sole portion 108. The internal weight portion 120 is formed integrally with the sole portion 108. The internal weight portion 120 is integrated with the body member 100b. The entirety of the body member 100b including the internal weight portion 120 is integrally formed as a single-piece member. The method for forming the body member 100b is casting. The body member 100b is formed by lost-wax precision casting. The internal weight portion 120 may be a different member from the sole portion 108. The internal weight portion 120 may be formed separately from the body member 100b. The internal weight portion 120 may be formed independently and fixed to the sole portion 108. Examples of this fixing method include welding, press fitting, screwing, and bonding.
The internal weight portion 120 is positioned on the back side with respect to the face portion 104. The internal weight portion 120 is located apart from the face portion 104.
The internal weight portion 120 includes a base portion 122, and a protruding portion 124 that protrudes from the base portion 122 toward the face side. The base portion 122 protrudes upward from the inner surface 108b of the sole portion 108. The base portion 122 is integrated with the inner surface 108b.
The protruding portion 124 is positioned on the face side with respect to the head center of gravity CG (see
As shown in
The protruding portion 124 includes an upper surface 124a and a lower surface 124b. The protruding portion 124 also includes a front end face 124c. The front end face 124c is a face-side end face of the protruding portion 124. The front end face 124c extends from a front edge (face-side edge) of the upper surface 124a to a front edge (face-side edge) of the lower surface 124b. The front end face 124c does not have to be present. For example, when the protruding portion 124 has a pointed end, no front end face 124c is formed.
The upper surface 124a is inclined such that it goes upward as its proximity to the face portion 104 increases. The lower surface 124b is inclined such that it goes upward as its proximity to the face portion 104 increases. The upper surface 124a is parallel to the lower surface 124b. The upper surface 124a does not have to be parallel to the lower surface 124b.
The base portion 122 includes an upper surface 122a. The upper surface 122a is inclined such that it goes upward as its proximity to the face portion 104 increases. The upper surface 122a may be a flat surface, or may be a curved surface. In the present embodiment, the upper surface 122a is a single flat surface. The upper surface 122a extends until reaching the inner surface 108b of the sole portion 108, thereby terminating on the back side. The upper surface 122a is inclined such that it goes upward as its proximity to the protruding portion 124 increases. An entirety of the upper surface of the internal weight portion 120, including the upper surface 122a and the upper surface 124a, is inclined such that it goes upward as its proximity to the face portion 104 increases. In the internal weight portion 120, the upper surface 122a is flush with the upper surface 124a. The upper surface 122a and the upper surface 124a form a single flat surface. The upper surface 122a and the upper surface 124a do not have to be flush with each other.
As shown in
With reference to
A toe-side part of the protruding portion 124 (hereinafter, also referred to as a toe protruding part 124T) has a first thickness t1. A heel-side part of the protruding portion 124 (hereinafter, also referred to as a heel protruding part 124H) has a second thickness t2. A middle part of the protruding portion 124 (hereinafter, also referred to as a middle protruding part 124M) has a third thickness t3. The third thickness t3 is smaller than the first thickness t1 and/or the second thickness t2. In the present embodiment, the third thickness t3 is smaller than the first thickness t1, and smaller than the second thickness t2. In the present embodiment, the second thickness t2 is greater than the first thickness t1. The thicknesses t1, t2, and t3 can be measured in respective directions of lines normal to the upper surface 124a at measured positions.
In the present disclosure, the terms of “first thickness t1”, “second thickness t2”, and “third thickness t3” are used, but these thicknesses do not have to be different from one another. For example, the first thickness t1 may be equal to the third thickness t3. Note that in the middle part 120M, the protruding portion 124 does not have to be present, as described below.
The protruding portion 124 includes the toe protruding part 124T, the heel protruding part 124H, and the middle protruding part 124M. The toe protruding part 124T is a toe-side part of the protruding portion 124. The toe protruding part 124T is contained in the toe-side part 120T. The heel protruding part 124H is a heel-side part of the protruding portion 124. The heel protruding part 124H is contained in the heel-side part 120H. The middle protruding part 124M is a part positioned between the toe-side part and the heel-side part in the protruding portion 124. The middle protruding part 124M is contained in the middle part 120M. The toe protruding part 124T is positioned on the toe side of the middle protruding part 124M. The toe protruding part 124T is adjacent to the middle protruding part 124M. The heel protruding part 124H is positioned on the heel side of the middle protruding part 124M. The heel protruding part 124H is adjacent to the middle protruding part 124M. As described above, the middle protruding part 124M does not have to be present.
