JP2009160050A - Golf club - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a golf club with excellent operability, allowing a player to easily swing the golf club by controlling the air resistance against the movement of a head from the top position till a ball is hit considering the whole swing of the player. <P>SOLUTION: The golf club includes a shell formed of a face part 8, a crown part 9, a sole part 10, side parts 11 on a toe side 11a and a heel side 11b, and a back part 12 in the rear; and the hollow metal head with an internal space formed inside the shell. The sole part 10 has a plurality of recesses having a heel-side recess 20 as an air flowing passage from the heel side 11b toward the toe side 11a, a toe-side recess 21, and a center recesses 22 and 23. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a golf club, and more particularly to a golf club that reduces the adverse effects of air resistance during a swing, is easy to swing, and has excellent operability.

  Conventionally, for example, a technique disclosed in Patent Document 1 is known as a technique related to air resistance during swing in a golf club. This technique has a central rib at the rear of the head and a cavity above and below it, and forms a curved concave shape in the cavity to prevent vibration of the head due to air resistance.

Further, in Patent Document 2, an air flow guide groove is formed on the sole surface so as to extend from the ball striking surface side toward the rear end portion and penetrate rearward from the head rear end portion. A technique is disclosed in which the rear end side is made smaller. In this technique, the movement of the high pressure portion of the air by reducing the groove width and the action of the rectified air flow act synergistically to prevent the head from side to side blurring.
Japanese Patent No. 3697270 JP-A-5-337220

  However, the golf club disclosed in the above-mentioned patent document only captures the movement of the head in the direction orthogonal to the face surface, that is, the movement of the head after the direction of hitting the ball. In other words, during the series of swings of the player, only measures are taken by capturing only the movement of the head immediately before the ball is hit. Considering the air resistance acting on the head as seen from the entire swing, It is difficult to achieve a sufficient effect. In other words, since the golf swing moves from the top state to the downswing position and from the time when the golfer hits the ball to hit the ball, the direction of the head changes. Even if only the moving direction of the head is taken into consideration, the effect cannot be expected, or it becomes extremely limited.

  The present invention has been made on the basis of the above-mentioned problems. In consideration of the player's entire swing, the air resistance is controlled for the movement of the head from the top position until the hitting ball is made, and the swing is easy to operate. An object of the present invention is to provide an excellent golf club.

  In order to achieve the above object, a golf club according to the present invention forms an outer shell with a face portion, a crown portion, a sole portion, a side portion on a toe side and a heel side, and a back portion on the rear side. A hollow metal head having an inner space formed in the outer shell, and a heel side recess serving as a passage through which air flows from the heel side to the toe side, and a toe side recess. And a plurality of recesses having a central recess.

  In general, when a golfer swings, the face is facing the front until the golfer swings from the top position to the downswing position, and the air flow due to the swing moves from the heel side of the head to the toe side. Will come to do. Also, from the downswing position to the impact, the head gradually moves while rotating so that the face faces the ball by the wrist turning operation.

  According to the golf club having the head having the structure as described above, a plurality of recesses serving as air passages are formed in the sole portion from the heel side toward the toe side, so that the golfer swings. At the time, during the swing before the transition from the top position to the downswing position, air easily flows from the heel side to the toe side, air resistance acting on the head can be reduced, and the head speed is prevented from decreasing. .

  In addition, since the plurality of recesses are formed, turbulence is generated depending on the ridgeline (or peak) between the recesses and the depth of the recesses when air flows. Such turbulence can reduce the difference in atmospheric pressure (suppressing the sole side from becoming low pressure) when the air flow on the surface of the crown portion and the air flow on the surface of the sole portion are taken into consideration. Thus, it is possible to reduce the force with which the head is pulled in the centrifugal direction, and it is easy to control the head by preventing a strong tension from acting on the player's hand holding the club.

  Furthermore, in the swing from the downswing position to the hit ball, the central recess can create a path for air to flow from the face side to the back side, thereby reducing the air resistance acting on the head until the impact. become.

  Therefore, the golf club is easy to swing and has excellent operability over the entire swing from the top to the hit ball.

  According to the present invention, when a golfer swings, the air resistance is controlled with respect to the movement of the head from the top position until a hit ball is made, and a golf club that is easy to swing and has excellent operability can be obtained. It becomes like this.

