GOLF CLUB

TECHNICAL FIELD

This disclosure relates to golf clubs. More specifically, this disclosure relates to golf club alignment.

SUMMARY

Aspects of the invention are directed to golf club heads including a body having a face, a crown and a sole together defining an interior cavity, the golf club body including a heel and a toe portion and having x, y and z axes which are orthogonal to each other having their origin at USGA center face and wherein the golf club head has a primary alignment feature comprising a paint or masking line which delineates the transition between at least a first portion of the crown having an area of contrasting shade or color with the shade or color of the face.

In some embodiments the golf club head includes a body having a face, a sole and a crown, the crown having a first portion having a first color or shade and a second portion having a second color or shade, the face crown and sole together defining an interior cavity, the golf club body including a heel and a toe portion and having x, y and z axes which are orthogonal to each other having their origin at USGA center face and wherein the golf club head has a primary alignment feature comprising a paint or masking line which delineates the transition between at least a first portion of the crown having an area of contrasting shade or color and the area of shade or color of the face, and the club head also includes a secondary alignment feature including a paint or masking line which delineates the transition between the first portion of the crown having an area of contrasting shade or color with the shade or color of the face; and a second portion of the crown having an area of contrasting shade or color with the shade or color of the first portion, the secondary alignment feature comprising a first elongate side having a length of from about 0.5 inches to about 1.7 inches, and a second and third elongate side extending back from the face and rearward from and at an angle to the first elongate side.

In some embodiments the golf club heads have a body having a face, a crown and a sole together defining an interior cavity, the golf club body also includes a heel and a toe portion and a portion of the crown comprises an electronic display, wherein the electronic display includes an organic light-emitting diode (OLED) display for providing active color and wherein the OLED display is divided into independently operating electronic display zones.

In some examples, golf club heads comprise a crown having at least an upward facing surface portion provided with a diffused surface treatment as viewed from an address orientation, wherein the diffused surface treatment defines a highest reflected intensity location on the crown in response to illumination from a light source situated within a cone of angular radius of about 30 degrees above the crown and a secondary location situated on the crown at a distance of at least 20% of a crown effective length from the highest reflected intensity location having a reflected intensity of at least 25% of the highest reflected intensity. The golf club head also includes a striking surface situated so as to define an interface with the crown. In some embodiments, the crown effective length is selected from a plurality of pixel radii having a 30 degree angular spacing and radiating from the highest reflected intensity location to an edge of the crown. In other examples, the crown effective length is associated with a toe-to-heel direction, a direction perpendicular thereto, or an angle that is an integer multiple of 5 degrees with respect to the toe-to-heel direction. In still other examples, a zone of crown intensity is defined from the crown effective length in a direction of 30 degrees and negative 30 degrees from the crown effective length orientation, wherein the reflected intensity is at least 20% of the highest reflected intensity within a distance of at least 20%, 40%, or 60% of the crown effective length from the highest reflected intensity location. In representative examples, the secondary location is situated on the crown at a distance of at least 30%, 40%, 50%, or 60% of the crown effective length from the highest reflected intensity location.

In some example embodiments, a plurality of secondary locations are situated on the crown at distances of at least 50% of the crown effective length along a respective plurality of pixel radii situated at angles of at least 30 degrees with respect to each other such that the secondary locations are situated on the crown a distance of at least 50% of a respective pixel radius and are associated with reflected intensities of at least 50% of the highest reflected intensity. In some particular examples, the secondary locations are situated on the crown a distance of at least 75% of the respective pixel radii and are associated with reflected intensities of at least 70% of the highest reflected intensity. In other representative examples, the diffused surface treatment is a white surface treatment associated with a gloss value of less than about 60.

In some embodiments, a transparent matte coating is situated on at least the upward facing portion of the crown, wherein the transparent matte surface is a semigloss or low gloss surface. In typical examples, the transparent matte coating has a gloss value of less than 60 gloss units. In other examples, at least the upward facing portion of the crown surface has a chroma value of less than 5 and at least a top portion of the face surface adjacent the crown has a black surface treatment. In representative examples, at least the top portion of the face surface has a gloss value of less than 50 gloss units, or the black surface treatment has a chroma of less than one and a brightness of less than 50. In additional examples, the face surface has a black surface treatment having a chroma of less than 1.0 and a brightness of less than 50, and at least the upward facing portion of the crown surface has a chroma value of less than 5 and a brightness greater than 85.