As well illustrated in
According to the different thicknesses of the protruding portion 124, the internal weight portion 120 can be divided into the toe-side part 120T, the heel-side part 120H, and the middle part 120M. In the present embodiment, a lower edge 126a of the toe-side step 126 can be a boundary between the toe-side part 120T and the middle part 120M. Similarly, a lower edge 128a of the heel-side step 128 can be a boundary between the heel-side part 120H and the middle part 120M. The step 126 and/or the step 128 does not have to be present.
The upper surface 124a of the middle protruding part 124M is positioned on the lower side with respect to the upper surface 124a of the toe protruding part 124T and/or the upper surface 124a of the heel protruding part 124H. In the present embodiment, the upper surface 124a of the middle protruding part 124M is positioned on the lower side with respect to the upper surface 124a of the toe protruding part 124T, and is positioned on the lower side with respect to the upper surface 124a of the heel protruding part 124H.
As shown in
As shown in
The average value of the fifth thickness t5 is greater than the average value of the sixth thickness t6. The average value of the fourth thickness t4 is greater than the average value of the sixth thickness t6. The average value of the fifth thickness t5 is greater than the average value of the fourth thickness t4. Each of these average values can be calculated from the volume and the surface area of the upper surface. For example, when the toe base part 122T has a volume of V1 and the upper surface 122a of the toe base part 122T has a surface area of S1, the average value of the fourth thickness t4 can be given as V1/S1. The volume of the heel base part 122H is greater than the volume of the toe base part 122T.
The average value of the thickness t5 is greater than the average value of the thickness t6, and the average value of the thickness t4 is greater than the average value of the thickness t6. The weight of the base portion 122 is largely allocated to the toe side and the heel side, which increases the lateral moment of inertia of the head 100. This can expand an area having a high rebound performance (hereinafter referred to as high rebound performance area). The average value of the thickness t5 is greater than the average value of the thickness t4. The weight of the base portion 122 is largely allocated to the heel side, which decreases a distance of the center of gravity (hereinafter also referred to as gravity center distance) of the head 100. This can improve ball catchability. The head 100 has a sweet spot SS positioned on the heel side with respect to the face center Fc.
The maximum value of the thickness t5 is greater than the maximum value of the thickness t6, and the maximum value of the thickness t4 is greater than the maximum value of the thickness t6. This increases the lateral moment of inertia of the head 100, and can expand the high rebound performance area. The maximum value of the thickness t5 is greater than the maximum value of the thickness t4. This decreases the gravity center distance of the head 100, and can improve the ball catchability.
A double-pointed arrow dl in
As shown in
On the lower surface 124b of the present embodiment, a first flat surface portion 130 that extends upward as it goes toward the toe side is formed in the toe protruding part 124T, a second flat surface portion 132 that is substantially parallel to the toe-heel direction is formed in the middle protruding part 124M, and a third flat surface portion 134 that extends upward as it goes toward the heel side is formed in the heel protruding part 124H. The lower surface 124b is constituted by such a plurality of flat surfaces, but is formed so as to extend along the inner surface 108b which is a curved surface.
A cross section taken along the toe-heel direction is specified at each position in the face-back direction. It is preferable that the lower surface 124b is formed so as to extend along the inner surface 108b at at least one position in the face-back direction. An example of this position is the center position CP described above. It is more preferable that the lower surface 124b is formed so as to extend along the inner surface 108b at every position in the face-back direction.
As shown in
The “excellent ball catchability” means that the face 104a is unlikely to be opened at impact with a ball (hereinafter, “at impact with a ball” is also simply referred to as “at impact”). When a head having excellent ball catchability is used, the face 104a is likely to be square or slightly closed at impact. When a head having excellent ball catchability is used, the energy of the head is efficiently transmitted to a ball, which can produce a strong trajectory of the hit ball and increase the flight distance. The gravity center distance means a distance between the shaft axis line and the head center of gravity.
By the heel protruding part 124H and the inner extending part 110b connecting with each other, vibration of the heel protruding part 124H is suppressed. This can suppress vibration of the protruding portion 124 even when the middle protruding part 124M is made thinner. The suppression of vibration improves the durability of the protruding portion 124 and the internal weight portion 120. In addition, the suppression of vibration can contribute to improvement of feel at impact. If vibration of the protruding portion 124 is transmitted to golfer's hands, the feel at impact can deteriorate. The feel at impact can be improved by suppressing this vibration.