Hereinafter, embodiments of a golf club according to the present invention will be described.
FIG. 1 is a front view showing an embodiment of a golf club according to the present invention. The golf club 1 has a specified lie angle α with respect to a reference horizontal plane P at the tip of a shaft 5 made of metal or FRP. The head 7 set to be fixed. In this case, the head main body 7A constituting the head 7 is made of a hollow metal, and includes a face portion 8, a crown portion 9, a sole portion 10, a toe side 11a and a heel side 11b as will be described later. An outer shell is formed by the side portion 11 and the back portion 12 on the rear side, and an internal space is formed in the outer shell.

  When the golfer swings as described above, the golf club 1 addresses and holds the head 7 with respect to the ball (impact position P1) as shown in FIG. 2 and then backswings to the top position P2. Shake up. Then, the shaft 5 is swung down along a predetermined circular orbit until it shifts from this state to the downswing position P3 (position immediately before the head return operation is performed). Until the transition from the top position P2 to the downswing position P3, the face portion 8 of the head 7 is substantially facing the front (as shown in FIG. 2, the face portion 8 is always visible when the golfer is viewed from the front. During the swing, air flows on the surface of the sole portion 10 of the head 7 from the heel side toward the toe side.

  Then, while the golf club moves from the downswing position P3 to the impact position P1, the face portion 8 faces the front with respect to the ball while the head rotates approximately 90 ° by the wrist turning operation. The position where the face portion 8 faces the front with respect to the ball is an impact position P1, and after impacting the ball, the golf club is finally swung up to the position P4 by a follow-through operation.

  As described above, in the swing operation when impacting the ball, the air moves from the heel side to the toe side along the surface of the sole portion 10 of the head 7 until the top position P2 shifts to the downswing position P3. In the present invention, the sole portion is shaped so as to be easily controlled without lowering the swing speed of the head 7 by paying attention to the air flow.

  Further, in this embodiment, even in such a sole portion shape, even if the head 7 is rotated and rotated by the wrist returning operation during the transition from the downswing position P3 to the impact position P1, the influence of the air resistance during that time. And the head 7 is easily controlled.

  Hereinafter, a specific configuration of the head 7 will be described with reference to FIGS. 3 is a plan view of the head viewed from the crown side, FIG. 4 is a front view of the head viewed from the face side, and FIG. 5 is a bottom view of the head viewed from the sole side. 6 is a sectional view taken along the line AA in FIG. 5, FIG. 7 is a sectional view taken along the line BB in FIG. 3, FIG. 8 is a side view of the head viewed from the heel side, and FIG. 9 is a side view of the head as viewed from the toe side.

  A head main body 7A constituting the head 7 is made of a metal having a hollow structure, and includes a face portion 8 having a hitting surface, a crown portion 9 extending rearward from an upper edge (top edge) of the face portion 8, and a face portion. 8 and a sole portion 10 extending rearward from the lower edge (leading edge), and further extending from the toe side edge of the face portion 8 to the heel side edge of the face portion via the back side. The hollow portion is provided with a side portion 11 connecting the crown portion 9 and the edge portion of the sole portion 10. In the drawings, the toe side and the heel side constituting such a side portion 11 are denoted by reference numerals 11a and 11b, respectively. Moreover, the toe side 11a and the heel side 11b are connected by the back part 12 as it moves rearward.

  The face portion 8 is provided with a face member 8a on which a hit ball is actually formed. In this case, the face member 8a may be formed of a plate-like member that closes the front opening of the crown portion 9, the sole portion 10, and the side portion 11 (the entire face portion is constituted by a face member). ), May be formed in a so-called cup shape, and may constitute part of the crown portion 9, the sole portion 10, and the side portion 11. Alternatively, a configuration in which an opening having a predetermined size is formed in the face portion 8 and a plate-like face member is fitted in the opening portion may be employed.

  The head main body 7A is preferably integrally formed by casting, for example, a titanium-based alloy, an iron-based alloy, or the like, except for the face member 8a provided on the face portion 8, and on the front surface side of the face portion 8A. An opening is formed in which the face member 8a formed in the cup shape constituting the hitting surface is fixed by welding, adhesion or the like. Of course, in the head main body 7A, each member (face portion, crown portion, sole portion, side portion; outer shell member) constituting the head main body 7A is individually formed and fixed by welding, bonding or the like. good.