Metal wood-type golf club heads include a body comprising a face plate positioned at a forward portion of the golf club head, a sole positioned at a bottom portion of the golf club head, a crown positioned at a top portion of the golf club head and a skirt positioned around a periphery of the golf club head between the sole and the crown. The head has a golf club head origin positioned on the face plate at an approximate geometric center of the face plate, the head origin including an x-axis tangential to the face plate and generally parallel to the ground when the head is in an address position, a y-axis generally perpendicular to the x-axis and generally parallel to the ground when the head is in an address position, and a z-axis generally perpendicular to the x-axis and to the y-axis and generally perpendicular to the ground when the head is in an address position. A positive x-axis extends toward a club head heel, a positive y-axis extends toward the cavity, and a positive z-axis extends away from the ground with the head in the address position. At least a perimeter portion of the crown adjacent a top portion of the faceplate and having an area that is at least 5% of the crown area has a bright, diffusely reflecting surface, and at least a top perimeter portion of the face plate has a dark diffusely reflecting surface area. In some embodiments, the bright, diffusely reflecting portion of the crown is white and includes at least the upper facing portion of the crown, and the face plate surface is a dark diffusely reflecting surface. In other examples, the bright, diffusely reflecting portion of the crown has a chroma value of less than 5, and the face plate surface has a chroma value of less than 1. In additional representative examples, the bright, diffusely reflecting portion of the crown has a brightness of at least 80.

In some examples, at least a portion of the crown adjacent a top perimeter of the face plate has a semigloss surface with a chroma value of less than 10 and a brightness of at least 50. In other examples, the bright diffusely reflecting surface extends over at least 80% of the upward facing crown area or the crown surface has a CIELab brightness of between 50 and 100, and a gloss value of less than 60 gloss units. In still further examples, the dark, diffusively reflecting face plate surface area has a CIELab brightness of less than 40 and a chroma of less than 10 or the face plate has a gloss value of less than 60 gloss units. In other examples, a difference in L* values between the crown and the face is high contrast for more than about 14.3%, 28.6%, 42.9%, 57.1%, 71.4%, or 85.7% of the face distance.

Putter heads comprise a crown having at least an upward facing surface portion provided with a white diffusing surface treatment as viewed from an address orientation, and a striking face that includes a dark surface portion. In some examples, the crown has a CIELab L* value of between 50 and 100, a chroma of less than 2, a hue of between 235 degrees and 270 degrees. The white diffusing surface treatment extends over at least 90% of the upward facing surface portion and has a gloss that is less than 60 gloss units. In other examples, the crown has a CIELab L* value of between 64 and 93, a chroma of less than 4, and the white diffusing surface treatment extends over at least 80% of the upward facing surface portion and is a semigloss surface treatment. In still further embodiments, the crown has a CIELab L* value of between 88 and 93, a chroma of between 3 and 4, a hue between 215 and 235, and the white diffusing surface treatment extends over at least 60% of the upward facing surface portion and is a semigloss surface treatment.

In other embodiments, golf club heads comprise a crown having at least an upward facing surface portion provided with a diffused surface treatment as viewed from an address orientation, wherein the white surface treatment defines a highest reflected intensity location on the crown in response to illumination from a light source situated within a cone of angular radius of about 30 degrees above the crown. A secondary location situated on the crown a distance of at least 50% of a crown effective length from the highest reflected intensity location has a reflected intensity of at least 25% of the highest reflected intensity. A striking surface is situated so as to define an interface with the crown. In some examples, the secondary location is situated on the crown a distance of at least 20%, 30%, 40%, 60%, 75%, or 85% of the crown effective length from the highest reflected intensity location, and has a reflected intensity of at least 50% or 70% of the highest reflected intensity.

