Iron-type golf club head

Information

  • Patent Grant
  • 11478685
  • Patent Number
    11,478,685
  • Date Filed
    Wednesday, June 23, 2021
    3 years ago
  • Date Issued
    Tuesday, October 25, 2022
    2 years ago
Abstract
An iron-type golf club incorporating an aperture extending through the shell on the sole. The location and size of the aperture selectively increase deflection of the face.
Description
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was not made as part of a federally sponsored research or development project.


TECHNICAL FIELD

The present invention relates to the field of golf clubs, namely hollow golf club heads. The present invention is a hollow golf club head characterized by a stress reducing feature that includes a stress reducing feature having an aperture.


BACKGROUND OF THE INVENTION

The impact associated with a golf club head, often moving in excess of 100 miles per hour, impacting a stationary golf ball results in a tremendous force on the face of the golf club head, and accordingly a significant stress on the face. It is desirable to reduce the peak stress experienced by the face and to selectively distribute the force of impact to other areas of the golf club head where it may be more advantageously utilized.


SUMMARY OF INVENTION

In its most general configuration, the present invention advances the state of the art with a variety of new capabilities and overcomes many of the shortcomings of prior methods in new and novel ways. In its most general sense, the present invention overcomes the shortcomings and limitations of the prior art in any of a number of generally effective configurations.


The present golf club incorporating a stress reducing feature including a crown located SRF, short for stress reducing feature, located on the crown of the club head and/or a sole located SRF located on the sole of the club head. The SRF may contain an aperture extending through the shell of the golf club head. The location and size of the SRF and aperture play a significant role in reducing the peak stress seen on the golf club's face during an impact with a golf ball, as well as selectively increasing deflection of the face.


Numerous variations, modifications, alternatives, and alterations of the various preferred embodiments, processes, and methods may be used alone or in combination with one another as will become more readily apparent to those with skill in the art with reference to the following detailed description of the preferred embodiments and the accompanying figures and drawings.





BRIEF DESCRIPTION OF THE DRAWINGS

Without limiting the scope of the present invention as claimed below and referring now to the drawings and figures:



FIG. 1 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 2 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 3 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 4 shows a toe side elevation view of an embodiment of the present invention, not to scale;



FIG. 5 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 6 shows a toe side elevation view of an embodiment of the present invention, not to scale;



FIG. 7 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 8 shows a toe side elevation view of an embodiment of the present invention, not to scale;



FIG. 9 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 10 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 11 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 12 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 13 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 14 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 15 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 16 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 17 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 18 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 19 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 20 shows a toe side elevation view of an embodiment of the present invention, not to scale;



FIG. 21 shows a front elevation view of an embodiment of the present invention, not to scale;



FIG. 22 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 23 shows a bottom plan view of an embodiment of the present invention, not to scale;



FIG. 24 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 25 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 26 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 27 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 28 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 29 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 30 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 31 shows a bottom plan view of an embodiment of the present invention, not to scale;



FIG. 32 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 33 shows a bottom plan view of an embodiment of the present invention, not to scale;



FIG. 34 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 35 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 36 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 37 shows a bottom plan view of an embodiment of the present invention, not to scale;



FIG. 38 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 39 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 40 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 41 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 42 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 43 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 44 shows a graph of face displacement versus load;



FIG. 45 shows a graph of peak stress on the face versus load;



FIG. 46 shows a graph of the stress-to-deflection ratio versus load;



FIG. 47 shows a top plan view of an embodiment of the present invention, not to scale;



FIG. 48 shows a bottom plan view of an embodiment of the present invention, not to scale;



FIG. 49 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 50 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 51 shows a partial cross-sectional view of an embodiment of the present invention, not to scale;



FIG. 52 shows a partial cross-sectional view of an embodiment of the present invention, not to scale; and



FIG. 53 shows a partial cross-sectional view of an embodiment of the present invention, not to scale.





These drawings are provided to assist in the understanding of the exemplary embodiments of the present golf club as described in more detail below and should not be construed as unduly limiting the golf club. In particular, the relative spacing, positioning, sizing and dimensions of the various elements illustrated in the drawings are not drawn to scale and may have been exaggerated, reduced or otherwise modified for the purpose of improved clarity. Those of ordinary skill in the art will also appreciate that a range of alternative configurations have been omitted simply to improve the clarity and reduce the number of drawings.


DETAILED DESCRIPTION OF THE INVENTION

The hollow golf club of the present invention enables a significant advance in the state of the art. The preferred embodiments of the golf club accomplish this by new and novel methods that are configured in unique and novel ways and which demonstrate previously unavailable, but preferred and desirable capabilities. The description set forth below in connection with the drawings is intended merely as a description of the presently preferred embodiments of the golf club, and is not intended to represent the only form in which the present golf club may be constructed or utilized. The description sets forth the designs, functions, means, and methods of implementing the golf club in connection with the illustrated embodiments. It is to be understood, however, that the same or equivalent functions and features may be accomplished by different embodiments that are also intended to be encompassed within the spirit and scope of the claimed golf club head.


In order to fully appreciate the present disclosed golf club some common terms must be defined for use herein. First, one of skill in the art will know the meaning of “center of gravity,” referred to herein as CG, from an entry level course on the mechanics of solids. With respect to wood-type golf clubs, hybrid golf clubs, and hollow iron type golf clubs, which are may have non-uniform density, the CG is often thought of as the intersection of all the balance points of the club head. In other words, if you balance the head on the face and then on the sole, the intersection of the two imaginary lines passing straight through the balance points would define the point referred to as the CG.


It is helpful to establish a coordinate system to identify and discuss the location of the CG. In order to establish this coordinate system one must first identify a ground plane (GP) and a shaft axis (SA). First, the ground plane (GP) is the horizontal plane upon which a golf club head rests, as seen best in a front elevation view of a golf club head looking at the face of the golf club head, as seen in FIG. 1. Secondly, the shaft axis (SA) is the axis of a bore in the golf club head that is designed to receive a shaft. Some golf club heads have an external hosel that contains a bore for receiving the shaft such that one skilled in the art can easily appreciate the shaft axis (SA), while other “hosel-less” golf clubs have an internal bore that receives the shaft that nonetheless defines the shaft axis (SA). The shaft axis (SA) is fixed by the design of the golf club head and is also illustrated in FIG. 1.


Now, the intersection of the shaft axis (SA) with the ground plane (GP) fixes an origin point, labeled “origin” in FIG. 1, for the coordinate system. While it is common knowledge in the industry, it is worth noting that the right side of the club head seen in FIG. 1, the side nearest the bore in which the shaft attaches, is the “heel” side of the golf club head; and the opposite side, the left side in FIG. 1, is referred to as the “toe” side of the golf club head. Additionally, the portion of the golf club head that actually strikes a golf ball is referred to as the face of the golf club head and is commonly referred to as the front of the golf club head; whereas the opposite end of the golf club head is referred to as the rear of the golf club head and/or the trailing edge.


A three dimensional coordinate system may now be established from the origin with the to Y-direction being the vertical direction from the origin; the X-direction being the horizontal direction perpendicular to the Y-direction and wherein the X-direction is parallel to the face of the golf club head in the natural resting position, also known as the design position; and the Z-direction is perpendicular to the X-direction wherein the Z-direction is the direction toward the rear of the golf club head. The X, Y, and Z directions are noted on a coordinate system symbol in FIG. 1. It should be noted that this coordinate system is contrary to the traditional right-hand rule coordinate system; however it is preferred so that the center of gravity may be referred to as having all positive coordinates.


Now, with the origin and coordinate system defined, the terms that define the location of the CG may be explained. One skilled in the art will appreciate that the CG of a hollow golf club head such as the wood-type golf club head illustrated in FIG. 2 will be behind the face of the golf club head. The distance behind the origin that the CG is located is referred to as Zcg, as seen in FIG. 2. Similarly, the distance above the origin that the CG is located is referred to as Ycg, as seen in FIG. 3. Lastly, the horizontal distance from the origin that the CG is located is referred to as Xcg, also seen in FIG. 3. Therefore, the location of the CG may be easily identified by reference to Xcg, Ycg, and Zcg.


The moment of inertia of the golf club head is a key ingredient in the playability of the club. Again, one skilled in the art will understand what is meant by moment of inertia with respect to golf club heads; however it is helpful to define two moment of inertia components that will be commonly referred to herein. First, MOIx is the moment of inertia of the golf club head around an axis through the CG, parallel to the X-axis, labeled in FIG. 4. MOIx is the moment of inertia of the golf club head that resists lofting and delofting moments induced by ball strikes high or low on the face. Secondly, MOIy is the moment of the inertia of the golf club head around an axis through the CG, parallel to the Y-axis, labeled in FIG. 5. MOIy is the moment of inertia of the golf club head that resists opening and closing moments induced by ball strikes towards the toe side or heel side of the face.


Continuing with the definitions of key golf club head dimensions, the “front-to-back” dimension, referred to as the FB dimension, is the distance from the furthest forward point at the leading edge of the golf club head to the furthest rearward point at the rear of the golf club head, i.e. the trailing edge, as seen in FIG. 6. The “heel-to-toe” dimension, referred to as the HT dimension, is the distance from the point on the surface of the club head on the toe side that is furthest from the origin in the X-direction, to the point on the surface of the golf club head on the heel side that is 0.875″ above the ground plane and furthest from the origin in the negative X-direction, as seen in FIG. 7.


A key location on the golf club face is an engineered impact point (EIP). The engineered impact point (EIP) is important in that it helps define several other key attributes of the present golf club head. The engineered impact point (EIP) is generally thought of as the point on the face that is the ideal point at which to strike the golf ball. Generally, the score lines on golf club heads enable one to easily identify the engineered impact point (EIP) for a golf club. In the embodiment of FIG. 9, the first step in identifying the engineered impact point (EIP) is to identify the top score line (TSL) and the bottom score line (BSL). Next, draw an imaginary line (IL) from the midpoint of the top score line (TSL) to the midpoint of the bottom score line (BSL). This imaginary line (IL) will often not be vertical since many score line designs are angled upward toward the toe when the club is in the natural position. Next, as seen in FIG. 10, the club must be rotated so that the top score line (TSL) and the bottom score line (BSL) are parallel with the ground plane (GP), which also means that the imaginary line (IL) will now be vertical. In this position, the leading edge height (LEH) and the top edge height (TEH) are measured from the ground plane (GP). Next, the face height is determined by subtracting the leading edge height (LEH) from the top edge height (TEH). The face height is then divided in half and added to the leading edge height (LEH) to yield the height of the engineered impact point (EIP). Continuing with the club head in the position of FIG. 10, a spot is marked on the imaginary line (IL) at the height above the ground plane (GP) that was just calculated. This spot is the engineered impact point (EIP).


The engineered impact point (EIP) may also be easily determined for club heads having alternative score line configurations. For instance, the golf club head of FIG. 11 does not have a centered top score line. In such a situation, the two outermost score lines that have lengths within 5% of one another are then used as the top score line (TSL) and the bottom score line (BSL). The process for determining the location of the engineered impact point (EIP) on the face is then determined as outlined above. Further, some golf club heads have non-continuous score lines, such as that seen at the top of the club head face in FIG. 12. In this case, a line is extended across the break between the two top score line sections to create a continuous top score line (TSL). The newly created continuous top score line (TSL) is then bisected and used to locate the imaginary line (IL). Again, then the process for determining the location of the engineered impact point (EIP) on the face is determined as outlined above.


The engineered impact point (EIP) may also be easily determined in the rare case of a golf club head having an asymmetric score line pattern, or no score lines at all. In such embodiments the engineered impact point (EIP) shall be determined in accordance with the USGA “Procedure for Measuring the Flexibility of a Golf Clubhead,” Revision 2.0, Mar. 25, 2005, which is incorporated herein by reference. This USGA procedure identifies a process for determining the impact location on the face of a golf club that is to be tested, also referred therein as the face center. The USGA procedure utilizes a template that is placed on the face of the golf club to determine the face center. In these limited cases of asymmetric score line patterns, or no score lines at all, this USGA face center shall be the engineered impact point (EIP) that is referenced throughout this application.


The engineered impact point (EIP) on the face is an important reference to define other attributes of the present golf club head. The engineered impact point (EIP) is generally shown on the face with rotated crosshairs labeled EIP. The precise location of the engineered impact point (EIP) can be identified via the dimensions Xeip, Yeip, and Zeip, as illustrated in FIGS. 22-24. 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, except that Zeip is always a positive value regardless of whether it is in front of the origin point or behind the origin point.


One important dimension that utilizes the engineered impact point (EIP) is the center face progression (CFP), seen in FIGS. 8 and 14. The center face progression (CFP) is a single dimension measurement and is defined as the distance in the Z-direction from the shaft axis (SA) to the engineered impact point (EIP). A second dimension that utilizes the engineered impact point (EIP) is referred to as a club moment arm (CMA). The CMA is the two dimensional distance from the CG of the club head to the engineered impact point (EIP) on the face, as seen in FIG. 8. Thus, with reference to the coordinate system shown in FIG. 1, the club moment arm (CMA) includes a component in the Z-direction and a component in the Y-direction, but ignores any difference in the X-direction between the CG and the engineered impact point (EIP). Thus, the club moment arm (CMA) can be thought of in terms of an impact vertical plane passing through the engineered impact point (EIP) and extending in the Z-direction. First, one would translate the CG horizontally in the X-direction until it hits the impact vertical plane. Then, the club moment arm (CMA) would be the distance from the projection of the CG on the impact vertical plane to the engineered impact point (EIP). The club moment arm (CMA) has a significant impact on the launch angle and the spin of the golf ball upon impact.


Another important dimension in golf club design is the club head blade length (BL), seen in FIG. 13 and FIG. 14. The blade length (BL) is the distance from the origin to a point on the surface of the club head on the toe side that is furthest from the origin in the X-direction. The blade length (BL) is composed of two sections, namely the heel blade length section (Abl) and the toe blade length section (Bbl). The point of delineation between these two sections is the engineered impact point (EIP), or more appropriately, a vertical line, referred to as a face centerline (FC), extending through the engineered impact point (EIP), as seen in FIG. 13, when the golf club head is in the normal resting position, also referred to as the design position.


Further, several additional dimensions are helpful in understanding the location of the CG with respect to other points that are essential in golf club engineering. First, a CG angle (CGA) is the one dimensional angle between a line connecting the CG to the origin and an extension of the shaft axis (SA), as seen in FIG. 14. The CG angle (CGA) is measured solely in the X-Z plane and therefore does not account for the elevation change between the CG and the origin, which is why it is easiest understood in reference to the top plan view of FIG. 14.


