Golf club head, iron golf club head, wood golf club head, and golf club set

Information

  • Patent Grant
  • 6695712
  • Patent Number
    6,695,712
  • Date Filed
    Friday, December 1, 2000
    24 years ago
  • Date Issued
    Tuesday, February 24, 2004
    20 years ago
Abstract
A golf club head (11) has an ellipsoid of inertia (12) with its center at a center of gravity G. When the ellipsoid of inertia (12) is virtually cut with a plane passing through the center of gravity of the golf club head (11) and being parallel to a face surface (11f), a major axis of a plane ellipse (13) appearing on its cut surface forms an angle of θ with an intersecting line (15) of the cut surface and a ground surface (16). The major axis extends upward and away from the ground surface (16) as it approaches a toe part (11t). The angle θ is not smaller than 0.5° and not larger than 9.5°. An aspect ratio a/b defined by a ratio of the length a of the major axis (13d) to the length b of a minor axis (13e) of the plane ellipse (13) is not smaller than 1 and not larger than 4.
Description




TECHNICAL FIELD




The present invention generally relates to a golf club head, an iron golf club head, a wood golf club head, and a golf club set. Specifically, it relates to a golf club head, an iron golf club head, a wood golf club head that can improve the directivity of a flying ball and increase the flying distance by restraining the rotation of the golf club head in striking a golf ball with the golf club head, and a golf club set using the golf club heads.




BACKGROUND OF THE INVENTION




The first conventional example of a golf club head is described in Japanese Patent Application Laid-open No. 07-67991(1995). In this document, the toe weight and the hosel weight have a center of mass positioned above the horizontal line that passes through the center of gravity of the golf club head when the gold club head is in an addressed position.




Further, the second conventional example is described in Japanese Patent Application Laid-open No. 09-149954(1997). In this document, X-axis, Y-axis, and Z-axis that intersect perpendicularly to each other are set using the center of gravity of the gold club head as an origin. The angle formed by X-axis and the line obtained by projecting onto XZ-plane the principal axis of inertia having the smallest angle with X-axis among the three principal axes of inertia of the golf club head that intersect perpendicularly to each other, is not smaller than 10° and not larger than 40°.




Further, a wood golf club as the third conventional example is described in Japanese Patent Application Laid-open No. 01-300970(1989). This document discloses a technique of providing a horizontal principal axis of inertia by setting the weight of the hosel part to be not larger than 5% of the weight of the golf club head body and setting the length of the hosel part to be not larger than 4 cm.




Further, as a technique for improving the directivity of a hit ball, a technique of increasing the moment of inertia of a golf club head is known. As the fourth conventional example, a so-called cavity structure is known in which a cavity part is provided in the inside of an iron golf club head body and the peripheral part is made thick to increase the moment of inertia. Also, as the fifth conventional example, a hollow structure is known in which the inside of an iron golf club head is made into a complete cavity.




The flying distance and the directivity of a hit ball may be mentioned as the characteristics required in a golf club. Particularly, the directivity is a great factor that is related to fairway keep and green keep, and gives an influence on the score. The directivity is determined by the position (hitting point position) at which the golf club head is brought into contact with a golf ball. Apart from professional golfers and top amateurs, most of the general players strike the golf ball at various locations on the upper side, the lower side, the right side, and the left side of the face surface of the golf club head. For this reason, the directivity of the hit ball decreases if the golf ball impinges on the position out of the center of gravity, although the directivity of the hit ball is good if the golf ball impinges on a neighborhood of the center of gravity of the golf club head.




Thus, in order to prevent decrease in the directivity even if the golf ball impinges on a position located away from the center of gravity of the golf club head, a method of increasing the moment of inertia of the golf club head, particularly the moment of inertia in the direction from the toe part to the heel part of the golf club when the golf club head is placed on a plane, is proposed.




The first conventional example does not disclose a technique of restraining the rotation of the golf club head at the time of striking. The second conventional example does not disclose a technique of restraining the rotation of the golf club head at the time of striking, either.




Also, the distribution shape of the variation of the points at which: the golf ball impinges on the face surface has a width in the up-and-down direction of the face surface. Further, the shape of the variation changes depending on the golf clubs having different identification numbers. For this reason, it is necessary not only to improve the directivity of the hit ball in the right-and-left direction but also to reduce the variation of the flying distance.




Furthermore, the aforesaid third example involves a problem that the variation of the flying distance of the hit ball cannot be reduced.




Further, even the aforesaid fourth and fifth conventional examples fail to disclose a technique of restraining the rotation of the golf club head.




Therefore, the object of the present invention is to provide a golf club head and a golf club set that can reduce the variation of the hit ball in the right-and-left direction and the variation of the flying distance.




DISCLOSURE OF THE INVENTION




A golf club head according to one aspect of the present invention has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, the major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.5° and not larger than 9.5°. An aspect ratio a/b defined by a ratio of the length a of the major axis to the length b of the minor axis is not smaller than 1 and not larger than 4.




A golf club set according to one aspect of the present invention includes a plurality of golf clubs having different identification numbers. Each of the plurality of golf clubs has a golf club head and a shaft connected to the golf club head. Each of the golf club heads has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, the major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.5° and not larger than 9.5°. An aspect ratio a/b defined by a ratio of the length a of the major axis to the length b of the minor axis is not smaller than 1 and not larger than 4. The angle θ of each of the plurality of golf club heads increases successively or remains approximately equal according as the identification number increases. The aspect ratio a/b of each of the plurality of golf club heads decreases successively or remains approximately equal according as the identification number increases.




Preferably, the angle θ increases successively with an approximately constant ratio according as the identification number of the golf club head increases.




Also, preferably, the aspect ratio a/b decreases successively with an approximately constant ratio according as the identification number of the golf club head increases.




A golf club head according to another aspect of the present invention has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, the major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.50 and not larger than 9.5°. The height h of a sweet spot from the ground surface is not smaller than 10 mm and not larger than 30 mm.




A golf club set according to another aspect of the present invention includes a plurality of golf clubs having different identification numbers. Each of the plurality of golf clubs has a golf club head and a shaft connected to the golf club head. Each of the golf club heads has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, the major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.5° and not larger than 9.5°. The angle θ of each of the plurality of golf club heads increases successively or remains approximately equal according as the identification number increases. The height h of the sweet spot of each of the plurality of golf club heads decreases successively or remains approximately equal according as the identification number increases.




Also, preferably, the angle θ increases successively with an approximately constant ratio according as the identification number of the golf club increases.




Also, preferably, the height h of the sweet spot decreases successively with an approximately constant ratio according as the identification number of the golf club increases.




A golf club head according to still another aspect of the present invention has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, an aspect ratio a/b defined by a ratio of the length a of the major axis to the length b of the minor axis of a plane ellipse appearing on its cut surface is not smaller than 1 and not larger than 4. The height h of a sweet spot from the ground surface is not smaller than 10 mm and not larger than 30 mm.




Also, preferably, the major axis forms an angle of θ with an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.5° and not larger than 9.5°.




A golf club set according to still another aspect of the present invention includes a plurality of golf clubs having different identification numbers. Each of the plurality of golf clubs has a golf club head and a shaft connected to the golf club head. Each of the golf club heads has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, an aspect ratio a/b defined by a ratio of the length a of the major axis to the length b of the minor axis of a plane ellipse appearing on its cut surface is not smaller than 1 and not larger than 4. The height h of a sweet spot from the ground surface is not smaller than 10 mm and not larger than 30 mm. The aspect ratio a/b of each of the plurality of golf club heads decreases successively or remains approximately equal according as the identification number increases. The height h of the sweet spot of each of the plurality of golf club heads decreases successively or remains approximately equal according as the identification number increases.




Also, preferably, the major axis forms an angle of θwith an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.5° and not larger than 9.5°. The angle θ of each of the plurality of golf club heads increases successively or remains approximately equal according as the identification number increases.




Also, preferably, the aspect ratio a/b decreases successively with an approximately constant ratio according as the identification number of the golf club increases.




Also, preferably, the height h of the sweet spot decreases successively with an approximately constant ratio according as the identification number of the golf club increases.




Also, preferably, the angle θ increases successively with an approximately constant ratio according as the identification number of the golf club increases.




An iron golf club head according to the present invention includes a head body having a toe, a sole, and a heel; a first weight member disposed in an upper part of the toe of the head body; and a second weight member disposed in a heel side part of the sole of the head body.




Preferably, the first weight member has a larger specific gravity than a material constituting the head body.




Preferably, the second weight member has a larger specific gravity than a material constituting the head body.




Preferably, the first weight member has a larger density than other parts of the head body.




Preferably, the second weight member has a larger density than other parts of the head body.




Preferably, the head body has a back cavity.




Preferably, the depth of the back cavity increases according as it approaches from a lower part of the toe to a heel part.




Preferably, the width of a sole part decreases according as it approaches from a lower part of the toe to a heel part.




Preferably, the head body has a through-hole, and further includes an insert member fitted into the through-hole so as to form a back cavity.




A wood golf club head according to the present invention includes a head body having a toe, a sole, and a back; a first weight member disposed in an upper part of the toe of the head body; and a second weight member disposed in a back part of the center of the sole of the head body.




Preferably, the first weight member has a larger specific gravity than a material constituting the head body.




Preferably, the second weight member has a larger specific gravity than a material constituting the head body.




Preferably, the first weight member includes a part having a larger thickness than other parts of the head body.




Preferably, the second weight member includes a part having a larger thickness than other parts of the head body.




Preferably, the first weight member has a larger density than other parts of the head body.




Preferably, the second weight member has a larger density than other parts of the head body.




Preferably, the first weight member includes a part having a larger specific gravity than a material constituting the head body, and a part having a larger thickness than other parts of the head body.




Preferably, the second weight member includes a part having a larger specific gravity than a material constituting the head body, and a part having a larger thickness than other parts of the head body.




Preferably, the first and second weight members have a larger specific gravity than a material constituting the head body.











BRIEF DESCRIPTION OF THE DRAWINGS





FIGS. 1A and 1B

are views for explaining the principle of the present invention.





FIGS. 2A and 2B

are views showing a distribution of hitting points when a general player hits a ball with a third iron.





FIGS. 3A and 3B

are views showing a distribution of hitting points when a general player hits a ball with a sixth iron.





FIGS. 4A and 4B

are views showing a distribution of hitting points when a general player hits a ball with a ninth iron.





FIG. 5

is a view showing a relationship between an ellipsoid of inertia of a golf club head and XYZ-axes.





FIGS. 6A

to


6


C are views showing a cut ellipse surface appearing when the ellipsoid of inertia is cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface.





FIG. 7

is a view showing direction vectors in the cut ellipse surface.





FIGS. 8A and 8B

are views showing a variation of the flying distance by a club head according to an embodiment of the present invention.





FIGS. 9A and 9B

are views showing a variation of the flying distance by a conventional club head.





FIGS. 10A and 10B

are views showing an embodiment of the present invention.





FIGS. 11A and 11B

are views showing an example in which the aspect ratio and the direction of the axis are changed by the head shape.





FIGS. 12A and 12B

are views showing an example in which the aspect ratio and the direction of the axis are changed by a head shape.





FIGS. 13A and 13B

are views showing an example in which the aspect ratio and the direction of the axis are changed by the face shape.





FIGS. 14A and 14B

are views showing an example in which the aspect ratio is changed by the face shape and the direction of the axis is changed by the neck length.





FIGS. 15A and 15B

are views showing an example in which the aspect ratio and the direction of the axis are changed by disposing predetermined weights on the upper side of the toe and on the heel sole side.





FIGS. 16A

to


16


D are views showing an example in which the aspect ratio and the direction of the axis are changed by changing the thickness of the top edge on the toe side and changing the width of the sole on the heel side.





FIGS. 17A and 17B

are views showing an example in which the aspect ratio and the direction of the axis are changed by changing the angle of the top edge to the intersecting line of the cut surface and the ground surface.





FIGS. 18A and 18B

are views showing an example in which the aspect ratio and the direction of the axis are changed by changing the ratio of the height on the toe side to the height on the heel side.





FIGS. 19A

to


19


D are views showing an example in which the aspect ratio is changed by approximating the head shape to a sphere, and the axis is tilted by changing the thickness of the upper toe and the thickness of the lower heel.





FIGS. 20A and 20B

are views showing an example in which the axis is tilted and the sweet spot is lowered by decreasing the neck length and increasing the neck diameter according as it becomes a short iron.





FIGS. 21A and 21B

are views showing an example in which the axis is tilted and the sweet spot is lowered by increasing the weight of the lower heel.





FIGS. 22A and 22B

are views showing an example in which the axis is tilted and the sweet spot is lowered by decreasing the length of the neck and increasing the thickness of the sole on the heel side.





FIGS. 23A and 23B

are views showing an example in which the axis is tilted and the sweet spot is lowered by increasing the thickness of the sole of a short wood as compared with a driver.





FIGS. 24A and 24B

are views showing an example in which the direction of the axis is changed and the sweet spot is lowered by disposing a predetermined weight in the inside of the heel side head on the upper side of the sole.





FIGS. 25A and 25B

are views showing an example in which the direction of the axis is tilted and the sweet spot is lowered by increasing the thickness of the lower part of the back side heel of a short iron.





FIGS. 26A and 26B

are views showing an example in which the aspect ratio is changed and the sweet spot is lowered by changing the face surface heel height and the heel part crown height of a driver and a short wood.





FIGS. 27A and 27B

are views showing an example in which the aspect ratio is changed and the sweet spot is lowered by decreasing the back part heel height and changing the heel part crown height.





FIGS. 28A and 28B

are views showing an example in which the aspect ratio is changed and the sweet spot is lowered by disposing a predetermined weight in the lower part of the sole.





FIGS. 29A and 29B

are views showing an example in which the aspect ratio and the head length are changed and the sweet spot is lowered by changing the thickness of the cavity on the back side.





FIGS. 30A and 30B

are views showing an example in which the aspect ratio is changed and the sweet spot is lowered by changing the height of the power blade on the cavity sole on the back side.





FIGS. 31A and 31B

are views showing an example in which the aspect ratio is changed and the sweet spot is lowered by changing the lengths of the most protruding part on the head toe side and the heel end part of the sole and changing the neck length.





FIGS. 32A and 32B

are views showing an example in which the aspect ratio is changed and the sweet spot is lowered by increasing the sole thickness and allowing the sole thicknesses of a long iron and a short iron to have a predetermined relationship.





FIG. 33A

is a view showing a relationship between the identification number of an iron golf club and the aspect ratio.





FIG. 33B

is a graph showing a relationship between the identification number of an iron golf club and an angle Δ formed by the major axis of a plane ellipse that approximates the variation of the hitting points.





FIG. 33C

is a graph showing a relationship between the identification number of an iron golf club and the height H of the hitting point center.





FIGS. 34A and 34B

are views for explaining the principle of an iron golf club head according to the present invention.





FIGS. 35A and 35B

are views showing a distribution of the hitting points of a general player with a third iron.





FIGS. 36A and 36B

are views showing a distribution of the hitting points of a general player with a sixth iron.





FIGS. 37A and 37B

are views showing a distribution of the hitting points of a general player with a ninth iron.





FIG. 38

is a view for explaining the ellipsoid of inertia of an iron golf club head according to the present invention and the X-axis, Y-axis, Z-axis.





FIGS. 39A

to


39


C are views for explaining the ellipsoid of inertia of an iron golf club head according to the present invention and the a-axis, β-axis, γ-axis.





FIG. 40

is a view for explaining the ellipsoid of inertia of an iron golf club head according to the present invention and the direction vectors.





FIG. 41

is a perspective view showing an Example of an iron golf club head according to the present invention.





FIG. 42

is a perspective view showing an Example of an iron golf club head according to the present invention.





FIG. 43A

is a perspective view showing an Example that clearly describes a cut part of an iron golf club head according to the present invention.





FIGS. 43B

to


43


E are cross section views of an essential part showing cross sections of the A′—A′ part to the D′—D′ part in FIG.


43


A.





FIG. 44

is a view showing hitting point positions of an iron golf club head.





FIG. 45A

is a graph showing a flying distance and a variation of an iron golf club head according to the present invention.





FIG. 45B

is a graph showing a flying distance and a variation of a conventional iron golf club head.





FIGS. 46A and 46B

are views for explaining the principle of an iron golf club head according to the present invention.





FIGS. 47A and 47B

are views showing a distribution of the hitting points of a general player with a third iron.





FIGS. 48A and 48B

are views showing a distribution of the hitting points of a general player with a sixth iron.





FIGS. 49A and 49B

are views showing a distribution of the hitting points of a general player with a ninth iron.





FIG. 50

is a view for explaining the ellipsoid of inertia of an iron golf club head according to the present invention and the X-axis, Y-axis, Z-axis.





FIGS. 51A

to


51


C are views for explaining the ellipsoid of inertia of an iron golf club head according to the present invention and the α-axis, β-axis, γ-axis.





FIG. 52

is a view for explaining the ellipsoid of inertia of an iron golf club head according to the present invention and the direction vectors.





FIG. 53

is a perspective view showing an Example of an iron golf club head according to the present invention.





FIG. 54

is a perspective view showing an Example of an iron golf club head according to the present invention.





FIG. 55A

is a perspective view showing an Example that clearly describes a cut part of an iron golf club head according to the present invention.





FIGS. 55B

to


55


E are cross section views of an essential part showing cross sections of the A″—A″ part to the D″—D″ part in FIG.