As described above, in the present embodiment, the thickness t2 of the heel-side part of the protruding portion 124 (heel protruding part 124H) is greater than the thickness t1 of the toe-side part of the protruding portion 124 (toe protruding part 124T). This configuration can decrease the gravity center distance of the head 100. Decreasing the gravity center distance promotes the face rotation, whereby a head having excellent ball catchability can be obtained.
The heel protruding part 124H has a volume greater than that of the toe protruding part 124T. This configuration can decrease the gravity center distance of the head 100. By decreasing the gravity center distance, a head having excellent ball catchability can be obtained.
A point of contact on the face side between the internal weight portion 120 and the inner surface 108b of the sole portion 108 is defined as the first contact point P1. A vertex of an angular corner or a point having the smallest radius of curvature in the boundary portion on the face side between the internal weight portion 120 and the inner surface 108b can be the first contact point P1. When a part at which the radius of curvature is the smallest is not a point but an arc, an end point of the arc on the face side can be the first contact point P1. As shown in
A point of contact on the back side between the internal weight portion 120 and the inner surface 108b of the sole portion 108 is defined as a second contact point P2. A vertex of an angular corner or a point having the smallest radius of curvature in the boundary portion on the back side between the internal weight portion 120 and the inner surface 108b can be the second contact point P2. When a part at which the radius of curvature is the smallest is not a point but an arc, an end point of the arc on the back side can be the second contact point P2. As shown in
When the internal weight portion 120 is formed separately from the body member 100b, a boundary surface that separates the base portion 122 from the sole portion 108 can be present. In the present embodiment, the base portion 122 is integrated with the sole portion 108, and no boundary surface is present. In this case, a virtual boundary surface that separates the base portion 122 from the sole portion 108 can be defined. A vertical cross section can be set at any position in the toe-heel direction. On each vertical cross section, a line segment L2 that extends from the first contact point P1 to the second contact point P2 can be determined (see
A double-pointed arrow s1 in
The sole portion 108 includes a sole front part 108c that has a wall thickness greater than the wall thickness s1. The sole front part 108c is positioned on the face side with respect to the first contact point P1. In the present embodiment, the sole front part 108c is adjacent to the first contact point P1. Alternatively, the sole front part 108c may be located apart from the first contact point P1.
The sole front part 108c having a wall thickness greater than the wall thickness s1 extends from the first contact point P1 toward the face side, extending at least to reach the boundary k1. The length of the sole front part 108c in the face-back direction is not limited. The sole portion 108 includes a first thin part 108d.
The wall thickness s1 at the first contact point P1 is smaller than the wall thickness of the sole front part 108c, whereby the first thin part 108d is formed at the position of the first contact point P1. A part of the sole portion 108 positioned at the first contact point P1 is referred to as the first thin part 108d. The sole portion 108 includes the first thin part 108d thinner than the sole front part 108c at the position of the first contact point P1. Whether or not the first thin part 108d is formed is determined on a vertical cross section. The wall thickness s1 of the first thin part 108d can vary depending on the position in the toe-heel direction.
In the present embodiment, the first thin part 108d is the thinnest in a region extending from the first contact point P1 to the boundary k1. In the present embodiment, the first thin part 108d is the thinnest in a region extending from the first contact point P1 to a leading edge Le.
The sole portion 108 includes a thickness transition part 108e. The wall thickness of the thickness transition part 108e continuously decreases as its proximity to the first contact point P1 increases. The thickness transition part 108e has an upper surface 140. The upper surface 140 is a part of the inner surface 108b of the sole portion 108. The upper surface 140 is inclined such that it goes downward as its proximity to the first contact point P1 increases. In the embodiment shown in
In the present embodiment, the thickness transition part 108e is in contact with the first contact point P1. The thickness transition part 108e starts from the first contact point P1. The first contact point P1 and the thickness transition part 108e may be located apart from each other. For example, a part having a uniform wall thickness may be present between the first contact point P1 and the thickness transition part 108e. For example, a part having a wall thickness that increases toward the first contact point P1 may be present between the first contact point P1 and the thickness transition part 108e. A part having a wall thickness smaller than the wall thickness s1 may be present between the first contact point P1 and the thickness transition part 108e.
The thickness transition part 108e contributes to alleviation of stress concentration at the first thin part 108d. In addition, the thickness transition part 108e, having a thickness smaller than that at the point P3, contributes to a higher degree of deformation of the face portion 104 at impact. These are synergistic effects brought by the thickness transition part 108e and the first thin part 108d.