In some examples, a plurality of secondary locations are situated on the crown at distances of at least 50% of a pixel radius along a respective plurality of pixel radii situated at angles of at least 30 degrees with respect to each other such that the secondary locations are situated on the crown a distance of at least 50% of a respective crown effective length from the highest intensity location and are associated with reflected intensities of at least 50% of the highest reflected intensity. In some examples, the white surface treatment defines a semigloss surface that is associated with a gloss value of less than about 60 or 40.

In additional examples, a transparent matte coating is situated on at least the upward facing portion of the crown, wherein the transparent matte surface is a semigloss or low gloss surface, having a gloss value of less than 60 gloss units. In some alternatives, at least the upward facing portion of the crown surface has a chroma value of less than 5 or less than 2. In still other examples, at least a top portion of the face surface adjacent the crown has a black surface treatment that is a semigloss or low gloss surface. In some examples, the face surface has a gloss value of less than 60, 50, or 40 gloss units. In particular examples, the black surface treatment has a chroma of less than 1 or 0.9 and a brightness of less than 50 or 30. In some embodiments, the face surface has a black surface treatment having a chroma of less than 1.0 and a brightness of less than 50, and at least the upward facing portion of the crown surface has a chroma value of less than 5 and a brightness greater than 85.

In some examples, metal wood-type golf club heads comprise a body comprising a face plate positioned at a forward portion of the golf club head, a sole positioned at a bottom portion of the golf club head, a crown positioned at a top portion of the golf club head and a skirt positioned around a periphery of the golf club head between the sole and the crown. The head has a golf club head origin positioned on the face plate at an approximate geometric center of the face plate. The head origin includes an x-axis tangential to the face plate and generally parallel to the ground when the head is in an address position, a y-axis generally perpendicular to the x-axis and generally parallel to the ground when the head is in an address position, and a z-axis generally perpendicular to the x-axis and to the y-axis and generally perpendicular to the ground when the head is in an address position, wherein a positive x-axis extends toward a club head heel, a positive y-axis extends toward the cavity, and a positive z-axis extends away from the ground with the head in the address position. At least a perimeter portion of the crown adjacent a top portion of the faceplate and having an area that is at least 5% of the crown area has a bright, diffusely reflecting white surface, and at least a top perimeter portion of the face plate has a dark diffusely reflecting surface area. In other examples, the face plate comprises a plurality of scorelines, wherein the scorelines include a diffusely reflecting surface area that has an intermediate value of reflectance between that of the bright, diffusely reflecting portion of the crown and the dark portion of the face plate. In other embodiments, the bright, diffusely white reflecting portion of the crown includes at least the upper facing portion of the crown, and the face plate surface is a dark diffusely reflecting surface. In representative implementations, the bright, diffusely reflecting portion of the crown has a chroma value of less than 5, and the face plate surface has a chroma value of less than 1. In still further examples, the bright, diffusely reflecting white portion of the crown has a brightness of at least 80 and less than 100. Typically, at least a portion of the crown adjacent a top perimeter of the face plate has a semigloss surface with a chroma value of less than 10 and a brightness of at least 50.

In some example embodiments, least a portion of the crown adjacent a top perimeter of the face plate has a semigloss surface with a chroma value of less than 6 and a lightness of at least 75 or at least a portion of the crown adjacent a top perimeter of the face plate has a semigloss surface with a chroma value of less than 4 and a lightness of at least 90. In at least some embodiments, the bright diffusely reflecting surface extends over at least 80% of the upward facing crown area. In other examples, the crown surface has a CIELab brightness of between 50 and 100, and a gloss value of less than 60 gloss units. In typical examples, the dark, diffusively reflecting face plate surface area has a CIELab brightness of less than 30 or 40, a chroma of less than 5 or 10, and a gloss value of less than 60 gloss units.