Lastly, another important dimension in quantifying the present golf club only takes into consideration two dimensions and is referred to as the transfer distance (TD), seen in FIG. 17. The transfer distance (TD) is the horizontal distance from the CG to a vertical line extending from the origin; thus, the transfer distance (TD) ignores the height of the CG, or Ycg. Thus, using the Pythagorean Theorem from simple geometry, the transfer distance (TD) is the hypotenuse of a right triangle with a first leg being Xcg and the second leg being Zcg.


The transfer distance (TD) is significant in that is helps define another moment of inertia value that is significant to the present golf club. This new moment of inertia value is defined as the face closing moment of inertia, referred to as MOIfc, which is the horizontally translated (no change in Y-direction elevation) version of MOIy around a vertical axis that passes through the origin. MOIfc is calculated by adding MOIy to the product of the club head mass and the transfer distance (TD) squared. Thus,

MOIfc=MOIy+(mass*(TD)2)


The face closing moment (MOIfc) is important because is represents the resistance that a golfer feels during a swing when trying to bring the club face back to a square position for impact with the golf ball. In other words, as the golf swing returns the golf club head to its original position to impact the golf ball the face begins closing with the goal of being square at impact with the golf ball.


The presently disclosed hollow golf club incorporates stress reducing features unlike prior hollow type golf clubs. The hollow type golf club includes a shaft (200) having a proximal end (210) and a distal end (220); a grip (300) attached to the shaft proximal end (210); and a golf club head (100) attached at the shaft distal end (220), as seen in FIG. 21. The overall hollow type golf club has a club length of at least 36 inches and no more than 45 inches, as measure in accordance with USGA guidelines.


The golf club head (400) itself is a hollow structure that includes a face (500) positioned at a front portion (402) of the golf club head (400) where the golf club head (400) impacts a golf ball, a sole (700) positioned at a bottom portion of the golf club head (400), a crown (600) positioned at a top portion of the golf club head (400), and a skirt (800) positioned around a portion of a periphery of the golf club head (400) between the sole (700) and the crown (800). The face (500), sole (700), crown (600), and skirt (800) define an outer shell that further defines a head volume that is less than 300 cubic centimeters for the golf club head (400). Additionally, the golf club head (400) has a rear portion (404) opposite the face (500). The rear portion (404) includes the trailing edge of the golf club head (400), as is understood by one with skill in the art. The face (500) has a loft (L) of at least 12 degrees and no more than 30 degrees, and the face (500) includes an engineered impact point (EIP) as defined above. One skilled in the art will appreciate that the skirt (800) may be significant at some areas of the golf club head (400) and virtually nonexistent at other areas; particularly at the rear portion (404) of the golf club head (400) where it is not uncommon for it to appear that the crown (600) simply wraps around and becomes the sole (700).


The golf club head (100) includes a bore having a center that defines a shaft axis (SA) that intersects with a horizontal ground plane (GP) to define an origin point, as previously explained. The bore is located at a 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 opposite of the heel side (406). The presently disclosed golf club head (400) has a club head mass of less than 270 grams, which combined with the previously disclosed loft, club head volume, and club length establish that the presently disclosed golf club is directed to a hollow golf club such as a fairway wood, hybrid, or hollow iron.


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


With reference now to FIG. 24, in embodiments which incorporate both a crown located SRF (1100) and a sole located SRF (1300), a SRF connection plane (1500) passes through a portion of the crown located SRF (1100) and the sole located SRF (1300). To locate the SRF connection plane (1500) a vertical section is taken through the club head (400) in a front-to-rear direction, perpendicular to a vertical plane created by the shaft axis (SA); such a section is seen in FIG. 24. Then a crown SRF midpoint of the crown located SRF (1100) is determined at a location on a crown imaginary line following the natural curvature of the crown (600). The crown imaginary line is illustrated in FIG. 24 with a broken, or hidden, line connecting the CSRF leading edge (1120) to the CSRF trailing edge (1130), and the crown SRF midpoint is illustrated with an X. Similarly, a sole SRF midpoint of the sole located SRF (1300) is determined at a location on a sole imaginary line following the natural curvature of the sole (700). The sole imaginary line is illustrated in FIG. 24 with a broken, or hidden, line connecting the SSRF leading edge (1320) to the SSRF trailing edge (1330), and the sole SRF midpoint is illustrated with an X. Finally, the SRF connection plane (1500) is a plane in the heel-to-toe direction that passes through both the crown SRF midpoint and the sole SRF midpoint, as seen in FIG. 24. While the SRF connection plane (1500) illustrated in FIG. 24 is approximately vertical, the orientation of the SRF connection plane (1500) depends on the locations of the crown located SRF (1100) and the sole located SRF (1300) and may be angled toward the face, as seen in FIG. 26, or angled away from the face, as seen in FIG. 27.


The SRF connection plane (1500) is oriented at a connection plane angle (1510) from the vertical, seen in FIGS. 26 and 27, which aids in defining the location of the crown located SRF (1100) and the sole located SRF (1300). In one particular embodiment the crown located SRF (1100) and the sole located SRF (1300) are not located vertically directly above and below one another; rather, the connection plane angle (1510) is greater than zero and less than ninety percent of a loft (L) of the club head (400), as seen in FIG. 26. The sole located SRF (1300) could likewise be located in front of, i.e. toward the face (500), the crown located SRF (1100) and still satisfy the criteria of this embodiment; namely, that the connection plane angle (1510) is greater than zero and less than ninety percent of a loft of the club head (400).


In an alternative embodiment, seen in FIG. 27, the SRF connection plane (1500) is oriented at a connection plane angle (1510) from the vertical and the connection plane angle (1510) is at least ten percent greater than a loft (L) of the club head (400). The crown located SRF (1100) could likewise be located in front of, i.e. toward the face (500), the sole located SRF (1300) and still satisfy the criteria of this embodiment; namely, that the connection plane angle (1510) is at least ten percent greater than a loft (L) of the club head (400). In an even further embodiment the SRF connection plane (1500) is oriented at a connection plane angle (1510) from the vertical and the connection plane angle (1510) is at least fifty percent greater than a loft (L) of the club head (400), but less than one hundred percent greater than the loft (L). These three embodiments recognize a unique relationship between the crown located SRF (1100) and the sole located SRF (1300) such that they are not vertically aligned with one another, while also not merely offset in a manner matching the loft (L) of the club head (400).


With reference now to FIGS. 30 and 31, in the event that a crown located SRF (1100) or a sole located SRF (1300), or both, do not exist at the location of the CG section, labeled as section 24-24 in FIG. 22, then the crown located SRF (1100) located closest to the front-to-rear vertical plane passing through the CG is selected. For example, as seen in FIG. 30 the right crown located SRF (1100) is nearer to the front-to-rear vertical CG plane than the left crown located SRF (1100). In other words the illustrated distance “A” is smaller for the right crown located SRF (1100). Next, the face centerline (FC) is translated until it passes through both the CSRF leading edge (1120) and the CSRF trailing edge (1130), as illustrated by broken line “B”. Then, the midpoint of line “B” is found and labeled “C”. Finally, imaginary line “D” is created that is perpendicular to the “B” line.


The same process is repeated for the sole located SRF (1300), as seen in FIG. 31. It is simply a coincidence that both the crown located SRF (1100) and the sole located SRF (1300) located closest to the front-to-rear vertical CG plane are both on the heel side (406) of the golf club head (400). The same process applies even when the crown located SRF (1100) and the sole located SRF (1300) located closest to the front-to-rear vertical CG plane are on opposites sides of the golf club head (400). Now, still referring to FIG. 31, the process first involves identifying that the right sole located SRF (1300) is nearer to the front-to-rear vertical CG plane than the left sole located SRF (1300). In other words the illustrated distance “E” is smaller for the heel-side sole located SRF (1300). Next, the face centerline (FC) is translated until it passes through both the SSRF leading edge (1320) and the SSRF trailing edge (1330), as illustrated by broken line “F”. Then, the midpoint of line “F” is found and labeled “G”. Finally, imaginary line “H” is created that is perpendicular to the “F” line. The plane passing through both the imaginary line “D” and imaginary line “H” is the SRF connection plane (1500).


Next, referring back to FIG. 24, a CG-to-plane offset (1600) is defined as the shortest distance from the center of gravity (CG) to the SRF connection plane (1500), regardless of the location of the CG. In one particular embodiment the CG-to-plane offset (1600) is at least twenty-five percent less than the club moment arm (CMA) and the club moment arm (CMA) is less than 1.3 inches. The locations of the crown located SRF (1100) and the sole located SRF (1300) described herein, and the associated variables identifying the location, are selected to preferably reduce the stress in the face (500) when impacting a golf ball while accommodating temporary flexing and deformation of the crown located SRF (1100) and sole located SRF (1300) in a stable manner in relation to the CG location, and/or origin point, while maintaining the durability of the face (500), the crown (600), and the sole (700). Experimentation and modeling has shown that the crown located SRF (1100) and the sole located SRF (1300) increase the deflection of the face (500), while also reduce the peak stress on the face (500) at impact with a golf ball. This reduction in stress allows a substantially thinner face to be utilized, permitting the weight savings to be distributed elsewhere in the club head (400). Further, the increased deflection of the face (500) facilitates improvements in the coefficient of restitution (COR) of the club head (400), particularly for club heads having a volume of 300 cc or less.


In fact, further embodiments even more precisely identify the location of the crown located SRF (1100) and/or the sole located SRF (1300) to achieve these objectives. For instance, in one further embodiment the CG-to-plane offset (1600) is at least twenty-five percent of the club moment arm (CMA) and less than seventy-five percent of the club moment arm (CMA). In still a further embodiment, the CG-to-plane offset (1600) is at least forty percent of the club moment arm (CMA) and less than sixty percent of the club moment arm (CMA).


Alternatively, another embodiment relates the location of the crown located SRF (1100) and/or the sole located SRF (1300) to the difference between the maximum top edge height (TEH) and the minimum lower edge (LEH), referred to as the face height, rather than utilizing the CG-to-plane offset (1600) variable as previously discussed to accommodate embodiments in which a single SRF is present. As such, two additional variables are illustrated in FIG. 24, namely the CSRF leading edge offset (1122) and the SSRF leading edge offset (1322). The CSRF leading edge offset (1122) is the distance from any point along the CSRF leading edge (1120) directly forward, in the Zcg direction, to the point at the top edge (510) of the face (500). Thus, the CSRF leading edge offset (1122) may vary along the length of the CSRF leading edge (1120), or it may be constant if the curvature of the CSRF leading edge (1120) matches the curvature of the top edge (510) of the face (500). Nonetheless, there will always be a minimum CSRF leading edge offset (1122) at the point along the CSRF leading edge (1120) that is the closest to the corresponding point directly in front of it on the face top edge (510), and there will be a maximum CSRF leading edge offset (1122) at the point along the CSRF leading edge (1120) that is the farthest from the corresponding point directly in front of it on the face top edge (510). Likewise, the SSRF leading edge offset (1322) is the distance from any point along the SSRF leading edge (1320) directly forward, in the Zcg direction, to the point at the lower edge (520) of the face (500). Thus, the SSRF leading edge offset (1322) may vary along the length of the SSRF leading edge (1320), or it may be constant if the curvature of SSRF leading edge (1320) matches the curvature of the lower edge (520) of the face (500). Nonetheless, there will always be a minimum SSRF leading edge offset (1322) at the point along the SSRF leading edge (1320) that is the closest to the corresponding point directly in front of it on the face lower edge (520), and there will be a maximum SSRF leading edge offset (1322) at the point along the SSRF leading edge (1320) that is the farthest from the corresponding point directly in front of it on the face lower edge (520). Generally, the maximum CSRF leading edge offset (1122) and the maximum SSRF leading edge offset (1322) will be less than seventy-five percent of the face height. For the purposes of this application and ease of definition, the face top edge (510) is the series of points along the top of the face (500) at which the vertical face roll becomes less than one inch, and similarly the face lower edge (520) is the series of points along the bottom of the face (500) at which the vertical face roll becomes less than one inch.


In this particular embodiment, the minimum CSRF leading edge offset (1122) is less than the face height, while the minimum SSRF leading edge offset (1322) is at least two percent of the face height. In an even further embodiment, the maximum CSRF leading edge offset (1122) is also less than the face height. Yet another embodiment incorporates a minimum CSRF leading edge offset (1122) that is at least ten percent of the face height, and the minimum CSRF width (1140) is at least fifty percent of the minimum CSRF leading edge offset (1122). A still further embodiment more narrowly defines the minimum CSRF leading edge offset (1122) as being at least twenty percent of the face height.


Likewise, many embodiments are directed to advantageous relationships of the sole located SRF (1300). For instance, in one embodiment, the minimum SSRF leading edge offset (1322) is at least ten percent of the face height, and the minimum SSRF width (1340) is at least fifty percent of the minimum SSRF leading edge offset (1322). Even further, another embodiment more narrowly defines the minimum SSRF leading edge offset (1322) as being at least twenty percent of the face height.


Still further building upon the relationships among the CSRF leading edge offset (1122), the SSRF leading edge offset (1322), and the face height, one embodiment further includes an engineered impact point (EIP) having a Yeip coordinate such that the difference between Yeip and Ycg is less than 0.5 inches and greater than −0.5 inches; a Xeip coordinate such that the difference between Xeip and Xcg is less than 0.5 inches and greater than −0.5 inches; and a Zeip coordinate such that the total of Zeip and Zcg is less than 2.0 inches. These relationships among the location of the engineered impact point (EIP) and the location of the center of gravity (CG) in combination with the leading edge locations of the crown located SRF (1100) and/or the sole located SRF (1300) promote stability at impact, while accommodating desirable deflection of the SRFs (1100, 1300) and the face (500), while also maintaining the durability of the club head (400) and reducing the peak stress experienced in the face (500).


While the location of the crown located SRF (1100) and/or the sole located SRF (1300) is important in achieving these objectives, the size of the crown located SRF (1100) and the sole located SRF (1300) also plays a role. In one particular long blade length embodiment directed to fairway wood type golf clubs and hybrid type golf clubs, illustrated in FIGS. 42 and 43, the golf club head (400) has a blade length (BL) of at least 3.0 inches with a heel blade length section (Abl) of at least 0.8 inches. In this embodiment, preferable results are obtained when the CSRF length (1110) is at least as great as the heel blade length section (Abl) and the maximum CSRF depth (1150) is at least ten percent of the Ycg distance, thereby permitting adequate compression and/or flexing of the crown located SRF (1100) to significantly reduce the stress on the face (500) at impact. Similarly, in some SSRF embodiments, preferable results are obtained when the SSRF length (1310) is at least as great as the heel blade length section (Abl) and the maximum SSRF depth (1350) is at least ten percent of the Ycg distance, thereby permitting adequate compression and/or flexing of the sole located SRF (1300) to significantly reduce the stress on the face (500) at impact. It should be noted at this point that the cross-sectional profile of the crown located SRF (1100) and the sole mounted SRF (1300) may include any number of shapes including, but not limited to, a box-shape, as seen in FIG. 24, a smooth U-shape, as seen in FIG. 28, and a V-shape, as seen in FIG. 29. Further, the crown located SRF (1100) and the sole located SRF (1300) may include reinforcement areas as seen in FIGS. 40 and 41 to further selectively control the deformation of the SRFs (1100, 1300). Additionally, the CSRF length (1110) and the SSRF length (1310) are measured in the same direction as Xcg rather than along the curvature of the SRFs (1100, 1300), if curved.