The thickness transition part 108e is provided in the vicinity of the first contact point P1. The above-described synergistic effects are enhanced by positioning the thickness transition part 108e in the vicinity of the first contact point P1. This “vicinity” can mean that the distance between the thickness transition part 108e and the first contact point P1 is less than or equal to 5 mm. This distance is measured in the face-back direction. A double-pointed arrow W1 in
A double-pointed arrow W2 in
With a view to alleviating the stress concentration at the first thin part 108d and obtaining a higher degree of deformation of the face portion 104, the width W2 is preferably greater than or equal to 0.6 mm, more preferably greater than or equal to 0.8 mm, and still more preferably greater than or equal to 1.0 mm. An excessively large width W2 leads to an excessively small angle of inclination of the upper surface 140, which can decrease the effect of alleviating the stress concentration. From this viewpoint, the width W2 is preferably less than or equal to 5 mm, more preferably less than or equal to 4 mm, and still more preferably less than or equal to 3 mm.
As shown in
On the vertical cross section passing through the head center of gravity CG, a back-side end of the internal weight portion 120 is positioned on the back side with respect to the head center of gravity CG (see
With reference to
With reference to the enlarged portion of
Also in the head 150, the upper surface 124a is inclined such that it goes upward as its proximity to the face portion 104 increases. The upper surface 124a, however, is not parallel to the lower surface 124b in the head 150. The upper surface 124a is inclined such that the thickness of the protruding portion 124 decreases toward the face portion 104. A tapered portion that has a thickness decreasing toward its tip end is formed in the protruding portion 124. This configuration makes it further easier to remove a mold when the sole portion 108 and the internal weight portion 120 are integrally formed as a single-piece member.
When the thickness of the protruding portion 124 varies, similar to the head 150, the first thickness t1, the second thickness t2, and the third thickness t3 can be considered as respective average values. Each of the average values can be calculated from the volume and the surface area of the upper surface. For example, when the toe protruding part 124T has a volume of Va and the upper surface 124a of the toe protruding part 124T has a surface area of Sa, the average value of the first thickness t1 can be given as Va/Sa.
A double-pointed arrow HA in
In the present embodiment, an entirety of the middle part 120M is present in the impact area HA. An entirety of the middle base part 122M is present in the impact area HA. An entirety of the middle protruding part 124M is present in the impact area HA.
With a view to expanding the high rebound performance area in the toe-heel direction, the first thin part 108d preferably extend from the toe side to the heel side to form a sideward extending part 108f. The first thin part 108d is preferably disposed over a region that occupies 80% or more of the impact area HA. That is, the sideward extending part 108f present in the impact area HA preferably has a length in the toe-heel direction of greater than or equal to 80% of the length of the impact area HA. This configuration can improve the rebound performance in a face region (a region on the face) having a high probability of striking balls.
With a view to improving the rebound performance in the impact area HA and improving the lateral moment of inertia, an entirety of the sideward extending part 108f is preferably provided in the impact area HA. With a view to improving the lateral moment of inertia, no first thin part 108d is preferably formed on the toe side and on the heel side with respect to the impact area HA. With a view to improving the lateral moment of inertia, no first thin part 108d is preferably formed on the toe side with respect to the sideward extending part 108f, and no first thin part 108d is preferably provided on the heel side with respect to the sideward extending part 108f. With a view to improving the lateral moment of inertia, the wall thickness s1 on the toe side with respect to the sideward extending part 108f is preferably greater than the wall thickness s1 in the sideward extending part 108f. With a view to improving the lateral moment of inertia, the wall thickness s1 on the heel side with respect to the sideward extending part 108f is preferably greater than the wall thickness s1 in the sideward extending part 108f.
The toe-side part 120T includes a part located on the toe side with respect to the position T20. The toe base part 122T includes a part located on the toe side with respect to the position T20. The toe protruding part 124T includes a part located on the toe side with respect to the position T20. The heel-side part 120H includes a part located on the heel side with respect to the position H20. The heel base part 122H includes a part located on the heel side with respect to the position H20. The heel protruding part 124H includes a part located on the heel side with respect to the position H20. These configurations contribute to improvement of the lateral moment of inertia.
The head 200 includes a face portion 204, a crown portion 206, a sole portion 208, and a hosel portion 210. The sole portion 208 includes an outer surface 208a and an inner surface 208b. The hosel portion 210 includes an exposed part 210a exposed to outside of the head 200, and an inner extending part 210b positioned inside the head 200. The hosel portion 210 also has a hosel hole 212. The face portion 204 includes a striking face 204a.