55


A.





FIG. 56

is a view showing hitting point positions of an iron golf club head.





FIG. 57

is a graph showing a flying distance and a variation of an iron golf club head according to the present invention.





FIG. 58

is a graph showing a flying distance and a variation of a conventional iron golf club head.





FIGS. 59A and 59B

are views for explaining the principle of a wood golf club head according to the present invention.





FIGS. 60A and 60B

are views showing a distribution of the hitting points of a general player with a wood golf club head.





FIG. 61

is a view for explaining the ellipsoid of inertia of a wood golf club head according to the present invention and the X-axis, Y-axis, Z-axis.





FIGS. 62A

to


62


C are views for explaining the ellipsoid of inertia of a wood golf club head according to the present invention and the a-axis, β-axis, γ-axis.





FIG. 63

is a view for explaining the ellipsoid of inertia of a wood golf club head according to the present invention and the direction vectors.





FIG. 64

is a front view showing an Example of a wood golf club head according to the present invention.





FIG. 65

is a perspective view including a partial cross section showing an Example of a wood golf club head according to the present invention.





FIGS. 66

to


76


are cross section views showing an Example of a wood golf club head according to the present invention.





FIGS. 77 and 78

are perspective views showing an Example of a wood golf club head according to the present invention.





FIG. 79

is a left view showing an Example of a wood golf club head according to the present invention.





FIG. 80

is a perspective view of a back surface showing an Example of a wood golf club head according to the present invention.





FIGS. 81A and 81B

are views showing a ratio of the major axis to the minor axis and an extending direction of the major axis of a plane ellipse appearing when the ellipsoids of a wood golf club head according to the present invention and a conventional wood golf club head are virtually cut with a face surface.





FIG. 82

is a view showing hitting point positions of a wood golf club head.





FIG. 83

is a graph showing a flying distance and a variation of a wood golf club head according to the present invention.





FIG. 84

is a graph showing a flying distance and a variation of a conventional wood golf club head.











BEST MODES FOR CARRYING OUT THE INVENTION





FIGS. 1A and 1B

are views for explaining the principle of the present invention.

FIG. 1A

is a view for explaining a striking force generated on a face surface when a golf ball is hit with a golf club head.

FIG. 1B

is a view showing a state in which the face is rotated and the ball flies out at the striking time.




Referring to

FIG. 1A

, when a golf ball is struck with a golf club, a golf club head


11


receives a striking force F from the golf ball


2


in the proceeding direction of the swing at the hitting point position of the golf ball. In the golf club, an angle is formed between a sole and a face surface


11




f


in order to change the flying-out angle of the golf ball


2


in accordance with the identification number and to obtain a flying distance for each identification number. This angle is referred to as a loft angle. Typically, the loft angle is set to be about 10° in the case of a driver, about 20° in the case of a third iron, and about 40° in the case of a ninth iron. The loft angle increases according as the identification number increases.




Due to the presence of the loft angle, the striking force F at the striking time can be decomposed into a horizontal partial force FH and a perpendicular partial force FP with respect to the face surface


11




f


. The horizontal partial force FH is a force that rotates the golf ball


2


together with a frictional force of the face surface


11




f


, namely, it generates a back spin or a side spin. According as the swing speed increases and the impacting speed of the golf club head increases, the striking force F increases and the horizontal partial force FH increases, so that the back spin and the side spin are more likely to be generated. The ball trajectory of an iron of a professional golfer rises high above after the shot, and then falls vertically from above. This is due to the fact that, since the head speed is high, a back spin is generated, and the ball floats upward and falls down.




Also, the perpendicular partial force FP is a force that acts perpendicularly on the face surface


11




f


, as shown in

FIG. 1B

, and this force rotates the face surface


11




f


. By this rotation, the golf ball


2


after the shot flies out in the right-and-left direction and in the up-and-down direction. On the other hand, the point at which the line drawn perpendicularly from the center of gravity G of the golf club head


11


to the face surface


11




f


intersects the face surface


11




f


here is referred to as a sweet spot SS. The sweet spot SS is a point by which the golf ball flies most and, if the ball is struck here, the golf club head


11


rotates little. However, if a general players performs a shot, the ball hardly hits the sweet spot SS, and the player performs a shot in the neighborhood of the sweet spot SS.





FIGS. 2A

to


4


B are views showing a distribution of the hitting points of a general player.

FIGS. 2A and 2B

show a distribution of the hitting points by a third iron golf club.

FIGS. 3A and 3B

show a distribution of the hitting points by a sixth iron golf club.

FIGS. 4A and 4B

show a distribution of the hitting points by a ninth iron golf club. As will be clear from

FIGS. 2A

to


4


B, it is understood that a general player strikes at various positions up and down and to the right and left near the sweet spot SS. The player from whom these data have been obtained has a golf score of about 100 and is an average player. In the Figures, the points


3




b


,


6




b


, and


9




b


represent hit marks on the face surfaces


3




f


,


6




f


, and


9




f


of the golf club heads


3


,


6


, and


9


. The hitting point centers are represented by points


3




c


,


6




c


, and


9




c


. Ellipses


3




a


,


6




a


, and


9




a


that approximate the size and the shape of the hitting point distribution by determining an interval covering not less than 95% of the hit marks are shown in a solid line. Further, the A-axis passing through the hitting point centers


3




c


,


6




c


, and


9




c


of the face surfaces


3




f


,


6




f


, and


9




f


and being parallel to the intersecting line of the face surfaces


3




f


,


6




f


, and


9




f


and the ground surface, as well as the major axes


3




d


,


6




d


, and


9




d


of the ellipses


3




a


,


6




a


, and


9




a


approximating the variation of the hitting points, are shown in solid lines.




From this result, the player strikes a golf ball at various locations up and down and to the right and left of the face surfaces


3




f


,


6




f


, and


9




f


of the golf club heads


3


,


6


, and


9


. It is understood that the hitting points are varied in the right-and-left direction from the toe side to the heel side and in the up-and-down direction from the leading edge to the top edge. Since this variation degrades the directivity of the ball after hitting the ball, it is necessary to produce a golf club head that maintains the directivity to some extent even if the hitting points are varied.




On the other hand, as will be seen from the results of the hitting point distribution, the shape of the hitting point distribution is a shape of the ellipses


3




a


,


6




a


, and


9




a


having a major axis and a minor axis. Further, the angle that the major axes


3




d


,


6




d


, and


9




d


form with the A-axis is an angle such that the major axes


3




d


,


6




d


, and


9




d


extend upward and away from the ground surface as they approach the toe parts


3




t


,


6




t


, and


9




t


. In other words, the major axes


3




d


,


6




d


, and


9




d


extend in a toe-up direction. Further, as the identification number increases, the angle that the major axes


3




d


,


6




d


, and


9




d


form with the A-axis increase successively. Also, the shape of the ellipses


3




a


,


6




a


, and


9




a


successively approaches a circular shape. Further, it is understood that the height H of the hitting point centers


3




c


,


6




c


, and


9




c


from the ground surface decreases, as shown in

FIGS. 2A

to


4


B. Thus, it is understood that the shape of the hitting point distribution of a general player has a specific tendency.




In other words, from the aforesaid distribution of the hitting points, the hitting points are located approximately within the ellipses


3




a


,


6




a


, and


9




a


having a major axis and a minor axis. The angle Δ that the major axes


3




d


,


6




d


, and


9




d


of the ellipses form with the A-axis extending parallel to the intersecting line of the face surfaces


3




f


,


6




f


, and


9




f


and the ground surface, approaches the toe parts


3




t


,


6




t


, and


9




t


. Also, according as the identification number increases, the angle Δ successively increases, and the shape of the ellipses successively approaches a circular shape. Further, the height H of the points


3




c


,


6




c


, and


9




c


representing the hitting point centers decrease.




The inertial resistance in the direction perpendicular to the face surface of the golf club head can be determined as follows.





FIG. 5

is a view showing a relationship between the ellipsoid of inertia of a golf club head and X-axis, Y-axis, Z-axis. Referring to

FIG. 5

, the axis passing through the center of gravity G and being perpendicular to the ground surface is assumed to be the Z-axis. The axis passing through the center of gravity G and being perpendicular to the Z-axis and parallel to the intersecting line of the tangential plane at the centroid (center) of the face surface


11




f


and the ground surface, is assumed to be the X-axis. The tangential surface at the centroid (center) of the face surface


11




f


is approximately the same surface as the face surface


11




f


. The axis passing through the center of gravity G and being perpendicular to both the X-axis and the Z-axis is assumed to be the Y-axis.





FIG. 7

is a view showing direction vectors on an ellipse plane appearing when the ellipsoid of inertia is cut. Referring to

FIG. 7

, the direction vector of a plane passing through the center of gravity G and being parallel to the intersecting line of the tangential plane at the centroid of the face surface


11




f


and the ground surface is assumed to be f(l, m, n)


T


, and each of the following vectors is calculated.








f




1


(


l




1




, m




1




, n




1


)


T=




f X Z


(0, 0, 1)


T












f




2


(


l




2




, m




2




, n




2


)


T=




f




1




X f












f




3


(


l




3




, m




3




, n




3


)


T=




f




1




X f




2


  (1)






where X designates an outer product.





FIGS. 6A

,


6


B, and


6


C are views showing cut surfaces when the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of a golf club head and being parallel to the face surface. Referring to

FIGS. 6A

,


6


B, and


6


C, the axis passing through the center of gravity G and being parallel to the intersecting line of the tangential plane at the centroid of the face surface


11




f


and the ground surface is assumed to be α-axis. The axis being parallel to the tangential plane at the centroid of the face surface


11




f


and perpendicular to the α-axis is assumed to be β-axis. The axis being perpendicular to the α-axis and the β-axis is assumed to be γ-axis. The conversion from the α, β, γ coordinate system to the X, Y, Z coordinate system is represented by the following equations.








X=l




1




·α+l




2




·β+l




3


·γ










Y=m




1




·α+m




2




·β+m




3


·γ










Z=n




1




·α+n




2




·β+n




3


·γ  (2)






Here, supposing that I


1


, I


2


, I


3


are moments of inertia with respect to the X, Y, Z axes, I


12


is a product of inertia with respect to the YZ-plane and the XZ-plane, I


13


is a product of inertia with respect to the YZ-plane and the XY-plane, I


23


is a product of inertia with respect to the XZ-plane and the XY-plane, then the following relationship is obtained.







I




1




·X




2




+I




2·Y




2




+I




3




·Z




2


+2


·I




12




·X·Y


+2


·I




13




·X·Z


+2


·I




23·




Y·Z


=1  (3)




The ellipsoid represented by the equation (3) is referred to as an ellipsoid of inertia. This shows the magnitude of the inertial resistance in each direction. Substituting the equation (3) with the equation (2) and letting the γ term zero, the equation (4) of the cut ellipse plane is determined.






(


I




1




l




1




2




+I




2




m




1




2




+I




3




n




1




2




+I




12




l




1




m




1




+I




13




l




1




n




1




+I




23




m




1




n




1





2










+(


I




1




l




2




2




+I




3




m




2




2




+I




3




n




2




2




+I




12




l




2




m




2




+I




13




l




2




n




2




+I




23




m




2




n




2





2










+(


I




1




l




1




l




2




+I




2




m




1




m




2




+I




3




n




1




n




2




+I




12




l




1




m




2




+I




12




l




2




m




1




+I




13




l




1




n




2




+I




13




l




2




n




1










+


I




23




m




1




n




2




+I




23




m




2




n




1


)αβ=1  (4)






The magnitude of the cut surface represents the magnitude of the inertial resistance indicating the facility of rotation of this surface. Also, the cut surface represents the inertial resistance in the direction perpendicular to the cut surface. Further, as shown in

FIGS. 6A

,


6


B, and


6


C, it is apparent that the shape of the cut surface is a plane ellipse because it is a cut surface of a three-dimensional ellipsoid of inertia.




The plane ellipse appearing when the ellipsoid of inertia


12


of the golf club head


11


is cut with the face surface


11




f


represents the facility of the rotation in the perpendicular direction with respect to the face surface


11




f


. Also, in the plane ellipse


13


appearing on the cut surface when the ellipsoid of inertia


12


is cut with a plane passing through the center of gravity G and being parallel to the face surface


11




f


, the length of the major axis


13




d


, is represented by a and the length of the minor axis


13




e


is represented by b. The aspect ratio is defined by a/b. The angle formed by the major axis


13




d


, and the α-axis is assumed to be θ.




The distribution of the hitting points of the player shown in

FIGS. 2A

to


4


B has an elliptic shape with its center at the center of hitting points. Further, the major axes


3




d


,


6




d


, and


9




d


extend to go away from the ground surface as they approach the toe parts


3




t


,


6




t


, and


9




t


. In other words, in the third iron golf club head


3


shown in

FIGS. 2A and 2B

, the angle Δ formed by the A-axis on the face surface


3




f


and the major axis


3




d


, of the ellipse


3




a


is 5°. In the sixth iron golf club head


6


shown in

FIGS. 3A and 3B

, the angle Δ formed by the A-axis on the face surface


6




f


and the major axis


6




d


of the ellipse


6




a


is 7°. In the ninth iron golf club head


9


shown in

FIGS. 4A and 4B

, the angle Δ formed by the A-axis of the golf club head


9


on the face surface


9




f


and the major axis


9




d


of the ellipse


9




a


is 9°.




Therefore, by allowing the sweet spot to be approximately coincident with the center of the plane ellipse appearing when the ellipsoid of inertia


12


is virtually cut with the face surface


11




f


, the distance between the hitting points and the sweet spot can be made as small as possible even if the hitting points are varied. This can restrain the rotation of the golf club head. Further, since the ball is hit in the neighborhood of the sweet spot, the initial velocity of the ball is improved to increase the flying distance.




Furthermore, by allowing the angle θ formed by the major axis


13




d


, of the plane ellipse


13


shown in FIG.


6


B and the intersecting line


15


of the cut surface and the ground surface to be coincident with the angle Δ formed by the A-axis and the major axes


3




d


,


6




d


, and


9




d


of the ellipses


3




a


,


6




a


, and


9




a


indicating the hitting point distribution shown in

FIGS. 2A

to


4


B, the deviation of the golf club head in the up-and-down direction and the right-and-left direction can be restrained. Further, the major axis


13




d


, of the ellipse


13


, like the major axes


3




d


,


6




d


, and


9




d


, is set to extend away from the ground surface as it approaches the toe part


1


it. Further, by allowing the aspect ratio which is the ratio of the length a of the major axis


13




d


, and the length b of the minor axis


13




e


of the ellipse


13


, to be coincident with the aspect ratio a′/b′ of the ellipses


3




a


,


6




a


, and


9




a


indicating the hitting point distribution of a general player, the inertial resistance in the up-and-down direction and the inertial resistance in the right-and-left direction are allowed to conform to the variation of the hitting points of the general player. This can not only restrain the lateral deviation of the golf club head in the right-and-left direction but also restrain the variation of the flying distance in the flying ball line direction.




According as the identification number increases, the angle θ shown in

FIG. 6B

is successively increased. Also, the aspect ratio a/b is successively decreased according as the identification number of the golf club head increases. Also, the height h of the sweet spot from the ground surface


16


shown in

FIG. 6C

is successively decreased according as the identification number of the golf club head increases. By constructing a golf club set using these golf club heads, the variation of the flying distance in the right-and-left direction and the flying ball line direction can be restrained for a golf club of any identification number, whereby the flying distance can be increased by improving the speed of the ball.




Next, specific embodiments of the present invention will be explained.




A golf club head and set of an embodiment of the present invention includes the following constituent elements.




A golf club head according to the present invention has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to a face surface, the major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of the cut surface and the ground surface. The major axis extends upward and away from the ground surface as it approaches a toe part. The angle θ is not smaller than 0.5° and not larger than 9.5°. An aspect ratio a/b defined by a ratio of the length a of the major axis to the length b of the minor axis is not smaller than 1 and not larger than 4.




In a golf club set according to the present invention, the angle θ increases successively or remains approximately equal according as the identification number increases. The aspect ratio a/b decreases successively or remains approximately equal according as the identification number increases. The height h of the sweet spot decreases successively or remains approximately equal according as the identification number increases.




Also, these golf club head and golf club set can be produced from iron, stainless steel, aluminum, titanium, magnesium, tungsten, copper, nickel, zirconium, cobalt, manganese, zinc, silicon, tin, chromium, FRP (fiber reinforced plastics), synthetic resin, ceramics, or rubber or the like, which are materials often used in generally producing a golf club head. It may be produced from a single material of these or may be fabricated from a combination of two or more kinds of these materials.




As a production method, use of a precision casting method is preferable because the cost will be low and the dimension precision is high. In addition, the head body can be produced by die-casting, pressing, or forging. It is also possible to produce each of the parts by pressing, forging, precision casting, metal injection, die-casting, cut-processing, powder-metallurgy, or the like and bonding these by welding, adhesion, press-fit, fitting engagement, press-contact, screwing, soldering, or the like to fabricate a golf club head.




Next, with the use of an actual golf club, the fact that the product of the present invention produces a more excellent effect than a conventional product was verified.















