The present application claims priorities on Japanese Patent Applications Nos. 2008-200499 filed on Aug. 4, 2008, 2008-290231 filed on Nov. 12, 2008, and 2008-327484 filed on Dec. 24, 2008. The whole contents of the Japanese Patent Applications are hereby incorporated by reference.
1. Field of the Invention
The present invention relates to a golf club head.
2. Description of the Related Art
An adherend such as a weight member, a vibration absorbing member and a batch is sometimes attached to a golf club head. An adhesive or a double-stick tape is usually used for the attachment. The double-stick tape has a front surface and a reverse surface which have adhesiveness. Generally, the double-stick tape is referred to as a double-sided tape in Japan.
Japanese Patent Publication No. 2792642 discloses a golf club head having a face and a thin plate stuck on the back surface of the face by a double-stick tape. The double-stick tape has a tape base material and adhesive layers provided on both surfaces thereof. Japanese patent publication No. 2792642 (U.S. Pat. No. 5,409,229) describes that the tape base material can be made of paper.
A head impacts with a golf ball at the time of hitting the ball. Vibration is generated in the head by the impact. The vibration may be undesirable for a golf player. Particularly, the vibration in missed hit is undesirable. The adherend can absorb the vibration generated in hitting the ball.
In a golf club head, an impact force caused by hitting is great. In a conventional golf club head, the destruction of the double-stick tape itself and the separation of a bonded surface may be generated by the vibration caused by hitting.
A double-stick tape having a resin form layer has been commercially-supplied. The resin form layer is a resin layer having bubbles. The double-stick tape having the resin form layer is considered to be applied to the golf club head. The resin form layer can be easily deformed. Good adhesion can be obtained by the resin form layer even when unevenness exists on the surface of an adherend or the surface of the adherend is a curved surface.
However, it has been found that when the double-stick tape having the resin form layer is applied to the golf club head, a problem may be caused. Repeated hitting is performed with the golf club head. The vibration caused by the impact of the hitting is great. It has been found that the resin form layer is not necessarily suitable in repeating hitting. It also has been found that the repeating hitting may cause the separation of the bonded surface in the double-stick tape having the resin form layer.
On the other hand, as the case of the double-stick tape which is free of the resin form layer, for example, there is a double-stick tape having adhesive layers provided on both surfaces of paper. In this case, when the double-stick tape is stuck on the outer surface of the adherend, wrinkles are apt to be generated. In the double-stick tape, adhesion failure is apt to occur.
The impact force at the time of hitting may act in various directions. The present inventor directed attention to a shearing force which may act on the double-stick tape at the time of hitting. When the adherend is horizontally displaced, the shearing force acts on the double-stick tape. For example, a case where the double-stick tape bonds a plane of the head body and a plane of the adherend is considered. Hereinafter, a direction parallel to the plane of the head body and the plane of the adherend is referred to as an in-plane direction. In this case, a situation in which the head body attempts to move to one side of the in-plane direction and the adherend attempts to move to the other side of the in-plane direction may take place. In such case, the shearing force may act on the double-stick tape. Shear stress is generated in the double-stick tape by the shearing force. The shearing force may generate the shear deformation of the double-stick tape. The resin form layer may be greatly deformed by the shearing force. When the resin form layer is used, the shear deformation is great. The shear deformation may generate a separation. It has been found that the adhesiveness of the head body and the adherend can be enhanced by suppressing the shear deformation.
It is an object of a first aspect of the present invention to provide a golf club head having an adherend bonded by a double-stick tape, the adherend being less easily detached.
A golf club head according to the first aspect includes a head body; a double-stick tape; and an adherend bonded to the head body by the double-stick tape. The double-stick tape includes a first adhesive layer provided as an innermost layer, a second adhesive layer provided as an outermost layer, and an intermediate layer provided between the first adhesive layer and the second adhesive layer. The intermediate layer includes a fiber layer and/or a resin layer. The resin layer is free of bubbles.
In the first aspect, preferably, the fiber layer is a nonwoven fabric layer.
In the first aspect, preferably, the head body and the adherend have a bonded surface bonded to the double-stick tape. Preferably, the head body or the adherend has a recessed part. Preferably, an inner surface of the recessed part and the bonded surface are adjacent to each other. Preferably, a space exists between the double-stick tape and the recessed part.
In the first aspect, preferably, the head body has a face surface and a back surface located on a back of the face surface. Preferably, the adherend is bonded to the back surface. Preferably, the adherend has a metal member and an elastic member. Preferably, the elastic member has a peripheral part directly or indirectly abutting on a side surface of the metal member.
In the first aspect, preferably, the intermediate layer consists of only a nonwoven fabric layer and a resin layer free of bubbles. Preferably, the double-stick tape has a five-layered structure obtained by laminating the first adhesive layer, the resin layer free of bubbles, the nonwoven fabric layer, the resin layer free of bubbles and the second adhesive layer in this order.
In the first aspect, preferably, the intermediate layer consists of only a nonwoven fabric layer.
In the first aspect, preferably, the intermediate layer consists of only the resin layer free of bubbles.
In the first aspect, preferably, a thickness of the double-stick tape is equal to or less than 0.5 mm.
During the bonding work, air may enter between the double-stick tape and the adherend. Similarly, during the bonding work, air may enter between the double-stick tape and the head body. The air forms bubbles, which reduce the bonding strength of the double-stick tape.
In the golf club head, an impact force caused by hitting is great. The impact force may cause the separation of the bonded surface. Strong bonding strength capable of enduring the impact force is required.
It is an object of a second aspect of the present invention to provide a golf club head in which an adherend bonded by a double-stick tape is less likely to be separated.
A golf club head of the second aspect includes a head body; a double-stick tape; and an adherend bonded to the head body by the double-stick tape. The head body and the adherend have a bonded surface bonded to the double-stick tape. The head body or the adherend has a recessed part. An inner surface of the recessed part and the bonded surface are adjacent to each other. A space exists between the double-stick tape and the recessed part.
In the second aspect, preferably, the bonded surface of the head body is a back surface of the head body. Preferably, the adherend has an approximately plate shape. Preferably, the recessed part is formed on the adherend. Preferably, an existence region of the adherend includes a back surface point of a sweet spot.
In the second aspect, preferably, the recessed part is formed on the adherend. Preferably, the double-stick tape has a first adhesive layer, a second adhesive layer, and an intermediate layer provided between the first adhesive layer and the second adhesive layer. Preferably, the intermediate layer includes a fiber layer.
In the second aspect, preferably the space is in a closed state.
The vibration absorbing effect can be enhanced by increasing the thickness of the adhesive or the double-stick tape. However, when the thickness is great, the movable amount of the adherend is great. When the movement of the adherend is great, a probability that the adherend is separated is increased.
It is an object of a third aspect of the present invention to provide a golf club head having an adherend less likely to be separated and having a high vibration absorbing effect.
A golf club head of the third aspect includes a head body; and an adherend bonded to the head body. The head body has a face surface and a back surface located on a back of the face surface. The adherend is bonded to the back surface. The adherend has a metal member and an elastic member. The elastic member has a peripheral part directly or indirectly abutting on a side surface of the metal member.
In the third aspect, preferably, the elastic member has an interposition part interposed between the metal member and the back surface of the head body.
In the third aspect, preferably, the elastic member has a back surface having a recessed part (E). Preferably, the metal member is disposed inside the recessed part (E). Preferably, a peripheral wall of the recessed part (E) is the peripheral part. Preferably, a bottom part of the recessed part (E) is the interposition part.
In the third aspect, preferably, the metal member has a front surface having a recessed part (M). Preferably, the interposition part of the elastic member extends inside the recessed part (M).
In the third aspect, preferably, the peripheral part of the elastic member extends further backward relative to the side surface of the metal member.
In the third aspect, preferably, the adherend is bonded to the head body by a double-stick tape. Preferably, a thickness of the double-stick tape is equal to or less than 0.4 mm.
In the third aspect, preferably, the adherend is bonded to the head body by a double-stick tape. Preferably, the double-stick tape has a first adhesive layer, a second adhesive layer, and an intermediate layer provided between the first adhesive layer and the second adhesive layer. Preferably, the intermediate layer includes a fiber layer.
In the head of the first aspect, the double-stick tape provided with the fiber layer and/or the resin layer free of bubbles has high durability to the shearing force. The detachment of the adherend caused by repeated hitting is less likely to occur due to the double-stick tape.
The head of the second aspect can release the bubbles generated on the bonded surface into the recessed part and thereby enhancing the bonding strength.
In the head of the third aspect, the adherend has the metal member and the elastic member, and the elastic member is disposed on the side surface of the metal member. The vibration absorbing effect is enhanced by the constitution. The adherend is less likely to be separated due to the constitution.
Hereinafter, the present invention will be described in detail according to the preferred embodiments with appropriate references to the accompanying drawings.
The double-stick tape t1 is interposed between the adherend s1x and the head body h1x. The adherend s1x is bonded to the head body h1x by the double-stick tape t1. The profile shape of the double-stick tape t1 and the profile shape of the adherend s1x are substantially equal.
The shape of the double-stick tape t1 is not limited. A width and a length of the double-stick tape t1 are not limited. The double-stick tape t1 is a sheet having both surfaces having adhesiveness.
The double-stick tape t1 is shown as a single layer in
The head body h1x has a face part 13x provided with a face surface 4x, a top surface 6x, a sole surface 8x, a back surface 10x and a hosel part 12x. The face part 13x has the face surface 4x as an outer surface. The face part 13x is solid. A recessed part 14x is formed on the back surface 10x. The recessed part 14x is formed on the reverse side of the face surface 4x. The head 2x having the recessed part 14x is generally referred to as a cavity back iron. The recessed part 14x forms a so-called cavity back. The face part is thinned by the recessed part 14x. A thin wall part (a first thin wall part) 18x is formed by the recessed part 14x. The thin wall part 18x is a part of the face part 13x. The thin wall part 18x is solid. The adherend s1x is stuck on the back surface of the thin wall part 18x. A front surface of the thin wall part 18x is the face surface 4x. The back surface of the thin wall part 18x is a bottom surface 20x of the recessed part 14x. A sweet spot of the head 2x is located in the thin wall part 18x. The sweet spot is a point of intersection between a line passing through the center of gravity of the head 2x and being perpendicular to the face surface 4x and the face surface 4x.
In light of the durability, the thickness of the thin wall part is preferably equal to or greater than 1.5 mm, and more preferably equal to or greater than 1.8 mm, and still more preferably equal to or greater than 2.0 mm. When the thin wall part is thin, the vibration of the face part at the time of hitting a ball is great. When the thin wall part is thin, a great impact force acts on a portion on which the double-stick tape is stuck. Therefore, in this case, the effect of the aspect may be actualized. From this viewpoint, the thickness of the thin wall part is preferably equal to or less than 3.0 mm, more preferably equal to or less than 2.7 mm, and still more preferably equal to or less than 2.4 mm.
Although illustration is omitted, an impact area marking (not shown) is formed on the face surface 4x. The impact area marking is typically a face line (face groove).
A recessed part 16x is further formed in the recessed part 14x. The recessed part (a second recessed part) 16x is formed on the bottom surface 20x of the recessed part (a first recessed part) 14x. The recessed part 16x is shallower than the recessed part 14x. A depth of the recessed part 16x is greater than the thickness of the double-stick tape t1. The recessed part 16x accommodates the whole of the double-stick tape t1. The profile shape of the recessed part 16x and the profile shape of the adherend s1x are substantially equal.
