JP2013165962A - Golf club head having stress-reducing feature with aperture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hollow golf club incorporating a stress-reducing feature including an aperture located on the crown or sole of a club head.SOLUTION: A golf club head includes a crown-side stress-reducing feature (SRF) located at a crown 600 of a club head 400 and a sole-side stress-reducing feature SRF located at a sole 700 of the club head 400. The SRF may contain an aperture penetrating through the shell of the golf club head 400. The location and size of the SRF and aperture play an important role in reducing a peak stress received by a face 500 of the golf club and in a selective increase of deflection of the face 500.

Description

  The present invention relates to the field of golf clubs, and more particularly to the field of hollow golf club heads. The present invention relates to a hollow golf club head having a stress reducing structure including a hollow portion.

[Cross-reference of related applications]
This application is a continuation-in-part of US patent application Ser. No. 12 / 791,025 filed Jun. 1, 2010, which is incorporated by reference in its entirety as described herein.

[Description of research and development funded by the federal government]
The present invention was not devised as part of a research and development project funded by the federal government.

  The impact of a golf club head, which often moves over 100 miles per hour, collides with a stationary golf ball, exerts a very large force on the face of the golf club head, and accordingly, a large stress is applied to the face. Take it. It is desirable to reduce the peak stress experienced by the face, and the impact force is preferably selectively distributed to other areas of the golf club head where the impact force can be advantageously utilized.

  In its most general features, the present invention develops the prior art with a variety of new functions and solves many of the problems of the conventional methods with new and unprecedented methods. In its most general embodiment, the present invention solves the problems of the prior art and overcomes the limitations in any of a number of generally useful features.

  The golf club of the present invention includes a stress reduction structure including a crown side stress reduction structure (SRF) located at the crown of the club head and / or a sole side SRF located at the sole of the club head. The SRF may include a hollow portion that penetrates the shell of the golf club head. The location and size of the SRF and the hollow portion play an important role in reducing the peak stress experienced by the golf club face during impact with the golf ball and selectively increasing the deflection of the face.

  Many variations, modifications, and alternatives to the various preferred embodiments, processes and methods will become more readily apparent to those skilled in the art by reference to the following detailed description of the preferred embodiments and the accompanying drawings. The modification examples can be used alone or in combination with each other.

The present invention will be described with reference to the following drawings, but the present invention described in the claims is not limited by these drawings.
FIG. 1 is a front view of one embodiment of the present invention, shown in non-scale. FIG. 2 is a top view of one embodiment of the present invention, shown in non-scale. FIG. 3 is a front view of one embodiment of the present invention, shown non-scaled. FIG. 4 is a toe side side view of one embodiment of the present invention, shown in non-scale. FIG. 5 is a top view of one embodiment of the present invention, shown in non-scale. FIG. 6 is a toe side side view of one embodiment of the present invention shown in non-scale. FIG. 7 is a front view of one embodiment of the present invention shown in non-scale. FIG. 8 is a toe side side view of one embodiment of the present invention, shown in non-scale. FIG. 9 is a front view of one embodiment of the present invention, shown in non-scale. FIG. 10 is a front view of one embodiment of the present invention shown in non-scale. FIG. 11 is a front view of one embodiment of the present invention shown in non-scale. FIG. 12 is a front view of one embodiment of the present invention, shown in non-scale. FIG. 13 is a front view of one embodiment of the present invention shown in non-scale. FIG. 14 is a top view of one embodiment of the present invention, shown non-scaled. FIG. 15 is a front view of one embodiment of the present invention shown in non-scale. FIG. 16 is a top view of one embodiment of the present invention, shown non-scale. FIG. 17 is a top view of one embodiment of the present invention, shown non-scaled. FIG. 18 is a top view of one embodiment of the present invention shown in non-scale. FIG. 19 is a front view of one embodiment of the present invention shown in non-scale. FIG. 20 is a toe side side view of one embodiment of the present invention shown in non-scale. FIG. 21 is a front view of one embodiment of the present invention shown in non-scale. FIG. 22 is a top view of one embodiment of the present invention shown in non-scale. FIG. 23 is a bottom view of one embodiment of the present invention, shown non-scaled. FIG. 24 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 25 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale. FIG. 26 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 27 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 28 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 29 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale. FIG. 30 is a top view of one embodiment of the present invention, shown non-scaled. FIG. 31 is a bottom view of one embodiment of the present invention shown in non-scale. FIG. 32 is a top view of one embodiment of the present invention shown in non-scale. FIG. 33 is a bottom view of one embodiment of the present invention, shown non-scaled. FIG. 34 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 35 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 36 is a top view of one embodiment of the present invention shown in non-scale. FIG. 37 is a bottom view of one embodiment of the present invention, shown non-scaled. FIG. 38 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 39 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 40 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 41 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale. FIG. 42 is a top view of one embodiment of the present invention, shown non-scale. FIG. 43 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale. FIG. 44 is a graph showing the face shift according to the load. FIG. 45 is a graph showing the peak stress that the face receives according to the load. FIG. 46 is a graph showing the ratio of stress-deflection according to load. FIG. 47 is a top view of one embodiment of the present invention, shown non-scale. FIG. 48 is a bottom view of one embodiment of the present invention, shown non-scaled. FIG. 49 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 50 is a partial cross-sectional view of one embodiment of the present invention, shown in non-scale. FIG. 51 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale. FIG. 52 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale. FIG. 53 is a partial cross-sectional view of one embodiment of the present invention shown in non-scale.

  These drawings are provided to facilitate understanding of the embodiments of the golf club of the present invention described in more detail below and should not be construed to unduly limit the golf club. In particular, the relative spacing, positioning, size, and dimensions of the various elements shown in the drawings are shown on a non-scale basis, and are exaggerated, reduced, or modified for clarity of explanation. It shows something. Those skilled in the art will also appreciate that a range of alternative features has been omitted in order to make the description clearer and reduce the number of drawings.

  The hollow golf club of the present invention significantly improves the prior art. A preferred embodiment of a golf club achieves this significant development with a new and unprecedented method that has been previously realized but preferably exhibits the desired functionality, constructed in a unique and unprecedented way. To do. The following description with reference to the drawings is a description of the presently preferred embodiment of the golf club and does not represent all forms of making or utilizing the golf club of the present invention. In the following description, designs, functions, means and methods for implementing a golf club are shown in connection with the embodiments. However, similar or equivalent functions and features may be achieved by other different embodiments that are intended to be included in the spirit and aspects of the claimed golf club head.

  In order to provide a thorough understanding of the golf club of the present invention, some general terms used herein are defined. First, those skilled in the art will understand the meaning of “center of gravity” as learned in a basic level course in solid mechanics, sometimes referred to herein as CG. In wooden golf clubs, hybrid golf clubs, and hollow iron type golf clubs that do not necessarily have a uniform density, CG is often regarded as the intersection of all balance points of the club head. That is, when the head is balanced by the face and then the head is balanced by the sole, the intersection of two imaginary lines that linearly pass through these balance points is a point called CG.

  A coordinate system used for specifying and explaining the position of the CG is determined. In determining the coordinate system, first, the base surface (GP) and the shaft axis (SA) are specified. First, as shown in FIG. 1 which is a front view of a golf club head in a state in which the face of the golf club head is viewed, a horizontal plane on which the golf club head is placed is a base surface (GP). Next, the central axis of the bore of the golf club head that receives the shaft is the shaft axis (SA). Some golf club heads have an outer hosel that houses a bore that receives the shaft, and those skilled in the art will readily understand the shaft axis (SA). Other “hosel-free” golf clubs have an internal bore that receives the shaft, which again defines the shaft axis (SA). The shaft axis (SA) is determined by the design of the golf club head. The shaft axis (SA) is shown in FIG.

  The intersection of the shaft axis (SA) and the base surface (GP) is the origin. The origin is indicated as “origin” in the coordinate system of FIG. As generally known in the art, the right side of the club head shown in FIG. 1 on the side near the bore to which the shaft is attached is referred to as the “heel” side of the golf club head and on the opposite side. The left side of FIG. 1 is called the “toe” side of the golf club head. Further, the part of the golf club head that actually hits the golf ball is called the face of the golf club head and is generally called the front of the golf club head. On the other hand, the opposite side of the golf club head is called the rear and / or rear edge of the golf club head.

  A three-dimensional coordinate system is determined based on the origin. The Y direction is a vertical direction from the origin. The X direction is a horizontal direction that is perpendicular to the Y direction and parallel to the face of the golf club head in a natural resting posture, also known as the design posture. The Z direction is perpendicular to the X direction and is a direction toward the rear of the golf club head. The X, Y, and Z directions are indicated by symbols in the coordinate system of FIG. This coordinate system is opposite to the conventional coordinate system in which the X direction is directed to the right, but this is preferable because the center of gravity has positive coordinates in all directions.

  Now that the origin and coordinate system have been defined, the terms that define the position of the CG will be described. Those skilled in the art will appreciate that the CG of a hollow golf club head, such as a wooden golf club head, as shown in FIG. 2, is behind the face of the golf club head. As shown in FIG. 2, the distance from the origin to the rear CG is called Zcg. Similarly, as shown in FIG. 3, the distance from the origin to CG upward is called Ycg. Finally, as shown in FIG. 3, the horizontal distance from the origin to CG is called Xcg. Therefore, the position of CG can be easily specified by using Xcg, Ycg, and Zcg.

  The moment of inertia of a golf club head is a major factor that determines the performance of the club. Again, those skilled in the art will understand what moment of inertia is with respect to a golf club head, but define two components of moment of inertia for use herein. First, the moment of inertia shown as MOIx in FIG. 4 is the moment of inertia of the golf club head about an axis parallel to the X axis and passing through CG. MOIx is the moment of inertia of the golf club head that resists the lofting or delofting moment caused by hitting the ball above or below the face. Next, the moment of inertia shown as MOIy in FIG. 5 is the moment of inertia of the golf club head around an axis parallel to the Y axis and passing through CG. MOIy is the moment of inertia of the golf club head that resists the opening moment caused by hitting the ball on the toe side or heel side of the face or the closing moment.

  To further describe the definition of the main dimensions of the golf club head, the “front-back” dimension, referred to as the FB dimension, is shown in FIG. 6 from the forefront of the front edge of the golf club head to the rear of the golf club head, That is, it is the distance to the rear end edge. As shown in FIG. 7, the dimension of the “heel-toe” called the HT dimension is determined from the point on the surface of the face of the club head farthest from the origin in the positive X direction on the toe side. , The distance to the point on the face of the face of the golf club head that is furthest from the origin in the negative X direction and is 0.875 inches above the base.