The crown located SRF (1100) has a CSRF wall thickness (1160) and sole located SRF (1300) has a SSRF wall thickness (1360), as seen in FIG. 25. In most embodiments the CSRF wall thickness (1160) and the SSRF wall thickness (1360) will be at least 0.010 inches and no more than 0.150 inches. In particular embodiment has found that having the CSRF wall thickness (1160) and the SSRF wall thickness (1360) in the range of ten percent to sixty percent of the face thickness (530) achieves the required durability while still providing desired stress reduction in the face (500) and deflection of the face (500). Further, this range facilitates the objectives while not have a dilutive effect, nor overly increasing the weight distribution of the club head (400) in the vicinity of the SRFs (1100, 1300).


Further, the terms maximum CSRF depth (1150) and maximum SSRF depth (1350) are used because the depth of the crown located SRF (1100) and the depth of the sole located SRF (1300) need not be constant; in fact, they are likely to vary, as seen in FIGS. 32-35. Additionally, the end walls of the crown located SRF (1100) and the sole located SRF (1300) need not be distinct, as seen on the right and left side of the SRFs (1100, 1300) seen in FIG. 35, but may transition from the maximum depth back to the natural contour of the crown (600) or sole (700). The transition need not be smooth, but rather may be stepwise, compound, or any other geometry. In fact, the presence or absence of end walls is not necessary in determining the bounds of the claimed golf club. Nonetheless, a criteria needs to be established for identifying the location of the CSRF toe-most point (1112), the CSRF heel-most point (1116), the SSRF toe-most point (1312), and the SSRF heel-most point (1316); thus, when not identifiable via distinct end walls, these points occur where a deviation from the natural curvature of the crown (600) or sole (700) is at least ten percent of the maximum CSRF depth (1150) or maximum SSRF depth (1350). In most embodiments a maximum CSRF depth (1150) and a maximum SSRF depth (1350) of at least 0.100 inches and no more than 0.500 inches is preferred.


The CSRF leading edge (1120) may be straight or may include a CSRF leading edge radius of curvature (1124), as seen in FIG. 36. Likewise, the SSRF leading edge (1320) may be straight or may include a SSRF leading edge radius of curvature (1324), as seen in FIG. 37. One particular embodiment incorporates both a curved CSRF leading edge (1120) and a curved SSRF leading edge (1320) wherein both the CSRF leading edge radius of curvature (1124) and the SSRF leading edge radius of curvature (1324) are within forty percent of the curvature of the bulge of the face (500). In an even further embodiment both the CSRF leading edge radius of curvature (1124) and the SSRF leading edge radius of curvature (1324) are within twenty percent of the curvature of the bulge of the face (500). These curvatures further aid in the controlled deflection of the face (500).


One particular embodiment, illustrated in FIGS. 32-35, has a CSRF depth (1150) that is less at the face centerline (FC) than at a point on the toe side (408) of the face centerline (FC) and at a point on the heel side (406) of the face centerline (FC), thereby increasing the potential deflection of the face (500) at the heel side (406) and the toe side (408), where the COR is generally lower than the USGA permitted limit. In another embodiment, the crown located SRF (1100) and/or the sole located SRF (1300) have reduced depth regions, namely a CSRF reduced depth region (1152) and a SSRF reduced depth region (1352), as seen in FIG. 35. Each reduced depth region is characterized as a continuous region having a depth that is at least twenty percent less than the maximum depth for the particular SRF (1100, 1300). The CSRF reduced depth region (1152) has a CSRF reduced depth length (1154) and the SSRF reduced depth region (1352) has a SSRF reduced depth length (1354). In one particular embodiment, each reduced depth length (1154, 1354) is at least fifty percent of the heel blade length section (Abl). A further embodiment has the CSRF reduced depth region (1152) and the SSRF reduced depth region (1352) approximately centered about the face centerline (FC), as seen in FIG. 35. Yet another embodiment incorporates a design wherein the CSRF reduced depth length (1154) is at least thirty percent of the CSRF length (1110), and/or the SSRF reduced depth length (1354) is at least thirty percent of the SSRF length (1310). In addition to aiding in achieving the objectives set out above, the reduced depth regions (1152, 1352) may improve the life of the SRFs (1100, 1300) and reduce the likelihood of premature failure, while increasing the COR at desirable locations on the face (500).


As seen in FIG. 25, the crown located SRF (1100) has a CSRF cross-sectional area (1170) and the sole located SRF (1300) has a SSRF cross-sectional area (1370). The cross-sectional areas are measured in cross-sections that run from the front portion (402) to the rear portion (404) of the club head (400) in a vertical plane. Just as the cross-sectional profiles (1190, 1390) of FIGS. 28 and 29 may change throughout the CSRF length (1110) and the SSRF length (1310), the CSRF cross-sectional area (1170) and/or the SSRF cross-sectional area (1370) may also vary along the lengths (1110, 1310). In fact, in one particular embodiment, the CSRF cross-sectional area (1170) is less at the face centerline (FC) than at a point on the toe side (408) of the face centerline (FC) and a point on the heel side (406) of the face centerline (FC). Similarly, in another embodiment, the SSRF cross-sectional area (1370) is less at the face centerline than at a point on the toe side (408) of the face centerline (FC) and a point on the heel side (406) of the face centerline (FC); and yet a third embodiment incorporates both of the prior two embodiments related to the CSRF cross-sectional area (1170) and the SSRF cross-sectional area (1370). In one particular embodiment, the CSRF cross-sectional area (1170) and/or the SSRF cross-sectional area (1370) fall within the range of 0.005 square inches to 0.375 square inches. Additionally, the crown located SRF (1100) has a CSRF volume and the sole located SRF (1300) has a SSRF volume. In one embodiment the combined CSRF volume and SSRF volume is at least 0.5 percent of the club head volume and less than 10 percent of the club head volume, as this range facilitates the objectives while not have a dilutive effect, nor overly increasing the weight distribution of the club head (400) in the vicinity of the SRFs (1100, 1300). In yet another embodiment directed to single SRF variations, the individual volume of the CSRF volume or the SSRF volume is preferably at least 1 percent of the club head volume and less than 5 percent of the club head volume to facilitate the objectives while not have a dilutive effect, nor overly increasing the weight distribution of the club head (400) in the vicinity of the SRFs (1100, 1300). The volumes discussed above are not meant to limit the SRFs (1100, 1300) to being hollow channels, for instance the volumes discussed will still exist even if the SRFs (1100, 1300) are subsequently filled with a secondary material, as seen in FIG. 51, or covered, such that the volume is not visible to a golfer. The secondary material should be elastic, have a compressive strength less than half of the compressive strength of the outer shell, and a density less than 3 g/cm3.


Now, in another separate embodiment seen in FIGS. 36 and 37, a CSRF origin offset (1118) is defined as the distance from the origin point to the CSRF heel-most point (1116) in the same direction as the Xcg distance such that the CSRF origin offset (1118) is a positive value when the CSRF heel-most point (1116) is located toward the toe side (408) of the golf club head (400) from the origin point, and the CSRF origin offset (1118) is a negative value when the CSRF heel-most point (1116) is located toward the heel side (406) of the golf club head (400) from the origin point. Similarly, in this embodiment, a SSRF origin offset (1318) is defined as the distance from the origin point to the SSRF heel-most point (1316) in the same direction as the Xcg distance such that the SSRF origin offset (1318) is a positive value when the SSRF heel-most point (1316) is located toward the toe side (408) of the golf club head (400) from the origin point, and the SSRF origin offset (1318) is a negative value when the SSRF heel-most point (1316) is located toward the heel side (406) of the golf club head (400) from the origin point.


In one particular embodiment, seen in FIG. 37, the SSRF origin offset (1318) is a positive value, meaning that the SSRF heel-most point (1316) stops short of the origin point. Further, yet another separate embodiment is created by combining the embodiment illustrated in FIG. 36 wherein the CSRF origin offset (1118) is a negative value, in other words the CSRF heel-most point (1116) extends past the origin point, and the magnitude of the CSRF origin offset (1118) is at least five percent of the heel blade length section (Abl). However, an alternative embodiment incorporates a CSRF heel-most point (1116) that does not extend past the origin point and therefore the CSRF origin offset (1118) is a positive value with a magnitude of at least five percent of the heel blade length section (Abl). In these particular embodiments, locating the CSRF heel-most point (1116) and the SSRF heel-most point (1316) such that they are no closer to the origin point than five percent of the heel blade length section (Abl) is desirable in achieving many of the objectives discussed herein over a wide range of ball impact locations.


Still further embodiments incorporate specific ranges of locations of the CSRF toe-most point (1112) and the SSRF toe-most point (1312) by defining a CSRF toe offset (1114) and a SSRF toe offset (1314), as seen in FIGS. 36 and 37. The CSRF toe offset (1114) is the distance measured in the same direction as the Xcg distance from the CSRF toe-most point (1112) to the most distant point on the toe side (408) of golf club head (400) in this direction, and likewise the SSRF toe offset (1314) is the distance measured in the same direction as the Xcg distance from the SSRF toe-most point (1312) to the most distant point on the toe side (408) of golf club head (400) in this direction. One particular embodiment found to produce preferred face stress distribution and compression and flexing of the crown located SRF (1100) and the sole located SRF (1300) incorporates a CSRF toe offset (1114) that is at least fifty percent of the heel blade length section (Abl) and a SSRF toe offset (1314) that is at least fifty percent of the heel blade length section (Abl). In yet a further embodiment the CSRF toe offset (1114) and the SSRF toe offset (1314) are each at least fifty percent of a golf ball diameter; thus, the CSRF toe offset (1114) and the SSRF toe offset (1314) are each at 0.84 inches. These embodiments also minimally affect the integrity of the club head (400) as a whole, thereby ensuring the desired durability, particularly at the heel side (406) and the toe side (408) while still allowing for improved face deflection during off center impacts.


Even more embodiments now turn the focus to the size of the crown located SRF (1100) and the sole located SRF (1300). One such embodiment has a maximum CSRF width (1140) that is at least ten percent of the Zcg distance, and the maximum SSRF width (1340) is at least ten percent of the Zcg distance, further contributing to increased stability of the club head (400) at impact. Still further embodiments increase the maximum CSRF width (1140) and the maximum SSRF width (1340) such that they are each at least forty percent of the Zcg distance, thereby promoting deflection and selectively controlling the peak stresses seen on the face (500) at impact. An alternative embodiment relates the maximum CSRF depth (1150) and the maximum SSRF depth (1350) to the face height rather than the Zcg distance as discussed above. For instance, yet another embodiment incorporates a maximum CSRF depth (1150) that is at least five percent of the face height, and a maximum SSRF depth (1350) that is at least five percent of the face height. An even further embodiment incorporates a maximum CSRF depth (1150) that is at least twenty percent of the face height, and a maximum SSRF depth (1350) that is at least twenty percent of the face height, again, promoting deflection and selectively controlling the peak stresses seen on the face (500) at impact. In most embodiments a maximum CSRF width (1140) and a maximum SSRF width (1340) of at least 0.0.050 inches and no more than 0.750 inches is preferred.


Additional embodiments focus on the location of the crown located SRF (1100) and the sole located SRF (1300) with respect to a vertical plane defined by the shaft axis (SA) and the Xcg direction. One such embodiment has recognized improved stability and lower peak face stress when the crown located SRF (1100) and/or the sole located SRF (1300) are located behind the shaft axis plane. Further embodiments additionally define this relationship. In one such embodiment, the CSRF leading edge (1120) is located behind the shaft axis plane a distance that is at least twenty percent of the Zcg distance. Yet anther embodiment focuses on the location of the sole located SRF (1300) such that the SSRF leading edge (1320) is located behind the shaft axis plane a distance that is at least ten percent of the Zcg distance. An even further embodiment focusing on the crown located SRF (1100) incorporates a CSRF leading edge (1120) that is located behind the shaft axis plane a distance that is at least seventy-five percent of the Zcg distance. A similar embodiment directed to the sole located SRF (1300) has a SSRF leading edge (1320) that is located behind the shaft axis plane a distance that is at least seventy-five percent of the Zcg distance. Similarly, the locations of the CSRF leading edge (1120) and SSRF leading edge (1320) behind the shaft axis plane may also be related to the face height instead of the Zcg distance discussed above. For instance, in one embodiment, the CSRF leading edge (1120) is located a distance behind the shaft axis plane that is at least ten percent of the face height. A further embodiment focuses on the location of the sole located SRF (1300) such that the SSRF leading edge (1320) is located behind the shaft axis plane a distance that is at least five percent of the Zcg distance. An even further embodiment focusing on both the crown located SRF (1100) and the sole located SRF (1300) incorporates a CSRF leading edge (1120) that is located behind the shaft axis plane a distance that is at least fifty percent of the face height, and a SSRF leading edge (1320) that is located behind the shaft axis plane a distance that is at least fifty percent of the face height.


The club head (400) is not limited to a single crown located SRF (1100) and/or a single sole located SRF (1300). In fact, many embodiments incorporating multiple crown located SRFs (1100) and/or multiple sole located SRFs (1300) are illustrated in FIGS. 30, 31, and 39, showing that the multiple SRFs (1100, 1300) may be positioned beside one another in a heel-toe relationship, or may be positioned behind one another in a front-rear orientation. As such, one particular embodiment includes at least two crown located SRFs (1100) positioned on opposite sides of the engineered impact point (EIP) when viewed in a top plan view, as seen in FIG. 31, thereby further selectively increasing the COR and improving the peak stress on the face (500). Traditionally, the COR of the face (500) gets smaller as the measurement point is moved further away from the engineered impact point (EIP); and thus golfers that hit the ball toward the heel side (406) or toe side (408) of the a golf club head do not benefit from a high COR. As such, positioning of the two crown located SRFs (1100) seen in FIG. 30 facilitates additional face deflection for shots struck toward the heel side (406) or toe side (408) of the golf club head (400). Another embodiment, as seen in FIG. 31, incorporates the same principles just discussed into multiple sole located SRFs (1300).