The face part is further thinned by the recessed part 16x. A second thin wall part 22x is formed by the recessed part 16x. The second thin wall part 22x is a part of the first thin wall part 18x. The second thin wall part 22x is solid. The adherend s1x is stuck on the back surface of the second thin wall part 22x. The sweet spot of the head 2x is located in the second thin wall part 22x. The front surface of the second thin wall part 22x is the face surface 4x. The back surface of the second thin wall part 22x is a bottom surface 24x of the recessed part 16x. The bottom surface 24x is a part of the bottom surface 20x.
The first adhesive layer 30 is bonded to the head body h1x. The second adhesive layer 36 is bonded to the adherend s1x. The adherend s1x is bonded to head body h1x by the double-stick tape t10.
The first layer 30 and the fourth layer 36 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 32 is a resin layer which is free of bubbles. The second layer 32 is an unfoamed resin film. The second layer 32 is not a resin form layer. The kind of a resin forming the second layer 32 is not limited. As a base material resin of the resin layer, an acrylic resin and a polyester resin are exemplified.
The resin layer is apt to be deformed by the existence of the bubbles. The deformation of the resin layer 32 (resin film layer 32) which is free of bubbles caused by the shearing force is less than that of the resin layer having bubbles. The shearing force which acts on the double-stick tape t1 is generated, for example, when a force in an arrow y1 direction acts on the adherend s1x and a force in an arrow y2 direction acts on the head body h1x (see
The third layer 34 is a fiber layer. Although not shown in the drawings, a empty space exists in the fiber layer. A part of the adhesive layer 36 adjacent to the third layer 34 enters the empty space. The entering suppresses the deformation of the double-stick tape t10 caused by the shearing force.
The fiber of the third layer 34 is a nonwoven fabric. That is, the third layer 34 is a nonwoven fabric layer. Although not shown in the drawings, a empty space exists in the nonwoven fabric. A part of the adhesive layer 36 adjacent to the third layer 34 enters the empty space. The entering suppresses the deformation of the double-stick tape t10 caused by the shearing force.
A empty space exists in the nonwoven fabric layer 34. A part of the resin layer 32 adjacent to the third layer 34 enters the empty space. The entering suppresses the deformation of the double-stick tape t10 caused by the shearing force.
A part of the adhesive layer 36 adjacent to the nonwoven fabric layer 34 enters the empty space of the nonwoven fabric layer 34. The entering enhances the strength of the double-stick tape t10 to the shearing force.
Unlike the embodiment, the second layer 32 may be the fiber layer, and the third layer 34 may be the resin layer which is free of bubbles. For example, the second layer 32 may be the nonwoven fabric layer, and the third layer 34 may be the resin layer which is free of bubbles.
The fiber layer 34 has excellent strength. The fiber layer 34 has reduced deformation caused by the shearing force. The fiber layer 34 can suppress the deformation of the double-stick tape t10 caused by the shearing force.
The fiber layer 34 functions as a support of the double-stick tape t10. When the double-stick tape t10 is stuck, wrinkles are less likely to be generated due to the fiber layer 34. The fiber layer 34 can facilitate the sticking work of the double-stick tape t1.
The fiber layer 34 can absorb shear stress. The fiber layer 34 can suppress the vibration caused by the shear stress. The fiber layer 34 can terminate the vibration caused by the shear stress in a short time. The effect of absorbing the shear stress can develop a vibration absorbing effect. The vibration absorbing effect can suppress the vibration transmitted to the adherend s1x. As a result, the separation of the adherend s1x can be suppressed.
The effect due to the fiber layer and the effect due to the resin layer which is free of bubbles can be simultaneously obtained by using the fiber layer 34 and the resin layer 32 which is free of bubbles together.
The nonwoven fabric layer 34 has excellent strength. The nonwoven fabric layer 34 has reduced deformation caused by the shearing force. The nonwoven fabric layer 34 can suppress the deformation of the double-stick tape t10 caused by the shearing force.
The nonwoven fabric layer 34 functions as the support of the double-stick tape t10. When the double-stick tape t10 is stuck, wrinkles are less likely to be generated due to the nonwoven fabric layer 34. The nonwoven fabric layer 34 can facilitate the sticking work of the double-stick tape t1.
The nonwoven fabric layer 34 can absorb shear stress. The nonwoven fabric layer 34 can suppress the vibration caused by the shear stress. The nonwoven fabric layer 34 can terminate the vibration caused by the shear stress in a short time. An effect of absorbing the shear stress can develop a vibration absorbing effect. The vibration absorbing effect can suppress the vibration transmitted to the adherend s1x. As a result, the separation of the adherend s1x can be suppressed.
The effect due to the nonwoven fabric layer and the effect due to the resin layer which is free of bubbles can be simultaneously obtained by using the nonwoven fabric layer 34 and the resin layer 32 which is free of bubbles together.
The five layers are a first layer 50, a second layer 52, a third layer 54, a fourth layer 56 and a fifth layer 58 in order from the side of the head body h1x. The first layer 50 is an innermost layer of the double-stick tape t11. The first layer 50 is an adhesive layer. The first layer 50 is a first adhesive layer. The second layer 52, the third layer 54 and the fourth layer 56 are intermediate layers. The fifth layer 58 is an adhesive layer. The fifth layer 58 is an outermost layer of the double-stick tape t11. The fifth layer 58 is a second adhesive layer. Although boundaries between the layers are flatly shown in
The first adhesive layer 50 is bonded to the head body h1x. The second adhesive layer 58 is bonded to the adherend s1x. The adherend s1x is bonded to the head body h1x by the double-stick tape t11.
The first layer 50 and the fifth layer 58 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 52 and the fourth layer 56 are resin layers which are free of bubbles. The second layer 52 and the fourth layer 56 are an unfoamed resin film. The second layer 52 and the fourth layer 56 are not a resin form layer. The kind of a resin forming the resin layer which is free of bubbles is not limited. As a base material resin of the resin layer, an acrylic resin and a polyester resin are exemplified.
The third layer 54 is a fiber layer. A empty space exists in the fiber layer. A part of the resin layer 52 adjacent to the third layer 54 enters the empty space. A part of the resin layer 56 adjacent to the third layer 54 enters the empty space. The entering enhances the strength of the double-stick tape t11 to the shearing force.
The fiber layer 54 has excellent strength. The fiber layer 54 has reduced deformation caused by the shearing force. The fiber layer 54 can suppress the deformation of the double-stick tape t11 caused by the shearing force.
The fiber layer 54 functions as a support of the double-stick tape t1. When the double-stick tape t11 is stuck, wrinkles are less likely to be generated due to the fiber layer 54. The fiber layer 54 can facilitate the sticking work of the double-stick tape t11.
The fiber layer 54 can absorb shear stress. The fiber layer 54 can suppress the vibration caused by the shear stress. The fiber layer 54 can terminate the vibration caused by the shear stress in a short time. An effect of absorbing the shear stress can develop a vibration absorbing effect.
The effect due to the fiber layer 54 and the effect due to the resin layer which is free of bubbles can be simultaneously obtained by using the fiber layer 54 and the resin layer which is free of bubbles together.
The fiber of the third layer 54 is a nonwoven fabric. That is, the third layer 54 is a nonwoven fabric layer. A empty space exists in the nonwoven fabric. A part of the resin layer 52 adjacent to the third layer 54 enters the empty space. A part of the resin layer 56 adjacent to the third layer 54 enters the empty space. The entering enhances the strength of the double-stick tape t11 to the shearing force.
The nonwoven fabric layer 54 has excellent strength. The nonwoven fabric layer 54 has reduced deformation caused by the shearing force. The nonwoven fabric layer 54 can suppress the deformation of the double-stick tape t11 caused by the shearing force.
The nonwoven fabric layer 54 functions as the support of the double-stick tape t11. When the double-stick tape t11 is stuck, wrinkles are less likely to be generated due to the nonwoven fabric layer 54. The nonwoven fabric layer 54 can facilitate the sticking work of the double-stick tape t11.
The nonwoven fabric layer 54 may absorb shear stress. The nonwoven fabric layer 54 can suppress the vibration caused by the shear stress. The nonwoven fabric layer 54 can terminate the vibration caused by the shear stress for a short time. An effect of absorbing the shear stress can develop a vibration absorbing effect.
The resin layer which is free of bubbles can suppress the deformation of the double-stick tape t11 caused by the shearing force. The resin layer which is free of bubbles has higher strength than that of the resin layer having bubbles. The resin layer which is free of bubbles can enhance the strength of the double-stick tape t11.
The effect due to the nonwoven fabric layer and the effect due to the resin layer which is free of bubbles can be simultaneously obtained by using the nonwoven fabric layer and the resin layer which is free of bubbles together.
The resin layer is interposed between the nonwoven fabric layer and the adhesive layer, and thereby the separation of the nonwoven fabric layer in the boundary surface can be effectively suppressed. In the double-stick tape t11, the resin layer 52 is disposed on one surface of the nonwoven fabric layer 54, and the resin layer 56 is disposed on the other surface of the nonwoven fabric layer 54. Since the resin layers are disposed on both the surface of the nonwoven fabric layer 54, the separation of the nonwoven fabric layer 54 in the boundary surface can be effectively suppressed.
The three layers are a first layer 70, a second layer 72 and a third layer 74 in order from the side of the head body h1x. The first layer 70 is an innermost layer of the double-stick tape t12. The first layer 70 is an adhesive layer. The first layer 70 is a first adhesive layer. The second layer 72 is an intermediate layer. The third layer 74 is an adhesive layer. The third layer 74 is an outermost layer of the double-stick tape t12. The third layer 74 is a second adhesive layer. Although boundaries between the layers are flatly shown in
The first adhesive layer 70 is bonded to the head body h1x. The second adhesive layer 74 is bonded to the adherend s1x. The adherend s1x is bonded to the head body h1x by the double-stick tape t12.
The first layer 70 and the third layer 74 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 72 is a resin layer which is free of bubbles. The second layer 72 is an unfoamed resin film. The second layer 72 is not a resin form layer. The kind of a resin forming the second layer 72 is not limited. As a base material resin of the resin layer, an acrylic resin and a polyester resin are exemplified.
The resin layer which is free of bubbles can suppress the deformation of the double-stick tape t12 caused by the shearing force. The resin layer which is free of bubbles has higher strength than that of the resin layer having bubbles. The resin layer which is free of bubbles can enhance the strength of the double-stick tape t12.
The three layers are a first layer 90, a second layer 92 and a third layer 94 in order from the side of the head body h1x. The first layer 90 is an innermost layer of the double-stick tape t13. The first layer 90 is an adhesive layer. The first layer 90 is a first adhesive layer. The second layer 92 is an intermediate layer. The third layer 94 is an adhesive layer. The third layer 94 is an outermost layer of the double-stick tape t13. The third layer 94 is a second adhesive layer. Although boundaries between the layers are flatly shown in
The first adhesive layer 90 is bonded to the head body h1x. The second adhesive layer 94 is bonded to the adherend s1x. The adherend s1x is bonded to the head body h1x by the double-stick tape t11.
The first layer 90 and the third layer 94 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 92 is a fiber layer. A empty space exists in the fiber layer. A part of the adhesive layer 90 adjacent to the second layer 92 enters the empty space. A part of the adhesive layer 94 adjacent to the second layer 92 enters the empty space. The entering enhances the strength of the double-stick tape t13 to the shearing force.
The fiber layer 92 has excellent strength. The fiber layer 92 has reduced deformation caused by the shearing force. The fiber layer 92 can suppress the deformation of the double-stick tape t13 caused by the shearing force.