  An important location on the face of a golf club is the engineering impact point (EIP). Engineering impact points (EIP) are important because they are used to define some of the other important attributes of the golf club head of the present invention. Engineering impact points (EIP) are generally considered points on the face that are ideal for hitting a golf ball. In general, the engineering impact point (EIP) of a golf club can be easily identified by a score line on the golf club head. In the embodiment shown in FIG. 9, the first step performed to identify an engineering impact point (EIP) is to identify a top score line (TSL) and a bottom score line (BSL). Next, an imaginary line (IL) is drawn from the middle point of the top score line (TSL) to the middle point of the bottom score line (BSL). The imaginary line (IL) often does not extend in the vertical direction. This is because when the club is in a natural posture, the score line is often designed with an angle so as to become higher toward the toe side. Next, as shown in FIG. 10, the top score line (TSL) and the bottom score line (BSL) are parallel to the base surface (GP), that is, the imaginary line (IL) faces the vertical direction. Make the club rotate. In this posture, the lower edge height (LEH) and the upper edge height (TEH), which are heights from the base surface (GP), are measured. Next, the face height is specified by subtracting the top edge height (TEH) from the bottom edge height (LEH). Divide the face height by 2 and add the bottom edge height (LEH) to calculate the engineering impact point (EIP) height. Continuing to refer to the club head in the posture shown in FIG. 10, the position is marked on the imaginary line (IL) and higher than the base surface (GP) by the height obtained as described above. This mark indicates the engineering impact point (EIP).

  Engineering impact points (EIP) can also be easily identified for club heads with alternative score line configurations. For example, the golf club head of FIG. 11 does not have a top score line centered. In such a case, the two outermost score lines whose length differences are within 5% are used as the top score line (TSL) and the bottom score line (BSL). The process of locating the engineering impact point (EIP) on this face is performed as described above. Further, some golf club heads have non-continuous score lines as seen at the top of the club head face shown in FIG. In this case, a line connecting the disconnected portions of the two top score lines is drawn, and a continuous top score line (TSL) is drawn. This newly drawn continuous top score line (TSL) is bisected and used for positioning the imaginary line (IL). Again, the process of locating the engineering impact point (EIP) on this face is performed as described above.

  An engineering impact point (EIP) can be easily identified even in rare cases such as a golf club head with an asymmetrical score line pattern or a golf club head having no score line. In such an embodiment, the Engineering Impact Point (EIP) is identified based on “Procedure for Measuring the Flexibility of a Golf Clubhead” version 2.0, published on March 25, 2005, published by the USGA. This procedure is incorporated herein by reference. This USGA procedure describes the process of identifying the impact location on the face of the golf club to be inspected. In this document, the impact position is called the face center. This USGA procedure identifies a face center using a template placed on the face of a golf club. In limited cases where the score line pattern is asymmetric or has no score line, the location that the USGA calls the face center is the location called the Engineering Impact Point (EIP) throughout the specification.

  The engineering impact point (EIP) on the face is an important criterion that defines other attributes of the golf club head of the present invention. Generally, the engineering impact point (EIP) is indicated as EIP and is indicated by a cross on the face. The exact location of the engineering impact point (EIP) is specified by the dimensions Xeip, Yeip and Zeip, as shown in FIGS. The X coordinate Xeip is measured in the same manner as Xcg, the Y coordinate Yeip is measured in the same manner as Ycg, and the Z coordinate Zeip is measured in the same manner as Zcg. Zeip is always a positive value regardless of whether it is in front of or behind the origin.

  An important dimension using engineering impact points (EIP) is the center face progression (CFP), shown in FIGS. Center face progression (CFP) is a one-dimensional measurement and is defined as the distance in the Z direction from the shaft axis (SA) to the engineering impact point (EIP). Another dimension that uses an engineering impact point (EIP) is called the club moment arm (CMA). As shown in FIG. 8, CMA is the two-dimensional distance from the club head CG to the engineering impact point (EIP) on the face. Therefore, based on the coordinate system of FIG. 1, the club moment arm (CMA) includes a component in the Z direction and a component in the Y direction, but between the CG and the engineering impact point (EIP). The difference in is ignored. Thus, the club moment arm (CMA) can be considered with respect to the impact vertical plane extending through the engineering impact point (EIP) and extending in the X direction. First, the CG is moved horizontally in the X direction until it hits the impact vertical plane. Then, the club moment arm (CMA) is a distance from the position where the CG is projected onto the impact vertical direction plane to the engineering impact point (EIP). The club moment arm (CMA) has a great influence on the launch angle and spin of the golf ball at the time of impact.

  Another important dimension for golf club design is the club head blade length (BL) shown in FIGS. The blade length (BL) is a distance from the origin to a point on the surface of the club head farthest from the origin in the X direction on the toe side. The blade length (BL) consists of two parts. They are a heel side blade length part (Abl) and a toe side blade length part (Bbl). The distinction between these two parts is the engineering impact point (EIP), and more appropriately when the golf club head is in a natural static posture, also called the design posture, as shown in FIG. A vertical line, also called the face centerline (FC), that extends through the engineering impact point (EIP).

  In addition, there are several other dimensions that help to understand the location of the CG in relation to other points essential in golf club design. First, as shown in FIG. 14, the CG angle (CGA) is a one-dimensional angle between a line connecting the CG and the origin and an extension line of the shaft axis (SA). The CG angle (CGA) is measured only in the XZ plane, so the height difference between the CG and the origin is not taken into account. Therefore, it is most easily understood with reference to the top view of FIG.

  Lastly, an important dimension when quantifying the design of the golf club of the present invention is to consider only two dimensions called transfer distance (TD) shown in FIG. The transfer distance (TD) is a horizontal distance from CG to a vertical line extending from the origin. Therefore, the transfer distance (TD) ignores the height of CG, that is, Ycg. Thus, using the Pythagorean theorem of simple geometry, the transfer distance (TD) is the hypotenuse of a right triangle having Xcg as the first base and Zcg as the second base.

The transfer distance (TD) is important because it is used to determine another moment of inertia value that is important for the golf club of the present invention. This other moment of inertia value is a face closing moment of inertia (referred to as MOIfc) about a vertical axis passing through the origin. This moment of inertia is obtained by moving MOIy in the horizontal direction (no change in the Y direction). MOIfc is obtained by multiplying the mass of the club head by the square of the transfer distance (TD) and adding MOIy. Therefore, MOIfc is as follows.

  The face closing moment (MOIfc) is important because it represents the resistance felt by the golfer when swinging to return the club face to the square position, which is the impact position with the golf ball. In other words, as the golf club head is returned to the original position that is the impact position with the golf ball by the golf swing, the face starts to be closed so that the face is perpendicular to the direction in which the ball is thrown at the time of impact.

  The hollow golf club of the present invention has a stress reducing structure, unlike the conventional hollow type golf club. As shown in FIG. 21, the hollow golf club includes a shaft (200), a grip (300), and a golf club head (100). The shaft (200) has a shaft proximal end (210) and a shaft distal end (220). A grip (300) is attached to the shaft proximal end (210). The golf club head (100) is attached to the shaft distal end (220). The overall length of the hollow golf club, that is, the club length is 36 inches or more and 45 inches or less according to USGA guidelines.

The golf club head (400) itself has a hollow structure. The hollow structure includes a face (500), a sole (700), a crown (600) and a skirt (800). The face (500) is located at the front portion (402) of the golf club head (400), which is the impact position of the golf club head (400) on the golf ball. The sole (700) is located at the bottom of the golf club head (400). The crown (600) is located on top of the golf club head (400). The skirt (800) is located over a portion of the outer edge of the golf club head (400) between the sole (700) and the crown (600). An outer shell is defined by the face (500), sole (700), crown (600) and skirt (800), and the outer shell causes the head volume of the golf club head (400) to be less than 300 cm ^3. Determined. Further, the golf club head (400) has a rear portion (404) on the opposite side of the face (500). As will be appreciated by those skilled in the art, the rear portion (404) includes a trailing edge of the golf club head (400). The face (500) has a loft angle (L) of 12 ° or more and 30 ° or less, and the face (500) includes an engineering impact point (EIP) defined as described above. As will be appreciated by those skilled in the art, the skirt (800) may be large in certain areas of the golf club head (400) and may be substantially absent in other specific areas. The substantially non-existing portion is, in particular, the rear portion (404) of the golf club head (400) that is simply covered by the crown (600) and often directly connected to the sole (700).

  The golf club head (100) includes a bore having a center. The center defines the shaft axis (SA), and the shaft axis (SA) defines the origin by intersecting the horizontal base surface (GP) as described above. The bore is located on the heel side (406) of the golf club head (400) and receives the shaft distal end (220) for attachment to the golf club head (400). The golf club head (100) also has a toe side (408) located on the opposite side of the heel side (406). The club head mass, which is the mass of the golf club head (400) of the present invention, is less than 270 g. In view of the prior art loft, club head volume and club length, the golf club of the present invention is intended as a hollow golf club such as a fairway wood, a hybrid club or a hollow iron.

  The golf club head (400) may include a stress reduction structure (1000). The stress reducing structure (1000) includes a crown side SRF (1100) located on the crown (600) as shown in FIG. 22 and / or a sole side SRF (see FIG. 23) located on the sole (700). 1300). As shown in FIGS. 22 and 25, the crown side SRF (1100) is the CSRF length (1110) between the most toe point (1112) of the CSRF and the most heel point (1116) of the CSRF, CSRF It has a leading edge (1120), a CSRF trailing edge (1130), a CSRF width (1140) and a CSRF depth (1150). Similarly, as shown in FIGS. 23 and 25, the sole-side SRF (1300) has an SSRF length (1310) between the SSRF most toe point (1312) and the SSRF most heel point (1316). ), SSRF leading edge (1320), SSRF trailing edge (1330), SSRF width (1340) and SSRF depth (1350).

  Referring to FIG. 24, in an embodiment that includes both a crown side SRF (1100) and a sole side SRF (1300), the SRF connection surface (1500) is one of the crown side SRF (1100) and the sole side SRF (1300). Go through the department. In order to specify the position of the SRF connection surface (1500), a vertical section is obtained by cutting the club head (400) in the front-rear direction perpendicular to the vertical direction including the shaft axis (SA). The cross section is shown in FIG. Thereafter, the crown side SRF midpoint of the crown side SRF (1100) is identified at a position on the imaginary line of the crown along the natural bending of the crown (600). In FIG. 24, the imaginary line of the crown is indicated by a broken line or a hidden line connecting the CSRF front end edge (1120) and the CSRF rear end edge (1130), and the crown side SRF intermediate point is indicated by a cross. Similarly, the sole-side SRF midpoint of the sole-side SRF (1300) is identified at a position on the imaginary line of the sole along the natural bending of the sole (700). In FIG. 24, the imaginary line of the sole is indicated by a broken line or a hidden line connecting the SSRF front end edge (1320) and the SSRF rear end edge (1330), and the sole side SRF intermediate point is indicated by a cross. Finally, as shown in FIG. 24, the SRF connection surface (1500) is a surface extending in the heel-toe direction passing through both the crown side SRF intermediate point and the sole side SRF intermediate point. The SRF connection surface (1500) shown in FIG. 24 extends in the vertical direction, but the direction of the SRF connection surface (1500) depends on the positions of the crown side SRF (1100) and the sole side SRF (1300). Alternatively, the upper portion may be inclined toward the face as shown in FIG. 26, or the upper portion may be inclined away from the face as shown in FIG.