TABLE 1










Aspect ratio




Angle Δ formed








a‘/b’ of a




by the ground surface and







Identificati




plane ellipse




the major axis of a plane




Height H of






on number




approximating the




ellipse approximating the




the center of






of a golf




variation of




variation of




hitting points






club (iron)




hitting points




hitting points (°)




(mm)


























I-3




2.1




5




21






I-6




2




7




19.5






I-9




1.9




9




18














Table 1 is a data showing a relationship between the identification number of the golf club heads shown in

FIGS. 2A

to


4


B and the variation of the hitting points. From Table 1, for example, in the third iron golf club, the aspect ratio (the length of the major axis


3




d


/ the length of the minor axis) of the ellipse


3




a


approximating the variation of the hitting points is 2.1; the angle formed between the axis A and the major axis


3




d


, is 5°; and the height H of the hitting point center from the ground surface is 21 mm.





FIG. 8B

is a front view of a golf club head according to the present invention. A golf club head


20


shown in

FIG. 8B

was fabricated on the basis of this data. The golf club head


20


has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head


20


and being parallel to the face surface


20




f


, the angle θ formed by the major axis


25


of the plane ellipse appearing on the cut surface and the intersecting line of the cut surface and the ground surface was set to be 5°. Further, the major axis


25


was set to extend upward and away from the ground surface as it approaches a toe part


20




t


. Further, the aspect ratio a/b defined by a ratio of the length a of the major axis to the length b of the minor axis of the plane ellipse obtained by cutting the ellipsoid of inertia was set to be 2.1. Furthermore, the height h of the sweet spot was set to be 21 mm.





FIG. 9B

is a front view of a conventional golf club head. A conventional golf club head


30


shown in

FIG. 9B

was prepared. The golf club head


30


has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head


30


and being parallel to the face surface


30




f


, the angle formed by the major axis


35


of the plane ellipse appearing on the cut surface and the intersecting line of the cut surface and the ground surface was set to be 2°. However, the major axis


35


was set to extend to approach the ground surface as it approaches a toe part


30




t


. Further, the height of the sweet spot from the ground surface was set to be 20 mm. Here, the masses of the golf club heads


20


and


30


shown in

FIGS. 8B and 9B

were each set to be 248 g.




A shaft was attached to the golf club head


20


to make a golf club. This golf club was mounted on a golf robot, and balls were struck by setting the speed of the golf club head to be 37 m/sec. In order to allow the hitting point position to correspond to the variation of the hitting points of a player, the balls were struck at the upper toe part


21


, the lower toe part


22


, the upper heel part


23


, and the lower heel part


24


.




Here, the upper toe part


21


is distant by 12 mm in the direction from the sweet spot to the toe part


20




t


and by 6 mm in the upward direction. The lower toe part


22


is distant by 12 mm in the direction from the sweet spot to the toe part


20




t


and by 6 mm in the downward direction. The upper heel part


23


is distant by 12 mm in the direction from the sweet spot to the heel part


20




h


and by 6 mm in the upward direction. The lower heel part


24


is distant by 12 mm in the direction from the sweet spot to the heel part


20




h


and by 6 mm in the downward direction.




Also, with the golf club head


30


shown in

FIG. 9B

, balls were struck at the upper toe part


31


, the lower toe part


32


, the upper heel part


33


, and the lower heel part


34


similar to the upper toe part


21


, the lower toe part


22


, the upper heel part


23


, and the lower heel part


24


of

FIG. 8B

, and with a head speed similar to that of the golf club head


20


shown in FIG.


8


B. The results of these are shown in

FIGS. 8A and 9A

.





FIG. 8A

is a graph showing a flying distance and a variation of the lateral deviation generated when the balls are struck with the golf club according to the embodiment of the present invention.

FIG. 9A

is a graph showing a flying distance and a variation of the lateral deviation generated when the balls are struck with a conventional golf club. The point


21




a


of

FIG. 8A

is a data showing a flying distance and a lateral deviation of the golf balls struck at the upper toe part


21


of FIG.


8


B. Also, the points


22




a


to


24




a


are points showing a flying distance and a lateral deviation of the golf balls struck at the lower toe part


22


, the upper heel part


23


, and the lower heel part


24


, respectively. Similarly, the points


31




a


to


34




a


of

FIG. 9A

are points showing a flying distance and a lateral deviation of the golf balls struck at the upper toe part


31


, the lower toe part


32


, the upper heel part


33


, and the lower heel part


34


shown in FIG.


9


B.




From

FIGS. 8A and 9A

, it is understood that, with the golf club head


20


according to the present invention, the variation of the flying distance and the lateral deviation in the right-and-left direction are restrained as compared with the conventional golf club head


30


that does not take the variation of the hitting points of the general players into account. Specifically, while the variation of the hit balls to the right and the left is about 6 m with the golf club head


30


, the variation in the right-and-left direction is about


4


m with the golf club head


20


of the present invention, whereby the distance of the variation could be reduced by 33%.




Also, when the variation in the flying ball line direction (the variation in the flying distance) is compared, the variation of the flying distance is about 9 m in the case of the golf club head


20


of the present invention, while the variation of the flying distance is about 23 m in the case of the golf club head


30


. Therefore, the variation of the flying distance can be reduced by 61%. Further, when the average flying distance is compared, while the golf club head


30


gives an average flying distance of 149.6 m, the golf club head


20


of the present invention gives an average flying distance of 151.2 m, whereby the increase of about 2 m in the flying distance has been obtained. Here,

FIGS. 8A and 9A

show an average value when balls were hit for six times with each golf club head.




Also, when one takes a look at the result of striking at the upper toe parts


21


and


31


, it is understood that there is a difference in the rotation performance of golf club heads. In other words, with the golf club head


30


, the decrease in the flying distance in the flying ball line direction caused by the striking at the upper toe part


31


is conspicuous, and also the balls fall in the right direction as compared with the case in which the balls are struck at other parts. In contrast, with the golf club head


20


, the decrease in the flying distance by the upper toe part


21


is small, and the lateral deviation is also small. This means that the rotation of the golf club head


20


is restrained more than the rotation of the golf club head


30


, whereby it is understood that the rotation performance of the golf club head


20


is excellent.




Also, on the basis of the data shown in Table 1, a sixth iron golf club head and a ninth iron golf club head according to the present invention were prepared. Namely, the sixth iron golf club head has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to the face surface, the angle θ formed by the major axis of the plane ellipse appearing on the cut surface and the intersecting line of the cut surface and the ground surface was set to be 7°. Further, the major axis of the plane ellipse was set to extend upward and away from the ground surface as it approaches a toe part. Also, the aspect ratio a/b was set to be 2. Further, the height h of the sweet spot was set to be 19.5 mm.




The ninth iron golf club head according to the present invention has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of the golf club head and being parallel to the face surface, the angle θ formed by the major axis of the plane ellipse appearing on the cut surface and the intersecting line of the cut surface and the ground surface was set to be 9°. The aspect ratio a/b was set to be 1.9. The height h of the sweet spot was set to be 18 mm.




The identification numbers of the golf clubs having these golf club heads, the aspect ratios a/b, the angle θ, and the height h of the sweet spot have a relationship shown in

FIGS. 33A

to


33


C. In other words, also, according as the identification number of the golf club increases, the aspect ratio a/b successively decreases. According as the identification number increases, the angle θ of each of the golf club heads successively increases with a constant ratio. Also, according as the identification number of the golf club increases, the height h of the sweet spot successively decreases with an approximately constant ratio.




Also, with respect to wood golf clubs, the aspect ratio of the ellipse approximating the variation of the hitting points of a general player, the angle Δ formed by the major axis of the ellipse and the intersecting line of the ground surface and the face surface, and the height H of the center of hitting points were determined. The results are shown in Table 2.















TABLE 2











Angle Δ formed








Aspect ratio




by the ground surface








a‘/b’ of a




and the major axis of a







Identificatio




plane ellipse




plane ellipse




Height H of






n number of




approximating the




approximating the




the center of






a golf club




variation of




variation of hitting




hitting points






(wood)




hitting points




points (°)




(mm)


























W-1




1.45




2




25






W-3




1.4




4




22






W-5




1.3




5




21.5














On the basis of this Table 2, wood golf club heads according to the present invention were prepared. Namely, each of the first, third, and fifth wood golf club heads has an ellipsoid of inertia with its center at the center of gravity. When the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of each golf club head and being parallel to each face surface, the major axis of the plane ellipse appearing on the cut surface was set to extend upward and away from the ground surface as it approaches a toe part. Further, the angle θ formed by the major axis and the intersecting line of the cut surface and the ground surface was set to be 2° for the first wood golf club head, 4° for the third wood golf club head, and 5° for the fifth wood golf club head. Also, the aspect ratio a/b was set to be 1.45 for the first wood golf club head, 1.4 for the third wood golf club head, and 1.3 for the fifth wood golf club head. Also, the height h of the sweet spot was set to be 25 mm for the first wood golf club head, 22 mm for the third wood golf club head, and 21.5 mm for the fifth wood golf club head.




A test of variation of the hit balls was carried out on these first, third, and fifth wood golf club heads and a conventional wood golf club head. As a result, it was confirmed that the wood golf club heads according to the present invention can reduce the variation in the right-and-left direction and in the flying ball line direction to a great extent.




Also, as a result of applying the present invention to various golf club heads it was made clear that the angle θ must be not smaller than 0.5° and not larger than 9.5°. Also, it was made clear that the aspect ratio a/b must be not smaller than 1 and not larger than 4. Further, it was found out that the height h of the sweet spot from the ground surface must be not smaller than 10 mm and not larger than 30 mm.




Hereafter, specific embodiments to which the present invention is applied will be explained.





FIG. 10A

is a bottom view of a wood golf club according to the present invention.

FIG. 10B

is a side view of a wood golf club according to the present invention. Referring to

FIGS. 10A and 10B

, a weight member


43


serving as the first weight member is embedded in the upper part


41




a


of the toe of the wood golf club head


41


. A weight member


44


is embedded also in the back part


41




b


at the center of the sole. Thus, in the case where the third wood golf club and the seventh wood golf club shown in

FIGS. 10A and 10B

are constructed, the dimension and the weight of each will be shown in Table 3.


















TABLE 3












Wood golf





Wood golf








Item




club #3





club #7































Toe tip weight




10




g




10




g







Sole back center weight




10




g




20




g







Loft angle




18°





24°








Lie angle




57.5°





58.5°








Head length: C




96




mm




96




mm







Head width: E




79




mm




60




mm







Head thickness: F




36




mm




33




mm







Head weight




200




g




213




g















Further, according to more preferable embodiments of the present invention, among the aforesaid constituent elements, the angle θ is set to be within a range not smaller than 1° and not larger than 9°, the aspect ratio a/b is set to be within a range not smaller than 1.5 and not larger than 2.5, and the height of the sweet spot is set to be within a range not smaller than 15 mm and not larger than 27 mm, and a design is made by suitably combining these.





FIGS. 11A and 11B

show iron golf clubs in which the aspect ratio is changed by changing the head shape.

FIG. 11A

shows a long iron golf club, and

FIG. 11B

shows a short iron golf club.




In

FIGS. 11A and 11B

, the point A shows the highest part of the toe part of the face surface having the largest height from the ground surface. The point B shows the lowest part of the top edge of the face surface having the smallest height from the ground surface. The length XL between the highest part A of the toe part of the long iron golf club and the lowest part B of the top edge, the length Y


L


from the ground surface to the highest part A of the toe part, the length X


S


from the highest part A of the toe part of the short iron golf club to the lowest part B of the top edge, and the length Y


S


from the ground surface to the highest part A of the toe part are selected to satisfy the following relationship.








X




L




/Y




L




>X




S




/Y




S








In these iron golf clubs shown in

FIGS. 11A and 11B

, the direction of the axis (here, the direction of the axis refers to the direction formed by the major axis of the plane ellipse and the ground surface) can be changed by increasing the height of the toe part according as it becomes a short iron golf club, namely, according as the identification number increases.





FIGS. 12A and 12B

show examples in which the aspect ratio is changed by changing the head shape in wood golf clubs, in the same manner as in

FIGS. 11A and 11B

.

FIG. 12A

shows a driver.

FIG. 12B

shows a short wood golf club such as a ninth wood, for example. In

FIGS. 12A and 12B

, the point C shows a top point of the crown part. The point D shows the most protruding part of the toe part of the head. The point E shows the heel end part of the sole part. The length XL from the most protruding part D of the toe part of the head of the driver to the heel end part E of the sole part, the length Y


L


from the ground surface to the top point C of the crown part, the length X


S


from the most protruding part D of the toe part of the head of the short wood gold club to the heel end part E of the sole part, and the length Y


S


from the ground surface to the top point C of the crown part are selected to satisfy the following relationship.








X




L




/Y




L




>X




S




/Y




S








In the examples shown in

FIGS. 12A and 12B

, the direction of the axis can be changed by increasing the height of the toe part according as it becomes a short wood golf club, namely, according as the identification number increases.





FIGS. 13A and 13B

show iron golf clubs in which the aspect ratio is changed by changing the face shape.

FIG. 13A

shows a long iron golf club.

FIG. 13B

shows a short iron golf club. The point F in

FIGS. 13A and 13B

shows the toe end part of the sole part. In the examples shown in

FIGS. 13A and 13B

, the ratios of the length XL from the most protruding part D of the toe part of the head to the heel end part E of the sole part, the length Y


L


from the ground surface to the most protruding part A of the toe part, the length X


S


from the most protruding part D of the toe part of the head of the short iron gold club to the heel end part E of the sole part, and the length Y


S


from the ground surface to the highest part A of the toe part are selected to satisfy the following relationship.








Y




L




/X




L




>Y




S




/X




S








Also, the relationship between the length T


L


from the ground surface to the toe end part F of the sole part in the long iron golf club and the length T


S


from the ground surface to the toe end part of the sole part in the short iron is selected to satisfy the following formula.








T




L




>T




S








In this example, the direction of the axis can be changed by setting T


L


>T


S


.





FIGS. 14A and 14B

show iron golf clubs in which the aspect ratio is changed by changing the face shape and the direction of the axis is changed by changing the neck length. In

FIGS. 14A and 14B

, the point G shows the tip end part of the neck part. Then, the lengths from the neck tip end part G to the heel end part E of the sole part are respectively represented by N


L


and N


S


. In this example also, X


L


, Y


L


, X


S


,




Y


S


, N


L


, and N


S


are selected to satisfy the following relationship.








Y




L




/X




L




>Y




S




/X




S












N




L




>N




S









FIGS. 15A and 15B

show iron golf clubs in which the aspect ratio and the direction of the axis are changed by disposing weight members in the upper part of the toe and the heel part of the sole.

FIG. 15A

shows a long iron golf club.

FIG. 15B

shows a short iron golf club.




Weight members


1108




a


and


1108




b


serving as the first weight members and weight members


1109




a


and


1109




b


serving as the second weight members are disposed in the upper parts


1106




a


and


1106




b


of the toe and in the heel side parts


1107




a


and


1107




b


of the sole of the iron golf club heads


1105




a


and


1105




b


, respectively. The weight members


1108




a


,


1108




b


,


1109




a


, and


1109




b


have masses W


L


and W


S


. The masses W


L


and W


S


satisfy a relationship shown by W


L


<W


S


. By this, the aspect ratio and the direction of the axis can be changed.





FIGS. 16A

to


16


D show iron golf clubs in which the aspect ratio and the direction of the axis are changed by changing the thickness of the top edge on the toe part side and changing the sole width of the heel part.

FIG. 16A

is a view of a long iron golf club as seen from the top edge side.

FIG. 16B

is a view of a long iron golf club as seen from the sole side.

FIG. 16C

is a view of a short iron golf club as seen from the top edge side.

FIG. 16D

is a view of a short iron golf club as seen from the sole side. In this example, the thickness T


L


of the top edge of the long iron golf club shown by FIG.


16


A and the thickness T


S


of the top edge of the short iron golf club shown by

FIG. 16C

are selected to satisfy the relationship represented by T


S


>T


L


. Also, the sole width S


L


of the heel part of the long iron golf club shown by FIG.


16


B and the sole width S


S


of the heel part of the short iron golf club shown by

FIG. 16D

are selected to satisfy the relationship represented by S


L


>S


S


.





FIGS. 17A and 17B

show iron golf clubs in which the aspect ratio and the direction of the axis are changed by changing the angle θ


L


formed by the top edge and the intersecting line of the cut surface and the ground surface.

FIG. 17A

shows a long iron golf club.

FIG. 17B

shows a short iron golf club.




In this example, the angle θ


S


formed by the top edge of the short iron golf club and the intersecting line of the ground surface and the angle θ


L


in the long iron are selected to satisfy the relationship represented by θ


L





S


. By this, the aspect ratio and the direction of the axis can be changed.





FIGS. 18A and 18B

show iron golf clubs in which the aspect ratio and the direction of the axis are changed by changing the height of the toe part and the height of the heel part.

FIG. 18A

shows a long iron golf club.

FIG. 18B

shows a short iron golf club.




In this example, the lengths Y


L


and Y


S


from the ground surface to the highest point A of the toe part, and the lengths Y′


L


and Y′


S


to the lowest point B of the top edge are selected to satisfy the relationship represented by Y′


L


/Y


L


>Y′


S


/Y


S


.





FIGS. 19A

to


19


D show wood golf clubs in which the aspect ratio is changed by approximating the shape of the head to a sphere and the axis is tilted by changing the thickness of the upper side of the toe part and the thickness of the lower side of the heel part.

FIG. 19A

shows a plan view of a driver.