The fiber layer 92 functions as a support of the double-stick tape t13. When the double-stick tape t13 is stuck, wrinkles are less likely to be generated due to the fiber layer 92. The fiber layer 92 can facilitate the sticking work of the double-stick tape t13.
The fiber layer 92 can absorb shear stress. The fiber layer 92 can suppress the vibration caused by the shear stress. The fiber layer 92 can terminate the vibration caused by the shear stress in a short time. An effect of absorbing the shear stress can develop a vibration absorbing effect. The double-stick tape t13 having the fiber layer 92 is less likely to be separated by repeated hitting.
The fiber of the second layer 92 is a nonwoven fabric. That is, the second layer 92 is a nonwoven fabric layer. A empty space exists in the nonwoven fabric. A part of the adhesive layer 90 adjacent to the second layer 92 enters the empty space. A part of the adhesive layer 94 adjacent to the second layer 92 enters the empty space. The entering enhances the strength of the double-stick tape t13 to the shearing force.
The nonwoven fabric layer 92 has excellent strength. The nonwoven fabric layer 92 has reduced deformation caused by the shearing force. The nonwoven fabric layer 92 can suppress the deformation of the double-stick tape t13 caused by the shearing force.
The nonwoven fabric layer 92 functions as a support of the double-stick tape t13. When the double-stick tape t13 is stuck, wrinkles are less likely to be generated due to the nonwoven fabric layer 92. The nonwoven fabric layer 92 can facilitate the sticking work of the double-stick tape t13.
The nonwoven fabric layer 92 can absorb shear stress. The nonwoven fabric layer 92 can suppress the vibration caused by the shear stress. The nonwoven fabric layer 92 can terminate the vibration caused by the shear stress for a short time. An effect of absorbing the shear stress can develop a vibration absorbing effect. The double-stick tape t13 having the nonwoven fabric layer 92 is less likely to be separated by repeated hitting.
A thickness of the double-stick tape t1 is shown by a double-pointed arrow A1 in
In light of enhancing the adhesiveness of the adhesive layer and the resin layer, the kind of the base material resin of the adhesive layer is preferably the same as that of the resin layer which is free of bubbles. For example, when the base material resin of the adhesive layer is the acrylic resin, the base material resin of the resin layer which is free of bubbles is also preferably the acrylic resin. The enhancement of the adhesiveness suppresses the separation in the boundary surface between the layers. The enhancement of the adhesiveness can suppress the shear deformation of the double-stick tape t1.
The adherend s1x is preferably disposed on the back side of the face surface. The double-stick tape t1 is preferably disposed between the back surface of the face part and the adherend s1x. A ball impacts the face part directly. When the ball is hit, a great impact force acts on the face part. Therefore, when the double-stick tape t1 is disposed on the back side of the face surface, the effect of the aspect is significantly exhibited.
In the embodiment of
The material of the adhesive layer is not limited. When the adherend s1x is attached to the outer surface of the head, the double-stick tape t1 may be protruded from the outer edge of the adherend s1x. The protruded double-stick tape t1 is exposed to the outside. The protruded double-stick tape t1 may be visually recognized. The protruded double-stick tape t1 is preferably inconspicuous. Considering the case where the double-stick tape t1 is exposed to the outside, it is preferable that the adhesive layer has transparency and weatherability. From this viewpoint, the material of the adhesive layer is preferably the acrylic adhesive compound.
The material of the resin layer which is free of bubbles is not limited. As described above, the double-stick tape t1 may be exposed to the outside. Considering the case where the double-stick tape t1 is exposed to the outside, it is preferable that the resin layer which is free of bubbles has transparency and weatherability. From this viewpoint, the base material resin of the resin layer which is free of bubbles is preferably the acrylic resin. The polyester resin is also preferable as the base material resin of the resin layer which is free of bubbles. The polyester resin has weatherability and strength.
The material of a fiber which constitutes the fiber layer is not limited. As the material of the fiber, a natural fiber, a synthetic fiber and a regenerated fiber are exemplified. As the synthetic fiber, vinylon, polyester, polypropylene, polyethylene and nylon are exemplified. As the natural fiber, pulp and hemp are exemplified. As the regenerated fiber, rayon is exemplified. In light of the weatherability and the strength, the synthetic fiber is preferable, and polyester and nylon are more preferable. The fiber layer may be a layer produced by weaving fibers, or may be the nonwoven fabric layer.
When the fiber layer is the nonwoven fabric layer, the material of the nonwoven fabric which constitutes the nonwoven fabric layer is not limited. As the material of the nonwoven fabric, a natural fiber, a synthetic fiber and a regenerated fiber are exemplified. As the synthetic fiber, vinylon, polyester, polypropylene, polyethylene and nylon are exemplified. As the natural fiber, pulp and hemp are exemplified. As the regenerated fiber, rayon is exemplified. In light of the weatherability and the strength, the synthetic fiber is preferable, and polyester and nylon are more preferable.
The specific examples of the double-stick tapes which may be used for the aspect include “Y-4625” (trade name), “VHX-802” (trade name), “Y-9448HK” (trade name), “4393” (trade name), “Y-9448HK” (trade name), “Y-9448HKB” (trade name) and “Y-9448SK” (trade name). All of them are produced by the Sumitomo 3M Limited.
A thickness between the face surface 4x and the double-stick tape t1 is shown by a double-pointed arrow d1x in
A contact area Sm1 of the double-stick tape t1 and the head is not limited. In light of actualizing the effect of the aspect, the contact area Sm1 is preferably equal to or greater than 900 mm2, more preferably equal to or greater than 1000 mm2, and still more preferably equal to or greater than 1100 mm2. When the weight of the adherend s1x is excessive, a weight which can be distributed to the head body is reduced, and the strength of the head body is reduced. From this viewpoint, the contact area Sm1 is preferably equal to or less than 1700 mm2, more preferably equal to or less than 1600 mm2, and still more preferably equal to or less than 1500 mm2.
The material of the adherend s1x is not limited. Examples of the materials of the adherend s1x include a metal, a resin and a viscoelastic material. The thickness of the adherend s1x is not limited. In light of enhancing hitting feeling while reducing the weight of the head, the thickness of the adherend s1x is preferably equal to or greater than 0.3 mm, more preferably equal to or greater than 0.5 mm, or preferably equal to or less than 2.0 mm, and more preferably equal to or less than 1.5 mm.
Usually, a golf player tries to hit the ball to the center of the face surface 4x. The ball is likely to be hit at the center of gravity of the area of the face surface 4x. When the double-stick tape t1 exists on the back surface of an hitting point, the impact shock transmitted to the double-stick tape t1 is great. In light of actualizing the effect of the aspect, it is preferable that the double-stick tape t1 exists on the back surface of the center of gravity of the area of the face surface 4x. That is, it is preferable that a straight line L1x passing through the center of gravity of the area of the face surface 4x and being perpendicular to the face surface 4x passes through the double-stick tape t1 and the adherend s1x.
The material of the head body is not limited. As the material of the head body, soft iron (low carbon steel having a carbon content of less than 0.3 wt %), CFRP (carbon fiber reinforced plastic), maraging steel, stainless steel, a titanium alloy, an aluminum alloy and a magnesium alloy are exemplified. The whole of the head body may be integrally formed, or may be produced by joining a plurality of members. Forging and casting are exemplified as a process for forming the head body.
The material of the face part is not limited. As the material of the face part, soft iron (low carbon steel having carbon content of less than 0.3 wt %), stainless steel, a titanium alloy, CFRP (carbon fiber reinforced plastic), maraging steel, an aluminum alloy and a magnesium alloy are exemplified.
The method for producing the nonwoven fabric which constitutes the nonwoven fabric layer is not limited. As the method for producing the nonwoven fabric, a thermal bond method, a chemical bond method, a needle punch method, a spunlace method (a water flow interlacing method), a stitch bond method and a steam jet method are exemplified. When polyester or nylon is used as the fiber, the nonwoven fabric produced by the thermal bond method is preferable in light of the productivity, the thickness accuracy and the strength.
The double-stick tape t1 is interposed between the adherend s1y and the head body h1y. The adherend s1y is bonded to the head body h1y by the double-stick tape t1. The profile shape of the double-stick tape t1 and the profile shape of the adherend s1y are substantially equal.
The shape of the double-stick tape t1 is not limited. The width and length of the double-stick tape t1 are not limited. The double-stick tape t1 is a sheet having both surfaces having adhesiveness.
The double-stick tape t1 is shown as a single layer in
The head body h1y has a face part 13y provided with a face surface 4y, a top surface 6y, a sole surface 8y, a back surface 10y and a hosel part 12y. The face part 13y is a portion having the face surface 4y as an outer surface. The face part 13y is solid. A main body recessed part 14y is formed on the back surface 10y. The main body recessed part 14y is formed on the reverse side of the face surface 4y. The head 2y having the main body recessed part 14y is generally referred to as a cavity back iron. The main body recessed part 14y forms a so-called cavity back. The face part is thinned by the main body recessed part 14y. A thin wall part (a first thin wall part) 18y is formed by the main body recessed part 14y. The thin wall part 18y is a part of the face part 13y. The thin wall part 18y is solid. The adherend s1y is stuck on the back surface of the head 2y. The adherend s1y is stuck on the back surface of the thin wall part 18y. The front surface of the thin wall part 18y is the face surface 4y. The back surface of the thin wall part 18y is a bottom surface 20y of the main body recessed part 14y. A sweet spot SS1y of the head 2y is located in the thin wall part 18y. The sweet spot SS1y is a point of intersection between a line passing through the center of gravity of the head 2y and being perpendicular to the face surface 4y and the face surface 4y.
In light of the durability, the thickness of the thin wall part 18y is preferably equal to or greater than 1.5 mm, more preferably equal to or greater than 1.8 mm, and still more preferably equal to or greater than 2.0 mm. When the thin wall part 18y is thin, the vibration of the face part at the time of hitting a ball is great. When the thin wall part is thin, a great impact force acts on a portion on which a double-stick tape is stuck. Therefore, in this case, the effect of the aspect may be actualized. From this viewpoint, the thickness of the thin wall part is preferably equal to or less than 3.0 mm, more preferably equal to or less than 2.7 mm, and still more preferably equal to or less than 2.4 mm.
Although illustration is omitted, an impact area marking is formed on the face surface 4y. The impact area marking is typically a face line (face groove).
A recessed part 16y is further formed inside the main body recessed part 14y. The recessed part (the second recessed part) 16y is formed on the bottom surface 20y of the main body recessed part (the first recessed part) 14y. The second recessed part 16y is shallower than the main body recessed part 14y. The depth of the second recessed part 16y is greater than thickness of the double-stick tape t1. The second recessed part 16y accommodates the whole of the double-stick tape t1. The profile shape of the second recessed part 16y and the profile shape of the adherend s1y are substantially equal.
The face part is further thinned by the second recessed part 16y. A second thin wall part 22y is formed by the second recessed part 16y. The second thin wall part 22y is a part of the first thin wall part 18y. The second thin wall part 22y is solid. The adherend s1y is stuck on the back surface of the second thin wall part 22y. The sweet spot SS1y of the head 2y is located in the second thin wall part 22y. The front surface of the second thin wall part 22y is the face surface 4y. The back surface of the second thin wall part 22y is a bottom surface 24y of the second recessed part 16y. The bottom surface 24y is a part of the bottom surface 20y.
The second recessed part 16y may not be provided. That is, the whole of the bottom surface 20y of the main body recessed part 14y may be a plane. In the aspect, the shape of the bonded surface of the head body h1y is not limited.
The adherend s1y has an approximately plate shape as a whole. The adherend s1y has a bonded surface 26y and a recessed part 27y. In the existence region of the bonded surface 26y, the adherend s1y is a flat plate.