The impact of a club head (400) and a golf ball may be simulated in many ways, both experimentally and via computer modeling. First, an experimental process will be explained because it is easy to apply to any golf club head and is free of subjective considerations. The process involves applying a force to the face (500) distributed over a 0.6 inch diameter centered about the engineered impact point (EIP). A force of 4000 lbf is representative of an approximately 100 mph impact between a club head (400) and a golf ball, and more importantly it is an easy force to apply to the face and reliably reproduce. The club head boundary condition consists of fixing the rear portion (404) of the club head (400) during application of the force. In other words, a club head (400) can easily be secured to a fixture within a material testing machine and the force applied. Generally, the rear portion (404) experiences almost no load during an actual impact with a golf ball, particularly as the “front-to-back” dimension (FB) increases. The peak deflection of the face (500) under the force is easily measured and is very close to the peak deflection seen during an actual impact, and the peak deflection has a linear correlation to the COR. A strain gauge applied to the face (500) can measure the actual stress. This experimental process takes only minutes to perform and a variety of forces may be applied to any club head (400); further, computer modeling of a distinct load applied over a certain area of a club face (500) is much quicker to simulate than an actual dynamic impact.


A graph of displacement versus load is illustrated in FIG. 44 for a club head having no stress reducing feature (1000), a club head (400) having only a sole located SRF (1300), and a club head (400) having both a crown located SRF (1100) and a sole located SRF (1300), at the following loads of 1000 lbf, 2000 lbf, 3000 lbf, and 4000 lbf, all of which are distributed over a 0.6 inch diameter area centered on the engineered impact point (EIP). The face thickness (530) was held a constant 0.090 inches for each of the three club heads. Incorporation of a crown located SRF (1100) and a sole located SRF (1300) as described herein increases face deflection by over 11% at the 4000 lbf load level, from a value of 0.027 inches to 0.030 inches. In one particular embodiment, the increased deflection resulted in an increase in the characteristic time (CT) of the club head from 187 microseconds to 248 microseconds. A graph of peak face stress versus load is illustrated in FIG. 45 for the same three variations just discussed with respect to FIG. 44. FIG. 45 nicely illustrates that incorporation of a crown located SRF (1100) and a sole located SRF (1300) as described herein reduces the peak face stress by almost 25% at the 4000 lbf load level, from a value of 170.4 ksi to 128.1 ksi. The stress reducing feature (1000) permits the use of a very thin face (500) without compromising the integrity of the club head (400). In fact, the face thickness (530) may vary from 0.050 inches, up to 0.120 inches.


Combining the information seen in FIGS. 44 and 45, a new ratio may be developed; namely, a stress-to-deflection ratio of the peak stress on the face to the displacement at a given load, as seen in FIG. 46. In one embodiment, the stress-to-deflection ratio is less than 5000 ksi per inch of deflection, wherein the approximate impact force is applied to the face (500) over a 0.6 inch diameter, centered on the engineered impact point (EIP), and the approximate impact force is at least 1000 lbf and no more than 4000 lbf, the club head volume is less than 300 cc, and the face thickness (530) is less than 0.120 inches. In yet a further embodiment, the face thickness (530) is less than 0.100 inches and the stress-to-deflection ratio is less than 4500 ksi per inch of deflection; while an even further embodiment has a stress-to-deflection ratio that is less than 4300 ksi per inch of deflection.


In addition to the unique stress-to-deflection ratios just discussed, one embodiment of the present invention further includes a face (500) having a characteristic time of at least 220 microseconds and the head volume is less than 200 cubic centimeters. Even further, another embodiment goes even further and incorporates a face (500) having a characteristic time of at least 240 microseconds, a head volume that is less than 170 cubic centimeters, a face height between the maximum top edge height (TEH) and the minimum lower edge (LEH) that is less than 1.50 inches, and a vertical roll radius between 7 inches and 13 inches, which further increases the difficulty in obtaining such a high characteristic time, small face height, and small volume golf club head.


Those skilled in the art know that the characteristic time, often referred to as the CT, value of a golf club head is limited by the equipment rules of the United States Golf Association (USGA). The rules state that the characteristic time of a club head shall not be greater than 239 microseconds, with a maximum test tolerance of 18 microseconds. Thus, it is common for golf clubs to be designed with the goal of a 239 microsecond CT, knowing that due to manufacturing variability that some of the heads will have a CT value higher than 239 microseconds, and some will be lower. However, it is critical that the CT value does not exceed 257 microseconds or the club will not conform to the USGA rules. The USGA publication “Procedure for Measuring the Flexibility of a Golf Clubhead,” Revision 2.0, Mar. 25, 2005, is the current standard that sets forth the procedure for measuring the characteristic time.


With reference now to FIGS. 47-49, another embodiment of the crown located SRF (1100) may include a CSRF aperture (1200) recessed from the crown (600) and extending through the outer shell. As seen in FIG. 49, the CSRF aperture (1200) is located at a CSRF aperture depth (1250) measured vertically from the top edge height (TEH) toward the center of gravity (CG), keeping in mind that the top edge height (TEH) varies across the face (500) from the heel side (406) to the toe side (408). Therefore, as illustrated in FIG. 49, to determine the CSRF aperture depth (1250) one must first take a section in the front-to-rear direction of the club head (400), which establishes the top edge height (TEH) at this particular location on the face (500) that is then used to determine the CSRF aperture depth (1250) at this particular location along the CSRF aperture (1200). For instance, as seen in FIG. 47, the section that is illustrated in FIG. 49 is taken through the center of gravity (CG) location, which is just one of an infinite number of sections that can be taken between the origin and the toewardmost point on the club head (400). Just slightly to the left of the center of gravity (CG) in FIG. 47 is a line representing the face center (FC), if a section such as that of FIG. 49 were taken along the face center (FC) it would illustrate that the top edge height (TEH) is generally the greatest at this point.


At least a portion of the CSRF aperture depth (1250) is greater than zero. This means that at some point along the CSRF aperture (1200), the CSRF aperture (1200) will be located below the elevation of the top of the face (400) directly in front of the point at issue, as illustrated in FIG. 49. In one particular embodiment the CSRF aperture (1200) has a maximum CSRF aperture depth (1250) that is at least ten percent of the Ycg distance. An even further embodiment incorporates a CSRF aperture (1200) that has a maximum CSRF aperture depth (1250) that is at least fifteen percent of the Ycg distance. Incorporation of a CSRF aperture depth (1250) that is greater than zero, and in some embodiments greater than a certain percentage of the Ycg distance, preferably reduces the stress in the face (500) when impacting a golf ball while accommodating temporary flexing and deformation of the crown located SRF (1100) in a stable manner in relation to the CG location, engineered impact point (EIP), and/or outer shell, while maintaining the durability of the face (500) and the crown (600).


The CSRF aperture (1200) has a CSRF aperture width (1240) separating a CSRF leading edge (1220) from a CSRF aperture trailing edge (1230), again measured in a front-to-rear direction as seen in FIG. 49. In one embodiment the CSRF aperture (1200) has a maximum CSRF aperture width (1240) that is at least twenty-five percent of the maximum CSRF aperture depth (1250) to allow preferred flexing and deformation while maintaining durability and stability upon repeated impacts with a golf ball. An even further variation achieves these goals by maintaining a maximum CSRF aperture width (1240) that is less than maximum CSRF aperture depth (1250). In yet another embodiment the CSRF aperture (1200) also has a maximum CSRF aperture width (1240) that is at least fifty percent of a minimum face thickness (530), while optionally also being less than the maximum face thickness (530).


In furtherance of these desirable properties, the CSRF aperture (1200) has a CSRF aperture length (1210) between a CSRF aperture toe-most point (1212) and a CSRF aperture heel-most point (1216) that is at least fifty percent of the Xcg distance. In yet another embodiment the CSRF aperture length (1210) is at least as great as the heel blade length section (Abl), or even further in another embodiment in which the CSRF aperture length (1210) is also at least fifty percent of the blade length (BL).


Referring again to FIG. 49, the CSRF aperture leading edge (1220) has a CSRF aperture leading edge offset (1222). In one embodiment preferred flexing and deformation occur, while maintaining durability, when the minimum CSRF aperture leading edge offset (1222) is at least ten percent of the difference between the maximum top edge height (TEH) and the minimum lower edge height (LEH). Even further, another embodiment has found preferred characteristics when the minimum CSRF aperture leading edge offset (1222) at least twenty percent of the difference between the maximum top edge height (TEH) and the minimum lower edge height (LEH), and optionally when the maximum CSRF aperture leading edge offset (1222) less than seventy-five percent of the difference between the maximum top edge height (TEH) and the minimum lower edge height (LEH).


Again with reference now to FIGS. 47-49 but now turning our attention to the sole located SRF (1300), an embodiment of the sole located SRF (1300) may include a SSRF aperture (1400) recessed from the sole (700) and extending through the outer shell. As seen in FIG. 49, the SSRF aperture (1400) is located at a SSRF aperture depth (1450) measured vertically from the leading edge height (LEH) toward the center of gravity (CG), keeping in mind that the leading edge height (LEH) varies across the face (500) from the heel side (406) to the toe side (408). Therefore, as illustrated in FIG. 49, to determine the SSRF aperture depth (1450) one must first take a section in the front-to-rear direction of the club head (400), which establishes the leading edge height (LEH) at this particular location on the face (500) that is then used to determine the SSRF aperture depth (1450) at this particular location along the SSRF aperture (1400). For instance, as seen in FIG. 47, the section that is illustrated in FIG. 49 is taken through the center of gravity (CG) location, which is just one of an infinite number of sections that can be taken between the origin and the toewardmost point on the club head (400). Just slightly to the left of the center of gravity (CG) in FIG. 47 is a line representing the face center (FC), if a section such as that of FIG. 49 were taken along the face center (FC) it would illustrate that the leading edge height (LEH) is generally the least at this point.


At least a portion of the SSRF aperture depth (1450) is greater than zero. This means that at some point along the SSRF aperture (1400), the SSRF aperture (1400) will be located above the elevation of the bottom of the face (400) directly in front of the point at issue, as illustrated in FIG. 49. In one particular embodiment the SSRF aperture (1400) has a maximum SSRF aperture depth (1450) that is at least ten percent of the Ycg distance. An even further embodiment incorporates a SSRF aperture (1400) that has a maximum SSRF aperture depth (1450) that is at least fifteen percent of the Ycg distance. Incorporation of a SSRF aperture depth (1450) that is greater than zero, and in some embodiments greater than a certain percentage of the Ycg distance, preferably reduces the stress in the face (500) when impacting a golf ball while accommodating temporary flexing and deformation of the sole located SRF (1300) in a stable manner in relation to the CG location, engineered impact point (EIP), and/or outer shell, while maintaining the durability of the face (500) and the sole (700).


The SSRF aperture (1400) has a SSRF aperture width (4240) separating a SSRF leading edge (1420) from a SSRF aperture trailing edge (1430), again measured in a front-to-rear direction as seen in FIG. 49. In one embodiment the SSRF aperture (1400) has a maximum SSRF aperture width (1440) that is at least twenty-five percent of the maximum SSRF aperture depth (1450) to allow preferred flexing and deformation while maintaining durability and stability upon repeated impacts with a golf ball. An even further variation achieves these goals by maintaining a maximum SSRF aperture width (1440) that is less than maximum SSRF aperture depth (1450). In yet another embodiment the SSRF aperture (1400) also has a maximum SSRF aperture width (1440) that is at least fifty percent of a minimum face thickness (530), while optionally also being less than the maximum face thickness (530).


In furtherance of these desirable properties, the SSRF aperture (1400) has a SSRF aperture length (1410) between a SSRF aperture toe-most point (1412) and a SSRF aperture heel-most point (1416) that is at least fifty percent of the Xcg distance. In yet another embodiment the SSRF aperture length (1410) is at least as great as the heel blade length section (Abl), or even further in another embodiment in which the SSRF aperture length (1410) is also at least fifty percent of the blade length (BL).


Referring again to FIG. 49, the SSRF aperture leading edge (1420) has a SSRF aperture leading edge offset (1422). In one embodiment preferred flexing and deformation occur, while maintaining durability, when the minimum SSRF aperture leading edge offset (1422) is at least ten percent of the difference between the maximum top edge height (TEH) and the minimum lower edge height (LEH). Even further, another embodiment has found preferred characteristics when the minimum SSRF aperture leading edge offset (1422) at least twenty percent of the difference between the maximum top edge height (TEH) and the minimum lower edge height (LEH), and optionally when the maximum SSRF aperture leading edge offset (1422) less than seventy-five percent of the difference between the maximum top edge height (TEH) and the minimum lower edge height (LEH).


As previously discussed, the SRFs (1100, 1300) may be subsequently filled with a secondary material, as seen in FIG. 51, or covered, such that the volume is not visible to a golfer, similarly, the apertures (1200, 1400) may be covered or filled so that they are not noticeable to a user, and so that material and moisture is not unintentionally introduced into the interior of the club head. In other words, one need not be able to view the inside of the club head through the aperture (1200, 1400) in order for the aperture (1200, 1400) to exist. The apertures (1200, 1400) may be covered by a badge extending over the apertures (1200, 1400), or a portion of such cover may extend into the apertures (1200, 1400), as seen in FIG. 52. If a portion of the cover extends into the aperture (1200, 1400) then that portion should be compressible and have a compressive strength that is less than fifty percent of the compressive strength of the outer shell. A badge extending over the aperture (1200, 1400) may be attached to the outer shell on only one side of the aperture (1200, 1400), or on both sides of the aperture (1200, 1400) if the badge is not rigid or utilizes non-rigid connection methods to secure the badge to the outer shell.


The size, location, and configuration of the CSRF aperture (1200) and the SSRF aperture (1400) are selected to preferably reduce the stress in the face (500) when impacting a golf ball while accommodating temporary flexing and deformation of the crown located SRF (1100) and sole located SRF (1300) in a stable manner in relation to the CG location, and/or origin point, while maintaining the durability of the face (500), the crown (600), and the sole (700). While the generally discussed apertures (1200, 1400) of FIGS. 47-49 are illustrated in the bottom wall of the SRF's (1100, 1300), the apertures (1200, 1400) may be located at other locations in the SRF's (1100, 1300) including the front wall as seen in the CSRF aperture (1100) of FIG. 50 and both the CSRF aperture (1200) and SSRF aperture (1400) of FIG. 53, as well as the rear wall as seen in the SSRF aperture (1400) of FIG. 50.