Putter heads comprise a crown having at least an upward facing surface portion provided with a white diffusing surface treatment as viewed from an address orientation. A central alignment index is situated on the crown and extends so as to be perpendicular to a striking surface, the central alignment index provided with a black diffusing surface treatment. At least one aperture is defined in a club body and situated behind the striking surface as viewed from the address orientation, wherein the aperture is symmetrically situated with respect to the central alignment index. In some examples, the white diffusing surface treatment has a gloss of less than 60 gloss units, and a CIE hue value that is between 250 degrees and 320 degrees. In other examples, the white diffusing surface treatment extends over at least 85% of the upward facing surface portion and the central alignment index comprises a groove extending to the striking surface and the black diffusing surface is situated within the groove. In additional examples, a dark striking surface is provided having a CIE L* values of less than 50.

In some embodiments the golf club heads have a body having a face, a crown and a sole together defining an interior cavity, the golf club body also includes a heel and a toe portion and a portion of the crown or a layer covering at least a portion of the crown of the golf club head is covered by a dielectric coating system.

BRIEF DESCRIPTION OF THE DRAWINGS

The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Patent and Trademark Office upon request and payment of the necessary fee. The features and components of the following figures are illustrated to emphasize the general principles of the present disclosure. Corresponding features and components throughout the figures may be designated by matching reference characters for the sake of consistency and clarity.

FIG. 1A is a toe side view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 1B is a face side view of the golf club head of FIG. 1A.

FIG. 1C is perspective view of the golf club head of FIG. 1A.

FIG. 1D is a top view of the golf club head of FIG. 1A.

FIG. 2 is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 3 is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 4 is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 5 is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 6 is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 7 is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 8A is a front view of the apparatus used for measuring a Sight Adjusted Perceived Face Angle in accordance with the current disclosure.

FIG. 8B is a close up view of the arrangement of the laser and cameras in the apparatus used for measuring a Sight Adjusted Perceived Face Angle in accordance with the current disclosure.

FIG. 8C is a side view of a golf club head fixture in apparatus used for measuring a Sight Adjusted Perceived Face Angle in accordance with the current disclosure.

FIG. 9 is a graph of the Sight Adjusted Perceived Face Angle vs. the Dispersion in Ball Flight for four clubs having the alignment features in accordance with the current disclosure.

FIG. 10A is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 10B is a top view of a golf club head in accord with one embodiment of the current disclosure.

FIG. 11 is a reference to the CIELAB color system.

FIG. 12A is a perspective view of a mallet-type high visibility putter, as viewed from the rear, one side.

FIG. 12B is a top plan view of the putter head of FIG. 1A.

FIG. 12C is a bottom plan view of the putter head of FIG. 1A.

FIG. 12D is a front elevational view of the putter head of FIG. 1A.

FIG. 12E is a back elevational view of the putter head of FIG. 1A.

FIG. 13A is a top plan view of a one example of a high visibility putter head.

FIG. 13B is a front elevational view of the putter head of FIG. 2A.

FIG. 14A is a front elevational view of a golf club head in accordance with one embodiment.

FIG. 14B is a side elevational view of the golf club head of FIG. 3A.

FIG. 14C is a top plan view of the golf club head of FIG. 3A.

FIG. 14D is a side elevational view of the golf club head of FIG. 3A.

FIG. 15A is a view of a driver-type golf club head according to a representative embodiment.

FIG. 15B is a view of a driver-type golf club head according to a representative embodiment.

FIG. 15C is a view of a driver-type golf club head according to a representative embodiment.

FIG. 15D is a view of a driver-type golf club head according to a representative embodiment.

FIG. 15E is a view of a driver-type golf club head according to a representative embodiment.

FIG. 16 is a perspective view of a wood-type golf club as viewed from a top, one side, according to a representative embodiment.

FIG. 17 is a top plan view of a crown of a golf club head according to an additional embodiment.

FIG. 18 is a graph illustrating relative reflected intensity across a crown of a driver type golf club head for club heads with black glossy, black matte, and white matte finishes.

FIG. 19 is a top plan view of one embodiment of an iron type golf club head at normal address position.

FIG. 20A illustrates a representative system for measuring club head surface reflectance for putter type clubs.

FIG. 20B illustrates a representative system for measuring club head surface reflectance for metalwood type clubs.