  In FIGS. 26 and 27, the SRF connection surface (1500) is oriented with an inclination of the connection surface angle (1510) from the vertical direction. The connection surface angle (1510) is used to determine the position of the crown side SRF (1100) and the sole side SRF (1300). In one particular embodiment, as shown in FIG. 26, the crown side SRF (1100) and the sole side SRF (1300) are not vertically above or below each other, and the connection surface angle (1510) is 0. The angle is greater than 90% of the loft angle (L) of the club head (400). Similarly, the sole side SRF (1300) may be positioned in front of the crown side SRF (1100), that is, on the face (500) side, and in this case, the conditions of the present embodiment can be satisfied. In other words, the condition is that the connection surface angle (1510) is an angle larger than 0 and an angle less than 90% of the loft angle (L) of the club head (400).

  In an alternative embodiment, as shown in FIG. 27, the SRF connection surface (1500) is oriented at an angle of connection surface angle (1510) from the vertical direction, the connection surface angle (1510) being the club head. The angle is 10% or more larger than the loft angle (L) of (400). Similarly, the crown side SRF (1100) may be located in front of the sole side SRF (1300), that is, on the face (500) side, and in this case, the conditions of the present embodiment can be satisfied. That is, the connecting surface angle (1510) is an angle that is 10% or more larger than the loft angle (L) of the club head (400). In yet another embodiment, the SRF connection surface (1500) is oriented at an inclination of the connection surface angle (1510) from the vertical direction, the connection surface angle (1510) being the loft angle of the club head (400). The angle is greater than (L) by 50% or more and less than 100%. These three embodiments show a unique relationship between the crown side SRF (1100) and the sole side SRF (1300), and in these embodiments, the crown side SRF (1100) and the sole side SRF (1300). Are not vertically aligned with each other, the crown side SRF (1100) and the sole side SRF (1300) are offset, and the connection surface angle (1510) is the loft angle (L ) Is not necessarily equal.

  Referring to FIGS. 30 and 31, if either or both of the crown side SRF (1100) and the sole side SRF (1300) are not located in the CG section indicated by 24-24 in FIG. 22, the front-rear passing through the CG. The crown side SRF (1100) located closest to the vertical plane (front-rear vertical CG passage plane) is selected. For example, as shown in FIG. 30, the right crown side SRF (1100) is closer to the front-rear vertical direction CG passage surface than the left crown side SRF (1100). In other words, the distance “A” is shorter on the right crown side SRF (1100). Next, the face center line (FC) is moved to a position passing through both the CSRF front end edge (1120) and the CSRF rear end edge (1130) as indicated by a broken line “B”. Thereafter, an intermediate point of the line “B” is identified and indicated as “C”. Finally, an imaginary line “D” perpendicular to the line “B” is drawn.

  As shown in FIG. 31, the same process is repeated for the sole side SRF (1300). It is only a coincidence that both the crown side SRF (1100) and the sole side SRF (1300) closest to the front-rear vertical CG passage surface are on the heel side (406) of the golf club head (400). Absent. Even if the crown side SRF (1100) and the sole side SRF (1300) closest to the front-rear vertical CG passage surface are on opposite sides of the golf club head (400), the same process is performed. Applied. Referring now to FIG. 31, the process first identifies that the right sole side SRF (1300) is closer to the front-rear vertical CG passage plane than the left sole side SRF (1300). . In other words, the distance “E” is smaller in the sole side SRF (1300) on the heel side. Next, the face center line (FC) is moved to a position that passes through both the SSRF front end edge (1320) and the SSRF rear end edge (1330) as indicated by the broken line “F”. Thereafter, an intermediate point of the line “F” is identified and indicated as “G”. Finally, an imaginary line “H” perpendicular to the line “F” is drawn. The plane that passes through both the imaginary line “D” and the imaginary line “H” is the SRF connection plane (1500).

  Next, returning to FIG. 24, the CG-plane offset (1600) is determined as the shortest distance from the center of gravity (CG) to the SRF connection surface (1500) regardless of the position of the CG. In one particular embodiment, the CG-plane offset (1600) is 25% or more less than the club moment arm (CMA) and the club moment arm (CMA) is less than 1.3 inches. The variables that identify the location of the crown side SRF (1100) and sole side SRF (1300) and their associated locations described herein preferably reduce the stress on the face (500) upon impact with a golf ball. And adjusting the temporary bending and deformation of the crown side SRF (1100) and the sole side SRF (1300) so that the relative position with respect to the CG position and / or the origin is constant, and the face (500), crown (600) and sole (700) are selected to maintain durability. Experiments and modeling show that the crown side SRF (1100) and sole side SRF (1300) increase the deflection of the face (500) and reduce the peak stress on the face (500) upon impact with a golf ball. It was. This reduction in stress allows the use of a substantially thin face and allows the reduced weight to be used in other parts of the club head (400). Further, the increase in the deflection of the face (500) further improves the coefficient of restitution (COR) of the club head (400), particularly when the club head (400) has a volume of 300 cc or less.

  Indeed, in yet other embodiments, the location of the crown side SRF (1100) and / or the sole side SRF (1300) is identified in more detail to achieve these objectives. For example, in another embodiment, the CG-plane offset (1600) is greater than or equal to 25% of the club moment arm (CMA) and less than 75% of the club moment arm (CMA). In yet another embodiment, the CG-plane offset (1600) is greater than or equal to 40% of the club moment arm (CMA) and less than 60% of the club moment arm (CMA).

  In alternative alternative embodiments, the crown side SRF (1100) and / or without using the CG-plane offset (1600) variable as described above to include embodiments where a single SRF exists. The position of the sole side SRF (1300) is associated with the difference between the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH), which is called the face height. Thus, two new variables, CSRF leading edge offset (1122) and SSRF leading edge offset (1322) are shown in FIG. The CSRF leading edge offset (1122) is the distance from any point along the CSRF leading edge (1120) to the point of the top edge (510) of the face (500) going straight forward in the Zcg direction. Thus, the CSRF leading edge offset (1122) may vary at each point of the CSRF leading edge (1120), or the bending of the CSRF leading edge (1120) may be curved at the top edge (510) of the face (500). Is consistent. However, the CSRF front edge offset (1122) is always at the point where the distance from the corresponding point on the face front edge (510) straight ahead among the points along the CSRF front edge (1120) is the shortest distance. It becomes the minimum value, and becomes the maximum value at the point where the distance from the corresponding point on the face upper end edge (510) straight ahead among the points along the CSRF front end edge (1120) is the longest. Similarly, the SSRF leading edge offset (1322) is the distance from any point along the SSRF leading edge (1320) straight forward in the Zcg direction to the point of the bottom edge (520) of the face (500). is there. Thus, the SSRF leading edge offset (1322) may vary at each point of the SSRF leading edge (1320), or the bending of the SSRF leading edge (1320) may be the bending of the bottom edge (520) of the face (500). Is consistent. However, the SSRF front edge offset (1322) is always at the point where the distance from the corresponding point on the face lower edge (520) straight ahead among the points along the SSRF front edge (1320) is the shortest distance. It becomes the minimum value, and becomes the maximum value at the point where the distance from the corresponding point on the face lower end edge (520) straight ahead among the points along the SSRF front end edge (1320) is the longest. In general, the maximum value of the CSRF leading edge offset (1122) and the maximum value of the SSRF leading edge offset (1322) are less than 75% of the face height. In this application, and for simplicity of definition, the face top edge (510) is a series of points along the top of the face (500) where the vertical face roll is less than 1 inch, as well as the face bottom edge. The edges (520) are a series of points along the bottom of the face (500) where the vertical face roll is less than 1 inch.

  In this particular embodiment, the minimum value for the CSRF leading edge offset (1122) is less than the face height, and the minimum value for the SSRF leading edge offset (1322) is greater than or equal to 2% of the face height. In still other embodiments, the maximum CSRF leading edge offset (1122) is also less than the face height. In yet another embodiment, the minimum value of CSRF leading edge offset (1122) is 10% or more of the face height, and the minimum value of CSRF width (1140) is the minimum value of CSRF leading edge offset (1122). 50% or more. In yet another embodiment, the range is narrower and the minimum CSRF leading edge offset (1122) is 20% or more of the face height.

  Similarly, in many embodiments, an advantageous relationship for the sole SRF (1300) is defined. For example, in one embodiment, the minimum SSRF leading edge offset (1322) is 10% or more of the face height, and the minimum SSRF width (1340) is the minimum SSRF leading edge offset (1322). 50% or more. Furthermore, in other embodiments, the range is narrower and the minimum value of the SSRF leading edge offset (1322) is 20% or more of the face height.

  Further, if the relationship between the CSRF front edge offset (1122), the SSRF front edge offset (1322), and the face height is defined, in one embodiment, the engineering impact point (EIP) is a Yeip coordinate that satisfies the following conditions: It has Xeip coordinates and Zeip coordinates. The difference between Yeip and Ycg is less than 0.5 inch and greater than -0.5 inch, and the difference between Xeip and Xcg is less than 0.5 inch and greater than -0.5 inch, and the difference between Zeip and Zcg Is less than 2.0 inches. By using the relationship between the position of these engineering impact points (EIP) and the position of the center of gravity (CG) in conjunction with the position of the front edge of the crown side SRF (1100) and / or sole side SRF (1300) Improves stability during impact, enables desired deflection of the SRF (1100, 1300) and face (500), maintains the durability of the club head (400), and reduces the peak stress experienced by the face (500) It can be made.