  The face member 8a provided in the face portion 8 is preferably integrally formed by, for example, pressing or forging a titanium alloy, an iron alloy, or the like so as to have a predetermined cup shape, The face member 8a thus formed is fixed to the end face of the opening by adhesion, welding, brazing or the like. Of course, the face portion 8 may be integrally formed with the head main body 7A instead of fixing the face member 8a as a separate member.

  Further, a shaft fastening portion (not shown) for fastening the tip of the shaft 5 is integrally formed in the head main body 7A. In this case, the shaft is fixed to the shaft fixing portion by inserting the tip end portion of the shaft through the opening 9a of the hosel portion 9b formed to protrude from the crown portion 9.

  As shown in FIGS. 3 and 4, the crown portion 9 constituting the head body 7 </ b> A defines a ridge line 14 between the side portion 11 and the back portion 12. The ridge line 14 is a portion (boundary) that divides the air flow into the sole portion direction and the crown portion direction during the swing. As shown in FIG. 4, the front end side of the crown portion 9 and the front end side of the sole portion 10 define a top edge TE and a leading edge LE between the face portion 8.

  As shown in FIG. 5, the sole portion 10 has a plurality of recesses. The plurality of concave portions have a heel side concave portion, a toe side concave portion, and a central concave portion so that a passage through which air flows as indicated by an arrow X from the heel side toward the toe side is formed. In the present embodiment, the heel side recess has one location (indicated by reference numeral 20), the toe side recess has one location (indicated by reference numeral 21), the central recess has the heel side recess 20 formed in each one location, and the toe side recess. Two locations (indicated by reference numerals 22 and 23, respectively) are formed between the side recess 21 and the side recess 21.

  In the present embodiment, in the face-back direction, the heel side concave portion 20, the toe side concave portion 21, and the central concave portions 22, 23 are more easily flown from the heel side toward the toe side. It has a curved shape in which the substantially central portion is recessed most. In FIG. 8, the recesses (maximum recesses) formed in the heel side recess 20 and the center recess 22 are indicated by reference numerals 20A and 22A. Similarly, in FIG. 9, the toe side recess 21 and Recesses formed in the central recess 23 are indicated by reference numerals 21A and 23A.

  In this way, the recesses 20A, 22A and 21A, 23A formed so that air easily flows from the heel side to the toe side are indicated by a line X in FIG. 5 in consideration of the actual air flow. In this way, it is preferable to form a straight line (the recessed portions 20A and 22A and the recessed portions 21A and 23A coincide with the line X), but each recessed portion is slightly shifted to the face side or back side. You may shift to. In other words, when viewed as the entire sole portion, it is sufficient that the air is formed so as to easily flow from the heel side toward the toe side.

  By forming a plurality of concave portions in the sole portion 10 from the heel side toward the toe side, peak portions are formed between the respective concave portions. Specifically, a ridge 25 is formed between the heel side recess 20 and the center recess 22, a ridge 26 is formed between the center recesses 22, 23, and between the toe side recess 21 and the center recess 23. A ridge 27 is formed at the top. In this case, when the golf club is placed on the ground at a predetermined loft angle, the peak portion 26 comes into contact with the ground, and the peaks 25 and 27 have a small gap (distance) between the ground.

  Further, as shown in FIG. 5, ridgelines 20a, 21a, 22a, and 23a are formed at the boundaries between the concave portions and the peak portions.

  As described above, the plurality of recesses 20, 21, 22, and 23 that form air passages from the heel side 11b toward the toe side 11a are formed on the sole portion 10, so that when the golfer swings, the top During the swing before the transition from the position to the downswing, air easily flows from the heel side to the toe side.

  In particular, in this embodiment, the maximum depressions 20A, 22A and 21A, 23A in each recess are formed in a straight line so as to coincide with the direction indicated by the arrow X in FIG. 5, thereby reducing the air resistance acting on the head. It is possible to suppress the head speed from decreasing.

  Moreover, it is preferable to form the curved inclined surfaces 20b and 21b centering on the line X in the center side in the heel side recessed part 20 and the toe side recessed part 21 formed as mentioned above. . As shown in FIG. 5, the inclined surfaces 20 b and 21 b are configured as curved surfaces that gradually rise toward the center side with the curved bottom lines 20 c and 21 c as lower end edges in the respective recesses.

  By forming the curved inclined surfaces 20b and 21b in this way, air can be guided more smoothly from the heel side to the toe side, and the air flow can be converged and guided.