FIG. 21 is graph illustrating measured crown surface brightness along a plurality of pixel radii spaced at 30 degrees for a conventional glossy black driver crown.

FIG. 22 illustrates selected equal intensity contours for the club head associated with FIG. 10 and further illustrating pixel radii along which surface brightness is graphed.

FIG. 23 is a graph illustrating measured crown surface brightness along a plurality of pixel radii spaced at 30 degrees for a matte black driver crown.

FIG. 24 illustrates selected equal intensity contours for the club head associated with FIG. 12.

FIG. 25 is a graph illustrating measured crown surface brightness along a plurality of pixel radii spaced at 30 degrees for a contrast enhanced white driver crown.

FIG. 26 illustrates selected equal intensity contours for the club head associated with FIG. 14.

FIG. 27 is a graph illustrating measured crown surface brightness along a plurality of pixel radii spaced at 30 degrees for a conventional non-black driver crown.

FIG. 28 is a graph illustrating measured crown surface brightness along a plurality of pixel radii spaced at 30 degrees for a non-black metal type fairway wood crown.

FIG. 29 is a graph illustrating measured crown surface brightness along a plurality of pixel radii spaced at 30 degrees for a polymer driver crown.

FIG. 30 illustrates selected equal intensity contours for the club head associated with FIG. 29.

FIG. 31 is a graph illustrating measured top surface brightness along a plurality of pixel radii spaced at 30 degrees for another conventional driver.

FIG. 32 is a graph summarizing measured top surface brightness along a 0 degree radius for a plurality of club heads.

FIG. 33 is an elevational view of a representative contrast-enhanced wood-type club head.

FIG. 34 is a graph illustrating measured top surface brightness along pixel radii at 120 degrees and 270 degrees for a putter head having a matte clear coat over a metallic surface.

FIG. 35 is a graph illustrating measured top surface brightness along pixel radii at 120 degrees and 300 degrees for a putter head having a diffusing white top surface.

FIG. 36 illustrates selected equal intensity contours for the putter head associated with FIG. 35.

FIG. 37 is a graph illustrating measured top surface brightness along pixel radii at 120 degrees and 300 degrees for a putter head having a diffusing white top surface.

FIG. 38 is a graph illustrating measured top surface brightness along pixel radii at 120 degrees and 270 degrees for a conventional putter head.

FIG. 39 illustrates selected equal intensity contours for the putter head associated with FIG. 29.

FIG. 40 is a graph illustrating measured surface brightness along a radius at 270 degrees for a conventional putter head.

DETAILED DESCRIPTION

Disclosed are various golf clubs as well as golf club heads including alignment features along with associated methods, systems, devices, and various apparatus. It would be understood by one of skill in the art that the disclosed golf clubs and golf club heads are described in but a few exemplary embodiments among many. No particular terminology or description should be considered limiting on the disclosure or the scope of any claims issuing therefrom.

The sport of golf is fraught with many challenges. Enjoyment of the game is increased by addressing the need to hit the golf ball further, straighter, and with more skill. As one progresses in golfing ability, the ability to compete at golf becomes a source of enjoyment. However, one does not simply hit a golf ball straighter or further by mere desire. Like most things, skill is increased with practice—be it repetition or instruction—so that certain elements of the game become easier over time. But it may also be possible to improve one's level of play through technology.

Much technological progress in the past several decades of golf club design has emphasized the ability to hit the golf ball further. Some of these developments include increased coefficient of restitution (COR), larger golf club heads, lighter golf club heads, graphite shafts for faster club speed, and center of gravity manipulation to improve spin characteristics, among others. Other developments have addressed a golfer's variability from shot-to-shot, including larger golf club heads, higher moment of inertia (MOI), variable face thickness to increase COR for off-center shots, and more. Still further developments address a golfer's consistent miss-hits—of which the most common miss-hit is a slice-including flight control technology (FCT, such as loft and lie connection sleeves to adjust, inter alia, face angle), moveable weights, sliding weight technologies, and adjustable sole pieces (ASP). Such technologies aid golfers in fixing a consistent miss, such that a particular error can be addressed.