  The position of the crown side SRF (1100) and / or the sole side SRF (1300) is important for achieving the object of the present invention, but the size of the crown side SRF (1100) and the sole side SRF (1300) is also important. Play an important role. 42 and 43, in a particular embodiment where the blade length is long and is intended for fairway wood type golf clubs and hybrid type golf clubs, the blade length of the golf club head (400) ( BL) is 3.0 inches or more, and the heel side blade length portion (Abl) is 0.8 inches or more. In the present embodiment, preferable results are obtained in the following cases. The CSRF length (1110) is not less than the length of the heel side blade length portion (Abl), and the maximum value of the CSRF depth (1150) is not less than 10% of the distance Ycg. As a result, the crown side SRF (1100) is sufficiently compressed and / or bent, and the stress applied to the face (500) upon impact can be greatly reduced. Similarly, in some SSRF embodiments, favorable results are obtained when: The SSRF length (1310) is not less than the length of the heel side blade length portion (Abl), and the maximum value of the SSRF depth (1350) is not less than 10% of the distance Ycg. As a result, the sole side SRF (1300) is sufficiently compressed and / or bent, and the stress applied to the face (500) during impact can be greatly reduced. Here, examples of the cross-sectional profiles of the crown side SRF (1100) and the sole side SRF (1300) include a box shape shown in FIG. 24, a smooth U shape shown in FIG. 28, and a V shape shown in FIG. But are not limited to these shapes. Further, as shown in FIGS. 40 and 41, the crown side SRF (1100) and the sole side SRF (1300) may include a reinforcement area so that the deformation of the SRF (1100, 1300) can be further selectively controlled. . Furthermore, the CSRF length (1110) and SSRF length (1310), when curved, are measured in the same direction as Xcg, not along the curvature of SRF (1100, 1300).

  As shown in FIG. 25, the crown side SRF (1100) has a CSRF wall thickness (1160), and the sole side SRF (1300) has an SSRF wall thickness (1360). In many embodiments, the CSRF wall thickness (1160) and SSRF wall thickness (1360) are greater than or equal to 0.010 inches and less than or equal to 0.150 inches. In one particular embodiment, the face (500) is affected by setting the CSRF wall thickness (1160) and SSRF wall thickness (1360) in the range of 10% to 60% of the face thickness (530). The desired durability is obtained while obtaining the desired reduction in stress and the desired deflection of the face (500). Further, by using the thickness within this range, the present invention is not reduced without reducing the effect of the present invention, and the weight distribution is not excessively increased in the vicinity of the SRF (1100, 1300) of the club head (400). The achievement of the objective is encouraged.

  Furthermore, the terms such as the maximum value of the CSRF depth (1150) and the maximum value of the SSRF depth (1350) are used, as shown in FIGS. 32 to 35, the depth of the crown side SRF (1100) and the sole side SRF ( This is because the depth of 1300) does not have to be constant and can actually vary. Furthermore, as shown on the right and left sides of the SRF (1100, 1300) in FIG. 35, the end walls of the crown side SRF (1100) and the sole side SRF (1300) do not need to be clearly distinguishable, It may be continuous from the deepest part to the natural contour of the crown (600) or sole (700). This continuous portion need not be smooth, but may be stepped, a collection of shapes, or other shapes. Actually, the presence or absence of the end wall is not essential in specifying the shape of the golf club of the present invention. However, the position of the most toe point (1112) of the CSRF, the most heel point (1116) of the CSRF, the most toe point (1312) of the SSRF, and the most heel point (1316) of the SSRF is identified. Therefore, it is necessary to set a standard. Thus, if these points cannot be identified by distinguishable end walls, these points may be offset from the natural bend of the crown (600) or sole (700) by the maximum CSRF depth (1150) or SSRF depth ( 1350) starting from a point of 10% or more of the maximum value. In many embodiments, the maximum value of CSRF depth (1150) and the maximum value of SSRF depth (1350) are preferably between 0.100 inches and 0.500 inches.

  As shown in FIG. 36, the CSRF leading edge (1120) may be straight, or may have a CSRF leading edge curvature radius (1124). Similarly, the SSRF leading edge (1320) may be straight, as shown in FIG. 37, or may have a SSRF leading edge radius of curvature (1324). In one particular embodiment, the CSRF leading edge (1120) and the SSRF leading edge (1320) are curved, and both the CSRF leading edge radius of curvature (1124) and the SSRF leading edge radius of curvature (1324) are face ( 500) within 40% of the bulge bend. In yet other embodiments, both the CSRF leading edge radius of curvature (1124) and the SSRF leading edge radius of curvature (1324) are within 20% of the bulge curvature of the face (500). These bending conditions make it easier to control the bending of the face (500).

  As shown in FIGS. 32-35, in one particular embodiment, the CSRF depth (1150) is greater than the depth at the point toe side (408) from the face centerline (FC) and from the face centerline (FC). It is shallower at the face center line (FC) than at the point at the heel side (406). This increases the possible deflection on the heel side (406) and toe side (408) of the face (500), which generally has a COR that is lower than the limit allowed by the USGA. In other embodiments, as shown in FIG. 35, the crown-side SRF (1100) and / or the sole-side SRF (1300) may have a depth reduction region, ie, a CSRF depth reduction region (1152) and an SSRF depth reduction region. (1352). Each depth decreasing region is a continuous region whose depth is 20% or more shallower than the maximum value of the specific SRF depth (1100, 1300). The CSRF depth reduction region (1152) has a CSRF depth reduction region length (1154), and the SSRF depth reduction region (1352) has an SSRF depth reduction region length (1354). In one particular embodiment, each depth reduction region length (1154, 1354) is 50% or more of the heel side blade length portion (Abl). As shown in FIG. 35, in another embodiment, the approximate center position of the CSRF depth reduction region (1152) and SSRF depth reduction region (1352) is the face centerline (FC). In a design in yet another embodiment, the CSRF depth reduction region length (1154) is 30% or more of the CSRF length (1110) and / or the SSRF depth reduction region length (1354) is SSRF. It is 30% or more of the length (1310). In addition to encouraging the achievement of the object of the present invention, the depth reduction regions (1152, 1352) can improve the life of the SRF (1100, 1300) and reduce the probability of early failure. The COR at the desired position on the face (500) can be increased.

As shown in FIG. 25, the crown-side SRF (1100) has a CSRF cross-sectional area (1170), and the sole-side SRF (1300) has an SSRF cross-sectional area (1370). The cross-sectional area is measured using a cross section from the front portion (402) to the rear portion (404) of the club head (400) in the vertical plane. The CSRF cross-sectional area (1170) and / or the SSRF cross-sectional area so that the cross-sectional profiles (1190, 1390) of FIGS. 28 and 29 can change at each point within the range of the CSRF length (1110) and the SSRF length (1310). (1370) may also change at each point within the length (1110, 1310). In fact, in one particular embodiment, the CSRF cross-sectional area (1170) is the cross-sectional area at a point on the toe side (408) from the face center line (FC) and the heel side (406) from the face center line (FC). It is smaller at the face center line (FC) than the cross-sectional area at the point. Similarly, in other embodiments, the SSRF cross-sectional area (1370) has a cross-sectional area at a point on the toe side (408) from the face center line (FC) and a point on the heel side (406) from the face center line (FC). Is smaller at the face center line (FC) than the cross-sectional area at. In yet other embodiments, both features of the two previous embodiments relating to the CSRF cross section (1170) and SSRF cross section (1370) are included. In one particular embodiment, the CSRF cross-sectional area (1170) and / or the SSRF cross-sectional area (1370) is between 0.005 and 0.375 square inches. Further, the crown side SRF (1100) has a CSRF volume and the sole side SRF (1300) has an SSRF volume. In one embodiment, the sum of the CSRF volume and the SSRF volume is greater than or equal to 0.5% and less than 10% of the club head volume. By using a value within this range, the effect of the present invention is not reduced, and the weight distribution is not excessively increased in the vicinity of the SRF (1100, 1300) of the club head (400). Achievement is encouraged. In yet another embodiment, which is a variation that includes a single SRF, each of the CSRF volume or SSRF volume is preferably greater than or equal to 1% and less than 5% of the club head volume. This facilitates achievement of the object of the present invention without weakening the effect of the present invention and without excessively increasing the weight distribution in the vicinity of the SRF (1100, 1300) of the club head (400). By employing the volume described above, the SRF (1100, 1300) is not limited to being a hollow channel. For example, even when the volume described above is adopted, the SRF (1100, 1300) may be filled with a secondary material as shown in FIG. 51, or the SRF (1100, 1300) may be covered. It may be in a state where the golfer cannot see the inside. The secondary material is elastic, has a compressive strength less than half that of the outer shell, and a density of less than 3 g / cm ³ .

  Here, in another embodiment shown in FIGS. 36 and 37, the distance from the origin to the point closest to the heel (1116) of the CSRF in the same direction as the distance Xcg is defined as the CSRF origin offset (1118). Here, when the point (1116) closest to the heel of the CSRF is located on the toe side (408) of the golf club head (400) from the origin, the CSRF origin offset (1118) is a positive value, When the point closest to the heel (1116) is located on the heel side (406) of the golf club head (400) from the origin, the CSRF origin offset (1118) is a negative value. Similarly, the distance from the origin to the point closest to the heel of SSRF (1316) in the same direction as distance Xcg is defined as SSRF origin offset (1318). Here, when the point (1316) closest to the heel of SSRF is located on the toe side (408) of the golf club head (400) from the origin, the SSRF origin offset (1318) is a positive value, When the point (1316) closest to the heel is located on the heel side (406) of the golf club head (400) from the origin, the SSRF origin offset (1318) is a negative value.

  In one particular embodiment shown in FIG. 37, the SSRF origin offset (1318) is a positive value, that is, the SSRF most heeled point (1316) is in front of the origin. Furthermore, in another embodiment, the embodiment of FIG. 36 is combined. The CSRF origin offset (1118) is a negative value, that is, the point (1116) closest to the heel of the CSRF exceeds the origin, and the absolute value of the CSRF origin offset (1118) is the heel side blade length part (Abl) Of 5% or more. However, in an alternative embodiment, the CSRF most heeled point (1116) does not exceed the origin, so the CSRF origin offset (1118) is a positive value, the absolute value of which is the heel side blade length site. It is 5% or more of (Abl). In these particular embodiments, the most heeled point (1116) of the CSRF and the most heeled point (1316) of the SSRF, the distance between them and the origin is 5% of the heel blade length site (Abl). In order to achieve many purposes of the present invention, it is desirable that the position is set so as not to be less than the range in the impact position with a wide range of golf balls.