From the viewpoint of components, the head 200 includes a face member 200a and the body member 200b. The face member 200a is welded to the body member 200b. In
The head 200 includes an internal weight portion 220. The body member 200b includes the internal weight portion 220. The internal weight portion 220 is provided on the inner side of the sole portion 208. The internal weight portion 220 is provided on the inner surface 208b of the sole portion 208.
The internal weight portion 220 is integrated with the sole portion 208. The internal weight portion 220 is formed integrally with the sole portion 208. The internal weight portion 220 is integrated with the body member 200b. An entirety of the body member 200b including the internal weight portion 220 is integrally formed as a single-piece member.
The internal weight portion 220 includes a base portion 222, and a protruding portion 224 that protrudes from the base portion 222 toward the face side. The base portion 222 is integrated with the inner surface 208b of the sole portion 208.
The protruding portion 224 includes an upper surface 224a and a lower surface 224b. The protruding portion 224 also includes a front end face 224c. The upper surface 224a is inclined such that it goes upward as its proximity to the face portion 204 increases. The lower surface 224b is inclined such that it goes upward as its proximity to the face portion 204 increases.
The base portion 222 includes an upper surface 222a. The upper surface 222a is inclined such that it goes upward as its proximity to the face portion 204 increases.
With reference to
The protruding portion 224 includes a toe protruding part 224T and a heel protruding part 224H. As described above, no middle protruding part is present. In the present embodiment, of the internal weight portion 220, a part that does not include the protruding portion 224 is defined as the middle part 220M, a part located on the toe side with respect to the middle part 220M is defined as the toe-side part 220T, and a part located on the heel side with respect to the middle part 220M is defined as the heel-side part 220H.
As well illustrated in
The toe protruding part 224T has a first thickness t1. The heel protruding part 224H has a second thickness t2. The head 200 the same as the head 100 except that the middle part 220M of the internal weight portion 220 does not include a protruding portion.
The head 300 includes a face portion 304, a crown portion 306, a sole portion 308, and a hosel portion 310. The sole portion 308 includes an outer surface 308a and an inner surface 308b. The hosel portion 310 has a hosel hole 312. The face portion 304 includes a striking face 304a.
From the viewpoint of components, the head 300 includes a face member 300a and the body member 300b. The face member 300a is welded to the body member 300b. In
The head 300 includes an internal weight portion 320. The body member 300b includes the internal weight portion 320. The internal weight portion 320 is provided on the inner side of the sole portion 308. The internal weight portion 320 is provided on the inner surface 308b of the sole portion 308.
The internal weight portion 320 includes a base portion 322, and a protruding portion 324 that protrudes from the base portion 322 toward the face side. The base portion 322 is integrated with the inner surface 308b of the sole portion 308.
The protruding portion 324 includes an upper surface 324a and a lower surface 324b. The protruding portion 324 also includes a front end face 324c. The upper surface 324a is inclined such that it goes upward as its proximity to the face portion 304 increases. The lower surface 324b is inclined such that it goes upward as its proximity to the face portion 304 increases.
The base portion 322 includes an upper surface 322a. The upper surface 322a is inclined such that it goes upward as its proximity to the face portion 304 increases.
With reference to
As shown in
The head 400 includes a face portion 404, a crown portion 406, a sole portion 408, and a hosel portion 410. The sole portion 408 includes an outer surface 408a and an inner surface 408b. The hosel portion 410 has a hosel hole 412. The face portion 404 includes a striking face 404a.
From the viewpoint of components, the head 400 includes a face member 400a and the body member 400b. The face member 400a is welded to the body member 400b. In
The head 400 includes an internal weight portion 420. The body member 400b includes the internal weight portion 420. The internal weight portion 420 is provided on the inner side of the sole portion 408. The internal weight portion 420 is provided on the inner surface 408b of the sole portion 408.
The internal weight portion 420 includes a base portion 422, and a protruding portion 424 that protrudes from the base portion 422 toward the face side. The base portion 422 is integrated with the inner surface 408b of the sole portion 408.
The protruding portion 424 includes an upper surface 424a and a lower surface 424b. The protruding portion 424 also includes a front end face 424c. The upper surface 424a is inclined such that it goes upward as its proximity to the face portion 404 increases. In contrast, the lower surface 424b extends to be substantially parallel to the face-back direction. The term “substantially parallel” can mean that an angle of inclination with respect to the face-back direction is less than or equal to 10°.