As such, modern technology has done much to improve the golfer's experience and to tailor the golf club to the needs of the particular player. However, some methods are more effective than others at achieving the desired playing results. For example, research suggests that—for a drive of about 280 yards—a 1° difference in face angle at impact may account for about 16 yards of lateral dispersion in the resultant shot. Similarly, for moveable weights, changes in balance of weight by 12 grams moving for about 50 mm may result in about 15 yards of lateral dispersion on the resultant shot. However, it is also understood that a change in lie angle of the golf club head affects the face angle, but at a much smaller degree. As such, simply by increasing lie angle by 1°, the face angle alignment of the golf club head may be adjusted by 0.1° open or closed. As such, for better players who are simply trying to tune their ball flight, adjusting lie angle may be much more finely tunable than adjusting face angle. However, for many golfers, slicing (a rightward-curving shot for a right-handed golfer, as understood in the art) is the primary miss, and correction of such shot is paramount to enjoyment of the game.

One of the major challenges in the game of golf involves the difference between perception and reality. Golf includes psychological challenges—as the player's confidence wanes, his or her ability to perform particular shots often wanes as well. Similarly, a player's perception of his or her own swing or game may be drastically different from the reality. Some technology may address the player's perception and help aid in understanding the misconceptions. For example, technology disclosed in U.S. Pat. No. 8,771,095 to Beach, et. al, entitled “CONTRAST-ENHANCED GOLF CLUB HEADS,” filed Mar. 18, 2011, provides a player with a clearer understanding of his or her alignment than some of the preexisting art at the time, which may improve that player's ability to repeat his or her shots. However, it may be more helpful to provide those players a method to address the misconceptions and provide correction for them.

We have now surprisingly found that alignment features that includes all or a portion of the interface region between the areas of contrasting shade or color on the crown of the club head and the face of the club head and/or all or a portion of the interface region between areas of contrasting shade or color on different portions on the crown of the club head allows for improved performance in the resulting clubs by accounting for not only the actual alignment of the club head by the golfer during the shot but also as modified by the perceived alignment of the club head by the golfer. One example of a combination of contrasting colors or shades would be for example a black or metallic grey or silver color contrasting with white, but also included are other combinations which provide at a minimum a “just noticeable difference” to the human eye.

Although a “just noticeable difference” in terms of colors of a golf club head is to a degree somewhat subjective based on an individual's visual acuity, it can be quantified with reference to the CIELAB color system, a three dimensional system which defines a color space with respect to three channels or scales, one scale or axis for Luminance (lightness) (L) an “a” axis which extends from green (−a) to red (+a) and a “b” axis from blue (−b) to yellow (+b). This three dimensional axis is illustrated in FIG. 11.

A color difference between two colors can then be quantified using the following formula;

ΔE_ab*=√{square root over ((L₂*−L₁*)²+(α₂*−α₁*)²+(b₂*−b₁*)²|)}

where

(L*₁, a*₁and b*₁) and (L*₂, a*₂and b*₂) represents two colors in the L,a,b space and where

ΔE*_ab=2.3 sets the threshold for the “just noticeable difference” under illuminant conditions using the reference illuminant D65 (similar to outside day lighting) as described in CIE 15.2-1986.

Thus, for the alignment features of the golf clubs of the present invention, a contrasting color difference, ΔE*_ab, is greater than 2.3, preferably greater than 10, more preferably greater than 20, even more preferably greater than 40 and even more preferably greater than 60.

For general reference, a golf club head 100 is seen with reference to FIGS. 1A-1D. One embodiment of a golf club head 100 is disclosed and described with reference to FIGS. 1A-1D. As seen in FIG. 1A, the golf club head 100 includes a face 110, a crown 120, a sole 130, a skirt 140, and a hosel 150. Major portions of the golf club head 100 not including the face 110 are considered to be the golf club body for the purposes of this disclosure.