  In still other embodiments, as shown in FIGS. 36 and 37, the range of positions of the most toe point (1112) of the CSRF and the most toe point (1312) of the SSRF is defined as a CSRF toe offset (1114) and It is specified by defining an SSRF toe offset (1314). The CSRF toe offset (1114) is the distance from the point (1112) closest to the toe of the CSRF to the point furthest away in the same direction as the distance Xcg on the toe side (408) of the golf club head (400). Further, the SSRF toe offset (1314) is a distance from the point (1312) closest to the toe of the SSRF to the point farthest in the same direction as the distance Xcg on the toe side (408) of the golf club head (400). . In a specific embodiment that produces a preferred face stress distribution and compression and bending of the crown side SRF (1100) and sole side SRF (1300), the CSRF toe offset (1114) is provided at the heel side blade length site (Abl). The SSRF toe offset (1314) is 50% or more of the heel side blade length portion (Abl). In still other embodiments, the CSRF toe offset (1114) and the SSRF toe offset (1314) are each 50% or more of the diameter of the golf ball, so the CSRF toe offset (1114) and the SSRF toe offset (1314) are Each is 0.84 inches. These embodiments have little impact on the overall integrity of the club head (400), thus ensuring the desired durability, especially on the heel side (406) and toe side (408), and even in this case, Deflection of the face when the center is removed and impact is improved.

  In yet another embodiment, note the size of the crown side SRF (1100) and the sole side SRF (1300). In one such embodiment, the maximum value of the CSRF width (1140) is 10% or more of the distance Zcg, and the maximum value of the SSRF width (1340) is 10% or more of the distance Zcg. These increase the stability of the club head (400) during impact. In yet another embodiment, the maximum value of the CSRF width (1140) and the maximum value of the SSRF width (1340) are increased to 40% or more of the distance Zcg, respectively. This improves the selective controllability of the deflection at impact and the peak stress experienced by the face (500). In an alternative embodiment, the maximum value of the CSRF depth (1150) and the maximum value of the SSRF depth (1350) are related to the face height rather than the distance Zcg as described above. For example, in yet another embodiment, the maximum value of CSRF depth (1150) is 5% or more of the face height, and the maximum value of SSRF depth (1350) is 5% or more of the face height. is there. In yet another embodiment, the maximum value of the CSRF depth (1150) is 20% or more of the face height, and the maximum value of the SSRF depth (1350) is 20% or more of the face height. Even in this case, the selective controllability of the deflection at the time of impact and the peak stress received by the face (500) is improved. In many embodiments, the maximum value of the CSRF width (1140) and the maximum value of the SSRF width (1340) are preferably greater than or equal to 0.050 inches and less than or equal to 0.750 inches.

  Other embodiments focus on the position of the crown side SRF (1100) and sole side SRF (1300) relative to the vertical plane defined by the shaft axis (SA) and the Xcg direction. In one such embodiment, improved stability and reduced face stress were observed when the crown side SRF (1100) and / or the sole side SRF (1300) were located behind the shaft axis. In other embodiments, this relationship is further defined. In one such embodiment, the CSRF leading edge (1120) is located at a distance of 20% or more of the distance Zcg behind the shaft axis. Still another embodiment focuses on the position of the sole side SRF (1300), and the SSRF front end edge (1320) is located behind the shaft axial surface at a distance of 10% or more of the distance Zcg. In yet another embodiment focusing on the crown side SRF (1100), the CSRF leading edge (1120) is located behind the shaft axis at a distance of 75% or more of the distance Zcg. In a similar embodiment directed to the sole-side SRF (1300), the SSRF leading edge (1320) is located behind the shaft axis at a distance of 75% or more of the distance Zcg. Similarly, the position of the CSRF front end edge (1120) and the SSRF front end edge (1320) behind the shaft axial surface may be related to the face height instead of the distance Zcg as described above. For example, in one embodiment, the CSRF leading edge (1120) is located behind the shaft axial surface at a distance of 10% or more of the face height. Another embodiment focuses on the position of the sole-side SRF (1300), and the SSRF front end edge (1320) is located behind the shaft axial surface at a distance of 5% or more of the distance Zcg. In yet another embodiment, focusing on both the crown side SRF (1100) and the sole side SRF (1300), the CSRF leading edge (1120) is at a distance of 50% or more of the face height behind the shaft axis. The SSRF front end edge (1320) is located at a distance of 50% or more of the face height behind the shaft axial surface.

  The club head (400) includes but is not limited to a single crown side SRF (1100) and / or a single sole side SRF (1300). Indeed, as shown in FIGS. 30, 31 and 39, in many embodiments, multiple crown side SRFs (1100) and / or multiple sole side SRFs (1300) may be included, in which case multiple The SRFs (1100, 1300) may be arranged side by side in the heel-toe direction, or may be arranged side by side in the front-rear direction. Thus, as shown in FIG. 31, in one particular embodiment, it includes two or more crown side SRFs (1100) located on opposite sides of an engineering impact point (EIP) when viewed in a top view, As a result, the COR can be selectively increased, and the peak stress of the face (500) can be improved. According to the prior art, the COR of the face (500) decreases as the measurement point moves away from the engineering impact point (EIP), so that the golfer is on the heel side (406) or toe side (408) of the golf club head. When a golf ball was hit with a golf club, even if a golf club with a high COR was used, the benefits could not be obtained. Therefore, as shown in FIG. 30, by positioning the two crown sides SRF (1100), the deflection of the face when hit on the heel side (406) or the toe side (408) of the golf club head (400). Can be further improved. In another embodiment shown in FIG. 31, the principle just described is applied to a plurality of sole side SRFs (1300).

  The impact between the club head (400) and the golf ball can be simulated in many ways, such as by experimenting or modeling by a computer. First, an experimental process will be described because it is easy to apply to any golf club head and can eliminate subjectivity. In the process, a force is applied to the face (500) in a 0.6 inch diameter area centered around an engineering impact point (EIP). A force of 4000 lbf corresponds to an impact at approximately 100 mph between the club head (400) and the golf ball. More importantly, this force is easy to apply and reproduce on the face. As a condition regarding the boundary of the club head, the rear portion (404) of the club head (400) is fixed when force is applied. In other words, the club head (400) can be easily fixed to the fixture of the material testing machine and force can be applied. Generally, the rear portion (404) receives little load during actual impact with the golf ball. This is especially true when the “front-back” dimension (FB) is large. The peak deflection of the face (500) under applied force can be easily measured and is very close to the peak deflection seen during actual impact. Peak deflection is linearly correlated with COR. The actual stress is measured by a strain gauge applied to the face (500). This experimental process takes only a few minutes and can be applied to any type of club head (400). In addition, using computer modeling that allows a clearly distinguishable load to be applied to a specific area of the club face (500) enables simulation in a shorter time than actual dynamic impact.

  Club head without stress reducing structure (1000), club head (400) having only sole side SRF (1300), club head (400) having both crown side SRF (1100) and sole side SRF (1300) 44) FIG. 44 shows a graph of the face shift according to the load obtained from an experiment in which loads of 1000 lbf, 2000 lbf, 3000 lbf, and 4000 lbf are applied. All loads were applied to a 0.6 inch diameter area centered around an engineering impact point (EIP). The face thickness (530) was the same for all three club heads and was 0.090 inches. With a crown side SRF (1100) and a sole side SRF (1300) as described herein, face deflection from 0.027 inches to 0.030 inches at a load level of 4000 lbf. Increased by more than 11%. In one particular embodiment, the increase in deflection increased the club head characteristic time (CT) from 187 μs to 248 μs. FIG. 45 shows a graph of peak stress applied to the faces of the three types of club heads described with reference to FIG. 44 according to the load. As shown in FIG. 45, when having a crown side SRF (1100) and a sole side SRF (1300) as described in this specification, the peak stress experienced by the face from 170.4 ksi at a load level of 4000 lbf. Approximately 25% reduction to 128.1 ksi. The stress reduction structure (1000) allows a very thin face (500) to be used without sacrificing the integrity of the club head (400). Indeed, the face thickness (530) can vary from 0.050 to 0.120 inches.

  When the information obtained from FIGS. 44 and 45 is combined, a new ratio can be considered as shown in FIG. That is, the ratio of the stress-deflection, which is the ratio of the peak stress on the face to the shift of the face at an arbitrary load. In one embodiment, the rate of stress-deflection is less than 5000 ksi per inch of deflection, in which case the impact is applied to an area of 0.6 inches in diameter centered on the engineering impact point (EIP) of the face (500). A force similar to the force was applied, the force similar to the impact force was not less than 1000 lbf and not more than 4000 lbf, the volume of the club head was less than 300 cc, and the face thickness (530) was less than 0.120 inch. . In still other embodiments, the face thickness (530) was less than 0.100 inches and the stress-deflection ratio was less than 4500 ksi per inch of deflection. In yet other embodiments, the stress-deflection ratio was less than 4300 ksi per inch of deflection.

In addition to the specific stress-deflection ratio just described, in one embodiment of the present invention, it further includes a face (500) having a characteristic time of 220 μsec or more and a head volume of less than 200 cm ³ . Furthermore, in another embodiment, the characteristic time is 240 μsec or more, the head volume is less than 170 cm ³ , and the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH) are It includes a face (500) having a difference face height of less than 1.50 inches and a vertical roll radius between 7 and 13 inches. This roll radius makes it more difficult to obtain such long characteristic times, low face heights and small golf club head capacities.

  Those skilled in the art will understand that the characteristic time of a golf club head, often referred to as the CT value, is constrained by rules for equipment defined by the United States Golf Association (USGA). According to the rule, the characteristic time of the club head must be 239 μsec or less, and the maximum tolerance in the test is 18 μsec. Therefore, although the golf club is designed so that the target CT value is 239 μsec, depending on the club head, the CT value may exceed 239 μsec or lower than that due to manufacturing variations. However, the CT value must not exceed 257 microseconds, otherwise the USGA rules will not be met. The “Procedure for Measuring the Flexibility of a Golf Clubhead” version 2.0 published by USGA, March 25, 2005, is the current standard for defining the procedure for measuring characteristic time.

  47-49, another embodiment of the crown side SRF (1100) is recessed from the crown (600) and includes a CSRF cavity (1200) that penetrates the outer shell. As shown in FIG. 49, the CSRF hollow portion (1200) is located at the CSRF hollow portion depth (1250) measured in the vertical direction from the top edge height (TEH) toward the center of gravity (CG). Note that the upper edge height (TEH) changes along the face (500) at each point within the range from the heel side (406) to the toe side (408). Therefore, as shown in FIG. 49, a cross section in the front-rear direction of the club head (400) is cut to determine the CSRF hollow portion depth (1250). Accordingly, the upper edge height (TEH) is determined at the specific position on the face (500), and the specific position along the CSRF hollow portion (1200) is determined using the upper edge height (TEH). The CSRF hollow depth at 1250 (1250) is determined. For example, as can be seen from FIG. 47, the cross section shown in FIG. 49 is cut so as to pass through the position of the center of gravity (CG), and is cut between the point closest to the toe from the origin of the club head (400). It is just one of the infinite number of cross sections that can be made. In FIG. 47, a line slightly representing the center of gravity (CG) is a line representing the face center (FC). When a cross section as shown in FIG. 49 is cut along the face center (FC), the upper edge height (TEH) is generally maximum at this point.