As shown in an enlarged part of
The head body h1y has the bonded surface 28y. The bonded surface 28y is the above-mentioned bottom surface 24y. The bonded surface 28y is a plane. The bonded surface 28y is brought into contact with the double-stick tape t1. The bonded surface 28y is a back surface of the head body h1y. The bonded surface 28y is a back surface of the face surface 4y.
As shown in
The recessed part 27y has an outer surface 27gy and an inner surface 27ny. The bonded surface 26y and the inner surface 27ny are adjacent to each other. That is, the bonded surface 26y and the inner surface 27ny are continuous. The bonded surface 26y and the inner surface 27ny are adjacent to each other in a boundary k1y. The cross-section shape of the inner surface 27ny is an approximately circular arc. The cross-section shape of the outer surface 27gy is an approximately circular arc.
The cross-section shape of the recessed part 27y is not limited. As the section shape, a semicircle shape, a triangle shape and a square shape (rectangular shape) or the like are exemplified.
On the reverse surface of the recessed part 27y, a protruding part is formed. The recessed part 27y forms the protruding part toward the outside. The protruding part provides a three-dimensional image. The protruding part enhances the flexibility of the design of the head.
As shown in
The space SPy is in a closed state. The recessed part 27y does not reach the side surface of the adherend s1y. The circumference of the recessed part 27y is surrounded by the bonded surface 26y. That is, the circumference of the recessed part 27y is sealed. The opening of the recessed part 27y is closed by the double-stick tape t1 and the head body h1y. The recessed part 27y has no through-hole. The space SPy is not communicated with an outer space.
When water or the like enters the recessed part 27y, the bonding strength may be reduced. Since the space SPy is a closed state in the head 2y, water or the like does not enter the recessed part 27y.
When the double-stick tape t1 is stuck on the bonded surface 26y, air may enter between the double-stick tape t1 and the bonded surface 26y. The air may remain as bubbles. The bubbles weaken the bonding strength of the double-stick tape t1.
The bubbles form a clearance between the double-stick tape t1 and the bonded surface 26y. The clearance is narrow. This is because the double-stick tape t1 and the bonded surface 26y adhere to each other in a portion in which the bubbles do not exist. Since the distance of the clearance is narrow, the bubbles extend in a wide range even when the volume of bubbles is small. That is, the bubbles may extend as a thin air layer. In the present application, the “bubbles” include the air layer. The bubbles are apt to decrease the bonding strength. Layered bubbles reduce the bonding strength of the double-stick tape t1.
The recessed part 27y can take in the bubbles. The bubbles can be taken into the space SPy inside the recessed part 27y. Since the bonded surface 26y and the inner surface 27ny are adjacent to each other, the bubbles can move to the recessed part 27y. The recessed part 27y can decrease the bubbles.
The depth of the recessed part 27y is shown by a double-pointed arrow a1y in
When the adherend s1y is attached to the head body h1y, for example, the adherend s1y is pressed against the head body h1y. The bubbles can flow into the space SPy according to the pressing force. The reduction in the bubbles increases the adhesion area to enhance the bonding strength.
The bubbles generated near the center of the adherend s1y are less likely to reach the side surface of the adherend s1y. The bubbles generated near the center of the adherend s1y are less likely to be discharged to the outside. In light of removing the bubbles generated near the center of the adherend s1y, the recessed part 27y is preferably provided near the center of the adherend s1y. From this viewpoint, a centroid of a figure drawn by the profile line s11y is preferably located inside the recessed part 27y in a plan view as shown in
The recessed part 27y is not brought in contact with the double-stick tape t1. Therefore, the recessed part 27y is more likely to vibrate as compared with another portion of the adherend s1y. The vibration caused by the impact shock at the time of hitting the ball can be absorbed by the vibration of the recessed part 27y. The recessed part 27y can absorb the undesirable vibration at the time of hitting the ball. The vibrational absorption can attain a good hitting feeling.
The double-stick tape t1 is provided with an adhesive layer and a base material layer. The double-stick tape t1 has elasticity. The double-stick tape t1 has vibrational absorbability.
The head 2y can develop the vibrational absorbability due to the double-stick tape t1 in addition to the vibrational absorbability due to the recessed part 27y. The head 2y has high vibrational absorbability.
As shown in
A thickness of the recessed part 27y is shown by a double-pointed arrow T1y in
In light of the recessed part 27y being likely to vibrate, it is more preferable that the maximum value of the thickness T1y is smaller than the minimum value of the thickness T2y.
The adherend s1y and the double-stick tape t1 form a composite body. The composite body can exhibit a vibration absorbing effect. When the weight of the double-stick tape t1 is too small, the vibration absorbing effect of the composite body decreases. From this viewpoint, the weight of the double-stick tape t1 is preferably equal to or greater than 0.1 g, and more preferably equal to or greater than 0.2 g. In light of the weight saving, the weight of the double-stick tape t1 is preferably equal to or less than 2 g, and more preferably equal to or less than 1 g.
A ratio (T1y/T2y) of the thickness T1y to the thickness T2y is not limited. When the thickness T2y is too thin, the sticking workability is reduced, or the vibration absorbing effect of the composite body is reduced. On the other hand, the thinner thickness T1y can contribute to the weight saving. The recessed part and each of parts of the adherend s1y are easily deformed by thinning the thickness T1y. Particularly, when the thickness T1y is thinned, the adherend s1y is likely to be expanded or contracted in a direction (in-plane direction) parallel to the bonded surface 26y. The vibration absorbing effect can be enhanced by the deformation. From these viewpoints, the thickness T1y is preferably smaller than the thickness T2y. Furthermore, the ratio (T1y/T2y) is preferably equal to or less than 0.9, and more preferably equal to or less than 0.7. When the thickness T1y is too small, the producing failure of the double-stick tape t1 is apt to take place. When thickness T2y is too large, the weight increase is excessive. From these viewpoints, the ratio (T1y/T2y) is preferably equal to or greater than 0.2, and more preferably equal to or greater than 0.4.
The thickness T2y is not limited. The sticking workability is enhanced by enhancing the rigidity of the adherend s1y to suppress the generation of the bubbles. When the thickness T2y is too thin, the vibrational absorbability of the composite body is reduced. From this viewpoint, the thickness T2y is preferably equal to or greater than 0.5 mm, more preferably equal to or greater than 0.7 mm, and still more preferably equal to or greater than 1.0 mm. In light of the weight saving, the thickness T2y is preferably equal to or less than 2.0 mm, more preferably equal to or less than 1.7 mm, and still more preferably equal to or less than 1.5 mm.
The thickness T1y of the recessed part 27y is not limited. In light of the strength of the recessed part 27y, the thickness T1y is preferably equal to or greater than 0.3 mm, and more preferably equal to or greater than 0.4 mm. When the thickness T1y is thinned, the recessed part and the whole of the adherend s1y can be easily deformed to enhance the vibration absorbing effect. In light of the vibration absorbing effect and the weight saving, the thickness T1y is preferably equal to or less than 1.0 mm, more preferably equal to or less than 0.7 mm, and still more preferably equal to or less than 0.5 mm.
The projection area of the adherend s1y is defined as S1y (cm2). The projection area S1y is an area of a figure drawn by the profile line s11y (see
When the area S1y is great, the bubbles are less likely to be released to the outside. When the area S1y is great, the effect of the aspect can be actualized. From this viewpoint, the area S1y is preferably equal to or greater than 1 (cm2), more preferably equal to or greater than 2 (cm2), and still more preferably equal to or greater than 3 (cm2). When the adherend s1y is formed on the back surface of the head, the area of the back surface is limited. From this viewpoint, in some cases, the area S1y may be preferably equal to or less than 20 (cm2), and more preferably equal to or less than 15 (cm2).
In light of facilitating the release of the bubbles into the recessed part, a ratio (S2y/S1y) of the area S2y to the area S1y is preferably equal to or greater than 0.1, and more preferably equal to or greater than 0.13. In light of increasing the adhesion area, the ratio (S2y/S1y) is preferably equal to or less than 0.5, and more preferably equal to or less than 0.4.
A maximum length of the adherend s1y is shown by a double-pointed arrow W1y in
An inscribed circle E1y having the maximum diameter among circles inscribed in the boundary k1y is drawn by a two-dotted chain line in
The first adhesive layer 30 abuts on a bonded surface 28 of the head body h1y. The second adhesive layer 36 is brought into contact with a bonded surface 26 of the adherend s1y.
The first layer 30 and the fourth layer 36 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 32 is a resin layer. The second layer 32 is a resin layer which is free of bubbles. The second layer 32 is an unfoamed resin film. The second layer 32 is not a resin form layer. The kind of a resin forming the second layer 32 is not limited. As a base material resin of the resin layer, an acrylic resin and a polyester resin are exemplified. The acrylic resin is preferable.
The resin layer is apt to be deformed by the existence of bubbles. In light of the durability and the bonding strength, the resin layer which is free of bubbles is preferable.
The third layer 34 is a fiber layer. The third layer 34 is a nonwoven fabric layer. Although not shown in the drawings, a empty space exists in the nonwoven fabric. Although not shown in the drawings, a part of the adhesive layer 36 adjacent to the third layer 34 enters the empty space. The empty space exists in the nonwoven fabric layer 34. A part of the resin layer 32 adjacent to the third layer 34 enters the empty space. Although not shown in the drawings, a part of the adhesive layer 36 adjacent to the third layer 34 enters the empty space of the nonwoven fabric layer 34.
Unlike the embodiment, the second layer 32 may be the fiber layer, and the third layer 34 may be the resin layer.
The nonwoven fabric layer 34 functions as a support of the double-stick tape t10. When the double-stick tape t10 is stuck, wrinkles are less likely to be generated due to the nonwoven fabric layer 34. The nonwoven fabric layer 34 can suppress the above-mentioned generation of bubbles.
As described above, one example of the fiber layer is the nonwoven fabric layer. However, the fiber layer is not limited to the nonwoven fabric layer. The fiber layer is a layer containing a fiber. In the fiber layer, the fiber contributes to the enhancement of tensile strength. The fiber layer can suppress the generation of wrinkles. The fiber layer can suppress the generation of bubbles.
A step of sticking the adherend s1y on the head body h1y includes, for example, a first step of sticking the double-stick tape t1 on the adherend s1y, and a second step of sticking the adherend s1y on which the double-stick tape t1 is stuck, on the head body h1y. When the recessed part is formed on the adherend s1y, the double-stick tape t1 at a position corresponding to the recessed part is in a state where the double-stick tape t1 does not abut on any part immediately after the first step. Hereinafter, the part which is not brought into contact with any part is referred to as a non-bonded part. In the second step, the whole of the double-stick tape t1 containing the non-bonded part is stuck on the head body h1y. In the second step, wrinkles, slacks or tears are apt to be generated in the non-bonded part. The wrinkles are apt reduce the bonding strength. The double-stick tape t1 having the fiber layer can eliminate the problems caused by the non-bonded part. The combination of the fiber layer with the resin layer can further enhance the effect.
As preferable fiber layers, for example, the following items (a), (b), (c) and (d) are exemplified.
The fiber contained in the fiber layer is not limited. As the fiber, a synthetic fiber, a natural fiber and regenerated fiber are exemplified. As the synthetic fiber, a vinylon fiber, a polyester fiber, a polypropylene fiber, a polyethylene fiber and a nylon fiber are exemplified. As the natural fiber, a pulp fiber and a hemp fiber are exemplified. As the regenerated fiber, rayon is exemplified. In light of the suppression of bubbles, the synthetic fiber is preferable.