  In addition, since the plurality of recesses 20, 21, 22, and 23 are formed, turbulence is generated by the ridgelines 20a, 21a, 22a, and 23a between the recesses and the depth of each recess when air flows. It comes to occur. Specifically, for example, in the state shown in FIG. 6, when air flows from the heel side to the toe side, the air hitting the ridge lines 22 a and 23 a defining the peak portion 26 flows into the next central recess 23. Turbulent flow will occur. Such a turbulent flow is generated in each recess, and such a turbulent flow is obtained when the air flow X1 on the surface of the crown portion 9 and the air flow X on the surface of the sole portion 10 are considered. It acts to reduce the difference in atmospheric pressure (suppressing the sole side from becoming low pressure). This makes it possible to reduce the force pulled in the centrifugal direction while the head 7 moves from the top position to the downswing position, and prevents the player from holding a strong tension on the hand holding the golf club. This makes it easier to control the head 7.

  In the configuration described above, the direction of the maximum depression (direction indicated by arrow X) is not parallel to the line FX in contact with the center position C on the left and right sides of the face, but on the toe side with respect to the direction of the line FX It is desirable that the angle 11a be formed so that 11a is on the back side.

  By forming the angle θ in this way, when air flows in the direction of the arrow X, the air resistance is relatively increased on the face side with respect to the maximum depression position (line X) in each recess, so that the head 7 The toe side 11a easily returns in the direction of the arrow D1 with the shaft center as the center, and as a result, the head 7 can be easily returned before the transition from the downswing position to the impact position, and the swing is easy to operate. Can be an excellent golf club.

  If the angle θ is too small, the head cannot be expected to return due to the air flow. If the angle θ is too large, the air flows in the direction of the back portion, and the head during the swing can be kept in a stable posture. Since it becomes difficult, it is good to set in the range of 1 ° to 15 °, preferably 2 ° to 10 °.

  In addition to the configuration described above, the toe side of the head 7 can easily return in the direction of the arrow D1, for example, by changing the surface shape of the curved inclined surface 21b described above. That is, in the inclined surface 21b, with the line X as the center, the face-side inclined surface has a higher angle that air receives than the back-side inclined surface (or has a shape that increases air resistance). The air resistance acting on the face side is increased, and the toe side of the head 7 can be easily returned in the direction of the arrow D1.

  Alternatively, if the toe side recesses 21 and 23 are formed by shifting to the back side rather than the heel side recesses 20 and 22, when the air flows from the heel side to the toe side, a relatively large amount flows to the back side. During the swing, the toe side of the head 7 can be easily returned in the direction of the arrow D1. Moreover, you may make it the shape where the rear end of all the recessed parts or one of the recessed parts inclines to the side side.

  In the configuration as described above, the central recesses 22 and 23 are formed in the sole portion, so that a path through which air flows from the face side to the back side (in the direction indicated by the line Y) during the swing from the down swing to the hitting ball. This makes it possible to reduce the air resistance acting on the head until the impact occurs. Thus, in combination with the functions of the heel side recess 20 and the toe side recess 21 described above, the golf club is easy to swing and has excellent operability over the entire swing from the top to the hit ball.

  In addition, as described above, in the recessed region, air flows in the recess area by the passage (line X) through which air flows from the heel side toward the toe side and the passage (line Y) through which air flows from the face side to the back side. Turbulent flow is likely to occur, and as a result, it becomes easy to suppress the force pulled in the centrifugal direction during the swing, and it becomes possible to make the golf club more excellent in operability.

  As shown in FIG. 5, the central recesses 22 and 23 are preferably formed so that the length in the face / back direction is longer than the width in the toe / heel direction. In this case, the ratio of the width in the toe / heel direction to the length in the face / back direction is preferably (2 × the length in the toe / heel direction ≦ the length in the face / back direction).

  By adopting such a shape, it is possible to regulate the air flow up to the time of impact, and it is possible to effectively prevent a reduction in the head speed due to air resistance. That is, in the swing from the downswing position to the impact position, it is possible to create a path in which air flows from the leading edge portion LE of the face portion 8 to the rear of the sole portion, and it is easy to obtain a stable head trajectory. And the vertical force can be reduced. Therefore, it is possible to provide a golf club that is easy to swing and has excellent operability over the entire swing from the top position to the hit ball.