FIG. 19B

shows a plan view of a short wood golf club.

FIG. 19C

shows a front view of a driver.

FIG. 19D

shows a front view of a short wood golf club.




In this example, the lengths from the centroid H of the face surface to the most protruding part I of the back side are assumed to be Z


L


and Z


S


. The lengths from the most protruding part D of the toe part of the head to the heel end part E of the sole part are assumed to be X


L


and X


S


. The lengths from the ground surface to the top point C of the crown part are assumed to be Y


L


and Y


S


. The relationship of these is selected in such a manner that X


S


:Y


S


:Z


S


is nearer to 1:1:1 than X


L


:Y


L


:Z


L


. By this, the shape of the head can be approximated to a sphere. Moreover, the axis is tilted by changing the thicknesses D


L


and D


S


of the toe part and the thicknesses E


L


and E


S


of the heel part.





FIGS. 20A and 20B

show iron golf clubs in which the axis is tilted by decreasing the neck length and increasing the neck diameter according as it becomes a short iron golf club.

FIG. 20A

shows a long iron golf club.

FIG. 20B

shows a short iron golf club.




In this example, the neck length N


L


of the long iron golf club shown by FIG.


20


A and the neck length N


S


of the short iron golf club shown by

FIG. 20B

are selected to satisfy the relationship represented by N


L


>N


S


. The neck diameter φ


L


of the long iron golf club and the neck diameter φ


S


of the short iron golf club are selected to satisfy the relationship represented by φ


L





S


.





FIGS. 21A and 21B

show iron golf clubs in which the axis is tilted and the height of the sweet spot is decreased by increasing the mass of the lower part of the heel part.

FIG. 21A

shows a long iron golf club.

FIG. 21B

shows a short iron golf club. In this example, a weight member is added to the lower part of the heel part of each of the long iron golf club and the short iron golf club. Assuming the masses of the respective weight members to be W


L


and W


S


, these satisfy a relationship represented by W


L


<W


S


.





FIGS. 22A and 22B

show wood golf clubs in which the axis is tilted and the sweet spot is lowered by decreasing the length of the neck and increasing the thickness of the sole of the heel part.

FIG. 22A

shows a driver.

FIG. 22B

shows a short wood golf club. In this example, the neck length is decreased and the thickness of the heel part is increased according as it becomes a short wood golf club, namely, according as the identification number increases.





FIGS. 23A and 23B

show wood golf clubs in which the thickness of the sole part is successively increased.

FIG. 23A

shows a driver.

FIG. 23B

shows a short wood golf club. In this example, the axis is tilted and the sweet spot height is decreased by successively increasing the thickness of the sole part of the short wood golf club as compared with the driver, and by shifting the thick part to the heel part side.




In

FIGS. 24A and 24B

, a weight member is disposed on the upper part of the sole in the inside of the head at the heel part of the short wood golf club shown in

FIG. 24B

, as compared with the driver shown in FIG.


24


A. By this, the direction of the axis is changed, and the height of the sweet spot is decreased.




The thickness ts of the lower part of the heel on the back side of the short iron golf club shown in

FIG. 25B

is larger than the thickness tL of the lower part of the heel on the back side of the long iron golf club shown in FIG.


25


A. By this, the axis is tilted and the height of the sweet spot is decreased.




The height Y


L


of the heel part and the crown height J


L


of the heel part of the face surface of the driver shown in FIG.


26


A and the height Ys of the heel part and the crown height Js of the heel part of the face surface of the short wood golf club shown in

FIG. 26B

are selected to satisfy relationships respectively represented by Y


L


>Y


S


and J


L


>J


S


. By this, the axis is tilted and the height of the sweet spot is decreased.




In the driver shown in FIG.


27


A and in the short wood golf club shown in

FIG. 27B

, the heights Y′


L


and Y


S


of the heel part of the back part are decreased. The crown heights J


L


and J


S


of the heel part from the ground surface are changed. By this, the axis is tilted and the height of the sweet spot is decreased. However, in this case, these are selected to satisfy relationships represented by Y


L


>Y′


S


and J


L


>J


S


.




In the long iron golf club shown in FIG.


28


A and in the short iron golf club shown in

FIG. 28B

, weight members respectively having masses W


L


and W


S


are attached to the lower part of the sole part. These satisfy a relationship represented by W


L


<W


S


. By this, the aspect ratio is successively decreased, and the height of the sweet spot is decreased.




In the long iron golf club shown in FIG.


29


A and in the short iron golf club shown in

FIG. 29B

, the thicknesses t


L


and t


S


of the cavity on the back side are increased and the head length is decreased. By this, the aspect ratio is successively decreased, and the height of the sweet spot is decreased. Here, these are selected to satisfy relationships represented by tL<ts and X


L


>X


S


.




In the long iron golf club shown in FIG.


30


A and in the short iron golf club shown in

FIG. 30B

, the heights T


L


and T


S


of the power blades on the cavity sole of the back side are set to satisfy a relationship represented by T


L


<T


S


. By this, the aspect ratio is successively decreased, and the height of the sweet spot is decreased.




In the long iron golf club shown in FIG.


31


A and in the short iron golf club shown in

FIG. 31B

, the lengths X


L


and X


S


from the most protruding part D of the toe part of the head to the heel end part E of the sole part as well as the neck lengths N


L


and N


S


are decreased. By this, the aspect ratio is decreased, and the height of the sweet spot is decreased.




In the long iron golf club shown in FIG.


32


A and in the short iron golf club shown in

FIG. 32B

, the aspect ratio is successively decreased and the height of the sweet spot is decreased by increasing the sole thicknesses B


L


and B


S


. These are selected to satisfy a relationship represented by B


L


<B


S


.




Thus, by applying the modes shown in

FIGS. 10A

to


32


B to golf club heads and golf club sets, the variation of the flying distance in the right-and-left direction and in the flying ball line direction can be restrained, and the initial velocity of the balls can be improved. This increases the flying distance.




As described above, according to the present invention, the sweet spot of the golf club head is approximated to the center of hitting points while restraining not only the variation of the flying distance in the right-and-left direction but also the variation of the flying distance in the flying ball line direction by taking the variation of the hitting points of a general player into account while planning to improve the inertial characteristics in the direction perpendicular to the face surface. By this, the distance of the offset caused by the variation of the hitting points can be reduced as much as possible, and the initial velocity of the balls can be improved.




Different embodiments of the present invention will be explained.





FIGS. 34A and 34B

are views for explaining the principle of the present invention.

FIG. 34A

is a view for explaining a striking force generated on a face surface when a golf ball is hit with a golf club head.

FIG. 34B

is a view showing a state in which the face is rotated and the ball flies out at the striking time.




Referring to

FIG. 34A

, when a golf ball is struck with a golf club, an iron golf club head


11


receives a striking force F from the golf ball


2


in the proceeding direction of the swing at the hitting point position MP of the golf ball


2


. In the golf club, an angle is formed between a sole and a face surface


11




f


in order to change the flying-out angle of the golf ball


2


in accordance with the identification number and to obtain a flying distance for each identification number. This angle is referred to as a loft angle. Typically, the loft angle is set to be about 10° in the case of a driver, about 20° in the case of a third iron, and about 40° in the case of a ninth iron. The loft angle increases according as the identification number increases.




Due to the presence of the loft angle, the striking force F at the striking time can be decomposed into a horizontal partial force FH and a perpendicular partial force FP with respect to the face surface


11




f


. The horizontal partial force FH is a force that rotates the golf ball


2


together with a frictional force of the face surface


11




f


, namely, it generates a back spin or a side spin. According as the swing speed increases and the impacting speed of the golf club head increases, the striking force F increases and the horizontal partial force FH increases, so that the back spin and the side spin are more likely to be generated. The ball trajectory of an iron of a professional golfer rises high above after the shot, and then falls vertically from above. This is due to the fact that, since the head speed is high, a back spin is generated, and the ball floats upward and falls down.




Also, the perpendicular partial force FP is a force that acts perpendicularly on the face surface


11




f


, as shown in

FIG. 34B

, and this force rotates the face surface


11




f


. By this rotation, the golf ball


2


after the shot flies out in the right-and-left direction and in the up-and-down direction. Here, the point at which the line drawn perpendicularly from the center of gravity G of the golf club head


11


to the face surface


11




f


intersects the face surface


11




f


is referred to as a sweet spot SS. The sweet spot SS is a point by which the golf ball flies most and, if the ball is struck here, the golf club head


11


rotates little. However, if a general players performs a shot, the ball hardly hits the sweet spot SS, and the player performs a shot in the peripheries of the sweet spot SS.





FIGS. 35A

to


37


B are views showing a distribution of the hitting points of a general player.

FIGS. 35A and 35B

show a distribution of the hitting points by a third iron golf club.

FIGS. 36A and 36B

show a distribution of the hitting points by a sixth iron golf club.

FIGS. 37A and 37B

show a distribution of the hitting points by a ninth iron golf club. As will be clear from

FIGS. 35A

to


37


B, it is understood that a general player strikes at various positions up and down and to the right and left near the sweet spot SS. The player from whom these data have been obtained has a golf score of about 100 and is an average player. In the Figures, the points


3




b


,


6




b


, and


9




b


represent hit marks on the face surfaces


3




f


,


6




f


, and


9




f


of the golf club heads


3


,


6


, and


9


. The hitting point centers are represented by points


3




c


,


6




c


, and


9




c


. Ellipses


3




a


,


6




a


, and


9




a


that approximate the size and the shape of the hitting point distribution by determining an interval covering not less than


95


% of the hit marks are shown in a solid line. Further, the A-axis passing through the hitting point centers


3




c


,


6




c


, and


9




c


of the face surfaces


3




f


,


6




f


, and


9




f


and being parallel to the intersecting line of the face surfaces


3




f


,


6




f


, and


9




f


and the ground surface, as well as the major axes


3




d


,


6




d


, and


9




d


of the ellipses


3




a


,


6




a


, and


9




a


approximating the variation of the hitting points, are shown in solid lines.




From this result, the player strikes a golf ball at various locations up and down and to the right and left of the face surfaces


3




f


,


6




f


, and


9




f


of the golf club heads


3


,


6


, and


9


. It is understood that the hitting points are varied in the right-and-left direction from the toe side to the heel side and in the up-and-down direction from the leading edge to the top edge. Since this variation degrades the directivity of the ball after hitting the ball, it is necessary to produce a golf club head that maintains the directivity to some extent even if the hitting points are varied.




On the other hand, as will be seen from the results of the hitting point distribution, the shape of the hitting point distribution is a shape of the ellipses


3




a


,


6




a


, and


9




a


having a major axis and a minor axis. Further, the angle that the major axes


3




d


,


6




d


, and


9




d


form with the A-axis is an angle such that the major axes


3




d


,


6




d


, and


9




d


extend upward and away from the ground surface as they approach the toe parts


3




t


,


6




t


, and


9




t


. In other words, the major axes


3




d


,


6




d


, and


9




d


extend in a toe-up direction. Further, as the identification number increases, the angle that the major axes


3




d


,


6




d


, and


9




d


form with the A-axis increase successively. Also, the shape of the ellipses


3




a


,


6




a


, and


9




a


successively approaches a circular shape. Further, it is understood that the height H of the hitting point centers


3




c


,


6




c


, and


9




c


from the ground surface decreases, as shown in

FIGS. 35A

to


37


B. Thus, it is understood that the shape of the hitting point distribution of a general player has a specific tendency.




In other words, from the aforesaid distribution of the hitting points, the hitting points are positioned approximately within the ellipses


3




a


,


6




a


, and


9




a


having a major axis and a minor axis. The angle Δ that the major axes


3




d


,


6




d


, and


9




d


of the ellipses form with the A-axis extending parallel to the intersecting line of the face surfaces


3




f


,


6




f


, and


9




f


and the ground surface, approaches the toe parts


3




t


,


6




t


, and


9




t


. Also, according as the identification number increases, the angle Δ successively increases, and the shape of the ellipses successively approaches a circular shape. Further, the height H of the points


3




c


,


6




c


, and


9




c


representing the hitting point centers decreases.




The inertial resistance in the direction perpendicular to the face surface of the golf club head can be determined as follows.





FIG. 38

is a view showing a relationship between the ellipsoid of inertia of a golf club head and X-axis, Y-axis, Z-axis. Referring to

FIG. 38

, the axis passing through the center of gravity G and being perpendicular to the ground surface is assumed to be the Z-axis. The axis passing through the center of gravity G and being perpendicular to the Z-axis and parallel to the intersecting line of the tangential plane at the centroid (center) of the face surface


11




f


and the ground surface is assumed to be the X-axis. The tangential surface at the centroid (center) of the face surface


11




f


is approximately the same surface as the face surface


11




f


. The axis passing through the center of gravity G and being perpendicular to both the X-axis and the Z-axis is assumed to be the Y-axis.





FIG. 40

is a view showing direction vectors on an ellipse plane appearing when the ellipsoid of inertia is cut. Referring to

FIG. 40

, the direction vector of a plane passing through the center of gravity G and being parallel to the intersecting line of the tangential plane at the centroid of the face surface


11




f


and the ground surface is assumed to be f(l, m, n)


T


, and each of the following vectors is calculated.








f




1


(


l




1




, m




1




, n




1


)


T




=f X Z


(0, 0, 1)


T












f




2


(


l




2




, m




2




, n




2


)


T




=f




1




X f












f




3


(


l




3




, m




3




, n




3


)


T




=f




1




X f




2


  (1)






where X designates an outer product.





FIGS. 39A

,


39


B, and


39


C are views showing cut surfaces when the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of a golf club head and being parallel to the face surface. Referring to

FIGS. 39A

,


39


B, and


39


C, the axis passing through the center of gravity G and being parallel to the intersecting line of the tangential plane at the centroid of the face surface


11




f


and the ground surface is assumed to be β-axis. The axis being parallel to the tangential plane at the centroid of the face surface


11




f


and perpendicular to the α-axis is assumed to be β-axis. The axis being perpendicular to the α-axis and the β-axis is assumed to be γ-axis. The conversion from the α, β, γcoordinate system to the X, Y, Z coordinate system is represented by the following equations.








X=l




1




·α+l




2




·β+l




3




19


γ










Y=m




1




·α+m




2




·+m




3


·γ










Z=n




1




·α+n




2




·+n




3


γ  (2)






Here, supposing that I


1


, I


2


, I


3


are moments of inertia with respect to the X, Y, Z axes, I


12


is a product of inertia with respect to the YZ-plane and the XZ-plane, I


13


is a product of inertia with respect to the YZ-plane and the XY-plane, I


23


is a product of inertia with respect to the XZ-plane and the XY-plane, then the following relationship is obtained.






I


1




·X




2




+I




2




·Y




2




+I




3




·Z




2


+2


·I




12




·X·Y


+2


·I




13




X·Z


+2


I




23




·Y·Z=


1  (3)






The ellipsoid represented by the equation (3) is referred to as an ellipsoid of inertia. This shows the magnitude of the inertial resistance in each direction. Substituting the equation (3) with the equation (2) and letting the y term zero, the equation (4) of the cut ellipse plane is determined.






(


1




I




1




2




+I




2




m




1




2




+I




3




n




1




2




+I




12




l




1




m




1




+I




13




l




1




n




1+




I




23




m




1




n




1





2










+(


I




1




l




2




2




+I




2




m




2




2




+I




3




n




2




2




+I




12




l




2




m




2




+I




13




l




2




n




2




+I




23




m




2




n




2





2










+(


I




1




l




1




l




2




+I




2




m




1




m




2




+I




3




n




1




n




2




+I




12




l




1




m




2




+I




12




l




2




m




1




+I




13




l




1




n




2




+I




13




2




n




1










+


I




23




m




1




n




2




+I




23




m




2




n




1


)αβ=1  (4)






The magnitude of the cut surface represents the magnitude of the inertial resistance indicating the facility of rotation of this surface. Also, the cut surface represents the inertial resistance in the direction perpendicular to the cut surface. Further, as shown in

FIGS. 39A

,


39


B, and


39


C, it is apparent that the shape of the cut surface is a plane ellipse because it is a cut surface of a three-dimensional ellipsoid of inertia.




The plane ellipse appearing when the ellipsoid of inertia


12


of the golf club head


11


is cut with the face surface


11




f


represents the facility of the rotation in the perpendicular direction with respect to the face surface


11




f


. Also, in the plane ellipse


13


appearing on the cut surface when the ellipsoid of inertia


12


is cut with a plane passing through the center of gravity G and being parallel to the face surface


11




f


, the length of the major axis


13




d


, is represented by a and the length of the minor axis


13




e


is represented by b. The aspect ratio is defined by a/b. The angle formed by the major axis


13




d


, and the a axis is assumed to be θ.




The distribution of the hitting points of the player shown in

FIGS. 35A

to


37


B has an elliptic shape with its center at the center of hitting points. Further, the major axes


3




d


,


6




d


, and


9




d


extend to go away from the ground surface as they approach the toe parts


3




t


,


6




t


, and


9




t


. In other words, in the third iron golf club head


3


shown in FIGS.


35


A and


35


B, the angle Δ formed by the A-axis on the face surface


3




f


and the major axis


3




d


, of the ellipse


3




a


is 5°. In the sixth iron golf club head


6


shown in

FIGS. 36A and 36B

, the angle Δ formed by the A-axis on the face surface


6




f


and the major axis


6




d


of the ellipse


6




a


is 7°. In the ninth iron golf club head


9


shown in

FIGS. 37A and 37B

, the angle Δ formed by the A-axis of the golf club head


9


on the face surface


9




f


and the major axis


9




d


of the ellipse


9




a


is 9°.