  At least a portion of the CSRF hollow depth (1250) is greater than zero. This means that, as shown in FIG. 49, at any point along the CSRF hollow (1200), the CSRF hollow (1200) is the top of the face (400) just in front of the point. It is located lower than the height. In one specific embodiment, the maximum value of the CSRF hollow portion depth (1250) of the CSRF hollow portion (1200) is 10% or more of the distance Ycg. In yet another embodiment, the maximum value of the CSRF hollow portion depth (1250) of the CSRF hollow portion (1200) is 15% or more of the distance Ycg. Preferably, the stress on the face (500) upon impact with a golf ball is preferred by the CSRF hollow depth (1250) being greater than 0, or in some embodiments greater than a certain percentage of the distance Ycg. Reducing and adjusting the temporary bending and deformation of the crown side SRF (1100) to make the CG position, the engineering impact point (EIP), and / or the relative position relative to the outer shell constant, and the face ( 500) and the durability of the crown (600).

  The CSRF hollow portion (1200) has a CSRF hollow portion width (1240) measured in the front-rear direction in FIG. 49 again, separating the CSRF hollow portion front end edge (1220) and the CSRF rear end edge (1230). Have. In one embodiment, the maximum value of the CSRF hollow portion width (1240) of the CSRF hollow portion (1200) is 25% or more of the maximum value of the CSRF hollow portion depth (1250), which has an impact on the golf ball. Repeatedly allows favorable deflection and deformation, and maintains durability and stability. In yet another variation, these objectives are achieved by making the maximum value of the CSRF hollow portion width (1240) less than the maximum value of the CSRF hollow portion depth (1250). In still other embodiments, the maximum value of the CSRF hollow portion width (1240) of the CSRF hollow portion (1200) is 50% or more of the minimum value of the face thickness (530), or optionally the face thickness ( 530) may be less than the maximum value.

  Further developing these desirable characteristics, the CSRF hollow length of the CSRF hollow portion (1200) between the most toe point (1212) of the CSRF hollow portion and the most heel point (1216) of the CSRF hollow portion. (1210) is 50% or more of the distance Xcg. In still other embodiments, the CSRF hollow portion length (1210) is greater than or equal to the length of the heel side blade length portion (Abl), or in other embodiments, the CSRF hollow portion length (1210) is It is also 50% or more of the blade length (BL).

  Referring to FIG. 49, the CSRF hollow front edge (1220) has a CSRF hollow front edge offset (1222). In one embodiment, the minimum value of the CSRRF hollow front edge offset (1222) is 10% or more of the difference between the maximum value of the top edge height (TEH) and the minimum value of the bottom edge height (LEH). Sometimes favorable deflection and deformation are obtained and durability is maintained. In yet another preferred embodiment, the minimum value of the CSRF hollow front edge offset (1222) is the difference between the maximum value of the top edge height (TEH) and the minimum value of the bottom edge height (LEH). 20% or more, and optionally, the maximum value of the CSRRF hollow front edge offset (1222) is 75 of the difference between the maximum value of the top edge height (TEH) and the minimum value of the bottom edge height (LEH). %.

  Referring again to FIGS. 47-49, where attention is now directed to the sole side SRF (1300), the embodiment of the sole side SRF (1300) is recessed from the sole (700) and the SSRF hollow penetrates the outer shell. Part (1400). As shown in FIG. 49, the SSRF hollow portion (1400) is located at the SSRF hollow portion depth (1450) measured in the vertical direction from the lower edge height (LEH) toward the center of gravity (CG). Note that the lower edge height (LEH) changes at each point in the range from the heel side (406) to the toe side (408) along the face (500). Therefore, as shown in FIG. 49, the cross section of the club head (400) in the front-rear direction is cut to determine the SSRF hollow portion depth (1450). Accordingly, the lower edge height (LEH) is determined at the specific position on the face (500), and the specific position along the SSRF hollow portion (1400) is determined using the lower edge height (LEH). The SSRF hollow depth at 1450 (1450) is determined. For example, as can be seen from FIG. 47, the cross section shown in FIG. 49 is cut so as to pass through the position of the center of gravity (CG), and is cut between the point closest to the toe from the origin of the club head (400). It is just one of the infinite number of cross sections that can be made. In FIG. 47, a line slightly representing the center of gravity (CG) is a line representing the face center (FC). When a cross section as shown in FIG. 49 is cut along the face center (FC), the lower edge height (LEH) is generally minimum at this point.

  At least a portion of the SSRF hollow depth (1450) is greater than zero. This means that, as shown in FIG. 49, at any point along the SSRF hollow (1400), the SSRF hollow (1400) is the bottom of the face (400) directly in front of the point. It is located higher than the height. In one particular embodiment, the maximum SSRF hollow depth (1450) of the SSRF hollow portion (1400) is 10% or more of the distance Ycg. In yet another embodiment, the maximum SSRF hollow portion depth (1450) of the SSRF hollow portion (1400) is not less than 15% of the distance Ycg. The SSRF hollow depth (1450) is greater than zero or, in some embodiments, greater than a certain percentage of the distance Ycg, to favor stress on the face (500) upon impact with a golf ball. Adjusting the temporary bending and deformation of the sole side SRF (1300) to make the CG position, the engineering impact point (EIP), and / or the relative position relative to the outer shell constant, and the face ( 500) and the durability of the sole (700).

  The SSRF hollow portion (1400) separates the SSRF hollow portion front edge (1420) and the SSRF rear edge (1430), and again has the SSRF hollow portion width (1440) measured in the front-rear direction in FIG. Have. In one embodiment, the maximum value of the SSRF hollow portion width (1440) of the SSRF hollow portion (1400) is 25% or more of the maximum value of the SSRF hollow portion depth (1450), thereby improving the impact with the golf ball. Repeatedly allows favorable deflection and deformation, and maintains durability and stability. In yet another variation, these objectives are achieved by making the maximum value of the SSRF cavity width (1440) less than the maximum value of the SSRF cavity depth (1450). In still other embodiments, the maximum SSRF hollow width (1440) of the SSRF hollow portion (1400) is 50% or more of the minimum value of the face thickness (530), or optionally the face thickness ( 530) may be less than the maximum value.

  Further developing these desirable characteristics, SSRF hollow section length of SSRF hollow section (1400) between the most toe point (1412) of SSRF hollow section and the most heel point (1416) of SSRF hollow section. (1410) is 50% or more of the distance Xcg. In still other embodiments, the SSRF hollow portion length (1410) is greater than or equal to the length of the heel side blade length portion (Abl), or in other embodiments, the SSRF hollow portion length (1410) is It is also 50% or more of the blade length (BL).

  Referring to FIG. 49, the SSRF hollow front edge (1420) has an SSRF hollow front edge offset (1422). In one embodiment, the minimum value of the SSRF hollow front edge offset (1422) is 10% or more of the difference between the maximum value of the top edge height (TEH) and the minimum value of the bottom edge height (LEH). Sometimes favorable deflection and deformation are obtained and durability is maintained. In yet another preferred embodiment, the SSRF hollow front edge offset (1422) minimum value is the difference between the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH). 20% or more, and optionally, the maximum SSRF hollow front edge offset (1422) is 75 of the difference between the maximum value of the top edge height (TEH) and the minimum value of the bottom edge height (LEH). %.

  As described above, as shown in FIG. 51, the SRF (1100, 1300) may be filled with a secondary material, or may be covered so that the golfer cannot see the inside. . Similarly, the hollow portions (1200, 1400) are covered or filled so that they cannot be seen by the user and foreign objects and moisture will not inadvertently enter the club head. Also good. In other words, just because the hollow portions (1200, 1400) exist, it is not necessary to be able to see the inside of the club head through them. The hollow portions (1200, 1400) may be covered with a badge extending over them, and a portion of such a cover extends into the hollow portion (1200, 1400) as shown in FIG. May be. When a portion of the cover extends into the hollow portion (1200, 1400), that portion is compressible and has a compressive strength that is less than 50% of the compressive strength of the outer shell. The badge extending on the hollow portion (1200, 1400) is attached to the outer shell only on one side of the hollow portion (1200, 1400), or the badge is flexible or to the outer shell of the badge Is attached to the outer shell on both side surfaces of the hollow portions (1200, 1400).

  The size, position, and configuration of the CSRF hollow portion (1200) and the SSRF hollow portion (1400) preferably reduce stress applied to the face (500) upon impact with the golf ball, and the crown side SRF (1100) and sole side Temporary bending and deformation of the SRF (1300) is adjusted to make the CG position and / or relative position to the origin constant, and the durability of the face (500), crown (600) and sole (700) Selected to maintain. In FIGS. 47 to 49, the hollow portions (1200, 1400) are generally shown on the bottom wall of the SRF (1100, 1300). However, the hollow portions (1200, 1400) may be provided at other positions of the SRF (1100, 1300). For example, the hollow portion (1200, 1400) includes the front wall, as in the CSRF hollow portion (1100) in FIG. 50, and both the CSRF hollow portion (1200) and SSRF hollow portion (1400) in FIG. As in the SSRF hollow portion (1400) in FIG.

  As described above, the golf club head (100) has a blade length (BL), which is horizontal from the origin to the toe side of the golf club head, It is measured up to the most distant point of the golf club head in a direction parallel to the base surface (GP). In one particular embodiment, the golf club head (100) has a blade length (BL) of 3.1 inches or greater, a heel side blade length portion (Abl) of 1.1 inches or greater, and a club moment The arm (CMA) is less than 1.3 inches, which results in a long blade golf club with improved characteristic time properties that reduces the stress experienced by the face. Even in this case, it is not adversely affected by the large club moment arm (CMA) that tends to be in a fairway wood that is too large. The club moment arm (CMA) has a great influence on the flying of the ball when hit with the center off. Importantly, the smaller the club moment arm (CMA), the smaller the difference between the shot when hit with an engineering impact point (EIP) and the shot when hit with the center off. That is. Therefore, the golf ball hit near the heel or toe of the golf club of the present invention is more similar to that when hit with a perfect shot. On the contrary, the golf ball hit near the heel of the fairway wood or the toe which is too large and the club moment arm (CMA) is too large is the same as the engineering method of the fairway wood which is too large. It will be very different from the way the ball hit at the impact point (EIP). In general, a golf club with a large club moment arm (CMA) gives a faster spin speed to the golf ball when hit perfectly at an engineering impact point (EIP) and hits off the center There is a big difference in the spin speed that is born. Thus, in yet another embodiment, the club moment arm (CMA) is less than 1.1 inches, which results in more efficient firing conditions, such as a small change in the spin rate of the ball with respect to a change in launch angle. The golf club has a longer flight distance.