As the fiber layer, a woven fabric, a nonwoven fabric and paper are exemplified. In the present application, “paper” means Japanese paper or foreign paper. In the present application, “the nonwoven fabric” is defined as the concept which does not contain the paper.
As the materials of the Japanese paper, Broussonetia kazinoki, Diplomorpha sikokiana and Edgeworthia papyrifera are exemplified. In light of the strength, a fiber length of the Japanese paper is preferably equal to or greater than 3 mm, more preferably equal to or greater than 5 mm, still more preferably equal to or greater than 10 mm, and particularly preferably equal to or greater than 15 mm. A fiber length of the Japanese paper is usually equal to or less than 25 mm. The Japanese paper may be produced by hand-making or machine-making.
The material of the foreign paper is a broadleaf tree or a needle leaf tree. A fiber length of the foreign paper is usually 0.8 mm or greater and less than 5 mm. The foreign paper is obtained by machine-making.
As the nonwoven fabric, a wet nonwoven fabric and a dry nonwoven fabric are exemplified.
The method for producing the nonwoven fabric is not limited. As the method for producing the nonwoven fabric, a thermal bond method, a chemical bond method, a needle punch method, a spunlace method (water flow interlacing method), a stitch bond method and a steam jet method are exemplified. When the polyester fiber or the nylon fiber is used as the fiber, the nonwoven fabric produced by the thermal bond method is preferable in light of the productivity and the strength.
In light of suppressing the generation of the wrinkles or bubbles, the fiber layer is preferably the nonwoven fabric or the Japanese paper. In light of the vibrational absorbability, the nonwoven fabric is more preferable.
The five layers are a first layer 50, a second layer 52, a third layer 54, a fourth layer 56 and a fifth layer 58 in order from the side of the head body h1y. The first layer 50 is an innermost layer of the double-stick tape t11. The first layer 50 is an adhesive layer. The first layer 50 is a first adhesive layer. The second layer 52, the third layer 54 and the fourth layer 56 are intermediate layers. The fifth layer 58 is an adhesive layer. The fifth layer 58 is an outermost layer of the double-stick tape t11. The fifth layer 58 is a second adhesive layer. Although boundaries between the layers are flatly shown in
The first adhesive layer 50 is bonded to the head body h1y. The second adhesive layer 58 is bonded to the adherend s1y. The adherend s1y is bonded to the head body h1y by the double-stick tape t11.
The first layer 50 and the fifth layer 58 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 52 and the fourth layer 56 are resin layers. The second layer 52 and the fourth layer 56 are unfoamed resin films.
The third layer 54 is a fiber layer. Preferably, the fiber layer is a nonwoven fabric or Japanese paper.
The three layers are a first layer 70, a second layer 72 and a third layer 74 in order from the side of the head body h1y. The first layer 70 is an innermost layer of the double-stick tape t12. The first layer 70 is an adhesive layer. The first layer 70 is a first adhesive layer. The second layer 72 is an intermediate layer. The third layer 74 is an adhesive layer. The third layer 74 is an outermost layer of the double-stick tape t12. The third layer 74 is a second adhesive layer.
The first adhesive layer 70 is bonded to the head body h1y. The second adhesive layer 74 is bonded to the adherend s1y. The adherend s1y is bonded to the head body h1y by the double-stick tape t12.
The second layer 72 is a resin layer. The second layer 72 is an unfoamed resin film.
In the aspect, the double-stick tape t1 which is free of the fiber layer can be also used. However, as described above, the double-stick tape t1 having the fiber layer is preferable.
The three layers are a first layer 90, a second layer 92 and a third layer 94 in order from the side of the head body h1y. The first layer 90 is an innermost layer of the double-stick tape t13. The first layer 90 is an adhesive layer. The first layer 90 is a first adhesive layer. The second layer 92 is an intermediate layer. The third layer 94 is an adhesive layer.
The first adhesive layer 90 is bonded to the head body h1y. The second adhesive layer 94 is bonded to the adherend s1y. The adherend s1y is bonded to the head body h1y by the double-stick tape t11.
The first layer 90 and the third layer 94 are layers made of an adhesive compound. The second layer 92 is a fiber layer. In the aspect, the double-stick tape t1 having the three-layered structure can be also suitably used.
A thickness of the double-stick tape t1 is shown by a double-pointed arrow A1 in
The adherend s1y is preferably disposed on the back surface of the face surface 4y. The double-stick tape t1 is preferably disposed between the back surface of the face surface 4y and the adherend s1y. A ball impacts the face surface 4y directly. When the face surface 4y hits the ball, a great impact force acts on the face surface 4y. Therefore, when the double-stick tape t1 is disposed on the back surface (reverse side) of the face surface 4y, the vibration absorbing effect is significantly exhibited.
In the embodiment of
The material of the adhesive layer is not limited. When the adherend s1y is attached to the outer surface of the head, the double-stick tape t1 may be protruded from the outer edge of the adherend s1y. The protruded double-stick tape t1 is exposed to the outside. The protruded double-stick tape t1 may be visually recognized. The protruded double-stick tape t1 is preferably inconspicuous. Considering the case where double-stick tape t1 is exposed to the outside, it is preferable that the adhesive layer has transparency and weatherability. From this viewpoint, the material of the adhesive layer is preferably the acrylic adhesive compound.
The material of the resin layer which is free of bubbles is not limited. As described above, the double-stick tape t1 may be exposed to the outside. Considering the case where double-stick tape t1 is exposed to the outside, it is preferable that the resin layer which is free of bubbles has transparency and weatherability. From this viewpoint, the base material resin of the resin layer which is free of bubbles is preferably the acrylic resin.
When the fiber layer is the nonwoven fabric layer, the material of a nonwoven fabric which constitutes the nonwoven fabric layer is not limited. As the material of the nonwoven fabric, a natural fiber, a synthetic fiber and a regenerated fiber are exemplified. As the synthetic fiber, vinylon, polyester, polypropylene, polyethylene and nylon are exemplified. As the natural fiber, pulp and hemp are exemplified. As the regenerated fiber, rayon is exemplified. In light of the weatherability and the strength, the synthetic fiber is preferable, and polyester and nylon are more preferable.
The specific examples of the double-stick tapes which may be used for the aspect include “Y-4625” (trade name), “VHX-802” (trade name), “Y-9448HK” (trade name), “4393” (trade name), “Y-9448HK” (trade name), “Y-9448HKB” (trade name) and “Y-9448SK” (trade name). All of them are produced by the Sumitomo 3M Limited.
The material of the adherend s1y is not limited. Examples of the materials of the adherend s1y include a metal, a resin and a viscoelastic material. The plurality of materials may be combined.
The material of the head body h1y is not limited. As the material of the head body h1y, soft iron (low carbon steel having a carbon content of less than 0.3 wt %), CFRP (carbon fiber reinforced plastic), maraging steel, stainless steel, a titanium alloy, an aluminium alloy and a magnesium alloy are exemplified. The whole of the head body h1y may be integrally formed, or may be produced by joining a plurality of members. For example, the head body may be produced by combining a flat plate-shaped face member with a face opening member. In this case, as the face member, a titanium alloy is suitable. As the face opening member, stainless steel is suitable. Forging and casting are exemplified as a method for forming the head body or a component thereof.
The material of the face part is not limited. As the material of the face part, soft iron (low carbon steel having a carbon content of less than 0.3 wt %), stainless steel, a titanium alloy, CFRP (carbon fiber reinforced plastic), maraging steel, an aluminium alloy and a magnesium alloy are exemplified.
The embodiment is an example in which the recessed part is formed on the adherend s1y. The recessed part may be formed on the head body h1y. The bubbles can move into the recessed part formed on the head body h1y. The bubbles can move into a space formed by the recessed part formed on the head body h1y. In this case, the whole of the adherend s1y may have a flat plate shape.
In
The double-stick tape w1 is interposed between the adherend s1 and the head body h1. The adherend s1 is bonded to the head body h1 by the double-stick tape w1. The profile shape of the double-stick tape w1 and the profile shape s11 of the adherend s1 are substantially equal.
The shape of the double-stick tape w1 is not limited. The width and length of the double-stick tape w1 are not limited. The double-stick tape w1 is a sheet having both surfaces having adhesiveness.
The double-stick tape w1 is shown as a single layer in
A method for fixing the adherend s1 to the head body h1 is not limited. The double-stick tape w1 may not be used. An adhesive may be used instead of the double-stick tape w1.
The head body h1 has a face part 13 provided with a face surface 4, a top surface 6, a sole surface 8, a back surface 10 and a hosel part 12. The face part 13 has the face surface 4 as an outer surface. The face part 13 is solid. A main recessed part 14 is formed on the back surface 10. The main recessed part 14 is formed on the reverse side of the face surface 4. The head 2 having the main recessed part 14 is generally referred to as a cavity back iron. The main recessed part 14 forms a so-called cavity back. The face part is thinned by the main recessed part 14. A thin wall part (a first thin wall part) 18 is formed by the main recessed part 14. The thin wall part 18 is a part of the face part 13. The thin wall part 18 is solid. The adherend s1 is stuck on the back surface 10 of the head 2. The adherend s1 is stuck on the back surface of the thin wall part 18. That is, the adherend s1 is stuck on a bottom surface 20 of the main recessed part 14. The front surface of the thin wall part 18 is the face surface 4. The back surface of the thin wall part 18 is the bottom surface 20 of the main recessed part 14.
As shown in
In light of the durability, a thickness x1 (see
Although illustration is omitted, an impact area marking is formed on the face surface 4. The impact area marking is typically a face line (face groove).
A recessed part 16 is further formed in the main recessed part 14. The recessed part (a second recessed part) 16 is formed on the bottom surface 20 of the main recessed part (a first recessed part) 14. The second recessed part 16 is shallower than the main recessed part 14. The depth of the second recessed part 16 is greater than the thickness of the double-stick tape w1. The second recessed part 16 accommodates the whole of the double-stick tape w1. The profile shape of the second recessed part 16 and the profile shape s11 of the adherend s1 are substantially equal.
The face part 13 is further thinned by the second recessed part 16. A second thin wall part 22 is formed by the second recessed part 16. The second thin wall part 22 is a part of the first thin wall part 18. The second thin wall part 22 is solid. The adherend s1 is stuck on the back surface of the second thin wall part 22. The sweet spot SS1 of the head 2 is located in the second thin wall part 22. The front surface of the second thin wall part 22 is the face surface 4. The back surface of the second thin wall part 22 is a bottom surface 24 of the second recessed part 16. The bottom surface 24 is a part of the bottom surface 20.
The second recessed part 16 may not be provided. For example, the whole of the bottom surface 20 of the main recessed part 14 may be a plane. In the aspect, the shape of the bonded surface of the head body h1 is not limited.
The adherend s1 has a bonded surface 26, a metal member 27 and an elastic member 29. The bonded surface 26 is the front surface of the elastic member 29. The bonded surface 26 is a plane.
The metal member 27 is joined to the elastic member 29. The joining method is not limited. The joining is attained by, for example, an adhesive, fitting and a double-stick tape or the like. As the fitting, fitting using the plastic deformation of the elastic member 29 is exemplified. In light of the vibration absorbing effect, the joining using the adhesive is preferable.
The metal member 27 is set to a mold, the elastic member 29 may be formed by the mold, and meanwhile, the elastic member 29 and the metal member 27 may be joined. In this case, a method for forming the elastic member 29 is not limited, and injection forming, cast forming and vulcanization forming are exemplified. In this case, the needs for the adhesive and the double-stick tape can be eliminated.