Therefore, by allowing the sweet spot to be approximately coincident with the center of the plane ellipse appearing when the ellipsoid of inertia


12


is virtually cut with the face surface


11




f


, the distance between the hitting points and the sweet spot can be made as small as possible even if the hitting points are varied. This can restrain the rotation of the golf club head. Further, since the ball is hit in the neighborhood of the sweet spot, the initial velocity of the ball is improved to increase the flying distance.




Furthermore, by allowing the angle θ formed by the major axis


13




d


, of the plane ellipse


13


shown in FIG.


39


B and the intersecting line


15


of the cut surface and the ground surface to be coincident with the angle Δ formed by the A-axis and the major axes


3




d


,


6




d


, and


9




d


of the ellipses


3




a


,


6




a


, and


9




a


indicating the hitting point distribution shown in

FIGS. 35A

to


37


B, the deviation of the golf club head in the up-and-down direction and the right-and-left direction can be restrained. Further, the major axis


13




d


, of the ellipse


13


, like the major axes


3




d


,


6




d


, and


9




d


, is set to extend away from the ground surface as it approaches the toe part lit. Further, by allowing the aspect ratio a/b which is the ratio of the length a of the major axis


13




d


, and the length b of the minor axis


13




e


of the ellipse


13


, to be coincident with the aspect ratio of the ellipses


3




a


,


6




a


, and


9




a


indicating the hitting point distribution of a general player, the inertial resistance in the up-and-down direction and the inertial resistance in the right-and-left direction are allowed to conform to the variation of the hitting points of the general player. This can not only restrain the lateral deviation of the golf club head in the right-and-left direction but also restrain the variation of the flying distance in the flying ball line direction.




According as the identification number increases, the angle θ shown in

FIG. 39B

is successively increased. Also, the aspect ratio a/b is successively decreased according as the identification number of the golf club head increases. Also, the height h of the sweet spot SS from the ground surface


16


shown in

FIG. 39C

is successively decreased according as the identification number of the golf club head increases. By constructing a golf club set using these golf club heads, the variation of the flying distance in the right-and-left direction and the flying ball line direction can be restrained for a golf club of any identification number, whereby the flying distance can be increased by improving the speed of the ball.




Specific embodiments according to the present invention will be explained. Referring to

FIG. 41

, an iron golf club head


101


according to the present invention has a back cavity


106


. A through-hole


104


is formed in a face part


103


of a head body


102


. A face insert member


105


having a smaller specific gravity than the metal constituting the head body


102


is mounted in the through-hole


104


. In a peripheral weight disposing part


107


of the back cavity


106


, much weight is distributed and disposed at sites in the upper part


108


A of the toe and from the central part


109


A of the sole part


109


to the heel part


110


.




In other words, in the iron golf club head


101


shown in

FIG. 41

, the first weight member is disposed in the upper part


108


A of the toe of the head body


102


. The second weight member is disposed in the heel side part


109


B of the sole of the head body


102


.




Referring to

FIG. 42

, an iron golf club head


101


according to the present invention has a back cavity


106


. A through-hole


104


is formed in a face part


103


of a head body


102


. A face insert member


105


having a smaller specific gravity than the metal constituting the head body


102


is mounted in the through-hole


104


. In a peripheral weight disposing part


107


of the back cavity


106


, weight members


111


A and


111


B having a larger specific gravity than the metal constituting the head body


102


are fitted and integrated by engagement at parts in the upper part


108


A of the toe and from the central part


109


A of the sole part


109


to the heel part


110


.




In other words, the iron golf club head


101


shown in

FIG. 42

has a weight member


111


A serving as the first weight member provided in the upper part


108


A of the toe of the head body


102


, and a weight member


111


B serving as the second weight member provided in the heel side part


109


B of the sole of the head body


102


. The weight members


111


A and


111


B have a larger specific gravity than the material constituting the head body


102


. Also, the weight members


111


A and


111


B have a larger density than other parts of the head body


102


. Also, the density of the upper part


108


A of the toe and the heel side part


109


B of the sole may be made larger than other parts, for example, by disposing a metal densely on the upper part


108


A of the toe and the heel side part


109


B of the sole and by forming a hollow hole in the metal at other parts.




As shown in

FIGS. 43A

to


43


E, in the peripheral weight disposing part


107


of the back cavity


106


, the height of the rear back


107


A is constructed to become successively higher from the lower part


108


B of the toe to the sole part


110


B. Namely, the depth of the back cavity


106


increases according as it approaches from the lower part


108


B of the toe to the heel part


110


. Here, as shown in

FIGS. 43B and 43E

, it is a characteristic of the present invention that the rear back


107


A of the peripheral weight disposing part


107


of the back cavity


106


is not provided in the lower part


108


B of the toe and in the heel part


110


of the sole part


109


. By providing such a construction, more weight can be distributed and disposed at sites in the upper part


108


A of the toe and from the central part


109


A of the sole part


109


to the heel part


110


.




Further, as shown in

FIGS. 43A

to


43


E, the width of the sole part


109


successively decreases according as it approaches from the lower part


108


B of the toe to the heel part


110


.




Further, examples of the present invention will be explained in detail. The head body


102


is made of stainless steel. Pure titanium is used as the face insert member


105


, and this is press-fit and fixed.




Also, a tungsten alloy having a larger specific gravity than the head body


102


is used as the weight members


111


A and


111


B. The weight member


111


A is press-fit and integrated by engagement to the upper part


108


A of the toe of the peripheral weight disposing part


107


of the back cavity


106


, and its mass is 3 g. The weight member


111


B is press-fit and integrated by engagement to the sites from the central part


109


A of the sole part


109


to the heel part


110


, and its mass is 8 g.




Here, lead, beryllium copper alloy, brass, and others can be used besides the aforesaid tungsten alloy as the weight member


111


having a larger specific gravity than the head body


102


. These are press-fit and integrated by engagement to the sites in the upper part


108


A of the toe and from the central part


109


A of the sole part


109


to the heel part


110


of the peripheral weight disposing part


107


of the back cavity


106


.




In the face part


103


or in the upper opening part


107


B of the peripheral weight disposing part


107


of the back cavity


106


, the distance from the face surface part


106


A of the back cavity


106


to the upper opening part


107


is about 15 mm, for example, in the case of the fifth iron golf club head. The height of the rear back


107


A of the peripheral weight disposing part


107


of the back cavity


106


is 7 mm at a position shifted by 20 mm from the central part


103


A of the face to the toe part side. The height of the rear back


107


A is 9 mm at the central part


103


A of the face. The height of the rear back


107


A is 12 mm at a position shifted by 12 mm from the central part


103


A of the face to the heel part side, and successively increases as it approaches the heel part


110


.




As a result of this, the weights are disposed in the upper part


108


A of the toe and in the lower part of the heel part


110


. As a result of it, the angle formed by the major axis of the plane ellipse appearing when the ellipsoid of inertia is cut and the intersecting line of the cut surface and the ground surface increases as it approaches the upper part


8


A of the toe, and the height of the sweet spot decreases.




Next, as the material constituting the head body


102


, one can use a metal material such as iron, stainless steel, aluminum, titanium, magnesium, tungsten, copper, nickel, zirconium, cobalt, manganese, zinc, silicon, tin, or chromium, which are materials often used in generally producing a golf club head. Also, an alloy material of these metals, FRP (fiber reinforced plastics), synthetic resin, ceramics, rubber, and others can be used. It may be produced from a single material of these or may be produced from a combination of two or more kinds of these materials.




Also, as a production method, use of a precision casting method is highly convenient because the cost will be low and the dimension precision is high. In addition, the head body can be produced by die-casting, pressing, or forging. It is also possible to produce each of the parts by pressing, forging, precision casting, metal injection, die-casting, cut-processing, powder-metallurgy, or the like and bonding these by welding, adhesion, press-fit, fitting engagement, press-contact, screwing, soldering, or the like to fabricate a golf club head.





FIGS. 44

to


45


B are views for comparing the variations of the flying distance between the golf club head according to the present invention and a conventional golf club head. Particularly,

FIG. 45A

shows data for the golf club head according to the present invention, and relates to the third iron having a loft angle of 21°. The plane ellipse appearing when the ellipsoid of inertia of the golf club head is cut with a plane parallel to the face surface is made approximately coincident with the distribution of the hitting points of a general player.

FIG. 45B

shows data in the case of a conventional golf club head.




A test was performed with a golf robot. The speed of the iron golf club head was set to be 34.5 m/sec. Taking the variation of the hitting points of the general player into account, the hitting point positions were set to be from sweet spot (C) to toe tip part (T·M), upper part of toe tip (T·U), lower part of toe (T·D), upper part of heel (H·U), lower part of heel (H·D), foot part of heel (HEM), upper part of center (C·U), and lower part of center (C·D), as shown in FIG.


44


. The results of striking at respective points are shown. Here, the specifications of the inventive product and the conventional product are shown in Table 4.















TABLE 4










Angle formed by the major









axis of the plane ellipse




Aspect ratio of








appearing on the cut




the plane ellipse








surface of the ellipsoid of




appearing on the








inertia and the intersecting




cut surface of the








line of the cut surface and




ellipsoid of




Sweet spot






Sample




the ground surface




inertia




height











Inventive









2.2




20.0 mm






product






Conventional









2.1




20.7 mm






product














On the other hand, the iron golf club head used in collecting the data shown in

FIG. 45A

has the same mass (


248


g) as the iron golf club head used for collecting the data shown in FIG.


45


B. Referring to

FIG. 44

, when the ellipsoid of inertia is cut with a plane passing through the center of gravity and being parallel to the face surface, the aspect ratio of the plane ellipse appearing on the cut surface is 2.2; the angle formed by the major axis and the intersecting line of the cut surface and the ground surface extends in a toe-up direction to be 8°; and the height of the center of hitting points was 20 mm.




From the results of the flying distance measurement test by the robot, in the case of a golf club head in which the plane ellipse is made coincident with the distribution of the hitting points of the general player, the variation to the right and left is about 15 m, as shown in

FIG. 45A

, thereby reducing the variation by 17%, while in the golf club head that does not conform to the distribution of the hitting points of the general player, the variation to the right and left is about 18 m, as shown in FIG.


45


B.




On the other hand, with respect to the variation in the flying ball line direction, the variation is about 24 m in the case of the conventional product, as shown in FIG.


45


B. In contrast, the variation in the flying ball line direction is about 13 m in the case of the inventive product, as shown in

FIG. 45A

, thereby reducing the variation by 46%. Further, when the average flying distance is compared, the average flying distance is 155 m in the case of the conventional product, as shown in FIG.


45


B. In contrast, the average flying distance is 157 m in the case of the inventive product, as shown in

FIG. 45A

, thereby increasing the flying distance by about 2 m.




Here,

FIGS. 45A and 45B

show average values when balls were hit each for eleven times.




Also, when the results of striking on the upper part of the toe tip are observed, it is well understood that there is a difference in the rotation performance. Namely, with the conventional product, the decrease in the flying distance in the flying ball line direction due to striking on the upper part of the toe tip is conspicuous, as shown in

FIG. 45B

, and further, the balls fall in the right direction as compared with the average lateral deviation. In contrast, with the inventive product, the decrease in the flying distance due to striking on the upper part of the toe tip is small, as shown in

FIG. 45A

, and the lateral deviation is also small. This means that, with the inventive product, the rotation of the golf club head is restrained as compared with the conventional Product, and it is understood that the rotation performance of the head is excellent.




Here, the golf club head shown in

FIG. 44

is provided with a weight member such as in the golf club head shown in FIG.


42


.




Different embodiments of the present invention will be explained.





FIGS. 46A and 46B

are views for explaining the principle of the present invention.

FIG. 46A

is a view for explaining a striking force generated on a face surface when a golf ball is hit with a golf club head.

FIG. 46B

is a view showing a state in which the face is rotated and the ball flies out at the striking time.




Referring to

FIG. 46A

, when a golf ball is struck with a golf club, an iron golf club head


11


receives a striking force F from the golf ball


2


in the proceeding direction of the swing at the hitting point position MP of the golf ball


2


. In the golf club, an angle is formed between a sole and a face surface


11




f


in order to change the flying-out angle of the golf ball


2


in accordance with the identification number and to obtain a flying distance for each identification number. This angle is referred to as a loft angle. Typically, the loft angle is set to be about 10° in the case of a driver, about 20° in the case of a third iron, and about 40° in the case of a ninth iron. The loft angle increases according as the identification number increases.




Due to the presence of the loft angle, the striking force F at the striking time can be decomposed into a horizontal partial force FH and a perpendicular partial force FP with respect to the face surface


11




f


. The horizontal partial force FH is a force that rotates the golf ball


2


together with a frictional force of the face surface


11




f


, namely, it generates a back spin or a side spin. According as the swing speed increases and the impacting speed of the golf club head increases, the striking force F increases and the horizontal partial force FH increases, so that the back spin and the side spin are more likely to be generated. The ball trajectory of an iron of a professional golfer rises high above after the shot, and then falls vertically from above. This is due to the fact that, since the head speed is high, a back spin is generated, and the ball floats upward and falls down.




Also, the perpendicular partial force FP is a force that acts perpendicularly on the face surface


11




f


, as shown in

FIG. 46B

, and this force rotates the face surface


11




f


. By this rotation, the golf ball


2


after the shot flies out in the right-and-left direction and in the up-and-down direction. Here, the point at which the line drawn perpendicularly from the center of gravity G of the golf club head


11


to the face surface


11




f


intersects the face surface


11




f


is referred to as a sweet spot SS. The sweet spot SS is a point by which the golf ball flies most and, if the ball is struck here, the golf club head


11


rotates little. However, if a general players performs a shot, the ball hardly hits the sweet spot SS, and the player performs a shot in the peripheries of the sweet spot SS.





FIGS. 47A

to


49


B are views showing a distribution of the hitting points of a general player.

FIGS. 47A and 47B

show a distribution of the hitting points by a third iron golf club.

FIGS. 48A and 48B

show a distribution of the hitting points by a sixth iron golf club.

FIGS. 49A and 49B

show a distribution of the hitting points by a ninth iron golf club. As will be clear from

FIGS. 47A

to


49


B, it is understood that a general player strikes at various positions up and down and to the right and left near the sweet spot SS. The player from whom these data have been obtained has a golf score of about


100


and is an average player. In the Figures, the points


3




b


,


6




b


, and


9




b


represent hit marks on the face surfaces


3




f


,


6




f


, and


9




f


of the golf club heads


3


,


6


, and


9


. The hitting point centers are represented by points


3




c


,


6




c


, and


9




c


. Ellipses


3




a


,


6




a


, and


9




a


that approximate the size and the shape of the hitting point distribution by determining an interval covering not less than 95% of the hit marks are shown in a solid line. Further, the A-axis passing through the hitting point centers


3




c


,


6




c


, and


9




c


of the face surfaces


3




f


,


6




f


, and


9




f


and being parallel to the intersecting line of the face surfaces


3




f


,


6




f


, and


9




f


and the ground surface, as well as the major axes


3




d


,


6




d


, and


9




d


of the ellipses


3




a


,


6




a


, and


9




a


approximating the variation of the hitting points, are shown in solid lines.




From this result, the player strikes a golf ball at various locations up and down and to the right and left of the face surfaces


3




f


,


6




f


, and


9




f


of the golf club heads


3


,


6


, and


9


. It is understood that the hitting points are varied in the right-and-left direction from the toe side to the heel side and in the up-and-down direction from the leading edge to the top edge. Since this variation degrades the directivity of the ball after hitting the ball, it is necessary to produce a golf club head that maintains the directivity to some extent even if the hitting points are varied.




On the other hand, as will be seen from the results of the hitting point distribution, the shape of the hitting point distribution is a shape of the ellipses


3




a


,


6




a


, and


9




a


having a major axis and a minor axis. Further, the angle that the major axes


3




d


,


6




d


, and


9




d


form with the A-axis is an angle such that the major axes


3




d


,


6




d


, and


9




d


extend upward and away from the ground surface as they approach the toe parts


3




t


,


6




t


, and


9


t. In other words, the major axes


3




d


,


6




d


, and


9




d


extend in a toe-up direction. Further, according as the identification number increases, the angle that the major axes


3




d


,


6




d


, and


9




d


form with the A-axis increases successively. Also, the shape of the ellipses


3




a


,


6




a


, and


9




a


successively approaches a circular shape. Further, it is understood that the height H of the hitting point centers


3




c


,


6




c


, and


9




c


from the ground surface decreases, as shown in

FIGS. 47A

to


49


B. Thus, it is understood that the shape of the hitting point distribution of a general player has a specific tendency.




In other words, from the aforesaid distribution of the hitting points, the hitting points are positioned approximately within the ellipses


3




a


,


6




a


, and


9




a


having a major axis and a minor axis. The angle Δ that the major axes


3




d


,


6




d


, and


9




d


of the ellipses form with the A-axis extending parallel to the intersecting line of the face surfaces


3




f


,


6




f


, and


9




f


and the ground surface, approaches the toe parts


3




t


,


6




t


, and


9




t


. Also, according as the identification number increases, the angle Δ successively increases, and the shape of the ellipses successively approaches a circular shape. Further, the height H of the points


3




c


,


6




c


, and


9




c


representing the hitting point centers decreases.