  Previous technical knowledge of increasing the Zcg value to improve club head performance did not indicate that it is the club moment arm (CMA) that has a greater impact on golf club performance and ball flight. . Along with the long blade length (BL) and the long heel side blade length part (Abl), the club moment arm (CMA) is controlled to improve the club head's ability to disperse stress during impact, especially at the center Improving the characteristic time over a larger range of the face at the time of impact results in launch conditions with less difference between perfect impact and off-center impact than the prior art. In other embodiments, as shown in FIGS. 6 and 13, the ratio of the golf club head front-back dimension (FB) to the blade length (BL) is less than 0.925. In this embodiment, limiting the front-back dimension (FB) of the club head (100) relative to the blade length (BL) improves the performance of the club, even in this case, characteristic time, heel side and toe side Desired improvements in face deflection and reduced club moment arm (CMA) can be achieved. The reduced front-back dimension (FB) and related Zcg of the present invention can greatly reduce the dynamic loft angle of the golf club head. The blade length (BL) of the fairway wood is increased and the front-back dimension (FB) is reduced, the stress reduction structure (1000), the minimum value of the heel side blade length part (Abl), and the club moment arm By incorporating the features described above with respect to the maximum value of (CMA), golf club heads with improved performance can be made that would not be anticipated by those skilled in the art implementing the principles of the prior art. In another embodiment, a unique ratio of the heel side blade length portion (Abl) to the front-back dimension (FB) of the golf club head is identified, which is greater than or equal to 0.32. In yet another embodiment, the ratio of the club moment arm (CMA) to the heel side blade length part (Abl) is specified. In the present embodiment, the ratio of the club moment arm (CMA) to the heel side blade length part (Abl) is less than 0.9. In yet another embodiment, the fairway wood golf club head of the present invention is characterized by a unique ratio of heel side blade length portion (Abl) to blade length (BL), wherein the ratio is 0.33 or greater. And In other embodiments, a very advantageous performance of the club head with respect to firing conditions is obtained when the transfer distance (TD) is more than 10% longer than the club moment arm (CMA). Further, particularly effective with fairway wood is when the transfer distance (TD) is 10-40% longer than the club moment arm (CMA). By using a value in this range, the face closing moment (MOIfc) is reliably increased and the movement of the club head to the square position to impact is naturally felt, with respect to the small club moment arm (CMA) and CG position. Advantageous impact features can be utilized.

  Referring to FIG. 10, in one embodiment, the desired performance and sensation are further improved by making the relationship between the top edge height (TEH) and the distance Ycg specific. In this embodiment, the preferable ratio of the distance Ycg to the top edge height (TEH) is less than 0.40. Even in this case, the blade length is as long as 3.1 inches or more, and the blade length is 1 The heel side blade length portion (Abl) of 1 inch or more is included, the club moment arm (CMA) is less than 1.1 inch, and the transfer distance (TD) is 1.2 inch or more. Here, the transfer distance (TD) is 10 to 40% longer than the club moment arm (CMA). By satisfying this ratio, the CG is surely positioned below the engineering impact point (EIP). Even in this case, the relationship between the club moment arm (CMA) and the transfer distance (TD) is the stress reduction structure ( 1000), which is reliably achieved by the design of a club head with a long blade length (BL) and a heel side blade length portion (Abl). As described above, by definition, the club moment arm (CMA) increases as the CG height decreases. This also allows the club moment arm (CMA) to be less than 1.1 inches while shortening the distance Ycg, and a longer blade length (BL) and a longer heel side blade length section (Abl). Therefore, it is necessary to pay particular attention to increasing the transfer distance (TD). In yet another embodiment, the ratio of the distance Ycg to the top edge height (TEH) is less than 0.375, which makes ball flying performance more desirable. Generally, the top edge height (TEH) of fairway wood golf clubs is between 1.1 and 2.1 inches.

  In fact, many of the fairway wood type golf club heads that accidentally have a short distance Ycg have a short blade length (BL), a small heel side blade length portion (Abl), and / or a long club moment arm (CMA). Has been adversely affected by. Referring to FIG. 3, in one particular embodiment, improved performance is achieved with a distance Ycg of less than 0.65 inches, and even in this case, the blade length is increased to 3.1 inches or more. The length includes a heel side blade length part (Abl) of 1.1 inches or more, a club moment arm (CMA) is less than 1.1 inches, and a transfer distance (TD) is 1.2 inches or more. . Here, the transfer distance (TD) is 10 to 40% longer than the club moment arm (CMA). As described above, these relationships have a delicate balance between many variables and are often different from conventional club head design principles to achieve the desired performance. Furthermore, in other embodiments, the distance Ycg is further reduced to less than 0.60 inches while maintaining a delicate balance in this relationship.

  As described above, conventionally, a fairway wood having a large MOIy has been pursued to produce a fairway wood that is too large, and the position of the CG has been tried to be as far as possible from the club face and as low as possible. Referring to FIG. 8, this particular common practice has created a large club moment arm (CMA). The club moment arm (CMA) is intended to be reduced by the present invention. Further, those skilled in the art will actually lengthen the club moment arm (CMA) simply by lowering the CG position as shown in FIG. 8 while keeping the distance Zcg constant as shown in FIGS. You will understand that. In the present invention, the club moment arm (CMA) was kept below 1.1 inches to achieve the desired performance advantages described above. Even in this case, the distance Ycg is shortened in relation to the top edge height (TEH), which effectively reduces the distance Zcg, and the CG position is contrary to many conventional design goals. , Approaching the face.

  As explained so far, the relationship between many variables plays an important role in obtaining the desired performance and feel of the golf club. One of these weight relationships is the distance between the club moment arm (CMA) and the transfer distance (TD). In one particular embodiment, the club moment arm (CMA) is less than 1.1 and the transfer distance (TD) is 1.2 inches or greater. However, in yet another particular embodiment, this relationship is further refined and the ratio of the club moment arm (CMA) to the transfer distance (TD) of the fairway wood golf club is less than 0.75, especially The desired performance is possible. In one embodiment, further performance improvements are achieved and the club moment arm (CMA) is less than 1.0 inch, more preferably less than 0.95 inch. In one partially related embodiment, the mass distribution is such that the ratio of the distance Xcg to the distance Ycg is 2 or more.

In other embodiments, the distance Ycg is less than 0.65 inches and the required club head shell weight is very light. As a result, an arbitrarily selectable mass can be added to the sole region as much as possible without exceeding the normally allowable head weight and while maintaining the required durability. This can be accomplished, in one particular embodiment, by constructing the shell from a material having a density of less than 5 g / cm ^3, such as a titanium alloy, a non-metallic composite, or a thermoplastic material, and the final finished club head More than one third of the weight can be an arbitrarily selectable mass located in the sole of the club head. Such non-metallic composites may include composite materials such as continuous fiber prepreg materials (thermosetting materials or thermoplastic materials instead of resins). In still other embodiments, the optionally selectable mass is comprised of a second material having a density of 15 g / cm ³ or higher, such as tungsten. In still other embodiments, a distance Ycg of less than 0.55 inches is obtained by using an optional selectable mass of a titanium alloy shell and 80 g or more of tungsten. Even in this case, the ratio of the distance Ycg to the upper edge height (TEH) is less than 0.40, the blade length (BL) is 3.1 inches or more, and the blade length (BL) is 1.1 inches or more. The heel side blade length portion (Abl) is included, the club moment arm (CMA) is less than 1.1 inches, and the transfer distance (TD) is 1.2 inches or more.

  In another embodiment, a fairway wood type golf club can be created that further defines an unusual relationship between club head variables that provides extraordinary performance and feel. In the present embodiment, a heel side blade length portion (Abl) that is at least twice the distance Ycg is desirable from the viewpoints of performance, sense, and aesthetic sense. Furthermore, since the heel side blade length part (Abl) exceeding 2.75 times the distance Ycg is not desirable from the viewpoint of performance, feeling, and aesthetic feeling, a preferable range can be specified. Accordingly, in this embodiment, the heel side blade length portion (Abl) is between 2 and 2.75 times the distance Ycg.

  Similarly, the desired overall blade length (BL) is related to the distance Ycg. In yet another embodiment, favorable performance and feel is obtained when the blade length (BL) is greater than or equal to 6 times the distance Ycg. Such a relationship has not been explored in the prior art for golf clubs. The reason is that the blade length (BL) becomes excessively long. Furthermore, since a blade length (BL) exceeding 7 times the distance Ycg is not desirable from the viewpoint of performance and feeling, a preferable range can be specified. Thus, in one embodiment, the blade length (BL) is 6-7 times the distance Ycg.

  As a new relationship between the blade length (BL) and the distance Ycg and a new relationship between the heel side blade length part (Abl) and the distance Ycg are specified, it is possible to produce a golf club with particularly excellent performance. A possible relationship between the transfer distance (TD) and the distance Ycg is specified in another embodiment. In one embodiment, favorable performance and sensation are achieved when the transfer distance (TD) is greater than or equal to 2.25 times the distance Ycg. Further, when the transfer distance (TD) exceeds 2.75 times the distance Ycg, the performance and the feeling are deteriorated, so that a preferable range can be specified. Thus, in still other embodiments, the transfer distance (TD) should be within a relatively narrow range of 2.25 to 2.75 times the distance Ycg to obtain favorable performance and feel.

  All ratios defined in the embodiments of the present invention are the discovery of a unique relationship between the major engineering variables for the club head, and simply increase the MOIy as in the prior art knowledge of golf club head design. Conflicts with attempts to lower or lower the position of the CG. Many variations, modifications, and variations of the preferred embodiment disclosed herein will be apparent to those skilled in the art, and these variations, modifications, and variations are also included in the spirit and aspects of the present invention. Considered. Further, while specific embodiments have been described in detail, those skilled in the art will be able to modify the above-described embodiments and variations to provide various types of substitutes, or between additional or alternative materials, elements. It will be understood that relative arrangements, dimensions and the like can be incorporated. Accordingly, while only some of the variations of the present invention have been described herein, the implementation of such additional modifications, variations, and equivalents thereof is as defined in the following claims. It will be understood that they are within the spirit and aspect of the invention.