As previously explained, the golf club head (100) has a blade length (BL) that is measured horizontally from the origin point toward the toe side of the golf club head a distance that is parallel to the face and the ground plane (GP) to the most distant point on the golf club head in this direction. In one particular embodiment, the golf club head (100) has a blade length (BL) of at least 3.1 inches, a heel blade length section (Abl) is at least 1.1 inches, and a club moment arm (CMA) of less than 1.3 inches, thereby producing a long blade length golf club having reduced face stress, and improved characteristic time qualities, while not being burdened by the deleterious effects of having a large club moment arm (CMA), as is common in oversized fairway woods. The club moment arm (CMA) has a significant impact on the ball flight of off-center hits. Importantly, a shorter club moment arm (CMA) produces less variation between shots hit at the engineered impact point (EIP) and off-center hits. Thus, a golf ball struck near the heel or toe of the present invention will have launch conditions more similar to a perfectly struck shot. Conversely, a golf ball struck near the heel or toe of an oversized fairway wood with a large club moment arm (CMA) would have significantly different launch conditions than a ball struck at the engineered impact point (EIP) of the same oversized fairway wood. Generally, larger club moment arm (CMA) golf clubs impart higher spin rates on the golf ball when perfectly struck in the engineered impact point (EIP) and produce larger spin rate variations in off-center hits. Therefore, yet another embodiment incorporate a club moment arm (CMA) that is less than 1.1 inches resulting in a golf club with more efficient launch conditions including a lower ball spin rate per degree of launch angle, thus producing a longer ball flight.


Conventional wisdom regarding increasing the Zcg value to obtain club head performance has proved to not recognize that it is the club moment arm (CMA) that plays a much more significant role in golf club performance and ball flight. Controlling the club moments arm (CMA), along with the long blade length (BL), long heel blade length section (Abl), while improving the club head's ability to distribute the stresses of impact and thereby improving the characteristic time across the face, particularly off-center impacts, yields launch conditions that vary significantly less between perfect impacts and off-center impacts than has been seen in the past. In another embodiment, the ratio of the golf club head front-to-back dimension (FB) to the blade length (BL) is less than 0.925, as seen in FIGS. 6 and 13. In this embodiment, the limiting of the front-to-back dimension (FB) of the club head (100) in relation to the blade length (BL) improves the playability of the club, yet still achieves the desired high improvements in characteristic time, face deflection at the heel and toe sides, and reduced club moment arm (CMA). The reduced front-to-back dimension (FB), and associated reduced Zcg, of the present invention also significantly reduces dynamic lofting of the golf club head. Increasing the blade length (BL) of a fairway wood, while decreasing the front-to-back dimension (FB) and incorporating the previously discussed characteristics with respect to the stress reducing feature (1000), minimum heel blade length section (Abl), and maximum club moment arm (CMA), produces a golf club head that has improved playability that would not be expected by one practicing conventional design principles. In yet a further embodiment a unique ratio of the heel blade length section (Abl) to the golf club head front-to-back dimension (FB) has been identified and is at least 0.32. Yet another embodiment incorporates a ratio of the club moment arm (CMA) to the heel blade length section (Abl). In this embodiment the ratio of club moment arm (CMA) to the heel blade length section (Abl) is less than 0.9. Still a further embodiment uniquely characterizes the present fairway wood golf club head with a ratio of the heel blade length section (Abl) to the blade length (BL) that is at least 0.33. A further embodiment has recognized highly beneficial club head performance regarding launch conditions when the transfer distance (TD) is at least 10 percent greater than the club moment arm (CMA). Even further, a particularly effective range for fairway woods has been found to be when the transfer distance (TD) is 10 percent to 40 percent greater than the club moment arm (CMA). This range ensures a high face closing moment (MOIfc) such that bringing club head square at impact feels natural and takes advantage of the beneficial impact characteristics associated with the short club moment arm (CMA) and CG location.


Referring now to FIG. 10, in one embodiment it was found that a particular relationship between the top edge height (TEH) and the Ycg distance further promotes desirable performance and feel. In this embodiment a preferred ratio of the Ycg distance to the top edge height (TEH) is less than 0.40; while still achieving a long blade length of at least 3.1 inches, including a heel blade length section (Abl) that is at least 1.1 inches, a club moment arm (CMA) of less than 1.1 inches, and a transfer distance (TD) of at least 1.2 inches, wherein the transfer distance (TD) is between 10 percent to 40 percent greater than the club moment arm (CMA). This ratio ensures that the CG is below the engineered impact point (EIP), yet still ensures that the relationship between club moment arm (CMA) and transfer distance (TD) are achieved with club head design having a stress reducing feature (1000), a long blade length (BL), and long heel blade length section (Abl). As previously mentioned, as the CG elevation decreases the club moment arm (CMA) increases by definition, thereby again requiring particular attention to maintain the club moment arm (CMA) at less than 1.1 inches while reducing the Ycg distance, and a significant transfer distance (TD) necessary to accommodate the long blade length (BL) and heel blade length section (Abl). In an even further embodiment, a ratio of the Ycg distance to the top edge height (TEH) of less than 0.375 has produced even more desirable ball flight properties. Generally the top edge height (TEH) of fairway wood golf clubs is between 1.1 inches and 2.1 inches.


In fact, most fairway wood type golf club heads fortunate to have a small Ycg distance are plagued by a short blade length (BL), a small heel blade length section (Abl), and/or long club moment arm (CMA). With reference to FIG. 3, one particular embodiment achieves improved performance with the Ycg distance less than 0.65 inches, while still achieving a long blade length of at least 3.1 inches, including a heel blade length section (Abl) that is at least 1.1 inches, a club moment arm (CMA) of less than 1.1 inches, and a transfer distance (TD) of at least 1.2 inches, wherein the transfer distance (TD) is between 10 percent to 40 percent greater than the club moment arm (CMA). As with the prior disclosure, these relationships are a delicate balance among many variables, often going against traditional club head design principles, to obtain desirable performance. Still further, another embodiment has maintained this delicate balance of relationships while even further reducing the Ycg distance to less than 0.60 inches.


As previously touched upon, in the past the pursuit of high MOIy fairway woods led to oversized fairway woods attempting to move the CG as far away from the face of the club, and as low, as possible. With reference again to FIG. 8, this particularly common strategy leads to a large club moment arm (CMA), a variable that the present embodiment seeks to reduce. Further, one skilled in the art will appreciate that simply lowering the CG in FIG. 8 while keeping the Zcg distance, seen in FIGS. 2 and 6, constant actually increases the length of the club moment arm (CMA). The present invention is maintaining the club moment arm (CMA) at less than 1.1 inches to achieve the previously described performance advantages, while reducing the Ycg distance in relation to the top edge height (TEH); which effectively means that the Zcg distance is decreasing and the CG position moves toward the face, contrary to many conventional design goals.


As explained throughout, the relationships among many variables play a significant role in obtaining the desired performance and feel of a golf club. One of these important relationships is that of the club moment arm (CMA) and the transfer distance (TD). One particular embodiment has a club moment arm (CMA) of less than 1.1 inches and a transfer distance (TD) of at least 1.2 inches; however in a further particular embodiment this relationship is even further refined resulting in a fairway wood golf club having a ratio of the club moment arm (CMA) to the transfer distance (TD) that is less than 0.75, resulting in particularly desirable performance. Even further performance improvements have been found in an embodiment having the club moment arm (CMA) at less than 1.0 inch, and even more preferably, less than 0.95 inches. A somewhat related embodiment incorporates a mass distribution that yields a ratio of the Xcg distance to the Ycg distance of at least two.


A further embodiment achieves a Ycg distance of less than 0.65 inches, thereby requiring a very light weight club head shell so that as much discretionary mass as possible may be added in the sole region without exceeding normally acceptable head weights, as well as maintaining the necessary durability. In one particular embodiment this is accomplished by constructing the shell out of a material having a density of less than 5 g/cm3, such as titanium alloy, nonmetallic composite, or thermoplastic material, thereby permitting over one-third of the final club head weight to be discretionary mass located in the sole of the club head. One such nonmetallic composite may include composite material such as continuous fiber pre-preg material (including thermosetting materials or thermoplastic materials for the resin). In yet another embodiment the discretionary mass is composed of a second material having a density of at least 15 g/cm3, such as tungsten. An even further embodiment obtains a Ycg distance is less than 0.55 inches by utilizing a titanium alloy shell and at least 80 grams of tungsten discretionary mass, all the while still achieving a ratio of the Ycg distance to the top edge height (TEH) is less than 0.40, a blade length (BL) of at least 3.1 inches with a heel blade length section (Abl) that is at least 1.1 inches, a club moment arm (CMA) of less than 1.1 inches, and a transfer distance (TD) of at least 1.2 inches.


A further embodiment recognizes another unusual relationship among club head variables that produces a fairway wood type golf club exhibiting exceptional performance and feel. In this embodiment it has been discovered that a heel blade length section (Abl) that is at least twice the Ycg distance is desirable from performance, feel, and aesthetics perspectives. Even further, a preferably range has been identified by appreciating that performance, feel, and aesthetics get less desirable as the heel blade length section (Abl) exceeds 2.75 times the Ycg distance. Thus, in this one embodiment the heel blade length section (Abl) should be 2 to 2.75 times the Ycg distance.


Similarly, a desirable overall blade length (BL) has been linked to the Ycg distance. In yet another embodiment preferred performance and feel is obtained when the blade length (BL) is at least 6 times the Ycg distance. Such relationships have not been explored with conventional golf clubs because exceedingly long blade lengths (BL) would have resulted. Even further, a preferable range has been identified by appreciating that performance and feel become less desirable as the blade length (BL) exceeds 7 times the Ycg distance. Thus, in this one embodiment the blade length (BL) should be 6 to 7 times the Ycg distance.


Just as new relationships among blade length (BL) and Ycg distance, as well as the heel blade length section (Abl) and Ycg distance, have been identified; another embodiment has identified relationships between the transfer distance (TD) and the Ycg distance that produce a particularly playable golf club. One embodiment has achieved preferred performance and feel when the transfer distance (TD) is at least 2.25 times the Ycg distance. Even further, a preferable range has been identified by appreciating that performance and feel deteriorate when the transfer distance (TD) exceeds 2.75 times the Ycg distance. Thus, in yet another embodiment the transfer distance (TD) should be within the relatively narrow range of 2.25 to 2.75 times the Ycg distance for preferred performance and feel.


All the ratios used in defining embodiments of the present invention involve the discovery of unique relationships among key club head engineering variables that are inconsistent with merely striving to obtain a high MOIy or low CG using conventional golf club head design wisdom. Numerous alterations, modifications, and variations of the preferred embodiments disclosed herein will be apparent to those skilled in the art and they are all anticipated and contemplated to be within the spirit and scope of the instant invention. Further, although specific embodiments have been described in detail, those with skill in the art will understand that the preceding embodiments and variations can be modified to incorporate various types of substitute and or additional or alternative materials, relative arrangement of elements, and dimensional configurations. Accordingly, even though only few variations of the present invention are described herein, it is to be understood that the practice of such additional modifications and variations and the equivalents thereof, are within the spirit and scope of the invention as defined in the following claims.