The inertial resistance in the direction perpendicular to the face surface of the golf club head can be determined as follows.





FIG. 50

is a view showing a relationship between the ellipsoid of inertia of a golf club head and X-axis, Y-axis, Z-axis. Referring to

FIG. 50

, the axis passing through the center of gravity G and being perpendicular to the ground surface is assumed to be the Z-axis. The axis passing through the center of gravity G and being perpendicular to the Z-axis and parallel to the intersecting line of the tangential plane at the centroid (center) of the face surface


11




f


and the ground surface is assumed to be the X-axis. The tangential surface at the centroid (center) of the face surface


11




f


is approximately the same surface as the face surface


11




f


. The axis passing through the center of gravity G and being perpendicular to both the X-axis and the Z-axis is assumed to be the Y-axis.





FIG. 52

is a view showing direction vectors on an ellipse plane appearing when the ellipsoid of inertia is cut. Referring to

FIG. 52

, the direction vector of a plane passing through the center of gravity G and being parallel to the intersection of the tangential plane at the centroid of the face surface


11




f


and the ground surface is assumed to be f(l, m, n)


T


, and each of the following vectors is calculated.








f




1


(


1




, m




1




, n




1


)


T




=f X Z


(0, 0, 1)


T












f




2


(


l




2




, m




2




, n




2


)


T




=f




1




X f












f




3


(


l




3




, m




3




, n




3


)


T




=f, X f




2


  (1)






where X designates an outer product.





FIGS. 51A

,


51


B, and


51


C are views showing cut surfaces when the ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of a golf club head and being parallel to the face surface. Referring to

FIGS. 51A

,


51


B, and


51


C, the axis passing through the center of gravity G and being parallel to the intersecting line of the tangential plane at the centroid of the face surface


11




f


and the ground surface is assumed to be α-axis. The axis being parallel to the tangential plane at the centroid of the face surface


11




f


and perpendicular to the α-axis is assumed to be β-axis. The axis being perpendicular to the α-axis and the P-axis is assumed to be γ-axis. The conversion from the αβ, γ coordinate system to the X, Y, Z coordinate system is represented by the following equations.








X=l




1




·α+l




2




·α+l




3




·γ












Y=m




1




·α+m




2




·β+m




3·γ












Z=n




1




·α+n




2




·+n




3·γ


  (2)






Here, supposing that I


1


, I


2


, I


3


are moments of inertia with respect to the X, Y, Z axes,


112


is a product of inertia with respect to the YZ-plane and the XZ-plane, I


13


is a product of inertia with respect to the YZ-plane and the XY-plane, I


23


is a product of inertia with respect to the XZ-plane and the XY-plane, then the following relationship is obtained.








I




1




·X




2




+I




2




·Y




2




+I




3·Z




2


+2


·I




12




·X·Y


+2


·I




13




·X·Z


+2


I




23




·Y·Z


=1  (3)






The ellipsoid represented by the equation (3) is referred to as an ellipsoid of inertia. This shows the magnitude of the inertial resistance in each direction. Substituting the equation (3) with the equation (2) and letting the y term zero, the equation (4) of the cut ellipse plane is determined.






(


I




1




l




1




2




+I




2




m




1




2




+I




3




n




1




2




+I




12




l




1




m




1




+I




13




l




1




n




1




+I




23




m




1




n




1





2










+(


I




1




l




2




2




+I




2




m




2




2




+I




3




n




2




2




I




12




l




2




m




2




+I




13




l




2




n




2




+I




23




m




2




n




2





2










+(


I




1




l




1




l




2




+I




2




m




1




m




2




I




3




n




1




n




2




+I




12




m




2




+I




12




l




2




m




1




+I




13




l




1




n




2




+I




13




l




2




n




1












+I




23




m




1




n




2




+I




23




m




2




n




1


)αβ1  (4)






The magnitude of the cut surface represents the magnitude of the inertial resistance indicating the facility of rotation of this surface. Also, the cut surface represents the inertial resistance in the direction perpendicular to the cut surface. Further, as shown in

FIGS. 51A

,


51


B, and


51


C, it is apparent that the shape of the cut surface is a plane ellipse because it is a cut surface of a three-dimensional ellipsoid of inertia.




The plane ellipse appearing when the ellipsoid of inertia


12


of the golf club head


11


is cut with the face surface


11




f


represents the facility of the rotation in the perpendicular direction with respect to the face surface


11




f


. Also, in the plane ellipse


13


appearing on the cut surface when the ellipsoid of inertia


12


is cut with a plane passing through the center of gravity G and being parallel to the face surface


11




f


, the length of the major axis


13




d


is represented by a and the length of the minor axis


13




e


is represented by b. The aspect ratio is defined by a/b. The angle formed by the major axis


13




d


and the a axis is assumed to be θ.




The distribution of the hitting points of the player shown in

FIGS. 47A

to


49


B has an elliptic shape with its center at the center of hitting points. Further, the major axes


3




d


,


6




d


, and


9




d


extend to go away from the ground surface as they approach the toe parts


3




t


,


6




t


, and


9




t


. In other words, in the third iron golf club head


3


shown in

FIGS. 47A and 47B

, the angle Δ formed by the A-axis on the face surface


3




f


and the major axis


3




d


, of the ellipse


3




a


is 5°. In the sixth iron golf club head


6


shown in

FIGS. 48A and 48B

, the angle Δ formed by the A-axis on the face surface


6




f


and the major axis


6




d


of the ellipse


6




a


is 7°. In the ninth iron golf club head


9


shown in

FIGS. 49A and 49B

, the angle Δ formed by the A-axis of the golf club head


9


on the face surface


9




f


and the major axis


9




d


of the ellipse


9




a


is 9°.




Therefore, by allowing the sweet spot to be approximately coincident with the center of the plane ellipse appearing when the ellipsoid of inertia


12


is virtually cut with the face surface


11




f


, the distance between the hitting points and the sweet spot can be made as small as possible even if the hitting points are varied. This can restrain the rotation of the golf club head. Further, since the ball is hit in the neighborhood of the sweet spot, the initial velocity of the ball is improved to increase the flying distance.




Furthermore, by allowing the angle θ formed by the major axis


13




d


, of the plane ellipse


13


shown in FIG.


51


B and the intersecting line


15


of the cut surface and the ground surface to be coincident with the angle Δ formed by the A-axis and the major axes


3




d


,


6




d


, and


9




d


of the ellipses


3




a


,


6




a


, and


9




a


indicating the hitting point distribution shown in

FIGS. 47A

to


49


B, the deviation of the golf club head in the up-and-down direction and the right-and-left direction can be restrained. Further, the major axis


13




d


of the ellipse


13


, like the major axes


3




d


,


6




d


, and


9




d


, is set to extend away from the ground surface as it approaches the toe part lit. Further, by allowing the aspect ratio a/b which is the ratio of the length a of the major axis


13




d


to the length b of the minor axis


13




e


of the ellipse


13


, to be coincident with the aspect ratio a′/b′ of the ellipses


3




a


,


6




a


, and


9




a


indicating the hitting point distribution of a general player, the inertial resistance in the up-and-down direction and the inertial resistance in the right-and-left direction are allowed to conform to the variation of the hitting points of the general player. This can not only restrain the lateral deviation of the golf club head in the right-and-left direction but also restrain the variation of the flying distance in the flying ball line direction.




According as the identification number increases, the angle θ shown in

FIG. 51B

is successively increased. Also, the aspect ratio a/b is successively decreased according as the identification number of the golf club head increases. Also, the height h of the sweet spot SS from the ground surface


16


shown in

FIG. 51C

is successively decreased according as the identification number of the golf club head increases. By constructing a golf club set using these golf club heads, the variation of the flying distance in the right-and-left direction and the flying ball line direction can be restrained for a golf club of any identification number, whereby the flying distance can be increased by improving the speed of the ball.




Different examples of the present invention will be explained. Referring to

FIG. 53

, an iron golf club head


201


according to the present invention has a back cavity


206


.




In the peripheral weight disposing part


207


of the back cavity


206


, more weight is distributed and disposed in the upper part


208


of the toe and at sites from the central part


209


A of the sole part


209


to the heel part


210


. In other words, the iron golf club head


201


shown in

FIG. 53

has the first weight member provided in the upper part


208


A of the toe and the second weight member provided in the heel part


209


B of the sole.




Here, the head body


202


constituting the iron golf club head


201


is produced by using stainless steel, pure titanium, titanium alloy, and others. At that time, in the peripheral weight disposing part


207


of the back cavity


206


, the thickness is increased at sites in the upper part


208


A of the toe and from the central part


209


A of the sole part


209


to the heel part


210


, and a design can be made in such a manner that the weight distribution is larger on these sites in design.




Referring to

FIG. 54

, an iron golf club head


201


according to the present invention has a back cavity


206


. In the peripheral weight disposing part


207


of the back cavity


206


, weight members


211


A and


211


B having a larger specific gravity than the metal constituting the head body


202


are integrated by engagement to the sites in the upper part


208


A of the toe and from the central part


209


A of the sole part


209


to the heel part


210


. Namely, the iron golf club head


201


has a weight member


211


A serving as the first weight member provided in the upper part


208


A of the toe of the head body


202


and a weight member


211


B serving as the second weight member provided in the heel side part


209


B of the sole. The weight members


211


A and


211


B have a larger specific gravity than the material constituting the head body


202


, and has a larger density than other parts of the head body.




Referring to

FIGS. 55A

to


55


E, in the iron golf club head


201


, the shape of the peripheral weight disposing part


207


of the back cavity


206


is constructed in such a manner that the height of the rear back


207


A successively increases at sites from the lower part


208


B of the toe to the back surface part


210


B of the heel of the sole part


209


. In other words, in the iron golf club head


201


, the depth of the back cavity


206


increases as it approaches from the lower part


208


B of the toe to the heel part


210


. Also, the width of the sole part


209


decreases according as it approaches from the lower part


208


B of the toe to the heel part


210


.




Here, as shown in

FIGS. 55B and 55E

, it is a characteristic of the present invention that the rear back


207


A of the peripheral weight disposing part


207


of the back cavity


206


is not provided in the lower part


208


B of the toe and in the heel part


210


of the sole part


209


. By providing such a construction, more weight can be distributed and disposed at sites in the upper part


208


A of the toe and from the central part


209


A of the sole part


209


to the heel part


210


.




Further, as shown in

FIGS. 55A

to


55


E, the width of the sole part


209


successively decreases according as it approaches from the lower part


208


B of the toe to the heel part


210


.




Further, the aforesaid examples will be explained in detail. The head body


202


is made of pure titanium or titanium alloy. The weight members


211


A and


211


B are constructed with a tungsten alloy having a larger specific gravity than the head body


202


. The weight member


211


A is press-fit and integrated by engagement to the upper part


208


A of the toe of the peripheral weight disposing part


207


of the back cavity


206


. The weight member


211


B is press-fit and integrated by engagement to the sites from the central part


209


A of the sole part


209


to the heel part


210


of the peripheral weight disposing part


207


of the back cavity


206


.




Here, lead, beryllium copper alloy, and brass can be used besides the aforesaid tungsten alloy as a material having a larger specific gravity than the head body


202


. These members are press-fit and integrated by engagement to the sites in the upper part


208


A of the toe and from the central part


209


A of the sole part


209


to the heel part


210


of the peripheral weight disposing part


207


of the back cavity


206


.




In the face part


203


or in the upper opening part


207


B of the peripheral weight disposing part


207


of the back cavity


206


, the distance from the face surface part


206


A of the back cavity


206


to the upper opening part


207


B is about 15 mm, for example, in the case of the fifth iron golf club head. The height of the rear back


207


A of the peripheral weight disposing part


207


of the back cavity


206


is 7 mm at a position shifted by 20 mm from the central part


203


A of the face to the toe part side. The height of the rear back


207


A is 9 mm at the central part


203


A of the face. The height of the rear back


207


A is 12 mm at a position shifted by 12 mm from the central part


203


A of the face to the heel part side, and successively increases.




As a result of this, the weights are disposed in the upper part


208


A of the toe and in the lower part of the heel part


210


, and the angle formed by the major axis of the plane ellipse appearing when the ellipsoid of inertia of the golf club head is cut with a plane parallel to the face surface and the intersecting line of the cut surface and the ground surface increases as it approaches the upper part


208


A of the toe. Also, the height of the sweet spot decreases.




Next, as the material constituting the head body


202


, one can use a metal material such as iron, stainless steel, aluminum, titanium, magnesium, tungsten, copper, nickel, zirconium, cobalt, manganese, zinc, silicon, tin, or chromium, which are materials often used in generally producing a golf club head, or an alloy material of these. Also, FRP (fiber reinforced plastics), synthetic resin, ceramics, rubber, and others can be used, and it may be produced from a single material of these or may be produced from a combination of two or more kinds of these materials.




Also, as a production method, use of a precision casting method is highly convenient because the cost will be low and the dimension precision is high. In addition, the golf club head body can be produced by die-casting, pressing, or forging. It is also possible to produce each of the parts by pressing, forging, precision casting, metal injection, die-casting, cut-processing, powder-metallurgy, or the like and bonding these by welding, adhesion, press-fit, fitting engagement, press-contact, screwing, soldering, or the like to fabricate a golf club head.





FIGS. 56

to


58


are views for comparing the variations of the flying distance between the golf club head according to the present invention and a conventional golf club head. Particularly,

FIG. 57

shows data for the golf club head according to the present invention, and relates to the third iron having a loft angle of 21°. The plane ellipse appearing when the ellipsoid of inertia of the golf club head is cut with a plane parallel to the face surface is made approximately coincident with the distribution of the hitting points of a general player.

FIG. 58

shows data in the case of a conventional golf club head.




A test was performed with a golf robot. The speed of the iron golf club head was set to be 34.5 m/sec. Taking the variation of the hitting points of the general player into account, the hitting point positions were set to be from sweet spot (C) to toe tip part (T·M), upper part of toe tip (T·LT), lower part of toe (T·D), upper part of heel (H·U), lower part of heel (H·D), foot part of heel (HEM), upper part of center (C·U), and lower part of center (C·D), as shown in FIG.


56


. The result of striking at each is shown in Table 5.




Were set to be lower part (H·D), foot part of heel (H·M), upper part of center (C·U), and lower part of center (C·D). The results of striking at respective points are shown. Here, the specifications of the inventive product and the conventional product are shown in Table 5.















TABLE 5










Angle formed by the major









axis of the plane ellipse




Aspect








appearing on the cut




ratio of the








surface of the ellipsoid of




plane ellipse








inertia and the intersecting




appearing on the








line of the cut surface and




cut surface of the




Sweet spot






Sample




the ground surface




ellipsoid of inertia




height











Inventive









2.2




20.0 mm






product






Conventional









2.1




20.7 mm






product














On the other hand, the iron golf club head used in collecting the data shown in

FIG. 57

has the same mass (248 g) as the iron golf club head used for collecting the data shown in FIG.


58


. Referring to

FIG. 56

, when the ellipsoid of inertia is cut with a plane passing through the center of gravity and being parallel to the face surface, the aspect ratio of the plane ellipse appearing on the cut surface is 2.2; the angle formed by the major axis and the intersecting line of the cut surface and the ground surface extends in a toe-up direction to be 8°; and the height of the center of hitting points was 20 mm.




From the results of the flying distance measurement test using the robot, in the conventional product that does not conform to the distribution of the hitting points of the general player, the variation to the right and left by the iron golf club head is about 18 m, as shown in FIG.


58


. In contrast, in the inventive product in which the plane ellipse is made coincident with the distribution of the hitting points of the general player, the variation to the right and left by the iron golf club head is about 15 m, as shown in

FIG. 57

, thereby reducing the variation by 17%.




Also, with respect to the variation in the flying ball line direction, while the variation is about 24 m in the conventional product as shown in

FIG. 58

, it is about 13 m in the inventive product as shown in

FIG. 57

, thereby reducing the variation by 46%. Further, when the average flying distance is compared, while it is 155 m in the conventional product as shown in

FIG. 58

, it is 157 m in the inventive product as shown in FIG.


57


. Namely, an increase in the flying distance by about 2 m was seen.




Here,

FIGS. 57 and 58

show average values-when balls were hit each for ten times.




Also, when the results of striking on the upper part of the toe tip are observed, it is well understood that there is a difference in the rotation performance. Namely, with the conventional product, the decrease in the flying distance in the flying ball line direction due to striking on the upper part of the toe tip is conspicuous, as shown in

FIG. 58

, and further, the balls fall in the right direction as compared with the average lateral deviation. In contrast, with the inventive product, the decrease in the flying distance due to striking on the upper part of the toe tip is small, as shown in

FIG. 57

, and the lateral deviation is also small. This is because, with the inventive product, the rotation of the head is restrained, and it is understood that the rotation performance of the head is excellent.




Also, in the present invention, a labor in the process for fitting a multiple-stage face insert member by engagement, such as in the conventional iron golf club head, is not needed. Also, there is no need to fit the weight member to plural sites of the head body by engagement, so that labor is not needed in the production process, nor does it lead to increase in the cost.




Furthermore, in the case of producing the head body by a precision casting method using a lost wax, there is no fear that warping is generated in the cast product itself in the completed head body, because there are few recesses for fitting engagement of these, thereby improving the yield.