The inner surface 408b of the sole portion 408 is substantially parallel to the lower surface 424b. The inner surface 408b and the lower surface 424b are opposed to each other such that no undercut is formed.
The base portion 422 includes an upper surface 422a. The upper surface 422a is inclined such that it goes upward as its proximity to the face portion 404 increases.
With reference to
As shown in
The second thickness t2 is greater than the third thickness t3. The first thickness t1 is greater than the third thickness t3. The second thickness t2 is greater than the first thickness t1. When each of the thickness t1, the thickness t2, and the thickness t3 varies, the thickness t1, the thickness t2, and the thickness t3 can be considered as respective average values.
The maximum value of the second thickness t2 is greater than the maximum value of the third thickness t3. The maximum value of the first thickness t1 is greater than the maximum value of the third thickness t3. The maximum value of the second thickness t2 is greater than the maximum value of the first thickness t1.
A double-pointed arrow dl in
As shown in
The first embodiment (head 100), the second embodiment (head 200), the third embodiment (head 300), and the fourth embodiment (head 400) described above can achieve the following advantageous effects. Note that when descriptions below are applicable to two or more of the embodiments and different reference symbols are used for a common portion (same kind of portion) in the embodiments, the reference symbols are omitted in the following descriptions.
In all the embodiments, the head (this head means the head 100, the head 200, the head 300 and the head 400 but a singular form, not plural form, is used for the sake of easy understanding) includes the internal weight portion disposed at a position located apart from the face portion. If the internal weight portion is disposed on the inner surface of the sole portion, the rigidity of the sole portion can be increased. However, the internal weight portion is disposed apart from the face portion, which can prevent the internal weight portion from increasing the rigidity of a region of the sole portion located near the face portion. For this reason, the region of the sole portion located near the face portion is easily bent at impact, which can improve the rebound performance. In addition, the presence of the internal weight portion lowers the position of the head center of gravity CG, which can improve the rebound performance in a shot at a lower hit point. The “lower hit point” means that a head strikes a ball at a hit point that is located in a lower region of its striking face. When a ball that is not teed up but placed directly on the ground is hit, the hit point tends to be a lower hit point. The improvement of rebound performance in a shot at a lower hit point is advantageous for striking a ball placed directly on the ground.
The protruding portion which extends toward the face side can allow the head center of gravity CG to be located at a front-side position (face-side position) of the head. This allows the sweet spot SS to be located at a lower position of the striking face, thereby improving the rebound performance in a shot at a lower hit point.
Note that the sweet spot SS means an intersection point at which a line that is normal to the striking face and passes through the head center of gravity CG intersects the striking face (see
In the head 100, the head 300, and the head 400, the thickness of the toe-side part of the protruding portion and/or the thickness of the heel-side part of the protruding portion are/is greater than the thickness of the middle part of the protruding portion. For this reason, the weight of the protruding portion is largely allocated to the toe side and/or the heel side, which can increase the lateral moment of inertia of the head. This can make it possible to expand the high rebound performance area on the face while improving the directional stability of hit balls. The “lateral moment of inertia” means a moment of inertia about an axis line that passes through the head center of gravity CG and extends in the up-down direction.
In the head 100 and the head 400, the thickness of the toe-side part of the protruding portion and the thickness of the heel-side part of the protruding portion are greater than the thickness of the middle part of the protruding portion. For this reason, the weight of the protruding portion is largely allocated to the toe side and the heel side, which can increase the lateral moment of inertia of the head.
In the head 200, the protruding portion 224 includes the toe-side part (toe protruding part 224T) and the heel-side part (heel protruding part 224H), but a middle part in the toe-heel direction of the protruding portion 224 is absent. In other words, the toe-side part 220T and the heel-side part 220H of the internal weight portion 220 include respective protruding parts, but the middle part 220M of the internal weight portion 220 does not include a protruding part. For this reason, the weight of the protruding portion is largely allocated to the toe side and the heel side, which can increase the lateral moment of inertia of the head. This can make it possible to expand the high rebound performance area on the face while improving the directional stability of hit balls. In addition, the middle part 220M still includes the middle part of the base portion (middle base part 222M), which can allow the internal weight portion 220 to have a greater weight.
In all the embodiments, the thickness of the toe-side part of the base portion and/or the thickness of the heel-side part of the base portion is greater than the thickness of the middle part of the base portion. The weight of the base portion is therefore largely allocated to the toe side and/or the heel side. The synergistic effect of the protruding portion and the base portion can make it possible to further increase the lateral moment of inertia of the head. This therefore can make it possible to further expand the high rebound performance area on the face while improving the directional stability of hit balls.