Claims
  • 1. A multi-material iron-type golf club head comprising: (i) a shell having a face positioned at a front portion where the golf club head impacts a golf ball, the face being opposite a rear portion and extending between a top portion and a sole, thereby defining a closed internal volume, wherein the shell has an aperture located in the sole and extending through the shell from an exterior surface to the closed internal volume, the aperture has an aperture length between an aperture toe-most point and an aperture heel-most point, an aperture width between an aperture leading edge and an aperture trailing edge, and at least a portion of the aperture contains a filler material having a filler material compressive strength that is less than 50% of a shell compressive strength and a filler density less than 3 g/cm3, and wherein the shell includes a first material having a first density greater than the filler density, and a second material having a second density greater than the first density is attached to the shell;(ii) the face has a face thickness that varies from a minimum face thickness to a maximum face thickness, a characteristic time of at least 220 microseconds, and an engineered impact point, a face height, and a lower edge height, wherein the face has a blade length measured horizontally from an origin point toward a toe side of the golf club head to the most distant point on the golf club head in this direction, wherein the blade length includes a toe blade length section and a heel blade length section measured in the same direction as the blade length from the origin point to the engineered impact point, wherein the heel blade length section is at least 1.1″, and a front-to-back dimension from a furthest forward point on the face to the furthest rearward point at the rear portion;(iii) a bore having a center that defines a shaft axis which intersects with a horizontal ground plane to define the origin point, and defines a shaft axis plane containing the shaft axis, wherein the bore is located at a heel side of the golf club head, and wherein the toe side of the golf club head is located opposite of the heel side;(iv) a center of gravity located: (a) vertically from the origin point a distance Ycg;(b) horizontally from the origin point toward the toe side of the golf club head a distance Xcg;(c) a distance Zcg from the origin toward the rear portion in a direction generally orthogonal to the vertical direction used to measure Ycg and generally orthogonal to the horizontal direction used to measure Xcg;(d) a club moment arm from the center of gravity to the engineered impact point is less than 1.1″, wherein a ratio of the club moment arm to the heel blade length section is less than 0.9;(e) a transfer distance measured horizontally from the center of gravity to a vertical line extending from the origin, wherein the transfer distance is at least 10% greater than the club moment arm, and a ratio of the club moment arm to the transfer distance is less than 0.75; and(v) wherein the aperture leading edge is spaced rearward from an interior surface of the face a distance that is at least as great as the minimum face thickness, and at least a portion of the aperture leading edge is located between the shaft axis plane and the rear portion.
  • 2. The multi-material iron-type golf club head of claim 1, wherein the aperture width of at least a portion of the aperture is at least fifty percent of the minimum face thickness.
  • 3. The multi-material iron-type golf club head of claim 2, wherein the aperture width is less than the maximum face thickness.
  • 4. The multi-material iron-type golf club head of claim 2, wherein the second density is at least twice the first density.
  • 5. The multi-material iron-type golf club head of claim 4, wherein the second density is at least 15 g/cm3.
  • 6. The multi-material iron-type golf club head of claim 2, wherein a ratio of the front-to-back dimension to the blade length is less than 0.925, a ratio of the heel blade length section to the front-to-back dimension is at least 0.32, and the club moment arm is less than 1″.
  • 7. The multi-material iron-type golf club head of claim 2, wherein a ratio of the Ycg distance to the top edge height is less than 0.40, and the transfer distance is at least 1.2″.
  • 8. The multi-material iron-type golf club head of claim 7, wherein the ratio of the Ycg distance to the top edge height is less than 0.375, and the club moment arm is less than 0.95″.
  • 9. The multi-material iron-type golf club head of claim 8, wherein the characteristic time is at least 240 microseconds.
  • 10. The multi-material iron-type golf club head of claim 2, wherein the blade length is at least 3.1″, a ratio of the front-to-back dimension to the blade length is less than 0.925, a ratio of the heel blade length section to the front-to-back dimension is at least 0.32, and the club moment arm is less than 1″.
  • 11. The multi-material iron-type golf club head of claim 10, wherein a stress-to-deflection ratio of the peak stress on the face to the peak deflection of the face when exposed to an approximate impact force is less than 5500 ksi per inch of deflection, wherein the approximate impact force is applied to the face over a 0.6 inch diameter, centered on the engineered impact point, and the approximate impact force is at least 1000 lbf and no more than 4000 lbf.
  • 12. The multi-material iron-type golf club head of claim 2, wherein the aperture leading edge is curved.
  • 13. The multi-material iron-type golf club head of claim 2, wherein the aperture is located at an aperture depth measured vertically from the lower edge height toward the center of gravity, and the aperture depth of at least a portion of the aperture is greater than zero.
  • 14. The multi-material iron-type golf club head of claim 2, wherein the aperture length is at least fifty percent of the Xcg distance.
  • 15. A multi-material iron-type golf club head comprising: (i) a shell having a face positioned at a front portion where the golf club head impacts a golf ball, the face being opposite a rear portion and extending between a top portion and a sole, thereby defining a closed internal volume, wherein the shell has an aperture located in the sole and extending through the shell from an exterior surface to the closed internal volume, the aperture has an aperture length between an aperture toe-most point and an aperture heel-most point, an aperture width between an aperture leading edge and an aperture trailing edge, and at least a portion of the aperture contains a filler material having a filler material compressive strength that is less than 50% of a shell compressive strength and a filler density less than 3 g/cm3, and wherein the shell includes a first material having a first density greater than the filler density;(ii) the face has a face thickness that varies from a minimum face thickness to a maximum face thickness, a characteristic time of at least 220 microseconds, and an engineered impact point, a face height, and a lower edge height, wherein the face has a blade length measured horizontally from an origin point toward a toe side of the golf club head to the most distant point on the golf club head in this direction, wherein the blade length includes a toe blade length section and a heel blade length section measured in the same direction as the blade length from the origin point to the engineered impact point, wherein the heel blade length section is at least 1.1″, and a front-to-back dimension from a furthest forward point on the face to the furthest rearward point at the rear portion;(iii) a bore having a center that defines a shaft axis which intersects with a horizontal ground plane to define the origin point, and defines a shaft axis plane containing the shaft axis, wherein the bore is located at a heel side of the golf club head, and wherein the toe side of the golf club head is located opposite of the heel side;(iv) a center of gravity located: (a) vertically from the origin point a distance Ycg;(b) horizontally from the origin point toward the toe side of the golf club head a distance Xcg;(c) a distance Zcg from the origin toward the rear portion in a direction generally orthogonal to the vertical direction used to measure Ycg and generally orthogonal to the horizontal direction used to measure Xcg;(d) a club moment arm from the center of gravity to the engineered impact point is less than 1.1″, wherein a ratio of the club moment arm to the heel blade length section is less than 0.9;(e) a transfer distance measured horizontally from the center of gravity to a vertical line extending from the origin, wherein the transfer distance is at least 10% greater than the club moment arm, and a ratio of the club moment arm to the transfer distance is less than 0.75;(v) wherein the aperture leading edge is spaced rearward from an interior surface of the face a distance that is at least as great as the minimum face thickness, and the aperture leading edge is located between the shaft axis plane and the rear portion; and(vi) wherein the aperture width of at least a portion of the aperture is at least fifty percent of the minimum face thickness.
  • 16. The multi-material iron-type golf club head of claim 15, wherein the aperture width is less than the maximum face thickness.
  • 17. The multi-material iron-type golf club head of claim 15, wherein a ratio of the front-to-back dimension to the blade length is less than 0.925, a ratio of the heel blade length section to the front-to-back dimension is at least 0.32, and the club moment arm is less than 1″.
  • 18. The multi-material iron-type golf club head of claim 15, wherein a ratio of the Ycg distance to the top edge height is less than 0.375, and the club moment arm is less than 0.95″.
  • 19. The multi-material iron-type golf club head of claim 15, wherein the characteristic time is at least 240 microseconds.
  • 20. The multi-material iron-type golf club head of claim 15, wherein the blade length is at least 3.1″, a ratio of the front-to-back dimension to the blade length is less than 0.925, a ratio of the heel blade length section to the front-to-back dimension is at least 0.32, the club moment arm is less than 1″, the aperture leading edge is curved, and the aperture length is at least fifty percent of the Xcg distance.
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 16/786,430, filed on Feb. 10, 2020, which is a continuation of U.S. patent application Ser. No. 16/366,481, filed on Mar. 27, 2019, now U.S. Pat. No. 10,556,160, which is a continuation of U.S. patent application Ser. No. 15/957,961, filed on Apr. 20, 2018, now U.S. Pat. No. 10,245,485, which is a continuation of U.S. patent application Ser. No. 15/437,835, filed on Feb. 21, 2017, now U.S. Pat. No. 9,950,223, which is a continuation of U.S. patent application Ser. No. 14/868,446, filed on Sep. 29, 2015, now U.S. Pat. No. 9,610,482, which is a continuation of U.S. patent application Ser. No. 14/472,415, filed on Aug. 29, 2014, now U.S. Pat. No. 9,168,434, which is a continuation of U.S. patent application Ser. No. 13/397,122, filed on Feb. 15, 2012, now U.S. Pat. No. 8,821,312, which is a continuation-in-part of U.S. patent application Ser. No. 12/791,025, filed on Jun. 1, 2010, now U.S. Pat. No. 8,235,844, all of which is incorporated by reference as if completely written herein.