Also, wood golf club heads according to the present invention will be explained.

FIG. 59A

is a view for explaining a striking force generated on a face surface when a golf ball


320


is hit with a wood golf club head, and

FIG. 59B

is a view showing a state in which the golf ball is rotated and flies out from the face surface at the striking time. Referring to

FIG. 59A

, when a golf ball


320


is struck with a wood golf club head


301


, the wood golf club head


301


receives a striking force F from the golf ball


320


in the proceeding direction of the swing at the hitting point position MP of the golf ball


320


. In the wood golf club head


301


, an angle called loft angle is set so that the face surface


30


if forms a certain angle with respect to the ground surface when the sole part


304


is set on the ground surface and addressed, in order to change the flying-out angle of the golf ball


320


in accordance with the identification number and to obtain a flying distance for each identification number. Typically, the loft angle is about 10° in the case of a driver (the first wood golf club head); the loft angle is about 13° in the case of a brassie (the second wood golf club head); the loft angle is about 15° in the case of a spoon (the third wood golf club head); the loft angle is about 18° in the case of a baffy (the fourth wood golf club head); the loft angle is about 21° in the case of a cleek (the fifth wood golf club head); and the loft angle increases according as the identification number increases.




Due to the presence of the loft angle, the striking force F at the striking time can be decomposed into a horizontal partial force FH and a perpendicular partial force FP with respect to the face surface


301




f


. The horizontal partial force FH is a force that rotates the golf ball


302


together with a frictional force of the face surface


301




f


, namely, a force that generates a back spin or a side spin. According as the swing speed increases and the impacting speed of the golf club head


301


increases, the striking force F increases and the horizontal partial force FH increases, so that the back spin and the side spin are more likely to be generated. It seems that the ball trajectory of a wood golf club head of a professional golfer or the like rises high above after the shot, and then falls vertically from above. This is due to the fact that, since the head speed is high, a back spin is generated, and the ball floats upward and falls down.




The perpendicular partial force FP is a force that acts perpendicularly on the face surface


301




f


, as shown in

FIG. 59B

, and this force rotates the face surface


301




f


. By this rotation, the golf ball


302


after the shot flies out in the right-and-left direction and in the up-and-down direction. Here, the point at which the line drawn perpendicularly from the center of gravity G of the head body


302


to the face surface


30


if intersects the face surface


301




f


is referred to as a sweet spot SS. The sweet spot SS is a point by which the golf ball flies most and, if the ball is struck here, the head body


302


rotates little. However, if a general players performs a shot, the ball hardly hits the sweet spot SS, and in most cases the player performs a shot in the peripheries of the sweet spot SS.





FIGS. 60A and 60B

are views showing a distribution of the hitting points of a general player. Particularly,

FIGS. 60A and 60B

show a distribution of the hitting points by a spoon (the third wood golf club). As will be clear from

FIGS. 60A and 60B

, it is understood that a general player strikes at various positions up and down and to the right and left near the sweet spot SS. The player from whom these data have been obtained has a golf score of about 100 and is a general player. In the Figures, the points


301




b


represent hit marks on the face surfaces


301




f


of the wood golf club head


301


. The center of hitting points is denoted by


301




c


. An ellipse


301




a


that approximates the size and the shape of the hitting point distribution by determining an interval covering not less than 95% of the hit marks of the hitting points is shown in a solid line. Further, the face surface


301




f


, the A-axis being parallel to the intersecting line


316


of the face surface


301




f


and the ground surface, as well as the major axis


301




d


of the ellipse


301


approximating the variation of the hitting points, are shown in solid lines.




From this result, it is understood that the golf ball


320


is struck at various locations up and down and to the right and left of the face surface


301




f


of the wood golf club head


301


, and that the hitting points are varied in the right-and-left direction of the toe part


301




t


and the heel part


306


and in the up-and-down direction of the leading edge part


307


and the top edge


308


. Since this variation degrades the directivity of the golf ball


302


after hitting the ball, it is necessary to produce a wood golf club head that maintains the directivity to some extent even if the hitting points are varied.




On the other hand, as will be seen from the results of the hitting point distribution, the shape of the hitting point distribution is a shape of the ellipse


301




a


having a major axis and a minor axis. Further, the major axis


301




d


extends upward and away from the ground surface as it approaches the toe part


301




t


. Also, according as the identification number increases, the angle that the major axis forms with the intersecting line of the cut surface and the ground surface successively increases, and the shape of the ellipse successively approaches a circular


10


shape. Further, the height H of the hitting point center from the ground surface decreases. Thus, it is understood that the shape of the hitting point distribution of a general player has a specific tendency.





FIGS. 61

to


63


are views for explaining an ellipsoid of inertia in the case where the wood golf club head


301


is set on a plane by setting the lie angle and the loft angle to be predetermined angles.




Referring to

FIG. 61

, the axis passing through the center of gravity G and being perpendicular to the ground surface is assumed to be the Z-axis. The axis passing through the center of gravity G and being perpendicular to the Z-axis and parallel to the intersecting line of the angential plane at the centroid (center) of the face surface


301




f


and the ground surface is assumed to be the X-axis. The tangential plane at the centroid (center) of the face surface


301




f


is approximately the same surface as the face surface


301




f


. The axis passing through the center of gravity G and being perpendicular to both the X-axis and the Z-axis is assumed to be the Y-axis.





FIG. 63

is a view showing direction vectors on an ellipse plane appearing when the ellipsoid of inertia of the golf club head is cut.




Referring to

FIG. 63

, the direction vector of a plane passing through the center of gravity G and being parallel to the intersection of the tangential plane at the centroid of the face surface


301




f


and the ground surface is assumed to be f(l, m, n)


T


, and each of the following vectors is calculated.







f




1


(


l




1




, m




1




, n




1


)


T




=f X Z


(0, 0, 1)


T










f




2


(


l




2




, m




2




, n




2


)


T




=f




1




X f












f




3


(


l




3




, m




3




, n




3


)


T




=f




1




X f




2


  (1)






where X designates an outer product.




Referring to

FIGS. 62A

,


62


B, and


62


C, the axis passing through the center of gravity G and being parallel to the intersection of the tangential plane at the centroid of the face surface


301


f and the ground surface is assumed to be α-axis. The axis being parallel to the tangential plane at the centroid of the face surface


301




f


and perpendicular to the α-axis is assumed to be β-axis. The axis being :perpendicular to the α-axis and the β-axis is assumed to be γ-axis. The conversion from the α, β, γ coordinate system to the X, Y, Z coordinate system is represented by the following equations.








X=l




1




·α+l




2




·β+l




3·γ












Y=m




1




·α+m




2




·β+m




3·γ












Z=n




1




·α+n




2




·β+n




3·γ


  (2)






Here, supposing that I


1


, I


2


, I


3


are moments of inertia with respect to the X, Y, Z axes,


112


is a product of inertia with respect to the YZ-plane and the XZ-plane, I


13


is a product of inertia with respect to the YZ-plane and the XY-plane, I


23


is a product of inertia with respect to the XZ-plane and the XY-plane, then the following relationship is obtained.








I




1




·X




2




+I




2




·Y




2




+I




3




·Z




2


+2


·I




12




·X·Y


+2


·I




13




·X·Z


+2


·I




23




·Y·Z


=1  (3)






The ellipsoid represented by the equation (3) is referred to as an ellipsoid of inertia. This shows the magnitude of the inertial resistance in each direction. Substituting the equation (3) with the equation (2) and letting the y term zero, the equation. (4) of the cut ellipse plane is determined.






(


I




1




l




1




2




+I




2




m




1




2




+I




3




n




1




2




+I




12




l




1




m




1




+I




13




l




1




n




1




+I




23




m




1




n




1





2










(


I




1




l




2




2




+I




2




m




2




2




+I




3




n




2




2




+I




12




l




2




m




2




+I




13




l




2




n




2




+I




23




m




2




n




2





2










(


I




1




l




1




2




+I




2




m




1




m




2




+I




3




n




1




n




2




+I




12




l




1




m




2




+I




12




l




2




m




1




+I




13




l




1




n




2




+I




13




l




2




n




1










+(


I




23




m




1




n




2




+I




23




m




2




n




1


)αβ=1  (4)






The magnitude of the cut surface represents the magnitude of the inertial resistance indicating the facility of rotation of this surface. Also, the cut surface represents the inertial resistance in the direction perpendicular to the cut surface. Further, as shown in

FIGS. 62A

,


62


B, and


62


C, it is apparent that the shape of the cut surface is a plane ellipse because it is a cut surface of a three-dimensional ellipsoid of inertia.




The plane ellipse appearing when the ellipsoid of inertia


330


of the golf club head


301


is cut with the face surface


301




f


represents the facility of the rotation in the perpendicular direction with respect to the face surface


301




f


. Also, in the plane ellipse


313


appearing on the cut surface when the ellipsoid of inertia


330


is cut with a plane passing through the center of gravity G and being parallel to the face surface


301




f


, the length of the major axis


313




d


, is represented by a and the length of the minor axis


313


e is represented by b. The aspect ratio is defined by a/b. The angle formed by the major axis


313




d


, and the α-axis is assumed to be θ.




The aforesaid distribution of the hitting points of the general player shown in the

FIGS. 60A and 60B

has an elliptic shape with its center at the hitting point center


30




c


, and the major axis


301




d


extends to go away from the ground surface as it approaches the toe part


301




t


. In other words, as shown in

FIG. 60B

, in the third wood golf club head, the major axis


301




d


of the ellipse


301




a


approximating the variation of the hitting points forms an angle Δ of 5° with respect to the A-axis on the face surface


301




f.






Therefore, by allowing the sweet spot to be approximately coincident with the elliptic center of the plane ellipse appearing when this ellipsoid of inertia is virtually cut with a plane passing through the center of gravity and being parallel to the face surface, the distance between the hitting points and the sweet spot due to the variation of the hitting points can be made as small as possible, whereby the rotation of the golf club head can be restrained. Further, since the ball is hit in the neighborhood of the sweet spot, the velocity of the golf ball is improved to increase the flying distance.




Furthermore, the angle formed by the major axis of the plane ellipse and the intersecting line of the cut surface and the ground surface is allowed to be coincident with the angle of the hitting point distribution of the player (angle in the toe-up direction). By these, the variation of the lateral deviation in the right-and-left direction is restrained. Further, by allowing the aspect ratio which is the ratio of the major axis to the minor axis of the plane ellipse, to be coincident with the aspect ratio of the ellipse of the hitting point distribution of a general player to be approximately equal to the inertial resistance in the up-and-down direction, not only the variation of the lateral deviation in the right-and-left direction can be restrained but also the variation of the flying distance in the flying ball line direction can be restrained.




Here, generally in wood golf club heads, according as the identification number increases, i.e. according as they become a short wood, the angle formed by the major axis of the ellipse indicating the hitting point distribution and the intersecting line of the cut surface and the ground surface successively increases. Therefore, the angle formed by the major axis of the plane ellipse and the intersecting line of the cut surface and the ground surface is successively increased. Also, the shape of the plane ellipse, i.e. the aspect ratio which is a ratio of the major axis to the minor axis, is successively decreased, and the sweet spot is allowed to be coincident with the hitting point position, whereby the variation of the flying distance in the right-and-left direction and in the flying ball line direction is restrained for a golf club head of any identification number, and the flying distance increases by improving the speed of the ball.




Examples pertaining to the present invention will be explained. Referring to

FIGS. 64

to


68


, a wood golf club head


401


made of metal and having a hollow outer shell structure is constructed in such a manner that the weight distribution will be toe-and-low-back-weight by providing weight members


412


and


413


having a larger specific gravity than the material constituting the head body


402


in the upper part


405


A of the toe and in the back part


404


A of the center of the sole part


404


. In other words, the wood golf club head


401


according to the present invention is provided with a weight member


412


disposed in the upper part


405


A of the toe of the head body


402


and a weight member


413


disposed in the back part


404


A of the center of the sole of the head body


402


.




Also, the weight members


413


and


414


have a larger specific gravity than the material constituting the head body. Also, the weight members


413


and


414


have a larger density than other parts. The weight member


412


constitutes the first weight member, and the weight member


413


constitutes the second weight member.




Also, a wood golf club head according to the present invention is a wood golf club head


401


made of metal and having a hollow outer shell I.,structure as shown in

FIG. 67

, where a weight member


412


having a higher specific gravity than the material constituting the head body


402


is disposed in the upper part


405


A of the toe, and a thick part


404


B is provided by partially increasing the thickness of the back part


404


A of the center of the sole part


404


. Alternatively, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight by forming a protruding part


411


to increase the thickness, as shown in FIG.


68


. The weight member


412


constitutes the first weight member, and the thick part


411


constitutes the second weight member.




Also, a wood golf club head according to the present invention is a wood golf club head


401


made of metal and having a hollow outer shell structure as shown in

FIG. 69

, where a weight member


412


having a higher specific gravity than the material constituting the head body


402


is disposed in the upper part


405


A of the toe, and the thickness is increased by partially increasing the thickness of the back part


404


A of the center of the sole part


404


or by forming a protruding part


411


, as shown in FIG.


69


. With that part, a weight member


413


having a higher specific gravity than the material constituting the head body


402


is combined. By this, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight. In

FIG. 68

, the weight member


412


constitutes the first weight member, and the protruding part


411


constitutes the second weight member. In

FIG. 69

, the weight member


412


constitutes the first weight member, and the protruding part


411


and the weight member


413


constitute the second weight member.




Here, the thickness of the sole part


404


is preferably at least not smaller than 1 mm and not larger than 10 mm.




Another example of the present invention will be explained. Referring to

FIG. 70

, a wood golf club head


401


according to the present invention is a wood golf club head made of metal and having a hollow outer shell structure, in which a thick part


405


B is provided by partially increasing the thickness of the upper part


405


A of the toe, and a thick part


404


B is provided by partially increasing the thickness of the back part


404


A of the center of the sole part. By this, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight. The thick part


405


B constitutes the first weight member, and the thick part


404


B constitutes the second weight member.




Another example of the present invention will be explained. Referring to

FIG. 71

, in a wood golf club head;


401


made of metal and having a hollow outer shell structure, a thick art


405


B is formed by increasing the thickness of the upper part of the toe, and a protruding part


411


serving as the second weight member is disposed in the back part


404


A of the center of the sole part


404


. By this, the weight distribution will be toe-and-low-back weight. The thick part


405


B constitutes the first weight member, and the protruding part


411


constitutes the second weight member.




Another example of the present invention will be explained. Referring to

FIG. 72

, in a wood golf club he′ad


401


made of metal and having a hollow outer shell structure, a protruding part


414


is disposed in the upper part


405


A of the toe in the inside


410


of the head body, and a thick part


404


B is disposed in the back part


404


A of the center of the sole part


404


. By this, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight. The protruding part


414


constitutes the first weight member, and the thick part -


404


B constitutes the second weight,m ember.




Another example of the present invention will be explained.




Referring to

FIG. 73

, in a wood golf club head


401


made of metal and having a hollow outer shell structure, a protruding part


414


is disposed in the upper part


405


A of the toe in the inside


410


of the head body, and a protruding part


411


is disposed in the back part


404


A of the center of the sole-part


404


. By this, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight. The protruding part


414


constitutes the first weight member, and the protruding part


411


constitutes the second weight member.




Another example of the present invention will be explained. Referring to

FIG. 74

, in a wood golf club head


401


made of metal and having a hollow outer shell structure, a protruding part


414


is formed in the upper part


405


A of the toe in the inside


410


of the head body, and a weight member


412


having a larger specific gravity than the material constituting the head body


402


is disposed in the protruding part


414


. Also, a thick part


404


B is disposed in the back part


404


A of the center of the sole part


404


. By this, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight. The protruding par


414


and the weight member


412


constitute the first weight member, and the thick part


404


B constitutes the second weight member.




Another example of the present invention will be explained. Referring to

FIG. 75

, in a wood golf club head


401


made of metal and having a hollow outer shell structure, a protruding part


414


is formed in the upper part


405


A of the toe in the inside


410


of the head body, and a weight member


412


having a larger specific gravity than the material constituting the head body is disposed in the protruding part


414


. A protruding part


411


is formed in the back part


404


A of the center of the sole part


404


. By this, it is constructed in such a manner that the weight distribution will be toe-and-low-back-weight. The protruding part


414


and the weight member


412


constitute the first weight member, and the protruding part


411


constitutes the second weight member.




Another example will be explained. Referring to

FIG. 76

, in a wood golf club head


401


made of metal and having a hollow outer shell structure, a protruding part


414


is formed in the upper part


405


A of the toe in the inside


410


of the head body, and a weight member


412


having a larger specific gravity than the material constituting the head body is disposed in the protruding part


414


. A protruding part


411


is formed in the back part


404


A of the center of the sole part


404


, and a weighted member


413


having a larger specific gravity than the material constituting the head body is disposed thereon. By this, the weight distribution will be toe-and-low-back-weight. The protruding part


414


and the weight member


412


constitute the first weight member, and the. protruding part


411


and the weight member


413


constitute the second weight member.




Here, the shape of the wood golf club head of the present invention will be shown in

FIGS. 77

to


80


.

FIG. 77

is a perspective view seen from the toe part;

FIG. 78

is a perspective view seen from the heel part;

FIG. 79

is a left side view; and

FIG. 80

is a perspective view of a back surface seen from the toe part.