The same double-stick tape as the double-stick tape w1 may be used for adhesion between the metal member 27 and the elastic member 29. The detail of the double-stick tape will be described later.
The material of the metal member 27 is a metal. The metal is not limited. As the metal, an aluminium alloy, a stainless alloy, a nickel alloy, a titanium alloy and a magnesium alloy are exemplified. In light of the vibration absorbing effect and the ease of processing, the aluminium alloy and the stainless alloy are preferable.
The elastic member 29 is a nonmetal. As the material of the elastic member 29, a polymer containing a resin or a vulcanization rubber as main material is exemplified. As the resin, a polyurethane resin, an epoxy resin, a polypropylene resin, a phenol resin and a silicone resin are exemplified. In light of the vibrational absorbability and the strength, the polyurethane resin or the epoxy resin is preferable. The resin may be a thermoplastic resin and may be a thermosetting resin. The thermoplastic resin contains a thermoplastic elastomer having a hard segment and a soft segment. The thermosetting resin contains a thermosetting elastomer having a hard segment and a soft segment. The vulcanization rubber is a rubber obtained by crosslinking a base material rubber using a crosslinking agent. The base material rubber, which is not limited, is preferably at least one selected from the group consisting of SBR (a styrene-butadiene rubber), BR (a butadiene rubber), NR (a natural rubber) and a silicone rubber. The “main material” means that the content thereof to a base material polymer is equal to or greater than 50% by mass. The content is preferably equal to or greater than 70% by mass, and more preferably equal to or greater than 80% by mass, and particularly preferably equal to or greater than 100% by mass. The elastic member 29 may contain a metal powder.
The hardness of the elastic member 29 is not limited. In light of the strength, the Shore D hardness H1 of the elastic member 29 is preferably equal to or greater than 40, more preferably equal to or greater than 45, and still more preferably equal to or greater than 50. In light of the vibration absorbing effect, the hardness H1 is preferably equal to or less than 80, more preferably equal to or greater than 75, and still more preferably equal to or greater than 70.
The hardness H1 is measured in accordance with a standard of “ASTM-D 2240-68” by using a Shore D spring type hardness scale attached to an automated rubber hardness measuring device (trade name “P1”, available from Koubunshi Keiki Co., Ltd.). For the measurement, a slab formed by hot pressing to have a thickness of about 2 mm is used. For the measurement, a slab stored at a temperature of 23° C. for two weeks is used. When the measurement is carried out, three pieces of the slab are overlaid. A slab having the same composition as that of the elastic member 29 is used for the measurement.
In the head 2 of the sixth embodiment, the elastic member 29 has a recessed part r1. The recessed part r1 is formed on the reverse surface of the elastic member 29. In light of clearly discriminating the recessed part r1 from the other recessed part, in the present application, the recessed part r1 is also referred to as a recessed part (E). The recessed part (E) r1 is opened to the back of the head 2.
As shown in
The elastic member 29 has a peripheral part 29a and an interposition part 29b. The peripheral part 29a abuts on a side surface 31 of the metal member 27. The abutment may be direct or indirect. The indirect abutment means that the other member (adhesive or the like) is interposed between the side surface 31 and the peripheral part 29a.
As shown in
The peripheral part 29a and the interposition part 29b may be separately formed respectively. In this case, the peripheral part 29a and the interposition part 29b are preferably bonded by an adhesive or the like. In light of the strength and productivity of the adherend s1, it is preferable that the elastic member 29 including the peripheral part 29a and the interposition part 29b is integrally formed.
The depth d1 (see
The interposition part 29b is located between the head body h1 and the metal member 27. The interposition part 29b is located between the back surface 10 of the head body h1 and the metal member 27. The interposition part 29b is located between the bottom surface 20 of the main recessed part 14 and the metal member 27. The interposition part 29b is located between the bottom surface 24 of the second recessed part 16 and the metal member 27.
The double-stick tape w1 is disposed between the back surface 10 of the head body h1 and the interposition part 29b. The front surface of the interposition part 29b and the back surface 10 are bonded by the double-stick tape w1.
The interposition part 29b has a flat plate shape. The profile shape of the interposition part 29b is equal to the profile line s11 of the adherend s1. The interposition part 29b covers the whole of the front surface 27a of the metal member 27. The interposition part 29b abuts on the whole of the front surface 27a directly or indirectly. In the constitution, the vibration absorbing effect due to the elastic member 29 is high.
In the embodiment, the bottom part of the recessed part (E) r1 is the interposition part 29b. In the embodiment, a peripheral wall of the recessed part (E) r1 is the peripheral part 29a.
The elastic member 29 is constituted by only the peripheral part 29a and the interposition part 29b. The whole of the elastic member 29 is integrally formed. The peripheral part 29a and the interposition part 29b are integrally formed.
The profile shape of the double-stick tape w1 and the profile shape of a front surface 29c of the elastic member 29 are substantially equal. The double-stick tape w1 directly abuts on the whole of the front surface 29c. The front surface 29c of the elastic member 29 is the bonded surface 26.
As shown in
A golf player tends to try to hit the ball to the sweet spot SS1. A probability that a hitting point (a position where the ball is hit) is the sweet spot SS1 or near the sweet spot SS1 is high. In the embodiment, the vibration absorbing effect when the hitting point is the sweet spot SS1 or near the sweet spot SS1 is high.
The first adhesive layer 30 is brought into contact with the back surface 10 of the head body h1. The second adhesive layer 36 is brought into contact with the bonded surface 26 of the adherend s1. That is, the second adhesive layer 36 is brought into contact with the front surface 29c of the elastic member 29.
The first layer 30 and the fourth layer 36 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 32 is a resin layer. The second layer 32 is a resin layer which is free of bubbles. The second layer 32 is an unfoamed resin film. The second layer 32 is not a resin form layer. The kind of a resin forming the second layer 32 is not limited. As a base material resin of the resin layer, an acrylic resin and a polyester resin are exemplified. The acrylic resin is preferable.
The resin layer is apt to be deformed by the existence of bubbles. In light of the durability and the bonding strength, the resin layer which is free of bubbles is preferable.
The third layer 34 is a fiber layer. The third layer 34 is a nonwoven fabric layer. Although not shown in the drawing, a empty space exists in the nonwoven fabric. A part of the adhesive layer 36 adjacent to the third layer enters the empty space. The empty space exists in the nonwoven fabric layer 34. Although not shown in the drawing, a part of the resin layer 32 adjacent to the third layer 34 enters the empty space. Although not shown in the drawing, a part of the adhesive layer 36 adjacent to the third layer 34 enters the empty space.
Unlike the embodiment, the second layer 32 may be the fiber layer, and the third layer 34 may be the resin layer.
The nonwoven fabric layer 34 functions as a support of the double-stick tape w10. When the double-stick tape w10 is stuck, wrinkles are less likely to be generated due to the nonwoven fabric layer 34. The nonwoven fabric layer 34 can suppress bubbles between the bonded surface 26 and a tape w1.
As described above, one example of the fiber layer is the nonwoven fabric layer. However, the fiber layer is not limited to the nonwoven fabric layer. The fiber layer is a layer containing a fiber. In the fiber layer, the fiber contributes to the enhancement of tensile strength. The fiber layer can suppress the generation of wrinkles. The fiber layer can suppress the generation of bubbles. Even when the thickness A1 is small, the fiber layer suppresses wrinkles and bubbles at the time of sticking the tape. Therefore, the adherend s1 is less likely to be separated due to the fiber layer.
A step of sticking the adherend s1 on the head body h1 includes, for example, a first step of sticking the double-stick tape w1 on the adherend s1, and a second step of sticking the adherend s1 on which the double-stick tape w1 is stuck, on the head body h1. In the first step or the second step, wrinkles are sometimes generated on the tape w1. The wrinkles reduce the bonding strength. The double-stick tape w1 having the fiber layer suppresses the generation of the wrinkles.
As preferable fiber layers, for example, the following items (a), (b), (c) and (d) are exemplified.
The fiber contained in the fiber layer is not limited. As the fiber, a synthetic fiber, a natural fiber and regenerated fiber are exemplified. As the synthetic fiber, a vinylon fiber, a polyester fiber, a polypropylene fiber, a polyethylene fiber and a nylon fiber are exemplified. As the natural fiber, a pulp fiber and a hemp fiber are exemplified. As the regenerated fiber, rayon is exemplified. In light of the suppression of bubbles, the synthetic fiber is preferable.
As the fiber layer, a woven fabric, a nonwoven fabric and paper are exemplified. In the present application, “paper” means Japanese paper or foreign paper. In the present application, the “nonwoven fabric” is defined as the concept which does not contain the paper.
As the materials of the Japanese paper, Broussonetica kazinoki, Diplomorpha sikokiana and Edgeworthia papyrifera are exemplified. In light of the strength, the fiber length of the Japanese paper is preferably equal to or greater than 3 mm, more preferably equal to or greater than 5 mm, still more preferably equal to or greater than 10 mm, and particularly preferably equal to or greater than 15 mm. The fiber length of Japanese paper is usually equal to or less than 25 mm. The Japanese paper may be produced by hand-making or machine-making.
The material of the foreign paper is a broadleaf tree or a needle-leaf tree. The fiber length of the foreign paper is usually 0.8 mm or greater and less than 5 mm. The foreign paper is obtained by machine-making.
As the nonwoven fabric, a wet nonwoven fabric and a dry nonwoven fabric are exemplified.
The method for producing the nonwoven fabric is not limited. As the method for producing the nonwoven fabric, a thermal bond method, a chemical bond method, a needle punch method, a spunlace method (water flow interlacing method), a stitch bond method and a steam jet method are exemplified. When a polyester fiber or a nylon fiber is used as the fiber, the nonwoven fabric produced by the thermal bond method is preferable in light of the productivity and the strength.
In light of suppressing the generation of the wrinkles or bubbles, the fiber layer is preferably a nonwoven fabric or Japanese paper. In light of the vibrational absorbability, the nonwoven fabric is more preferable.
The five layers are a first layer 50, a second layer 52, a third layer 54, a fourth layer 56 and a fifth layer 58 in order from the side of the head body h1. The first layer 50 is an innermost layer of the double-stick tape w11. The first layer 50 is an adhesive layer. The first layer 50 is a first adhesive layer. The second layer 52, the third layer 54 and the fourth layer 56 are intermediate layers. The fifth layer 58 is an adhesive layer. The fifth layer 58 is an outermost layer of the double-stick tape w11. The fifth layer 58 is a second adhesive layer. Although boundaries between the layers are flatly shown in
The first adhesive layer 50 is bonded to the head body h1. The second adhesive layer 58 is bonded to the adherend s1. That is, the second adhesive layer 58 is brought into contact with the front surface 29c of the elastic member 29. The adherend s1 is bonded to the head body h1 by the double-stick tape w11.
The first layer 50 and the fifth layer 58 are layers made of an adhesive compound. The adhesive compound is not limited. As the adhesive compound, an acrylic adhesive compound, an epoxy adhesive compound, and a urethane adhesive compound or the like are exemplified.
The second layer 52 and the fourth layer 56 are resin layers. The second layer 52 and the fourth layer 56 are unfoamed resin films.
The third layer 54 is a fiber layer. Preferably, the fiber layer is a nonwoven fabric or Japanese paper.
The three layers are a first layer 70, a second layer 72 and a third layer 74 in order from the side of the head body h1. The first layer 70 is an innermost layer of the double-stick tape w12. The first layer 70 is an adhesive layer. The first layer 70 is a first adhesive layer. The second layer 72 is an intermediate layer. The third layer 74 is an adhesive layer. The third layer 74 is an outermost layer of the double-stick tape w12. The third layer 74 is a second adhesive layer.