Claims (26)

A golf club having a stress reducing structure including a hollow portion;
(A) a shaft;
(B) a grip;
(C) a golf club head,
The shaft has a shaft proximal end and a shaft distal end;
The grip is attached to the proximal end of the shaft;
The golf club head is
(I) a face;
(Ii) a sole;
(Iii) a crown;
(Iv) a skirt;
(V) the bore;
(Vi) club head mass;
(Vii) the center of gravity (CG);
(Viii) engineering impact point (EIP);
(Ix) a stress reducing structure;
The face is located at a front portion of the golf club head, which is an impact position of the golf club head with a golf ball, and has a loft angle of 12 ° or more and 30 ° or less, and the engineering impact point (EIP) ), Upper edge height (TEH), and lower edge height (LEH),
The sole is located at the bottom of the golf club head;
The crown is located at the top of the golf club head;
The skirt is located over a portion of the outer edge of the golf club head between the sole and the crown;
Defining an outer shell that defines a head volume, wherein the face, the sole, the crown, and the skirt are less than 300 cm ³ ;
The golf club head has a rear portion on the opposite side of the face,
The bore has a center that defines a shaft axis (SA) that defines an origin by intersecting a base surface (GP) that extends in a horizontal direction, and is positioned on a heel side of the golf club head, and the golf club head Receiving the shaft distal end for attachment to
The toe side of the golf club head is located on the opposite side of the heel side,
The club head mass is less than 270 g;
The center of gravity (CG) is
(A) A distance Ycg is placed in the vertical direction from the origin to the crown of the golf club head,
(B) A distance Xcg substantially parallel to the face and the base surface (GP) is placed in a horizontal direction from the origin toward the toe side of the golf club head,
(C) From the origin to the rear direction, substantially perpendicular to the vertical direction used for measuring the distance Ycg, and substantially perpendicular to the horizontal direction used for measuring the distance Xcg. In the direction with a distance Zcg,
The engineering impact point (EIP) is
(A) A distance Yeip is placed in a vertical direction from the origin to the crown of the golf club head,
(B) A distance Xeip substantially parallel to the face and the base surface (GP) is placed in a horizontal direction from the origin toward the toe side of the golf club head,
(C) The face direction from the origin, substantially orthogonal to the vertical direction used for measuring the distance Ycg, and substantially orthogonal to the horizontal direction used for measuring the distance Xcg. Put a distance Zeip in the direction to
Position to,
The stress reducing structure includes a sole side SRF,
(A) The sole-side SRF includes an SSRF length between a point closest to the toe of the SSRF and a point closest to the heel of the SSRF, an SSRF front end edge having an SSRF front end offset, an SSRF width, and an SSRF depth. Have
(B) The sole-side SRF has an SSRF hollow portion that is recessed from the sole and penetrates the outer shell, and the SSRF hollow portion is perpendicular from the lower edge height (LEH) to the center of gravity (CG). Located at the SSRF hollow depth measured in the direction, at least a portion of the SSRF hollow portion has the SSRF hollow depth greater than 0, and the SSRF hollow portion is The SSRF hollow portion length that is 50% or more of the distance Xcg between the point closest to the toe and the point closest to the heel of the SSRF hollow portion, and the SSRF hollow front end edge and the SSRF hollow rear end edge are separated from each other. A golf club having an SSRF hollow width.   The golf club according to claim 1, wherein a maximum value of the SSRF hollow portion depth of the SSRF hollow portion is 10% or more of the distance Ycg.   The golf club according to claim 1 or 2, wherein a maximum value of the SSRF hollow part depth of the SSRF hollow part is 15% or more of the distance Ycg.   4. The golf club according to claim 1, wherein a maximum value of the SSRF hollow portion width of the SSRF hollow portion is 25% or more of a maximum value of the SSRF hollow portion depth. 5.   5. The golf club according to claim 1, wherein a maximum value of the SSRF hollow portion width of the SSRF hollow portion is less than a maximum value of the SSRF hollow portion depth. The golf club head has a blade length (BL) measured from the origin to the farthest point of the golf club head in a horizontal direction from the origin toward the toe side of the golf club head,
The blade length (BL) is
(A) a heel side blade length portion (Abl) measured from the origin to the engineering impact point (EIP) in the same direction as the blade length (BL);
(B) a toe side blade length part (Bbl), and
(C) The golf club according to any one of claims 1 to 5, wherein a length of the SSRF hollow portion is equal to or longer than a length of the heel side blade length portion (Abl).   The golf club according to claim 6, wherein the blade length (BL) is 3.0 inches or more, and the heel side blade length portion (Abl) is 0.8 inches or more.   The golf club according to claim 6 or 7, wherein the SSRF hollow portion length is 50% or more of the blade length (BL).   9. The golf club according to claim 1, wherein a maximum value of the SSRF hollow portion width of the SSRF hollow portion is 50% or more of a minimum value of the face thickness.   The golf club according to claim 9, wherein a maximum value of the SSRF hollow portion width of the SSRF hollow portion is less than a maximum value of the face thickness.   The SSRF hollow part front edge has an SSRF hollow part front edge offset, and the minimum value of the SSRF hollow part front edge offset is the maximum value of the upper edge height (TEH) and the lower edge height (LEH). The golf club according to claim 1, wherein the golf club is 10% or more of a difference from the minimum value.   The minimum value of the SSRF hollow portion front edge offset is 20% or more of the difference between the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH). The listed golf club.   The maximum value of the SSRF hollow front edge offset is less than 75% of the difference between the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH). 12. The golf club according to 12. A golf club having a stress reducing structure including a hollow portion;
(A) a shaft;
(B) a grip;
(C) a golf club head,
The shaft has a shaft proximal end and a shaft distal end;
The grip is attached to the proximal end of the shaft;
The golf club head is
(I) a face;
(Ii) a sole;
(Iii) a crown;
(Iv) a skirt;
(V) the bore;
(Vi) club head mass;
(Vii) the center of gravity (CG);
(Viii) engineering impact point (EIP);
(Ix) a stress reducing structure;
The face is located at a front portion of the golf club head, which is an impact position of the golf club head with a golf ball, and has a loft angle of 12 ° or more and 30 ° or less, and the engineering impact point (EIP) ), Upper edge height (TEH), and lower edge height (LEH),
The sole is located at the bottom of the golf club head;
The crown is located at the top of the golf club head;
The skirt is located over a portion of the outer edge of the golf club head between the sole and the crown;
Defining an outer shell that defines a head volume, wherein the face, the sole, the crown, and the skirt are less than 300 cm ³ ;
The golf club head has a rear portion on the opposite side of the face,
The bore has a center that defines a shaft axis (SA) that defines an origin by intersecting a base surface (GP) that extends in a horizontal direction, and is positioned on a heel side of the golf club head, and the golf club head Receiving the shaft distal end for attachment to
The toe side of the golf club head is located on the opposite side of the heel side,
The club head mass is less than 270 g;
The center of gravity (CG) is
(A) A distance Ycg is placed in the vertical direction from the origin to the crown of the golf club head,
(B) A distance Xcg substantially parallel to the face and the base surface (GP) is placed in a horizontal direction from the origin toward the toe side of the golf club head,
(C) From the origin to the rear direction, substantially perpendicular to the vertical direction used for measuring the distance Ycg, and substantially perpendicular to the horizontal direction used for measuring the distance Xcg. In the direction with a distance Zcg,
The engineering impact point (EIP) is
(A) A distance Yeip is placed in a vertical direction from the origin to the crown of the golf club head,
(B) A distance Xeip substantially parallel to the face and the base surface (GP) is placed in a horizontal direction from the origin toward the toe side of the golf club head,
(C) The face direction from the origin, substantially orthogonal to the vertical direction used for measuring the distance Ycg, and substantially orthogonal to the horizontal direction used for measuring the distance Xcg. Put a distance Zeip in the direction to
Position to,
The stress reducing structure includes a crown side SRF;
(A) The crown side SRF includes a CSRF length between a point closest to the toe of the CSRF and a point closest to the heel of the CSRF, a CSRF front edge having a CSRF front edge offset, a CSRF width, and a CSRF depth. Have
(B) The crown side SRF includes a CSRF hollow portion that is recessed from the crown and penetrates the outer shell, and the CSRF hollow portion is perpendicular to the center of gravity (CG) from the upper edge height (TEH). At least a portion of the CSRF hollow portion has a CSRF hollow portion depth greater than 0, the CSRF hollow portion being the most of the CSRF hollow portion. The CSRF hollow portion length that is 50% or more of the distance Xcg between the point near the toe and the point closest to the heel of the CSRF hollow portion, and the CSRF that separates the CSRF hollow portion front end edge and the CSRF hollow portion rear end edge A golf club having a hollow width.   The golf club according to claim 14, wherein a maximum value of the CSRF hollow portion depth of the CSRF hollow portion is 10% or more of the distance Ycg.   The golf club according to claim 14 or 15, wherein a maximum value of the CSRF hollow portion depth of the CSRF hollow portion is 15% or more of the distance Ycg.   The golf club according to any one of claims 14 to 16, wherein a maximum value of the CSRF hollow portion width of the CSRF hollow portion is 25% or more of a maximum value of the CSRF hollow portion depth.   The golf club according to claim 17, wherein a maximum value of the CSRF hollow portion width of the CSRF hollow portion is less than a maximum value of the CSRF hollow portion depth. The golf club head has a blade length (BL) measured from the origin to the farthest point of the golf club head in a horizontal direction from the origin toward the toe side of the golf club head,
The blade length (BL) is
(A) a heel side blade length portion (Abl) measured from the origin to the engineering impact point (EIP) in the same direction as the blade length (BL);
(B) a toe side blade length part (Bbl), and
(C) The golf club according to any one of claims 14 to 18, wherein a length of the CSRF hollow portion is equal to or longer than a length of the heel side blade length portion (Abl).   The golf club according to claim 19, wherein the blade length (BL) is 3.0 inches or more, and the heel side blade length portion (Abl) is 0.8 inches or more.   The golf club according to claim 19 or 20, wherein the CSRF hollow portion length is 50% or more of the blade length (BL).   The golf club according to any one of claims 14 to 21, wherein a maximum value of the CSRF hollow portion width of the CSRF hollow portion is 50% or more of a minimum value of a face thickness.   The golf club according to claim 22, wherein a maximum value of the CSRF hollow portion width of the CSRF hollow portion is less than a maximum value of the face thickness.   The CSRF hollow part front edge has a CSRF hollow part front edge offset, and the minimum value of the CSRF hollow part front edge offset is the maximum value of the upper edge height (TEH) and the lower edge height (LEH). The golf club according to any one of claims 14 to 23, wherein the golf club is 10% or more of a difference from the minimum value.   The minimum value of the CSRF hollow portion front edge offset is 20% or more of the difference between the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH). The listed golf club.   The maximum value of the CSRF hollow front edge offset is less than 75% of the difference between the maximum value of the upper edge height (TEH) and the minimum value of the lower edge height (LEH). The golf club according to 25.

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