The metal wood club head 100 has a volume, typically measured in cubic-centimeters (cm³), equal to the volumetric displacement of the club head 100, assuming any apertures are sealed by a substantially planar surface. (See United States Golf Association “Procedure for Measuring the Club Head Size of Wood Clubs,” Revision 1.0, Nov. 21, 2003). In other words, for a golf club head with one or more weight ports within the head, it is assumed that the weight ports are either not present or are “covered” by regular, imaginary surfaces, such that the club head volume is not affected by the presence or absence of ports. In several embodiments, a golf club head of the present application can be configured to have a head volume between about 110 cm³and about 600 cm³. In more particular embodiments, the head volume is between about 250 cm³and about 500 cm³. In yet more specific embodiments, the head volume is between about 300 cm³and about 500 cm³, between 300 cm³and about 360 cm³, between about 360 cm³and about 420 cm³or between about 420 cm³and about 500 cm³.

In the case of a driver, the golf club head has a volume between approximately 300 cm³and approximately 460 ccm³, and a total mass between approximately 145 g and approximately 245 g. In the case of a fairway wood, the golf club head 10 has a volume between approximately 100 cm³and approximately 250 cm³, and a total mass between approximately 145 g and approximately 260 g. In the case of a utility or hybrid club the golf club head 10 has a volume between approximately 60 cm³and approximately 150 ccm³, and a total mass between approximately 145 g and approximately 280 g.

A three dimensional reference coordinate system 200 is shown. An origin 205 of the coordinate system 200 is located at the center of the face (CF) of the golf club head 100. See U.S.G.A. “Procedure for Measuring the Flexibility of a Golf Clubhead,” Revision 2.0, Mar. 25, 2005, for the methodology to measure the center of the striking face of a golf club. The coordinate system 200 includes a z-axis 206, a y-axis 207, and an x-axis 208 (shown in FIG. 1B). Each axis 206,207,208 is orthogonal to each other axis 206,207,208. The x-axis 208 is tangential to the face 110 and parallel to a ground plane (GP). The golf club head 100 includes a leading edge 170 and a trailing edge 180. For the purposes of this disclosure, the leading edge 170 is defined by a curve, the curve being defined by a series of forward most points, each forward most point being defined as the point on the golf club head 100 that is most forward as measured parallel to the y-axis 207 for any cross-section taken parallel to the plane formed by the y-axis 207 and the z-axis 206. The face 110 may include grooves or score lines in various embodiments. In various embodiments, the leading edge 170 may also be the edge at which the curvature of the particular section of the golf club head departs substantially from the roll and bulge radii.

As seen with reference to FIG. 1B, the x-axis 208 is parallel to the GP onto which the golf club head 100 may be properly soled-arranged so that the sole 130 is in contact with the GP in the desired arrangement of the golf club head 100. The y-axis 207 is also parallel to the GP and is orthogonal to the x-axis 208. The z-axis 206 is orthogonal to the x-axis 208, the y-axis 207, and the GP. The golf club head 100 includes a toe 185 and a heel 190. The golf club head 100 includes a shaft axis (SA) defined along an axis of the hosel 150. When assembled as a golf club, the golf club head 100 is connected to a golf club shaft (not shown). Typically, the golf club shaft is inserted into a shaft bore 245 defined in the hosel 150. As such, the arrangement of the SA with respect to the golf club head 100 can define how the golf club head 100 is used. The SA is aligned at an angle 198 with respect to the GP. The angle 198 is known in the art as the lie angle (LA) of the golf club head 100. A ground plane intersection point (GPIP) of the SA and the GP is shown for reference. In various embodiments, the GPIP may be used as a point of reference from which features of the golf club head 100 may be measured or referenced. As shown with reference to FIG. 1A, the SA is located away from the origin 205 such that the SA does not directly intersect the origin or any of the axes 206,207,208 in the current embodiment. In various embodiments, the SA may be arranged to intersect at least one axis 206,207,208 and/or the origin 205. A z-axis ground plane intersection point 212 can be seen as the point that the z-axis intersects the GP. The top view seen in FIG. 1D shows another view of the golf club head 100. The shaft bore 245 can be seen defined in the hosel 150.