  Further, it is preferable that the direction of the maximum depression (indicated by the line Y1) along the face-back direction in the central recesses 22 and 23 is formed so as to coincide with the traveling direction D2 of the head 7 at the time of impact.

  By adopting such a shape, it is possible to form the most efficient air flow along the line Y direction, and it is possible to make an impact while suppressing a decrease in speed due to air resistance as much as possible.

  The sole portion 10 and the concave portion configured as described above can be modified into various forms.

  The heel side recess 20 and the toe side recess 21 are preferably formed over the side portion 11 as shown in FIGS.

  By configuring in this way, it is possible to make a large path for the air flow from the heel side to the toe side of the sole part, more reliably control the air flow, easy swing and excellent operability. Can be.

  Further, the line connecting the heel-side recess 20 and the maximum depressions 20A, 21A formed in the toe-side recess 21 (corresponding to the line X in this embodiment) is when the head is viewed from the sole side. It is set within a range of ± 20 mm in the front-rear direction with respect to the center of gravity position G of the head, preferably ± 15 mm, and more preferably ± 10 mm. Further, the intersection position Q between the line X and the line Y in FIG. 5 described above is in a range of ± 20 mm in the front-rear direction with respect to the center of gravity position G of the head when viewed from the sole side, preferably ± 15 mm. Preferably, it is set to ± 10 mm.

  By setting in this way, the air flow path (air flow) flowing from the heel side to the toe side in the sole portion passes through the gravity center G of the head 7 or near the gravity center G, so that a stable air flow is generated. It becomes like this. For this reason, it is possible to prevent the head 7 from being shaken during the swing, to make the swing easy and to make the golf club excellent in operability.

  In this case, if the maximum recesses 20A and 21A have a predetermined length in the face-back direction, or if the maximum recesses 20A and 21A do not match in the toe-heel direction, the centers of the maximum recesses 20A and 21A The path through which the air flows is defined by a line that extracts the position and connects the center positions.

  Further, in the above-described configuration, the depth (maximum depth) of each of the recesses 20, 21, 22, 23 is difficult to cause air turbulence if it is too shallow, and it is necessary to form a large number of recesses. On the contrary, if it is too deep, the air resistance becomes large, or the shape discomfort and the low center of gravity are hindered. However, by arranging the weight member, etc., it is possible to make it 10 mm or more, and to make it an arbitrary depth.

  In the configuration described above, it is preferable that the peak portion 26 formed between the central recesses 22 and 23 is recessed in the middle as shown in FIG. 7 in the face-back direction. Is indicated by reference numeral 26A).

  As described above, the peak portion 26 is relatively depressed in the middle portion in the face-back direction, so that during the swing, when air passes from the heel side to the sole side, the ridge portion 26 is stably in the toe side direction. It becomes easy to flow and can be made into a golf club which is easy to swing and excellent in operability. In addition, the combination of the central concave portions 22 and 23 and the peak portion 26 causes turbulent air flow in the face-back direction even during the swing from the downswing position to the impact position. Like the turbulent flow on the sole side, the force pulled in the centrifugal direction can be suppressed, and the golf club can be easily operated.

  Of course, the ridge portion 26 may be any shape as long as the air can easily flow from the heel side to the toe side without providing the recess portion 26A as shown in FIG.

  In addition, since the above-described sole portion 10 may not have a shape in which the intermediate portion is recessed in consideration of contact with the ground or lawn and guideability, all of the above from the heel side to the toe side Thus, it is not necessary that the recesses are continuous, and a shape having no recesses in part may be used. Specifically, the concave portion can be arbitrarily set, but it is sufficient that at least three in total, one on the heel side, the toe side, and the center are formed. Furthermore, it is preferable to form it on the heel side and the toe side, and form 2 to 4 places in the center so that the total is 6 places or less.

  Further, each of the concave portions 20 to 23 formed in the sole portion 10 is formed on the rear side from the leading edge LE at the lower portion of the face portion 8 and ends in front of the rear end position P5 of the sole portion 10. preferable. That is, as shown in FIG. 5, the concave portion only needs to be formed within the range of the outer edge 30 that defines the sole portion when the sole portion 10 is viewed from the lower surface side.