US Referenced Citations (659)
Number Name Date Kind
411000 Anderson Sep 1889 A
708575 Mules Sep 1902 A
727819 Mattern May 1903 A
819900 Martin May 1906 A
1133129 Govan Mar 1915 A
1518316 Ellingham Dec 1924 A
1526438 Scott Feb 1925 A
1538312 Beat May 1925 A
1592463 Marker Jul 1926 A
1658581 Tobia Feb 1928 A
1704119 Buhrke Mar 1929 A
1970409 Wiedemann Aug 1934 A
2004968 Young Jun 1935 A
2034936 Barnhart Mar 1936 A
2041676 Gallagher May 1936 A
D107007 Cashmore Nov 1937 S
2198981 Sullivan Apr 1940 A
2214356 Wettlaufer Sep 1940 A
2225930 Sexton Dec 1940 A
2328583 Reach Sep 1943 A
2332342 Reach Oct 1943 A
2360364 Reach Oct 1944 A
2375249 Richer May 1945 A
2460435 Schaffer Feb 1949 A
2681523 Sellers Jun 1954 A
2968486 Jackson Jan 1961 A
3064980 Steiner Nov 1962 A
3084940 Cissel Apr 1963 A
3085804 Pieper Apr 1963 A
3166320 Onions Jan 1965 A
3466047 Rodia et al. Sep 1969 A
3486755 Hodge Dec 1969 A
3556533 Hollis Jan 1971 A
3589731 Chancellor Jun 1971 A
3606327 Gorman Sep 1971 A
3610630 Glover Oct 1971 A
3652094 Glover Mar 1972 A
3672419 Fischer Jun 1972 A
3692306 Glover Sep 1972 A
3743297 Dennis Jul 1973 A
3860244 Cosby Jan 1975 A
3893672 Schonher Jul 1975 A
3897066 Belmont Jul 1975 A
3961796 Thompson Jun 1976 A
3970236 Rogers Jul 1976 A
3976299 Lawrence et al. Aug 1976 A
3979122 Belmont Sep 1976 A
3979123 Belmont Sep 1976 A
3985363 Jepson et al. Oct 1976 A
3997170 Goldberg Dec 1976 A
4008896 Gordos Feb 1977 A
4027885 Rogers Jun 1977 A
4043563 Churchward Aug 1977 A
4052075 Daly Oct 1977 A
4065133 Gordos Dec 1977 A
4076254 Nygren Feb 1978 A
4077633 Studen Mar 1978 A
4085934 Churchward Apr 1978 A
4121832 Ebbing Oct 1978 A
4139196 Riley Feb 1979 A
4147349 Jeghers Apr 1979 A
4150702 Holmes Apr 1979 A
4165076 Celia Aug 1979 A
4189976 Becker Feb 1980 A
4193601 Reid, Jr. et al. Mar 1980 A
4214754 Zebelean Jul 1980 A
D256709 Reid, Jr. et al. Sep 1980 S
4247105 Jeghers Jan 1981 A
4262562 MacNeill Apr 1981 A
D259698 MacNeill Jun 1981 S
4322083 Imai Mar 1982 A
4340229 Stuff, Jr. Jul 1982 A
4398965 Campau Aug 1983 A
4411430 Dian Oct 1983 A
4423874 Stuff, Jr. Jan 1984 A
4431192 Stuff, Jr. Feb 1984 A
4432549 Zebelean Feb 1984 A
4438931 Motomiya Mar 1984 A
4471961 Masghati et al. Sep 1984 A
4489945 Kobayashi Dec 1984 A
4527799 Solheim Jul 1985 A
4530505 Stuff Jul 1985 A
D284346 Masters Jun 1986 S
4592552 Garber Jun 1986 A
4602787 Sugioka et al. Jul 1986 A
4607846 Perkins Aug 1986 A
D285473 Flood Sep 1986 S
4712798 Preato Dec 1987 A
4730830 Tilley Mar 1988 A
4736093 Braly Apr 1988 A
4754974 Kobayashi Jul 1988 A
4754977 Sahm Jul 1988 A
4762322 Molitor et al. Aug 1988 A
4787636 Honma Nov 1988 A
4795159 Nagamoto Jan 1989 A
4803023 Enomoto et al. Feb 1989 A
4809983 Langert Mar 1989 A
4852880 Kobayashi Aug 1989 A
4867457 Lowe Sep 1989 A
4867458 Sumikawa et al. Sep 1989 A
4869507 Sahm Sep 1989 A
4881739 Garcia Nov 1989 A
4890840 Kobayashi Jan 1990 A
4895367 Kajita et al. Jan 1990 A
4895371 Bushner Jan 1990 A
4915558 Muller Apr 1990 A
4919428 Perkins Apr 1990 A
D307783 Iinuma May 1990 S
4962932 Anderson Oct 1990 A
4994515 Washiyama et al. Feb 1991 A
5006023 Kaplan Apr 1991 A
5020950 Ladouceur Jun 1991 A
5028049 McKeighen Jul 1991 A
5039267 Wollar Aug 1991 A
5042806 Helmstetter Aug 1991 A
5050879 Sun et al. Sep 1991 A
5058895 Igarashi Oct 1991 A
5076585 Bouquet Dec 1991 A
D323035 Yang Jan 1992 S
5078400 Desbiolles et al. Jan 1992 A
5092599 Okumoto et al. Mar 1992 A
5116054 Johnson May 1992 A
5121922 Harsh, Sr. Jun 1992 A
5122020 Bedi Jun 1992 A
5172913 Bouquet Dec 1992 A
5190289 Nagai et al. Mar 1993 A
5193810 Antonious Mar 1993 A
5221086 Antonious Jun 1993 A
5232224 Zeider Aug 1993 A
5244210 Au Sep 1993 A
5251901 Solheim et al. Oct 1993 A
5253869 Dingle et al. Oct 1993 A
5255919 Johnson Oct 1993 A
D343558 Latraverse et al. Jan 1994 S
5297794 Lu Mar 1994 A
5301944 Koehler Apr 1994 A
5306008 Kinoshita Apr 1994 A
5312106 Cook May 1994 A
5316305 McCabe May 1994 A
5318297 Davis et al. Jun 1994 A
5320005 Hsiao Jun 1994 A
5328176 Lo Jul 1994 A
5340106 Ravaris Aug 1994 A
5346216 Aizawa Sep 1994 A
5346217 Tsuchiya et al. Sep 1994 A
D351441 Iinuma et al. Oct 1994 S
5385348 Wargo Jan 1995 A
5395113 Antonious Mar 1995 A
D357290 Viollaz et al. Apr 1995 S
5410798 Lo May 1995 A
5419556 Take May 1995 A
5421577 Kobayashi Jun 1995 A
5429365 McKeighen Jul 1995 A
5439222 Kranenberg Aug 1995 A
5439223 Kobayashi Aug 1995 A
5441274 Clay Aug 1995 A
5447309 Vincent Sep 1995 A
5449260 Whittle Sep 1995 A
D363750 Reed Oct 1995 S
D365615 Shimatani Dec 1995 S
D366508 Hutin Jan 1996 S
5482280 Yamawaki Jan 1996 A
5484155 Yamawaki et al. Jan 1996 A
5492327 Biafore, Jr. Feb 1996 A
5511786 Antonious Apr 1996 A
5518243 Redman May 1996 A
5533730 Ruvang Jul 1996 A
D372512 Simmons Aug 1996 S
5544884 Hardman Aug 1996 A
5547188 Dumontier et al. Aug 1996 A
5558332 Cook Sep 1996 A
D375130 Hlinka et al. Oct 1996 S
5564705 Kobayashi et al. Oct 1996 A
5571053 Lane Nov 1996 A
5573467 Chou et al. Nov 1996 A
5575723 Take et al. Nov 1996 A
5582553 Ashcraft et al. Dec 1996 A
5584770 Jensen Dec 1996 A
D377509 Katayama Jan 1997 S
5599243 Kobayashi Feb 1997 A
5613917 Kobayashi et al. Mar 1997 A
D378770 Hlinka et al. Apr 1997 S
5616088 Aizawa et al. Apr 1997 A
5620379 Borys Apr 1997 A
5624331 Lo et al. Apr 1997 A
5629475 Chastonay May 1997 A
5632694 Lee May 1997 A
5632695 Hlinka et al. May 1997 A
5645495 Saso Jul 1997 A
D382612 Oyer Aug 1997 S
5658206 Antonious Aug 1997 A
5669826 Chang et al. Sep 1997 A
5669827 Nagamoto Sep 1997 A
5681228 Mikame et al. Oct 1997 A
5683309 Reimers Nov 1997 A
5688189 Bland Nov 1997 A
5695412 Cook Dec 1997 A
5700208 Nelms Dec 1997 A
5709613 Sheraw Jan 1998 A
5718641 Lin Feb 1998 A
5720674 Galy Feb 1998 A
D392354 Burrows Mar 1998 S
D392526 Nicely Mar 1998 S
D394688 Fox May 1998 S
5746664 Reynolds, Jr. May 1998 A
5749795 Schmidt May 1998 A
5755627 Yamazaki et al. May 1998 A
5759114 Bluto et al. Jun 1998 A
5762567 Antonious Jun 1998 A
5766091 Humphrey et al. Jun 1998 A
5766095 Antonious Jun 1998 A
5769737 Holladay et al. Jun 1998 A
5772527 Liu Jun 1998 A
5776010 Helmstetter et al. Jul 1998 A
5776011 Su et al. Jul 1998 A
5785608 Collins Jul 1998 A
5785609 Sheets et al. Jul 1998 A
5788587 Tseng Aug 1998 A
5797807 Moore Aug 1998 A
5798587 Lee Aug 1998 A
D397750 Frazetta Sep 1998 S
RE35955 Lu Nov 1998 E
5833551 Vincent et al. Nov 1998 A
D402726 McCabe et al. Dec 1998 S
D403037 Stone et al. Dec 1998 S
5851160 Rugge et al. Dec 1998 A
D405488 Burrows Feb 1999 S
5876293 Musty Mar 1999 A
5885166 Shiraishi Mar 1999 A
5890971 Shiraishi Apr 1999 A
D409463 McMullin May 1999 S
5908356 Nagamoto Jun 1999 A
5911638 Parente et al. Jun 1999 A
5913735 Kenmi Jun 1999 A
5916042 Reimers Jun 1999 A
D412547 Fong Aug 1999 S
5935019 Yamamoto Aug 1999 A
5935020 Stites et al. Aug 1999 A
5941782 Cook Aug 1999 A
D413952 Oyer Sep 1999 S
5947840 Ryan Sep 1999 A
5954595 Antonious Sep 1999 A
5967905 Nakahara et al. Oct 1999 A
5971867 Galy Oct 1999 A
5976033 Takeda Nov 1999 A
5997415 Wood Dec 1999 A
6001029 Kobayashi Dec 1999 A
6007433 Helmstetter et al. Dec 1999 A
6015354 Ahn et al. Jan 2000 A
6017177 Lanham Jan 2000 A
6019686 Gray Feb 2000 A
6023891 Robertson et al. Feb 2000 A
6027415 Takeda Feb 2000 A
6032677 Blechman et al. Mar 2000 A
6033318 Drajan, Jr. et al. Mar 2000 A
6033319 Farrar Mar 2000 A
6033321 Yamamoto Mar 2000 A
6042486 Gallagher Mar 2000 A
6048278 Meyer Apr 2000 A
6056649 Imai May 2000 A
6062988 Yamamoto May 2000 A
6074308 Domas Jun 2000 A
6077171 Yoneyama Jun 2000 A
6080069 Long Jun 2000 A
6083115 King Jul 2000 A
6086485 Hamada et al. Jul 2000 A
6089994 Sun Jul 2000 A
6093113 Mertens Jul 2000 A
6123627 Antonious Sep 2000 A
6139445 Werner et al. Oct 2000 A
6146286 Masuda Nov 2000 A
6149533 Finn Nov 2000 A
6162132 Yoneyama Dec 2000 A
6162133 Peterson Dec 2000 A
6168537 Ezawa Jan 2001 B1
6171204 Starry Jan 2001 B1
6186905 Kosmatka Feb 2001 B1
6190267 Marlowe et al. Feb 2001 B1
6193614 Sasamoto et al. Feb 2001 B1
6203448 Yamamoto Mar 2001 B1
6206789 Takeda Mar 2001 B1
6206790 Kubica et al. Mar 2001 B1
6210290 Erickson et al. Apr 2001 B1
6217461 Galy Apr 2001 B1
6238303 Fite May 2001 B1
6244974 Hanberry, Jr. Jun 2001 B1
6248025 Murphey et al. Jun 2001 B1
6254494 Hasebe et al. Jul 2001 B1
6264414 Hartmann et al. Jul 2001 B1
6270422 Fisher Aug 2001 B1
6277032 Smith Aug 2001 B1
6290609 Takeda Sep 2001 B1
6296579 Robinson Oct 2001 B1
6299547 Kosmatka Oct 2001 B1
6306048 McCabe et al. Oct 2001 B1
6319150 Werner et al. Nov 2001 B1
6325728 Helmstetter et al. Dec 2001 B1
6334817 Ezawa et al. Jan 2002 B1
6334818 Cameron et al. Jan 2002 B1
6338683 Kosmatka Jan 2002 B1
6340337 Hasebe et al. Jan 2002 B2
6344002 Kajita Feb 2002 B1
6348012 Erickson et al. Feb 2002 B1
6348013 Kosmatka Feb 2002 B1
6348014 Chiu Feb 2002 B1
6364788 Helmstetter et al. Apr 2002 B1
6371868 Galloway et al. Apr 2002 B1
6379264 Forzano Apr 2002 B1
6379265 Hirakawa et al. Apr 2002 B1
6383090 Odoherty et al. May 2002 B1
6386987 Lejeune, Jr. May 2002 B1
6386990 Reyes et al. May 2002 B1
6390933 Galloway et al. May 2002 B1
6409612 Evans et al. Jun 2002 B1
6425832 Cackett et al. Jul 2002 B2
6434811 Helmstetter et al. Aug 2002 B1
6435977 Helmstetter et al. Aug 2002 B1
6436142 Paes et al. Aug 2002 B1
6440009 Guibaud et al. Aug 2002 B1
6440010 Deshmukh Aug 2002 B1
6443851 Liberatore Sep 2002 B1
6458042 Chen Oct 2002 B1
6458044 Vincent et al. Oct 2002 B1
6461249 Liberatore Oct 2002 B2
6464598 Miller Oct 2002 B1
6475101 Burrows Nov 2002 B2
6475102 Helmstetter et al. Nov 2002 B2
6514154 Finn Feb 2003 B1
6524194 McCabe Feb 2003 B2
6524197 Boone Feb 2003 B2
6524198 Takeda Feb 2003 B2
6527649 Neher et al. Mar 2003 B1
6530847 Antonious Mar 2003 B1
6530848 Gillig Mar 2003 B2
6533679 McCabe et al. Mar 2003 B1
6547676 Cackett et al. Apr 2003 B2
6558273 Kobayashi et al. May 2003 B2
6565448 Cameron May 2003 B2
6569029 Hamburger May 2003 B1
6569040 Bradstock May 2003 B2
6572489 Miyamoto et al. Jun 2003 B2
6592468 Vincent et al. Jul 2003 B2
6605007 Bissonnette et al. Aug 2003 B1
6607452 Helmstetter et al. Aug 2003 B2
6616547 Vincent et al. Sep 2003 B2
6620055 Saso Sep 2003 B2
6620056 Galloway et al. Sep 2003 B2
6638180 Tsurumaki Oct 2003 B2
6638183 Takeda Oct 2003 B2
D482089 Burrows Nov 2003 S
D482090 Burrows Nov 2003 S
D482420 Burrows Nov 2003 S
6641487 Hamburger Nov 2003 B1
6641490 Ellemor Nov 2003 B2
6648772 Vincent et al. Nov 2003 B2
6648773 Evans Nov 2003 B1
6652387 Liberatore Nov 2003 B2
D484208 Burrows Dec 2003 S
6663504 Hocknell et al. Dec 2003 B2
6663506 Nishimoto et al. Dec 2003 B2
6669571 Cameron et al. Dec 2003 B1
6669576 Rice Dec 2003 B1
6669577 Hocknell et al. Dec 2003 B1
6669580 Cackett et al. Dec 2003 B1
6676536 Jacobson Jan 2004 B1
6679786 McCabe Jan 2004 B2
D486542 Burrows Feb 2004 S
6695712 Iwata et al. Feb 2004 B1
6716111 Liberatore Apr 2004 B2
6716114 Nishio Apr 2004 B2
6719510 Cobzaru Apr 2004 B2
6719641 Dabbs et al. Apr 2004 B2
6719645 Kouno Apr 2004 B2
6723002 Barlow Apr 2004 B1
6739982 Murphy et al. May 2004 B2
6739983 Helmstetter et al. May 2004 B2
6743118 Soracco Jun 2004 B1
6749523 Forzano Jun 2004 B1
6757572 Forest Jun 2004 B1
6758763 Murphy et al. Jul 2004 B2
6766726 Schwarzkopf Jul 2004 B1
6773359 Lee Aug 2004 B1
6773360 Willett et al. Aug 2004 B2
6773361 Lee Aug 2004 B1
6776723 Bliss et al. Aug 2004 B2
6776726 Sano Aug 2004 B2
6783465 Matsunaga Aug 2004 B2
6800038 Willett et al. Oct 2004 B2
6800040 Galloway et al. Oct 2004 B2
6805643 Lin Oct 2004 B1
6808460 Namiki Oct 2004 B2
6811496 Wahl et al. Nov 2004 B2
6821214 Rice Nov 2004 B2
6824475 Burnett et al. Nov 2004 B2
6835145 Tsurumaki Dec 2004 B2
D501036 Burrows Jan 2005 S
D501523 Dogan et al. Feb 2005 S
D501669 Burrows Feb 2005 S
D501903 Tanaka Feb 2005 S
6855068 Antonious Feb 2005 B2
6860818 Mahaffey et al. Mar 2005 B2
6860823 Lee Mar 2005 B2
6860824 Evans Mar 2005 B2
6863624 Kessler Mar 2005 B1
D504478 Burrows Apr 2005 S
6875124 Gilbert et al. Apr 2005 B2
6875129 Erickson et al. Apr 2005 B2
6875130 Nishio Apr 2005 B2
6881158 Yang et al. Apr 2005 B2
6881159 Galloway et al. Apr 2005 B2
6887165 Tsurumaki May 2005 B2
6890267 Mahaffey et al. May 2005 B2
D506236 Evans et al. Jun 2005 S
6902497 Deshmukh et al. Jun 2005 B2
6904663 Willett et al. Jun 2005 B2
D508274 Burrows Aug 2005 S
D508275 Burrows Aug 2005 S
6923734 Meyer Aug 2005 B2
6926619 Helmstetter et al. Aug 2005 B2
6929563 Nishitani Aug 2005 B2
6932717 Hou et al. Aug 2005 B2
6960141 Noguchi et al. Nov 2005 B2
6960142 Bissonnette et al. Nov 2005 B2
6964617 Williams Nov 2005 B2
6974393 Caldwell et al. Dec 2005 B2
6984180 Hasebe Jan 2006 B2
6988960 Mahaffey et al. Jan 2006 B2
6991558 Beach et al. Jan 2006 B2
6991560 Tseng Jan 2006 B2
D515165 Zimmerman et al. Feb 2006 S
6994636 Hocknell et al. Feb 2006 B2
6997820 Willett et al. Feb 2006 B2
7004849 Cameron Feb 2006 B2
7004852 Billings Feb 2006 B2
D518129 Poynor et al. Mar 2006 S
7022028 Nagai et al. Apr 2006 B2
7029403 Rice et al. Apr 2006 B2
D520585 Hasebe May 2006 S
D523104 Hasebe Jun 2006 S
7070512 Nishio Jul 2006 B2