The first adhesive layer 70 is bonded to the head body h1. The second adhesive layer 74 is bonded to the adherend s1. That is, the second adhesive layer 74 is brought into contact with the front surface 29c of the elastic member 29. The adherend s1 is bonded to the head body h1 by the double-stick tape w12.
The second layer 72 is a resin layer. The second layer 72 is an unfoamed resin film.
Thus, in the aspect, the double-stick tape w1 which does not have the fiber layer can be also used. However, as described above, the double-stick tape w1 having the fiber layer is preferable.
The three layers are a first layer 90, a second layer 92 and a third layer 94 in order from the side of the head body h1. The first layer 90 is an innermost layer of the double-stick tape w13. The first layer 90 is an adhesive layer. The first layer 90 is a first adhesive layer. The second layer 92 is an intermediate layer. The third layer 94 is an adhesive layer.
The first adhesive layer 90 is bonded to the head body h1. The second adhesive layer 94 is bonded to the adherend s1. The adherend s1 is bonded to the head body h1 by the double-stick tape w13.
The first layer 90 and the third layer 94 are layers made of an adhesive compound. The second layer 92 is a fiber layer. The fiber layer is preferably a nonwoven fabric or Japanese paper. In the aspect, the double-stick tape w1 having the three-layered structure can be also suitably used.
A thickness of the double-stick tape w1 is shown by a double-pointed arrow A1 in
Even when the double-stick tape w1 is thinned, the generation of the wrinkles is effectively suppressed by providing the fiber layer as the intermediate layer. The adherend s1 is less likely to be separated due to the suppressing effect.
The double-stick tape w1 can exhibit the vibration absorbing effect. The adherend s1 is disposed on the back surface 10 of the face surface 4. The double-stick tape w1 is disposed between the back surface of the face surface 4 and the adherend s1. A ball impacts the face surface 4 directly. When the ball is hit, a great impact force acts on the face surface 4. Therefore, when the double-stick tape w1 is disposed on the back surface 10 of the face surface 4, the effect of the aspect is significantly exhibited. The vibration absorbing effect due to the elastic member 29 and the vibration absorbing effect due to the double-stick tape w1 can act synergistically.
The material of the adhesive layer is not limited. When the adherend s1 is attached to the outer surface of the head, the double-stick tape w1 may be protruded from the outer edge of the adherend s1. The protruded double-stick tape w1 is exposed to the outside. The protruded double-stick tape w1 may be visually recognized. The protruded double-stick tape w1 is preferably inconspicuous. Considering the case where the double-stick tape w1 is exposed to the outside, it is preferable that the adhesive layer has transparency and weatherability. From this viewpoint, the material of the adhesive layer is preferably the acrylic adhesive compound.
The material of the resin layer which is free of bubbles is not limited. As described above, the double-stick tape w1 may be exposed to the outside. Considering the case where the double-stick tape w1 is exposed to the outside, it is preferable that the resin layer which is free of bubbles has transparency and weatherability. From this viewpoint, the base material resin of the resin layer which is free of bubbles is preferably the acrylic resin.
When the fiber layer is the nonwoven fabric layer, the material of the nonwoven fabric which constitutes the nonwoven fabric layer is not limited. As the material of the nonwoven fabric, a natural fiber, a synthetic fiber and a regenerated fiber are exemplified. As the synthetic fiber, vinylon, polyester, polypropylene, polyethylene and nylon are exemplified. As the natural fiber, hemp is exemplified. As the regenerated fiber, rayon is exemplified. In light of the weatherability and the strength, the synthetic fiber is preferable, and polyester and nylon are more preferable.
The specific examples of the double-stick tapes which may be used for the embodiment include “Y-4625” (trade name), “VHX-802” (trade name), “Y-9448HK” (trade name), “4393” (trade name), “Y-9448HK” (trade name), “Y-9448HKB” (trade name) and “Y-9448SK” (trade name). All of them are produced by the Sumitomo 3M Limited.
In the exhibition of the vibration absorbing effect, the elastic member 29 and the double-stick tape w1 can act synergistically. The vibration absorbing effect is enhanced by providing the elastic member 29 and the double-stick tape w1 between the head body h1 and the metal member 27.
In the embodiment of
In the embodiment of
In
The head body h1 of the head 100 is the same as the head body h1 of the head 2. The double-stick tape w1 of the head 100 is the same as the double-stick tape w1 of the head 2. The profile line s11 of the adherend s1 in the head 100 is the same as the profile line s11 of the head 2.
The double-stick tape w1 is interposed between the adherend s1 and the head body h1. The adherend s1 is bonded to the head body h1 by the double-stick tape w1. The profile shape of the double-stick tape w1 and the profile shape s11 of the adherend s1 are substantially equal.
The adherend s1 has a bonded surface 102, a metal member 104 and an elastic member 106. The bonded surface 102 is a front surface of the elastic member 106. The bonded surface 102 is a plane.
The metal member 104 is joined to the elastic member 106. The joining method is not limited. The joining is attained by, for example, an adhesive, fitting, a double-stick tape or the like. As the fitting, fitting using the plastic deformation of the elastic member 106 is exemplified. In light of the vibration absorbing effect, the joining using the adhesive is preferable.
The metal member 104 is set to a mold, the elastic member 106 may be formed by the mold, and meanwhile, the elastic member 106 and the metal member 104 may be joined. In this case, a method for forming the elastic member 106 is not limited, and injection forming, cast forming and vulcanization forming are exemplified. In this case, the needs for the adhesive and the double-stick tape can be eliminated.
In the head 100 of the seventh embodiment, the metal member 104 has a recessed part r2. The recessed part r2 is provided on the front surface of the metal member 104. In light of clearly discriminating the recessed part r2 from the other recessed part, in the present application, the recessed part r2 is also referred to as a recessed part (M). The recessed part (M) r2 is opened to the front of the head 100.
As shown in
The inner side extending part 106c may be formed separately from the other portion of the elastic member 106. In this case, the inner side extending part 106c is preferably bonded to the other portion of the an elastic member 106 by an adhesive or the like. In light of the productivity and strength of the adherend s1, the whole of the interposition part 106b including the inner side extending part 106c is preferably integrally formed and the whole of the elastic member 106 having the interposition part 106b including the inner side extending part 106c, and having a peripheral part 106a is more preferably integrally formed.
The metal member 104 has a periphery wall part 104a and a main part 104b. The periphery wall part 104a is circular. The main part 104b has a flat plate shape. The metal member 104 consists of the periphery wall part 104a and the main part 104b. The recessed part (M) r2 is formed by the main part 104b and the periphery wall part 104a. The main part 104b constitutes a bottom part of the recessed part (M) r2.
The elastic member 106 has the peripheral part 106a and the interposition part 106b. The peripheral part 106a abuts on a side surface 108 of the metal member 104. The abutment may be direct or indirect.
The thickness of the interposition part 106b is greater than the depth of the recessed part (M) r2. The recessed part (M) r2 is filled with the interposition part 106b. The interposition part 106b is fitted into the recessed part (M) r2.
As shown in
The inner surface 110 of the periphery wall part 104a abuts on the interposition part 106b directly. The inner side extending part 106c is fitted to the recessed part (M) r2. The side surface of the inner side extending part 106c abuts on the inner surface 110 directly. The abutment may be direct or indirect. The whole surface of the inner surface 110 abuts on the inner side extending part 106c. The abutment enhances the vibration absorbing effect of the adherend s1.
The back surface 112 of the interposition part 106b abuts on the front surface 114 of the main part 104b. The whole of the front surface 114 abuts on the interposition part 106b directly. The abutment may be direct or indirect. The abutment enhances the vibration absorbing effect of the adherend s1.
A groove mz1 is formed in the elastic member 106 by the peripheral part 106a and the inner side extending part 106c (see an enlarged part of
In
The head body h1 of the head 120 is the same as the head body h1 of the head 2. The double-stick tape w1 of the head 120 is the same as the double-stick tape w1 of the head 2. The profile line s11 of the adherend s1 in the head 120 is the same as the profile line s11 of the head 2.
The double-stick tape w1 is interposed between the adherend s1 and the head body h1. The adherend s1 is bonded to the head body h1 by the double-stick tape w1. The profile shape of the double-stick tape w1 and the profile shape s11 of the adherend s1 are substantially equal.
The adherend s1 has a metal member 27 and an elastic member 122.
The metal member 27 of the head 120 is the same as the metal member 27 of the head 2. Except for the elastic member 122, the head 120 is the same as the head 2.
The elastic member 122 of the head 120 is different from the elastic member 29 of the head 2. The difference is only the thickness v1 of the peripheral part. That is, the thickness v1 of a peripheral part 122a in the elastic member 122 is greater than the thickness v1 of the peripheral part 29a in the head 2. An interposition part 122b of the elastic member 122 is the same as the interposition part 29b of the elastic member 29.
The thickness v1 of the peripheral part 122a is greater than that of the metal member 27. In the head 120, the peripheral part 122a of the elastic member 122 extends further backward relative to the back of the side surface 31 of the metal member 27. That is, the peripheral part 122a has a back extending part 122d extending further backward relative to the back of the side surface 31 of the metal member 27. The back extending part 122d exists over all the periphery of the metal member 27. The back extending part 122d is likely to vibrate. The vibration absorbing effect can be further enhanced by the back extending part 122d.
The thickness of the back extending part 122d is shown by a double-pointed arrow t2 in
In
The head body h1 of the head 130 is the same as the head body h1 of the head 2. The double-stick tape w1 of the head 130 is the same as the double-stick tape w1 of the head 2. The profile line s11 of the adherend s1 in the head 130 is the same as the profile line s11 of the head 2.
The double-stick tape w1 is interposed between the adherend s1 and the head body h1. The adherend s1 is bonded to the head body h1 by the double-stick tape w1. The profile shape of the double-stick tape w1 and the profile shape s11 of the adherend s1 are substantially equal.
The adherend s1 has a metal member 27 and an elastic member 132.
The metal member 27 of the head 130 is the same as the metal member 27 of the head 2. Except for the elastic member 132, the head 130 is the same as the head 2.
The elastic member 132 of the head 130 is different from the elastic member 29 of the head 2. The difference is the nonexistence of the interposition part. That is, the elastic member 132 does not have the interposition part. The elastic member 132 has only a peripheral part 132a directly or indirectly abutting on the side surface 31 of the metal member 27. That is, the elastic member 132 consists of only the peripheral part 132a. The elastic member 132 is a circular member. The front surface 27a of the metal member 27 is directly brought into contact with the double-stick tape w1.
In the head 130, the adherend s1 can absorb the vibration in a direction parallel to the face surface 4 effectively. The vibration in a direction perpendicular to the face surface 4 can be mainly absorbed by the double-stick tape w1.
The material of the head body h1 is not limited. As the material of the head body h1, soft iron (low carbon steel having a carbon content of less than 0.3 wt %), CFRP (carbon fiber reinforced plastic), maraging steel, stainless steel, a titanium alloy, an aluminium alloy and a magnesium alloy are exemplified. The whole of the head body h1 may be integrally formed, or the head body h1 may be produced by joining a plurality of members. For example, the head body may be produced by combining a flat plate—shaped face member with a face opening member. In this case, as the face member, a titanium alloy is suitable. In this case, as the face opening member, stainless steel is suitable. Forging and casting are exemplified as a method for forming the head body or a component thereof.