  Moreover, about each recessed part 20-23 formed in the sole part 10, the width | variety, depth, and shape can be arbitrarily set in the range which the path | route (line X and line Y) through which an air flows can be formed. In this case, the central concave portions 22 and 23 may be formed with a wide portion and a narrow portion in the width direction.

  Further, the ridge lines behind the central recesses 22 and 23 (the ridge lines on the back side and at least a part of the ridge lines on the back side with respect to the line X) can be eliminated if there is no need for air turbulence or focusing. . In this case, the flow of air to the rear becomes smoother.

  Further, as shown in FIG. 7, it is preferable to form an inclined portion 10c at the rear portion of the sole portion 10 so as to be gradually inclined upward as it moves to the back side.

  By forming the inclined portion 10c in this way, air can be easily flowed to the rear of the sole portion. In addition, about the shape which inclines upwards, it may be a shape that rises flush, or may be a shape that rises in a multifaceted (stepwise) manner.

  Furthermore, the surface of the back portion 12 may have a curved surface shape having irregularities along the toe / heel direction.

  With this configuration, it is possible to prevent an increase in air resistance during the swing in this portion, and to stabilize the head movement during the swing in combination with the above-described recesses.

FIG. 10 is a view showing another embodiment of the head, and is a side view seen from the heel side.
In this embodiment, a perpendicular line (reference line Z) passing through the intersection of the line X shown in FIG. 5 and the line Y passing through the center position C of the face part 8 is drawn, and the center of the face part 8 is drawn with respect to this reference line Z. Let H be the height at a portion that intersects with the ridge line 14 on the heel side in a straight line parallel to the line FX in contact with the position C.

  The head 7 may be formed such that the height H specified as described above is ½ or less of the height of the crown portion 9 when measured at the left and right center position of the face portion 8. preferable.

  With this configuration, it is possible to cause a large amount of air to flow to the crown side by the movement of the head from the top to the downswing, thus preventing strong tension from acting on the hand where the player grips the club. This makes it easier to control the head.

  Further, the above-described ridge line 14 is a ridge line 14a that rises at a steep angle on the face part 8 side with respect to the reference line Z, and the back part 12 side with respect to the reference line Z is inclined gently or horizontally. Is formed.

  With this configuration, it is possible to increase the air flow to the crown 9 side over a wide range from the reference line Z to the back side to increase the flow velocity, and to further control the head. It becomes easy.

It is a figure showing one embodiment of a golf club concerning the present invention, and a front view of a golf club. The figure which showed the swing of the golf club typically. The top view which looked at the head from the crown side. The front view which looked at the head from the face side. The bottom view which looked at the head from the sole side. Sectional drawing along the AA line of FIG. Sectional drawing along the BB line of FIG. The side view which looked at the head from the heel side. The side view which looked at the head from the toe side. It is a figure which shows another embodiment, and is the side view which looked at the head from the heel side.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Golf club 5 Shaft 7 Head 8 Face part 9 Crown part 10 Sole part 11 Side part 11a Toe side 11b Heel side 20 Heel side recessed part 21 Toe side recessed part 22, 23 Center recessed part

Claims (7)

A metal made of a hollow structure in which an outer shell is formed by a face portion, a crown portion, a sole portion, a side portion on the toe side and a heel side, and a back portion on the rear side, and an internal space is formed in the outer shell. A golf club comprising a head,
A golf club characterized in that a plurality of recesses having a heel side recess, a toe side recess, and a central recess are formed in the sole portion as a passage through which air flows from the heel side to the toe side.   2. The golf club according to claim 1, wherein the central recess has a length in the face-back direction that is longer than a width in the toe-heel direction.   3. The golf club according to claim 1, wherein each of the heel-side recess, the toe-side recess, and the center recess has a maximum recess along the toe-heel direction and the same direction. 4. .   The line connecting the heel side recess and the maximum recess formed in the toe side recess is set within a range of ± 20 mm in the front-rear direction with respect to the center of gravity of the head. The listed golf club.   The direction of the maximum recess formed in the heel side recess, the toe side recess, and the central recess has an angle such that the toe side is the back side with respect to the direction parallel to the face surface. The golf club according to claim 3 or 4.   The golf club according to claim 1, wherein the heel side recess and the toe side recess are formed over the side part. The central recess is formed at a plurality of locations along the face-back direction,
The golf club according to any one of claims 1 to 6, wherein a ridge formed between the plurality of central recesses is recessed in the middle in the face-back direction.

Images