In the head 100, the head 300, and the head 400, the upper surface of the middle part of the protruding portion (the middle protruding part) is positioned on the lower side with respect to the upper surface of the toe-side part of the protruding portion (the toe protruding part) and/or the upper surface of the heel-side part of the protruding portion (the heel protruding part). In the head 100 and the head 400, the upper surface of the middle part of the protruding portion (the middle protruding part) is positioned on the lower side with respect to the upper surface of the toe-side part of the protruding portion (the toe protruding part) and the upper surface of the heel-side part of the protruding portion (the heel protruding part). This can lower the position of the head center of gravity. In addition, this shape of the upper surface of the protruding portion conforms to the shape of the sole portion that is curved so as to be lower in the middle in the cross section taken along the toe-heel direction, and is effective for lowering the position of the head center of gravity CG while allowing the protruding portion to be disposed on the inner side of the sole portion.
In all the embodiments, the upper surface of the middle part of the base portion (the middle base part) is positioned on the lower side with respect to the upper surface of the toe-side part of the base portion (the toe base part) and/or the upper surface of the heel-side part of the base portion (the heel base part). In the head 100, the head 200, and the head 400, the upper surface of the middle part of the base portion (the middle base part) is positioned on the lower side with respect to the upper surface of the toe-side part of the base portion (the toe base part) and the upper surface of the heel-side part of the base portion (the heel base part). This can lower the position of the head center of gravity. In addition, this shape of the upper surface of the base portion conforms to the shape of the sole portion that is curved so as to be lower in the middle in the cross section taken along the toe-heel direction, and is effective for lowering the position of the head center of gravity CG while allowing the base portion to be disposed on the inner side of the sole portion. The shape of the upper surface of the base portion, together with the shape of the upper surface of the protruding portion described above, can lower the position of the head center of gravity CG.
In all the embodiments, the lower surface of the protruding portion is formed so as to extend along the inner surface of the sole portion, as viewed in the cross section taken along the toe-heel direction (see
In all the embodiments, the protruding portion is positioned on the face side with respect to the head center of gravity CG. This can make it possible to locate the head center of gravity CG at a front-side position of the head, which can lower the position of the sweet spot SS. In addition, the protruding portion is located apart from the sole portion, which can make it possible to avoid an increase in the rigidity of a region of the sole portion located near the face.
In all the embodiments, the lower surface of the protruding portion and the inner surface of the sole portion are opposed to each other such that no undercut is formed (see
In the head 100, the head 200, and the head 300, the upper surface of the protruding portion extends in parallel to the lower surface of the protruding portion. This configuration is effective for allocating the weight of the protruding portion to the front side and the lower side, and is helpful in lowering the position of the sweet spot SS.
In the modification example shown in
A double-pointed arrow W3 in
With a view to locating the head center of gravity CG closer to the face and lowering the position of the sweet spot SS, the distance W3 is preferably less than or equal to 25 mm, more preferably less than or equal to 24 mm, and still more preferably less than or equal to 23 mm. With a view to obtaining a larger bending in a region of the sole portion near the face, the distance W3 is preferably greater than or equal to 10 mm, more preferably greater than or equal to 12 mm, and still more preferably greater than or equal to 14 mm.
As shown in
From the viewpoint of the rebound performance, the wall thickness s1 is preferably less than or equal to 1.2 mm, more preferably less than or equal to 1.1 mm, and still more preferably less than or equal to 1.0 mm. From the viewpoint of the strength of the sole portion, the wall thickness s1 is preferably greater than or equal to 0.5 mm, more preferably greater than or equal to 0.6 mm, and still more preferably greater than or equal to 0.7 mm.
A double-pointed arrow W4 in
With a view to lowering the position of the sweet spot SS, the gravity center depth W4 is preferably less than or equal to 15 mm, more preferably less than or equal to 14.5 mm, and still more preferably less than or equal to 14 mm. With a view to obtaining a larger bending in a region of the sole portion near the face, it is not preferable that the distance W3 is excessively small. From this viewpoint, the gravity center depth W4 is preferably greater than or equal to 11 mm, more preferably greater than or equal to 11.5 mm, and still more preferably greater than or equal to 12 mm.