The material of the face part 13 is not limited. As the material of the face part 13, soft iron (low carbon steel having a carbon content of less than 0.3 wt %), stainless steel, a titanium alloy, CFRP (carbon fiber reinforced plastic), maraging steel, an aluminium alloy and a magnesium alloy are exemplified.
The adherend s1 and the double-stick tape w1 form a composite body. The composite body can exhibit a vibration absorbing effect. When the weight of the double-stick tape w1 is too small, the vibration absorbing effect of the composite body decreases. From this viewpoint, the weight of the double-stick tape w1 is preferably equal to or greater than 0.1 g, and more preferably equal to or greater than 0.2 g. In light of the weight saving, the weight of the double-stick tape w1 is preferably equal to or less than 2 g, and more preferably equal to or less than 1 g.
The area St of the projection image Tz1 of the adherend s1 is not limited. In light of enhancing the vibrational absorbability when the hitting points vary, the area St is preferably equal to or greater than 600 mm2, more preferably equal to or greater than 800 mm2, and still more preferably equal to or greater than 1000 mm2. When the area St is too large, the adherend s1 is difficult to follow the deformation of the head body, and the separation is likely to occur. From this viewpoint, the area St is preferably equal to or less than 1700 mm2, more preferably equal to or less than 1600 mm2 and still more preferably equal to or less than 1500 mm2.
The maximum thickness of the metal member is shown by a double-pointed arrow At in
In light of the vibration absorbing effect, the thickness v1 (see
The width of the peripheral part is shown by a double-pointed arrow Ct in
The thickness of the interposition part is shown by a double-pointed arrow Dt in
The thickness of the inner side extending part 106c is shown by a double-pointed arrow Et in
In light of the vibration absorbing effect, a ratio (Et/At) of the thickness Et (mm) to the thickness At (mm) is preferably equal to or greater than 0.2, more preferably equal to or greater than 0.3, and still more preferably equal to or greater than 0.4. When the thickness At is too small, the vibration absorbing effect is reduced, and the strength of the metal member is reduced. From this viewpoint, the ratio (Et/At) is preferably equal to or less than 0.8, and more preferably equal to or less than 0.7.
In the head 2 of the sixth embodiment, the head 100 of the seventh embodiment and the head 120 of the eighth embodiment, the whole of the front surface of the metal member is covered with the elastic member. On the other hand, in the head 130 of the ninth embodiment, the front surface of the metal member is not covered with the elastic member. In the head 130, the front surface of the metal member is directly brought into contact with the double-stick tape. In Comparative Example 2 (
Hereinafter, the effects of the present invention will be clarified by Examples. However, the present invention should not be interpreted in a limited way based on the description of Examples. Evaluation was carried out by the following Test 1, Test 2 and Test 3.
A head having a shape shown in
A head and a club according to Example 2x were obtained in the same manner as in Example 1x except that the double-stick tape was changed to “VHX-802” (trade name) produced by Sumitomo 3M Limited. The thickness of “VHX-802” was 0.25 mm. The “VHX-802” has a four-layered structure. The four layers are an acrylic adhesive layer, an acrylic resin layer which is free of bubbles, a nonwoven fabric layer and an acrylic adhesive layer in this order from an innermost layer.
A head and a club according to Example 3x were obtained in the same manner as in Example 1x except that the double-stick tape was changed to “4393” (trade name) produced by Sumitomo 3M Limited. The thickness of “4393” was 0.20 mm. “4393” has a three-layered structure. The three layers are an acrylic adhesive layer, a polyester film layer and an acrylic adhesive layer in this order from an innermost layer.
A head and a club according to Comparative Example 1x were obtained in the same manner as in Example 1x except that the double-stick tape was changed to “Y-4914” (trade name) produced by Sumitomo 3M Limited. The thickness of “Y-4914” was 0.25 mm. “Y-4914” has a three-layered structure. The three layers are an acrylic adhesive layer, an acrylic form layer and an acrylic adhesive layer in this order from an innermost layer. The acrylic form layer is a resin layer having bubbles.
[Evaluation of Durability]
Each of the clubs was attached to a swing robot produced by Miyamae Kabushiki Kaisha and made to hit golf balls at a head speed of 54 m/s. The state of the head was visually observed every 500 hittings, and the state of the bonded surface of the badge was confirmed. The hitting was finished when the separation was confirmed.
[Results of Evaluation of Durability]
In Example 1x, a part of the bonded surface of the badge was separated when the club is subjected to 9500 times of hitting. In Example 2x, a part of the bonded surface of the badge was separated when the club is subjected to 7000 times of hitting. In Example 3x, a part of the bonded surface of the badge was separated when the club is subjected to 5500 times of hitting. In Comparative Example 1x, a part of the bonded surface of the badge was separated when the club is subjected to 2500 times of hitting.
A head having a shape shown in
In Example 1y, the depth a1y of the recessed part was set to 4 mm, and the thickness T1y of the recessed part was constantly set to 0.5 mm. The thickness T2y of a portion (flat plate part) other than the recessed part was constantly set to 1.0 mm. The projection area S1y of the adherend s1y was set to 15 cm2, and the projection area S2y of the recessed part was set to 5 cm2. The diameter D1y of the maximum inscribed circle was set to 10 mm. The specifications and evaluation results of Example 1y are shown in the following Table 1.
[Evaluation of Durability]
Each of the clubs was attached to a swing robot produced by Miyamae Kabushiki Kaisha and made to hit golf balls at a head speed of 49 m/s. The state of the head was visually observed every 500 hittings, and the state of the bonded surface of the badge was confirmed. The hitting was finished when the separation was confirmed. Evaluation was finished after 10000 hittings. The evaluation results are shown in the following Table 1.
The same head as the head 2 of the sixth embodiment shown in
As a double-stick tape, “Y-4625” (trade name) produced by Sumitomo 3M Limited was used. The double-stick tape formed into the same shape as that of the batch was stuck on the batch, and the batch was stuck on the head body. Then, the batch was pressed to the head body for 10 seconds to obtain the head with the batch. The thickness of “Y-4625” was 0.25 mm. The head was a five-iron. The head was attached to the tip part of a shaft made of CFRP. As the shaft, “MP-400” (trade name) produced by SRI Sports Limited was used. A grip was attached to the back end part of the shaft to obtain a golf club according to Example 1. “Y-4625” has a five-layered structure. The five layers are an acrylic adhesive layer, an acrylic resin layer which is free of bubbles, a nonwoven fabric layer, an acrylic resin layer which is free of bubbles and an acrylic adhesive layer in this order from an innermost layer.
A golf club head and a golf club of each of Examples were obtained in the same manner as in Example 1 except that the values shown in Table 2 were changed. The specifications and evaluation results of Examples 2 and 3 are shown in the following Table 2.
A head of an embodiment of Example 3 is the same as the head 120 shown in
The same head as the head 100 of the seventh embodiment shown in
A golf club head and a golf club of each of Examples were obtained in the same manner as in Example 4 except that the values shown in Table 2 were changed. The specifications and evaluation results of Examples 5 and 6 are shown in the following Table 2.
Example 6 has a back extending part. The thickness t2 of the back extending part of Example 6 is 1.0 mm.
The same head as the head 130 shown in
The metal member used in Example 1 was used as an adherend. The adherend was made of only a metal member. That is, the adherend which is free of an elastic member was used. A head and a club of Comparative Example 1 were obtained in the same manner as in Example 1 except for the matters described above. The specifications and evaluation results of Comparative Example are shown in the following Table 2.
A head body h1 of Comparative Example 2 is the same as that of Example 1.
A metal member 142 has a periphery wall part 142a and a main part 142b. The periphery wall part 142a is circular. The main part 142b has a flat plate shape. The metal member 142 consists of the periphery wall part 142a and the main part 142b. A recessed part r3 is formed by the main part 142b and the periphery wall part 142a. An end face 143 of the periphery wall part 142a is directly brought into contact with a double-stick tape w1.
The metal member 142 of Comparative Example 2 has the recessed part r3. The recessed part r3 is formed on the front surface of the metal member 142. The recessed part r3 is opened to the front of the head 140. The main part 142b constitutes the bottom part of the recessed part r3. The thickness of the main part 142b is 2 mm. The recessed part r3 is filled with an elastic member 144. The depth of the recessed part r3 is 1 mm. The thickness of the elastic member 144 is 1 mm. Therefore, in the following Table 2, a thickness Dt and a thickness Et are described to be 1 mm. The elastic member 144 does not have a peripheral part which abuts on a side surface 146 of the metal member 142 directly or indirectly.
The metal member 142 of the head of Comparative Example 2 is the same as the metal member of Example 4 except for the thickness of the main part 142b.
A head and a club of Comparative Example 2 were obtained in the same manner as in Example 1 except for the matters described above. The specifications and evaluation results of Comparative Example 2 are shown in the following Table 2.
[Feeling Evaluation]
Ten testers hit and evaluated impact shock at the time of hitting balls. Five-step evaluation was carried out based on the following standard. Evaluation was carried out on the basis of Comparative Example 2. The higher scores are, the higher the evaluation is. The average value of ten testers' scores is shown in the following Table 2.
Five score: Impact shock is smaller than that of Comparative Example 2, and hitting feeling is better than that of Comparative Example 2.
Four score: Impact shock is slightly smaller than that of Comparative Example 2, and hitting feeling is slightly better than that of Comparative Example 2.
Three score: Impact shock and hitting feeling are equivalent to those of Comparative Example 2.
Two score: Impact shock is slightly greater than that of Comparative Example 2, and hitting feeling is slightly worse than that of Comparative Example 2.
One score: Impact shock is greater than that of Comparative Example 2, and hitting feeling is worse than that of Comparative Example 2.
As described above, Examples have higher evaluation than those of Comparative Examples. Advantages of the present invention are clearly indicated by these results of evaluation.
The present invention includes a head obtained by combining two or more of aspects selected from the first aspect, the second aspect and the third aspect. That is, the present invention includes a head obtained by combining the first aspect and the second aspect, a head obtained by combining the first aspect and the third aspect, a head obtained by combining the second aspect and the third aspect and a head obtained by combining the first aspect, the second aspect and the third aspect.
The present invention is applicable to all types of golf clubs.
The description hereinabove is merely for an illustrative example, and various modifications can be made in the scope not to depart from the principles of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
2008-200499 | Aug 2008 | JP | national |
2008-290231 | Nov 2008 | JP | national |
2008-327484 | Dec 2008 | JP | national |
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Number | Date | Country |
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2717702 | Sep 1995 | FR |
61-56434 | Mar 1986 | JP |
6-346027 | Dec 1994 | JP |
7-53926 | Feb 1995 | JP |
7-28578 | May 1995 | JP |
8-295856 | Nov 1996 | JP |
9-666 | Jan 1997 | JP |
9-75481 | Mar 1997 | JP |
2792642 | Sep 1998 | JP |
2000-73028 | Mar 2000 | JP |
2000-293124 | Oct 2000 | JP |
2001-212266 | Aug 2001 | JP |
2001-259092 | Sep 2001 | JP |
2002-102397 | Apr 2002 | JP |
2002-533179 | Oct 2002 | JP |
2002-323863 | Nov 2002 | JP |
2006-435 | Jan 2006 | JP |
2006-206621 | Aug 2006 | JP |
2008-45347 | Feb 2008 | JP |
2008-125811 | Jun 2008 | JP |
Entry |
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Japanese Office Action dated Mar. 29, 2011 for Application No. 2008-290231. |
Office Action for corresponding Japanese Application No. 2008-327484 dated Apr. 26, 2011. |
Number | Date | Country | |
---|---|---|---|
20100056296 A1 | Mar 2010 | US |