7070517 Cackett et al. Jul 2006 B2
7077762 Kouno et al. Jul 2006 B2
7083531 Aguinaldo et al. Aug 2006 B2
7094159 Takeda Aug 2006 B2
7097572 Yabu Aug 2006 B2
7101289 Gibbs Sep 2006 B2
D532474 Bennett et al. Nov 2006 S
7137905 Kohno Nov 2006 B2
7137906 Tsunoda et al. Nov 2006 B2
7137907 Gibbs et al. Nov 2006 B2
7140974 Chao et al. Nov 2006 B2
7144334 Ehlers et al. Dec 2006 B2
7147572 Kohno Dec 2006 B2
7147573 Dimarco Dec 2006 B2
7153220 Lo Dec 2006 B2
7156750 Nishitani et al. Jan 2007 B2
7163468 Gibbs et al. Jan 2007 B2
7163470 Galloway et al. Jan 2007 B2
7166038 Williams et al. Jan 2007 B2
7166040 Hoffman et al. Jan 2007 B2
7166041 Evans Jan 2007 B2
7169058 Fagan Jan 2007 B1
7169060 Stevens et al. Jan 2007 B2
D536402 Kawami Feb 2007 S
7179034 Ladouceur Feb 2007 B2
D538866 Kim et al. Mar 2007 S
7186190 Beach et al. Mar 2007 B1
7189169 Billlings Mar 2007 B2
7198575 Beach et al. Apr 2007 B2
7201669 Stites et al. Apr 2007 B2
D543600 Oldknow May 2007 S
7211005 Lindsay May 2007 B2
7211006 Chang May 2007 B2
7214143 Deshmukh May 2007 B2
7223180 Willett et al. May 2007 B2
D544939 Radcliffe et al. Jun 2007 S
7226366 Galloway Jun 2007 B2
7250007 Lu Jul 2007 B2
7255654 Murphy et al. Aug 2007 B2
7267620 Chao et al. Sep 2007 B2
7273423 Imamoto Sep 2007 B2
D552701 Ruggiero et al. Oct 2007 S
7278927 Gibbs et al. Oct 2007 B2
7281985 Galloway Oct 2007 B2
D554720 Barez et al. Nov 2007 S
7291074 Kouno et al. Nov 2007 B2
7294064 Tsurumaki Nov 2007 B2
7294065 Liang et al. Nov 2007 B2
7297072 Meyer et al. Nov 2007 B2
7303488 Kakiuchi et al. Dec 2007 B2
7306527 Williams et al. Dec 2007 B2
7318782 Imamoto et al. Jan 2008 B2
D561286 Morales et al. Feb 2008 S
7338387 Nycum et al. Mar 2008 B2
7344452 Imamoto et al. Mar 2008 B2
7347795 Yamgishi et al. Mar 2008 B2
D567317 Jertson et al. Apr 2008 S
7354355 Tavares et al. Apr 2008 B2
7377860 Breier et al. May 2008 B2
7390266 Gwon Jun 2008 B2
7407447 Beach et al. Aug 2008 B2
D577090 Pergande et al. Sep 2008 S
7419441 Hoffman et al. Sep 2008 B2
D579507 Llewellyn et al. Oct 2008 S
7438649 Ezaki et al. Oct 2008 B2
7448963 Beach et al. Nov 2008 B2
7470201 Nakahara et al. Dec 2008 B2
D584784 Barez et al. Jan 2009 S
D588223 Kuan Mar 2009 S
7500924 Yokota Mar 2009 B2
7520820 Dimarco Apr 2009 B2
D592723 Chau et al. May 2009 S
7530901 Imamoto et al. May 2009 B2
7530904 Beach et al. May 2009 B2
7540811 Beach et al. Jun 2009 B2
7563175 Nishitani et al. Jul 2009 B2
7568985 Beach et al. Aug 2009 B2
7572193 Yokota Aug 2009 B2
7578753 Beach et al. Aug 2009 B2
D600767 Horacek et al. Sep 2009 S
7582024 Shear Sep 2009 B2
7591737 Gibbs et al. Sep 2009 B2
7591738 Beach et al. Sep 2009 B2
D604784 Horacek et al. Nov 2009 S
7621823 Beach et al. Nov 2009 B2
7628707 Beach et al. Dec 2009 B2
7632194 Beach et al. Dec 2009 B2
7632196 Reed Dec 2009 B2
D612440 Oldknow Mar 2010 S
7674187 Cackett et al. Mar 2010 B2
7674189 Beach et al. Mar 2010 B2
7682264 Hsu et al. Mar 2010 B2
D616952 Oldknow Jun 2010 S
7731603 Beach et al. Jun 2010 B2
7744484 Chao Jun 2010 B1
7753806 Beach et al. Jul 2010 B2
7771291 Willett et al. Aug 2010 B1
7789773 Rae et al. Sep 2010 B2
7857711 Shear Dec 2010 B2
7857713 Yokota Dec 2010 B2
7887434 Beach et al. Feb 2011 B2
7922604 Roach et al. Apr 2011 B2
7927229 Jertson et al. Apr 2011 B2
7946931 Oyama May 2011 B2
8012038 Beach et al. Sep 2011 B1
8012039 Greaney et al. Sep 2011 B2
8083609 Burnett Dec 2011 B2
8088021 Albertsen Jan 2012 B2
8096897 Beach et al. Jan 2012 B2
8118689 Beach et al. Feb 2012 B2
8157672 Greaney et al. Apr 2012 B2
8167737 Oyama May 2012 B2
8187119 Rae et al. May 2012 B2
8206244 Honea et al. Jun 2012 B2
8235844 Albertsen Aug 2012 B2
8241143 Albertsen Aug 2012 B2
8241144 Albertsen Aug 2012 B2
8292756 Greaney et al. Oct 2012 B2
8353786 Beach et al. Jan 2013 B2
8403771 Rice et al. Mar 2013 B1
8430763 Beach et al. Apr 2013 B2
8435134 Tang et al. May 2013 B2
8496544 Curtis et al. Jul 2013 B2
8517860 Albertsen Aug 2013 B2
8574094 Nicolette et al. Nov 2013 B2
8591351 Albertsen Nov 2013 B2
8616999 Greaney et al. Dec 2013 B2
8663029 Beach et al. Mar 2014 B2
8696491 Myers Apr 2014 B1
8721471 Albertsen May 2014 B2
8753222 Beach et al. Jun 2014 B2
8821312 Burnett Sep 2014 B2
8827831 Burnett Sep 2014 B2
8834289 de la Cruz Sep 2014 B2
8900069 Beach et al. Dec 2014 B2
8956240 Beach et al. Feb 2015 B2
8956242 Rice Feb 2015 B2
9011267 Burnett Apr 2015 B2
9089749 Burnett Jul 2015 B2
9101808 Stites Aug 2015 B2
9168428 Albertsen Oct 2015 B2
9168434 Burnett Oct 2015 B2
9174101 Burnett et al. Nov 2015 B2
9265993 Albertsen et al. Feb 2016 B2
9403069 Boyd et al. Aug 2016 B2
9566479 Albertsen Feb 2017 B2
9610482 Burnett Apr 2017 B2
9610483 Burnett Apr 2017 B2
9656131 Burnett May 2017 B2
9694255 Oldknow Jul 2017 B2
9950222 Albertsen Apr 2018 B2
9950223 Burnett Apr 2018 B2
9956460 Burnett et al. May 2018 B2
10245485 Burnett Apr 2019 B2
10369429 Burnett Aug 2019 B2
10406414 Galvan Sep 2019 B2
10556160 Burnett Feb 2020 B2
10792542 Burnett Oct 2020 B2
10843050 Albertsen Nov 2020 B2
11045696 Burnett Jun 2021 B2
11351425 Albertsen Jun 2022 B2
20020077195 Carr et al. Jun 2002 A1
20020115501 Chen Aug 2002 A1
20020183130 Pacinella Dec 2002 A1
20020183134 Allen et al. Dec 2002 A1
20030013545 Vincent et al. Jan 2003 A1
20030036442 Chao et al. Feb 2003 A1
20030176238 Galloway et al. Sep 2003 A1
20030220154 Anelli Nov 2003 A1
20040176180 Yamaguchi et al. Sep 2004 A1
20040192463 Tsurumaki et al. Sep 2004 A1
20050003905 Kim et al. Jan 2005 A1
20050026716 Wahl et al. Feb 2005 A1
20050049081 Boone Mar 2005 A1
20050119070 Kumamoto Jun 2005 A1
20060009305 Lindsay Jan 2006 A1
20060052177 Nakahara et al. Mar 2006 A1
20060073910 Imamoto et al. Apr 2006 A1
20060084525 Imamoto et al. Apr 2006 A1
20060094535 Cameron May 2006 A1
20060116218 Burnett et al. Jun 2006 A1
20060281581 Yamamoto Dec 2006 A1
20070026961 Hou Feb 2007 A1
20070049416 Shear Mar 2007 A1
20070082751 Lo et al. Apr 2007 A1
20070099726 Rife May 2007 A1
20070117648 Yokota May 2007 A1
20070155534 Tsai et al. Jul 2007 A1
20070238551 Yokota Oct 2007 A1
20070275792 Horacek et al. Nov 2007 A1
20070281796 Gilbert et al. Dec 2007 A1
20080171612 Serrano et al. Jul 2008 A1
20080182681 Yokota Jul 2008 A1
20080261715 Carter Oct 2008 A1
20080268980 Breier et al. Oct 2008 A1
20080268981 Evans Oct 2008 A1
20090069114 Foster et al. Mar 2009 A1
20090082135 Evans et al. Mar 2009 A1
20090181789 Reed Jul 2009 A1
20090286622 Yokota Nov 2009 A1
20100029404 Shear Feb 2010 A1
20100113176 Boyd et al. May 2010 A1
20100248860 Guerrette Sep 2010 A1
20110021284 Stites et al. Jan 2011 A1
20110151997 Shear Jun 2011 A1
20110218053 Tang et al. Sep 2011 A1
20110294599 Albertsen Dec 2011 A1
20120083362 Albertsen Apr 2012 A1
20120083363 Albertsen Apr 2012 A1
20120135821 Boyd et al. May 2012 A1
20120142452 Burnett Jun 2012 A1
20120244960 Tang et al. Sep 2012 A1
20120270676 Burnett et al. Oct 2012 A1
20120277029 Albertsen Nov 2012 A1
20120277030 Albertsen Nov 2012 A1
20120289361 Beach et al. Nov 2012 A1
20130184100 Burnett et al. Jul 2013 A1
20130210542 Harbert et al. Aug 2013 A1
20130316848 Burnett Nov 2013 A1
Foreign Referenced Citations (110)
Number Date Country
2436182 Jun 2001 CN
201353407 Dec 2009 CN
9012884 Sep 1990 DE
0470488 Feb 1992 EP
0617987 Nov 1997 EP
1001175 May 2000 EP
194823 Dec 1921 GB
57-157374 Oct 1982 JP
01091876 Apr 1989 JP
03049777 Mar 1991 JP
03151988 Jun 1991 JP
4180778 Jun 1992 JP
H05317465 Dec 1993 JP
H06126004 May 1994 JP
06182004 Jul 1994 JP
H06238022 Aug 1994 JP
06285186 Oct 1994 JP
H06304271 Nov 1994 JP
08117365 May 1996 JP
H09028844 Feb 1997 JP
3035480 Mar 1997 JP
H09308717 Dec 1997 JP
H09327534 Dec 1997 JP
H10192453 Jul 1998 JP
H10234902 Sep 1998 JP
H10277187 Oct 1998 JP
H11114102 Apr 1999 JP
11-155982 Jun 1999 JP
2000167089 Jun 2000 JP
2000288131 Oct 2000 JP
2000296192 Oct 2000 JP
2000300701 Oct 2000 JP
2000342721 Dec 2000 JP
2000014841 Jan 2001 JP
2001054595 Feb 2001 JP
2001129130 May 2001 JP
2001170225 Jun 2001 JP
2001204856 Jul 2001 JP
2001231888 Aug 2001 JP
2001346918 Dec 2001 JP
2002003969 Jan 2002 JP
2002017910 Jan 2002 JP
2002052099 Feb 2002 JP
2002052099 Feb 2002 JP
2002052100 Feb 2002 JP
2002136625 May 2002 JP
2002248183 Sep 2002 JP
2002253706 Sep 2002 JP
2003038691 Feb 2003 JP
2003052866 Feb 2003 JP
2003093554 Apr 2003 JP
2003093554 Apr 2003 JP
2003126311 May 2003 JP
2003210621 Jul 2003 JP
2003226952 Aug 2003 JP
2003524487 Aug 2003 JP
2004008409 Jan 2004 JP
2004113370 Apr 2004 JP
2004174224 Jun 2004 JP
2004174224 Jun 2004 JP
2004183058 Jul 2004 JP
2004222911 Aug 2004 JP
2004232397 Aug 2004 JP
2004261451 Sep 2004 JP
2004265992 Sep 2004 JP
2004267438 Sep 2004 JP
2004271516 Sep 2004 JP
2004275700 Oct 2004 JP
2004313762 Nov 2004 JP
2004313762 Nov 2004 JP
2004-351054 Dec 2004 JP
2004351173 Dec 2004 JP
2004351173 Dec 2004 JP
2005028170 Feb 2005 JP
2005073736 Mar 2005 JP
2005111172 Apr 2005 JP
2005137494 Jun 2005 JP
2005137788 Jun 2005 JP
2005137940 Jun 2005 JP
2005193069 Jul 2005 JP
2005193069 Jul 2005 JP
2005296458 Oct 2005 JP
2005296582 Oct 2005 JP
2005323978 Nov 2005 JP
3819409 Sep 2006 JP
2006320493 Nov 2006 JP
2007136069 Jun 2007 JP
2007136069 Jun 2007 JP
3996539 Oct 2007 JP
4046511 Feb 2008 JP
4047682 Feb 2008 JP
4128970 Jul 2008 JP
2009000281 Jan 2009 JP
2009000292 Jan 2009 JP
2012526634 Nov 2012 JP
2013517894 May 2013 JP
2013255779 Dec 2013 JP
5404921 Feb 2014 JP
5625048 Nov 2014 JP
5653457 Jan 2015 JP
5827243 Dec 2015 JP
6072696 Feb 2017 JP
6096892 Mar 2017 JP
WO8802642 Apr 1988 WO
WO0166199 Sep 2001 WO
WO02062501 Aug 2002 WO
WO03061773 Jul 2003 WO
WO2004043549 May 2004 WO
WO2005009543 Feb 2005 WO
WO2006044631 Apr 2006 WO
Non-Patent Literature Citations (27)
Entry
Office action from the U.S Patent and Trademark office in the U.S. Appl. No. 13/401,690, dated May 23, 2012.
Adams Golf Speedline F11 Ti 14.5 degree fairway wood (www.bombsquadgolf.com, posted Oct. 18, 2010).
Callaway Golf, World's Straightest Driver: FT-i Driver downloaded from www.callawaygolf.com/ft%2Di/driver.aspx?lang=en on Apr. 5, 2007.
Jackson,Jeff, The Modern Guide to Golf Clubmaking, Ohio: Dynacraft Golf Products, Inc., copyright 1994, p. 237.
Nike Golf, Sasquatch 460, downloaded from www.nike.com/nikegolf/index.htm on Apr. 5, 2007.
Nike Golf, Sasquatch Sumo Squared Driver, downloaded from www.nike.com/nikegolf/index.htm on Apr. 5, 2007.
Office action from the U.S. Patent and Trademark office in the U.S. Appl. No. 12/781,727, dated Aug. 5, 2010.
Taylor Made Golf Company, Inc. Press Release, Burner Fairway Wood, www.tmag.com/media/pressreleases/2007/011807_burner_fairway_rescue.html, Jan. 26, 2007.
Taylor Made Golf Company Inc., R7 460 Drivers, downloaded from www.taylormadegolf.com/product_detail.asp?pID=14section=overview on Apr. 5, 2007.
Titleist 907D1, downloaded from www.tees2greens.com/forum/Uploads/Images/7ade3521-192b-4611-870b-395d.jpg on Feb. 1, 2007.
“Cleveland HiBore Driver Review,” http//thesandtrip.com, 7 pages, May 19, 2006.
“Invalidity Search Report for Japanese Registered Patent No. 4128970,” 4 pp (Nov. 29, 2013).
Office action from the U.S. Patent and Trademark Office in U.S. Appl. No. 13/401,690, dated Feb. 6, 2013.
Office action from the U.S. Patent and Trademark Office in U.S. Appl. No. 13/469,023, dated Jul. 31, 2012.
Office action from the U.S. Patent and Trademark Office in U.S. Appl. No. 13/338,197, dated Jun. 5, 2014.
Office action from the U.S. Patent and Trademark Office in U.S. Appl. No. 13/828,675, dated Jun. 30, 2014.
Restriction Requirement from the U.S. Patent and Trademark Office in U.S. Appl. No. 13/469,031, dated Jun. 5, 2014.
Mike Stachura, “The Hot List”, Golf Digest Magazine, Feb. 2004, pp. 82-86.
Mike Stachura, “The Hot List”, Golf Digest Magazine, Feb. 2005, pp. 120-130.
Mike Stachura, “The Hot List”, Golf Digest Magazine, Feb. 2005, pp. 131-143.
Mike Stachura, “The Hot List”, Golf Digest Magazine, Feb. 2006, pp. 122-132.
Mike Stachura, “The Hot List”, Golf Digest Magazine, Feb. 2006, pp. 133-143.
Mike Stachura, “The Hot List”, Golf Digest Magazine, Feb. 2007, pp. 130-151.
“The Hot List”, Golf Digest Magazine, Feb. 2008, pp. 114-139.
Mike Stachura, Stina Sternberg, “Editor's Choices and Gold Medal Drivers”, Golf Digest Magazine, Feb. 2010, pp. 95-109.
The Hot List, Golf Digest Magazine, Feb. 2009, pp. 101-127.
International Searching Authority (USPTO), International Search Report and Written Opinion for International Application No. PCT/US2011/038150, dated Sep. 16, 2011, 13 pages.
Related Publications (1)
Number Date Country
20210316195 A1 Oct 2021 US
Continuations (7)
Number Date Country
Parent 16786430 Feb 2020 US
Child 17355277 US
Parent 16366481 Mar 2019 US
Child 16786430 US
Parent 15957961 Apr 2018 US
Child 16366481 US
Parent 15437835 Feb 2017 US
Child 15957961 US
Parent 14868446 Sep 2015 US
Child 15437835 US
Parent 14472415 Aug 2014 US
Child 14868446 US
Parent 13397122 Feb 2012 US
Child 14472415 US
Continuation in Parts (1)
Number Date Country
Parent 12791025 Jun 2010 US
Child 13397122 US