A double-pointed arrow H1 in
With a view to lowering the position of the sweet spot SS, the height H1 is preferably less than or equal to 15 mm, more preferably less than or equal to 14.5 mm, and still more preferably less than or equal to 14 mm. Considering the length of the hosel portion 110 and the height of the head, the height H1 is preferably greater than or equal to 12 mm, more preferably greater than or equal to 12.5 mm, and still more preferably greater than or equal to 13 mm.
A double-pointed arrow H2 in
With a view to enhancing the rebound performance in striking a ball placed directly on the ground, the height H2 is preferably less than or equal to 23 mm, more preferably less than or equal to 22.5 mm, and still more preferably less than or equal to 22 mm. Considering the lower limit of the height H1 and the loft angle, the height H2 is preferably greater than or equal to 18.5 mm, more preferably greater than or equal to 19 mm, and still more preferably greater than or equal to 19.5 mm.
A reference symbol PL1 in
The head 100 is divided by the plane PL1 into a face-side part with respect to the plane PL1, and a back-side part the with respect to the plane PL1. With a view to locating the head center of gravity CG closer to the face, a ratio of the weight of the face-side part with respect to the plane PL1 to the weight of the entire head is preferably greater than or equal to 63%, more preferably greater than or equal to 64%, and still more preferably greater than or equal to 65%. Considering the width of the head in the face-back direction, this ratio is preferably less than or equal to 90%, more preferably less than or equal to 89%, and still more preferably less than or equal to 88%.
A fairway wood type head and a hybrid type head have a greater loft angle as compared with a driver head. In these heads, accordingly, a decrease in the gravity center depth W4 makes the sweet spot SS lower by a greater degree. In addition, these heads have many opportunities to strike a ball that is placed directly on the ground, not a ball that is teed up. Accordingly, the above-described effect of decreasing the height H2 of the sweet spot SS is particularly effective for the fairway wood type head and the hybrid type head. From this viewpoint, a fairway wood type head and a hybrid type head are preferred as the head.
As described above, as the loft angle is greater, a decrease in the gravity center depth W4 makes the sweet spot SS lower by a greater degree. From this viewpoint, the loft angle is preferably greater than or equal to 13°, more preferably greater than or equal to 15°, and still more preferably greater than or equal to 17°. Considering the specifications of a fairway wood type head and a hybrid type head, the loft angle is preferably less than or equal to 35°, more preferably less than or equal to 33°, and still more preferably less than or equal to 31°. This loft angle is a real loft angle.
From the viewpoint that a fairway wood type head and a hybrid type head are preferred, the head volume is preferably less than or equal to 300 cm3, more preferably less than or equal to 250 cm3, and still more preferably less than or equal to 200 cm3. From the same viewpoint, the head volume is preferably greater than or equal to 90 cm3, more preferably greater than or equal to 100 cm3, and still more preferably greater than or equal to 110 cm3.
As described above, in all the embodiments, the weight of the protruding portion is largely allocated to the toe side and/or the heel side, and this can increase the lateral moment of inertia of the head. From this viewpoint, the lateral moment of inertia of the head is preferably greater than or equal to 2000 g·cm2, more preferably greater than or equal to 2050 g·cm2, and still more preferably greater than or equal to 2100 g·cm2. Considering the head volume of a fairway wood type head and a hybrid type head, the lateral moment of inertia of the head is preferably less than or equal to 3000 g·cm2, more preferably less than or equal to 2950 g·cm2, and still more preferably less than or equal to 2900 g·cm2.
Regarding the above-described embodiments, the following clauses are disclosed.
[Clause 1]
A golf club head comprising:
The golf club head according to clause 1, wherein
The golf club head according to clause 2, wherein
The golf club head according to clause 2 or 3, wherein
The golf club head according to any one of clauses 1 to 4, wherein
The golf club head according to any one of clauses 1 to 5, wherein
The golf club head according to clause 6, wherein
The golf club head according to clause 7, wherein
The above descriptions are merely illustrative and various modifications can be made without departing from the principles of the present disclosure.
The terminology used in the description of the various described embodiments herein is for the purpose of describing particular embodiments only and is not intended to be limiting. The use of the terms “a”, “an”, “the”, and similar referents in the context of throughout this disclosure (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. As used throughout this disclosure, the word “may” is used in a permissive sense (i.e., meaning “having the potential to”), rather than the mandatory sense (i.e., meaning “must”). Similarly, as used throughout this disclosure, the terms “comprising”, “having”, “including”, and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted.
Number | Date | Country | Kind |
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2021-144880 | Sep 2021 | JP | national |
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Number | Date | Country | |
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20230074992 A1 | Mar 2023 | US |