Here, in the wood golf club head of the present invention, the material of the head body


402


is, for example,


6


-


4


titanium, and a tungsten alloy can be used as the material having a larger specific gravity than the head body


402


. A tungsten alloy of 8 g is press-fit and fixed into the upper part


405


A of the toe and a tungsten alloy of 15 g is press-fit-and fixed into the back part


404


A of the center of the sole part




Also, the thickness of the upper part


405


A of the toe is preferably about 2 mm, and a weight is disposed in the upper part


405


A of the toe by allowing the thickness of the upper part


405


A of the toe to be larger than the thickness (1.2 mm) of the crown part


415


. Further, the thickness of the sole part


404


is set to be about 4 mm.




Here, in the wood golf club head of the present invention, as a mode of the component (weight member) having a larger specific gravity than the head body


402


, those having a T-letter shape, a cylindrical shape, a male screw shape, a plate shape, a rectangular shape, a hemispherical shape, a toe part shape of the head body, a sole part shape, a curvature shape approximated to the head body, and other suitable shapes can be selected.




These can be fixed to the inside or the outside of the head body by welding, adhesion, fitting engagement, screwing, caulking, press-fitting, or the like.





FIGS. 81A and 81B

show constructions of third wood golf club heads of the inventive product and the conventional product. In the inventive product shown in

FIG. 81A

, when the ellipsoid of inertia of the golf club head


501


is cut with a plane passing through the center of gravity and being parallel to the face surface


501




f


, the ratio (aspect ratio: a/b) of the major axis


513




d


, to the minor axis


513




e


of the plane ellipse


513


appearing on the cut surface is 1.4, and the major axis


513




d


, extends upward and away from the ground surface as it approaches the toe part


501




t


. Also, the angle formed by the major axis


513




d


, and the α-axis which is parallel to the intersecting line of the cut surface and the ground surface, is 5°.




On the other hand, in the case of the conventional product shown in

FIG. 81B

, the ratio (aspect ratio: a/b) of the major axis


613




d


, to the minor axis


613




e


of the plane ellipse appearing when the ellipsoid of inertia of the golf club head


601


is cut with a plane passing through the center of gravity and being parallel to the face surface


601




f


, is 1.5. Also, the major axis


613




d


, extends to approach the ground surface as it approaches the toe part


601




t


, and the angle formed by the major axis


613




d


, and the α-axis was −3°. In other words, in the inventive product, the major axis


513




d


, had a toe-up angle, while in the conventional product, the major axis


613




d


, had a toe-down angle.




As the material of the wood golf club head according to the present invention, iron, stainless steel, aluminum, titanium, magnesium, tungsten, copper, nickel, zirconium, cobalt, manganese, zinc, silicon, tin, chromium, FRP (fiber reinforced plastics), synthetic resin, ceramics, rubber, and others, which are materials generally used in a wood golf club head, may be mentioned. It can be produced from a single material of these or can be produced from a combination of two or more of these materials.




Also, as a production method, if a precision casting method is used, the cost is low and the dimension precision is high. In addition, the head body can be produced by die-casting, pressing, or forging. On the other hand, it is also possible to produce each of the parts by pressing, forging, precision casting, metal injection, die-casting, cut-processing, powder-metallurgy, or the like and bonding these by welding, adhesion, press-fit, fitting engagement, press-contact, screwing, soldering, or the like to fabricate a golf club head.





FIGS. 82

to


84


are views for comparing the variations of the flying distance between the wood golf club head according to the present invention and a conventional wood golf club head. Particularly,

FIG. 83

is according to the inventive product, and is a spoon (the third wood golf club head) having a loft angle of 15°, where the plane ellipse appearing when the ellipsoid of inertia is cut is made approximately coincident with the distribution of the hitting points of a general player. On the other hand,

FIG. 84

is according to the conventional product.




A test was performed with a golf robot. The speed of the wood golf club head was set to be 40 m/sec and, by taking the variation of the hitting points of the general player into account, the hitting point positions of the wood golf club head were tilted by 5° from the sweet spot to the upper part of the toe to provide upper part of toe (T·U), lower part of toe (T·D), upper part of heel (H·U), and lower part of heel (H·D), as shown in FIG.


82


. Each of the points was set at a position located away by 12 mm in the toe-and-heel direction, and by 6 mm in the up-and-down direction. Here, in the wood golf club head shown in

FIG. 82

, a weight member was disposed in the same manner as in the wood golf club head shown in FIG.


65


.





FIG. 83

is a view showing variation of the flying distance by a wood golf club head according to the present invention.

FIG. 84

is a view showing variation of the flying distance by a wood golf club head according to a conventional product. The wood golf club heads that were put to use both have the same mass (215 g). From the results of the flying distance measurement test by the robot, with the conventional product in which the shape of the plane ellipse does not conform to the hitting point distribution of a general player, the variation to the right and left by the wood golf club head is about 18 m at the maximum, as shown in FIG.


84


. In contrast, with the inventive product in which the plane ellipse conforms to the hitting point distribution of the general player, the variation to the right and left by the wood golf club head is about 5 m, as shown in

FIG. 83

, thereby reducing the variation by 72%.




On the other hand, with respect to the variation in the flying ball line direction, the variation of the flying distance by the wood golf club head was 12 m at the maximum in the case of the inventive product as shown in

FIG. 83

, while the variation by the wood golf club head was about 30 m at the maximum in the case of the conventional product as shown in FIG.


84


. By this, a reduction of variation by 60% is seen. Further, when the average flying distance is compared, while the average value of the flying distance by the wood golf club was 193 m in the case of the conventional product as shown in

FIG. 84

, the average value of the flying distance was 205 m in the case of the inventive product as shown in

FIG. 83

, whereby increase in the flying distance by about 12 m was seen.




Here,

FIGS. 83 and 84

show average values when balls were hit each for three times.




Also, when the results of striking on the upper part of the toe are observed, it is well understood that there is a difference in the rotation performance. Namely, in the: case of the conventional wood golf club head, the decrease in the flying distance in the flying ball line direction due to striking on the upper part of the toe is conspicuous, as shown in

FIG. 84

, and further, the golf balls fall in the right direction as compared with the average lateral deviation. In contrast, in the case of the wood golf club head of the inventive product, the decrease in the flying distance due to striking on the upper part of the toe is small, as shown in

FIG. 83

, and the lateral deviation is also small. This means that, with the inventive product, the rotation of the head is restrained as compared with the conventional product, and it is understood that the rotation performance of the head is excellent.




As described above, in the wood golf club heads according to the present invention, the rotation of the head itself is restrained, as compared with the conventional wood golf club head, even if the balls are hit at the upper part of the toe at the time of hitting the balls. This produces an effect that a wood golf club head can be provided in which the decrease in the flying distance is small, the lateral deviation is small, and an excellent flying distance can be achieved. Industrial Applicability




The present invention is used for golf club heads and golf club sets.



Claims
  • 1. A golf club set comprising a plurality of golf clubs having different identification numbers, whereineach of said plurality of golf clubs has a golf club head and a shaft connected to said golf club head; each of sail golf club heads has an ellipsoid of inertia with its center at a center of gravity; when said ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, a major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of said cut surface and a ground surface; the major axis of said plane ellipse extends upward and away from the ground surface as it approaches a toe part; said angle θ is not smaller than 0.5° and not larger than 9.5°; an aspect ratio a/b defined by a ratio α length α of the major axis to length b of a minor axis of said plane ellipse is not smaller than 1 and not larger than 4; said angle θ of each of the plurality of golf club heads increases successively with an approximately constant ratio according as the identification number of said golf club increases; and said aspect ratio a/b of said plurality of golf club heads decreases successively or remains approximately equal according as said identification number increases.
  • 2. The golf club set as set forth in claim 1, wherein said aspect ratio a/b decreases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 3. A golf club set comprising a plurality of golf clubs having different identification numbers, whereineach of said plurality of golf clubs has a golf club head and a shaft connected to said golf club head; each of said golf club heads has an ellipsoid of inertia with its center at a center of gravity; when said ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, a major axis of a plane ellipse appearing on its cut surface for ms an angle of θ with an intersecting line of said cut surface and a ground surface; said major axis extends upward and away from the ground surface as it approaches a toe part; said angle θ is not smaller than 0.5° and not larger than 9.5°; said angle θ of each of the plurality of golf club heads increases successively with an approximately constant ratio according as the identification number of said golf club increases; and a height h of a sweet spot of each of said plurality of golf club heads decreases successively or remains approximately equal according as said identification number increases.
  • 4. The golf club set as set forth in claim 3, wherein the height h of said sweet spot decreases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 5. A golf club set comprising a plurality of golf clubs having different identification numbers, whereineach of said plurality of golf clubs has a golf club head and a shaft connected to said golf club head; each of said golf club heads has an ellipsoid of inertia with its center at a center of gravity; when said ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, an aspect ratio a/b defined by a ratio of a length a of the major axis to a length b of a minor axis of a plane ellipse appearing on its cut surface is not smaller than 1 and not larger than 4; a height h of a sweet spot from a ground surface is not smaller than 10 mm and not larger than 30 mm; said aspect ratio a/b of each of said plurality of golf club heads decreases successively with an approximately constant ratio according as the identification number of said golf club increases; and the height h of the sweet spot of each of said plurality of golf club heads decreases successively or remains approximately equal according as said identification number increases.
  • 6. The golf club set as set forth in claim 5, wherein the height h of said sweet spot decreases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 7. A golf club set comprising a plurality of golf clubs having different identification numbers, whereineach of said plurality of golf clubs has a golf club head and a shaft connected to said golf club head; each of said golf club heads has an ellipsoid of inertia with its center at a center of gravity; when said ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, an aspect ratio a/b defined by ratio of a length a of the major axis to a length b of a minor axis of a plane ellipse appearing on its cut surface is not smaller than 1 and not larger than 4; a height h of a sweet spot from a ground surface is not smaller than 10 mm and not larger than 30 mm; said aspect ratio a/b of each of said plurality of golf club heads decreases successively or remains approximately equal according as said identification number increases; the height h of the sweet spot of each of said plurality of golf club heads decreases successively or remains approximately equal according as said identification number increases; said major axis forms an angle of θ with an intersecting line of said cut surface and a ground surface; said major axis extends upward and away from the ground surface as it approaches a toe part; said angle θ is not smaller than 0.5° and not larger than 9.5°; and said angle θ of each of said plurality of golf club heads increases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 8. A golf club set comprising a plurality of iron golf clubs having different identification numbers wherein,each iron golf club has a head body having a toe, a sole, and a heel; wherein each iron golf club has a first weight member disposed in an upper part of the toe of said head body; and wherein each iron golf club has a second weight member disposed in a heel side part of the sole of said head body, wherein each of the iron golf club heads have an ellipsoid of inertia with its center at a center of gravity, wherein when said ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of said head body and being parallel to a face surface, a major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of said cut surface and a ground surface, and wherein said angle θ increases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 9. The golf club set as set forth in claim 8, wherein said first weight member has a larger specific gravity than a material constituting said head body.
  • 10. The golf club set as set forth in claim 8, wherein said second weight member has a larger specific gravity than in material constituting said head body.
  • 11. The golf club set as set forth in claim 8, wherein said first weight member has a larger density than other parts of said head body.
  • 12. The golf club set as set forth in claim 11, wherein a depth of said back cavity increases according as it approaches from a lower part of the toe to a heel pan.
  • 13. The golf club set as set forth in claim 8, wherein said second weight member has a larger density than other parts of said head body.
  • 14. The golf club set as set forth in claim 8, wherein said head body has a back cavity.
  • 15. The golf club set as set forth in claim 8, wherein a width of a sole part decreases according as it approaches from a lower part of the toe to a heel part.
  • 16. The golf club set as set forth in claim 8, wherein said head body has a through-hole, and further comprising an insert member fitted into said through-hole so as to form a back cavity.
  • 17. A golf club set comprising a plurality of golf clubs having an identification number a club head, and an ellipsoid of inertia with its center at a center of gravity, whereinwhen said ellipsoid of inertia of each of said plurality of golf clubs is virtually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, a major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of said cut surface and a ground surface; the major axis of said plane ellipse extends upward and away from the ground surface as it approaches a toe panrt; and an aspect ratio a/b defined by a ratio of a length a of the major axis to a length b of a minor axis of said plane ellipse decreases successively with an approximately constant ratio according as said identification number of said golf club increases.
  • 18. The golf club set as set forth in claim 17, wherein a height h of a sweet spot from the ground surface is not smaller than 10 mm and not larger than 30 mm.
  • 19. The golf club set as set forth in claim 17, wherein a height h of a sweet spot of said golf club head decreases successively or remains approximately equal according as said identification number of said golf club increases.
  • 20. The golf club set as set forth in claim 17, wherein said angle θ increases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 21. The golf club set as set forth in claim 17, wherein a height h of a sweet spot decreases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 22. The golf club set as set forth in claim 17, each of said golf clubs further comprise:a head body having a toe, a sole, and a heel; a first weight member disposed in an upper part of the toe of said head body; and a second weight member disposed in a heel side part of the sole of said head body.
  • 23. The golf club set as set forth in claim 22, wherein said first weight member has a larger specific gravity than a material constituting said head body.
  • 24. The golf club set as set forth in claim 22, wherein said second weight member has a larger specific gravity than a material constituting said head body.
  • 25. The golf club set as set forth in claim 22, wherein said first weight member has a larger density than other parts of said head body.
  • 26. A golf club set comprising a plurality of golf clubs having different identification numbers, whereineach of said plurality of golf clubs has a golf club head; each of said golf club heads has an ellipsoid of inertia; wherein said ellipsoid of inertia is virtually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, a major axis of a plane ellipse appearing on its cut surface forms an angle of θ with an intersecting line of said cut surface and a ground surface; and said angle θ increases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 27. The golf club set as set forth in claim 26, wherein said angle θ is not smaller than 0.5° and not larger than 9.5°.
  • 28. The golf club set as set forth in claim 26, wherein a height h of a sweet spot from the ground surface of said golf club head is not smaller than 10 mm and not larger than 30 mm.
  • 29. The golf club set as set forth in claim 26, wherein a height h of a sweet spot from the ground surface of said golf club head decreases successively or remains approximately equal according as said identification number of said golf club increases.
  • 30. A golf club set comprising a plurality of golf clubs having different identification numbers, whereineach of said plurality of golf clubs has a golf club head; each of said golf club heads has an ellipsoid of inertia; wherein said ellipsoid of inertia is visually cut with a plane passing through the center of gravity of said golf club head and being parallel to a face surface, an aspect ratio a/b defined by a ratio of a length a of the major axis to a length b of a minor axis of a plane ellipse appearing on its cut surface; and wherein said aspect ratio a/b decreases successively with an approximately constant ratio according as the identification number of said golf club increases.
  • 31. The golf club set as set forth in claim 30, wherein said aspect ratio is not smaller than 1 and not larger than 4.
  • 32. The golf club set as set forth in claim 30, wherein a height h of a sweet spot from the ground surface of said golf club head is not smaller than 10 mm and not larger than 30 mm.
  • 33. The golf club set as set forth in claim 30, wherein a height h of a sweet spot from the ground surface of said golf club head decreases successively or remains approximately equal according as said identification number of said golf club increases.
Priority Claims (4)
Number Date Country Kind
11-097990 Apr 1999 JP
11-260743 Sep 1999 JP
11-260845 Sep 1999 JP
2000-012304 Jan 2000 JP
Parent Case Info

This application claims priority based on the following; PCT Application No. PCT/JP00/02162 filed Apr. 3, 2000; Japanese patent application No. 11-097990(P) filed Apr. 5, 1999; Japanese patent application No. 11-260743(P) filed Sep. 14, 1999; Japanese patent application No. 11-260845(P) filed Sep. 14, 1999; and Japanese patent application No. 2000-012304(P) filed Jan. 20, 2000, entitled “Golf Club Head, Iron Golf Club Head, Wood Gold Club Head, and Golf Club Set.”

PCT Information
Filing Document Filing Date Country Kind
PCT/JP00/02162 WO 00
Publishing Document Publishing Date Country Kind
WO00/59585 10/12/2000 WO A
US Referenced Citations (11)
Number Name Date Kind
5309753 Johnson May 1994 A
5335914 Long Aug 1994 A
5366223 Werner Nov 1994 A
5375840 Hirsch et al. Dec 1994 A
5447309 Vincent Sep 1995 A
5613917 Kobayashi Mar 1997 A
5643103 Aizawa Jul 1997 A
5836830 Onuki et al. Nov 1998 A
5935018 Takeda Aug 1999 A
6045455 Kosmatka et al. Apr 2000 A
6093112 Peters Jul 2000 A
Foreign Referenced Citations (10)
Number Date Country
1300970 Dec 1989 JP
7-67991 Mar 1995 JP
9149954 Jun 1997 JP
9-154984 Jun 1997 JP
10225540 Aug 1998 JP
234903 Nov 1994 TW
296633 Jan 1997 TW
322789 Dec 1997 TW
353028 Feb 1999 TW
WO 9215374 Sep 1992 WO
Non-Patent Literature Citations (3)
Entry
International Publication No. WO 98/31433; Jul. 1998 (original and correction version).
Taiwanese Office Action dated Oct. 14, 2002 and English Translation, Application No. 91101363.
Taiwanese Office Action dated Mar. 13, 2003 and English Translation, Application No. 91101364.