Referring back to FIG. 1A, a crown height 162 is shown and measured as the height from the GP to the highest point of the crown 120 as measured parallel to the z-axis 206. The golf club head 100 also has an effective face height 163 that is a height of the face 110 as measured parallel to the z-axis 206. The effective face height 163 measures from a highest point on the face 110 to a lowest point on the face 110 proximate the leading edge 170. A transition exists between the crown 120 and the face 110 such that the highest point on the face 110 may be slightly variant from one embodiment to another. In the current embodiment, the highest point on the face 110 and the lowest point on the face 110 are points at which the curvature of the face 110 deviates substantially from a roll radius. In some embodiments, the deviation characterizing such point may be a 10% change in the radius of curvature. In various embodiments, the effective face height 163 may be 2-7 mm less than the crown height 162. In various embodiments, the effective face height 163 may be 2-12 mm less than the crown height 162. An effective face position height 164 is a height from the GP to the lowest point on the face 110 as measured in the direction of the z-axis 206. In various embodiments, the effective face position height 164 may be 2-6 mm. In various embodiments, the effect face position height 164 may be 0-10 mm. A distance 177 of the golf club head 100 as measured in the direction of the y-axis 207 is seen as well with reference to FIG. 1A. The distance 177 is a measurement of the length from the leading edge 170 to the trailing edge 180. The distance 177 may be dependent on the loft of the golf club head in various embodiments.

For the sake of the disclosure, portions and references disclosed above will remain consistent through the various embodiments of the disclosure unless modified. One of skill in the art would understand that references pertaining to one embodiment may be included with the various other embodiments.

As seen with reference to FIG. 2, a golf club head 500 includes a painted crown 120 and unpainted face 110. Painted or otherwise contrast-enabled crowns have been utilized as described in U.S. Pat. No. 8,771,095 to Beach, et. al, entitled “CONTRAST-ENHANCED GOLF CLUB HEADS,” filed Mar. 18, 2011, to provide golfers with aided alignment. Typically the golfer employs the crown to face transition or top-line to align the club with the desired direction of the target line. The top-line transition is clearly delineated by a masking line between the painted crown and the unpainted face. While such features may have been described to some degree, use of the features to bias alignment has not been conceived in the art. With the golf club head 500 of the current embodiment, one of skill in the art would understand that the high-contrast described in U.S. Pat. No. 8,771,095 to Beach, et. al, entitled “CONTRAST-ENHANCED GOLF CLUB HEADS,” filed Mar. 18, 2011, may be beneficial for emphasizing various alignment features. As such, the disclosure is incorporated by reference herein in its entirety.

For reference, a face angle tangent 505 is seen in FIG. 2. The face angle tangent 505 indicates a tangent line to the center face 205. The face angle tangent 505 in the current embodiment is coincident with the x-axis 206 (as seen with reference to prior FIGS.). Also seen in FIG. 2 is a top tangent 510. In the current embodiment, the top tangent 510 is a line made tangent to a top of the face 110 because, in the current embodiment, a joint between the face 110 and the crown 120 is coincident with paint lines. The top tangent 510 in the several embodiments of the current disclosure will follow the contours of various paint lines of the crown 120, and one of skill in the art would understand that the top tangent 510 need not necessarily be coincident with a tangent to the face 110. However, in the current embodiment, the top tangent 510 is parallel to the face angle tangent 505. As such, the paint of the crown 120 can be described as appearing square with the face angle.

The purpose of highlighting such features of the golf club head 500 is to provide a basis for the discussion of alignment with respect to the current disclosure. Through variations in alignment patterns, it may be possible to influence the golfer such that the golfer alters his or her play because of the appearance of misalignment. If a player perceives that the golf club head is such that the face is open with reference to the intended target, he or she would be more likely to try to “square up” the face by manually closing it. Many golfers prefer not to perceive a metal wood golf club head as appearing closed, as such an appearance is difficult to correct. However, even if such a player were to perceive the metal wood head as being closed, such perception does not mean that the golf club head is aligned in a closed position relative to the intended target.

As seen with reference to FIG. 3, a golf club head 600 includes similar head geometries to golf club head 500. However, the golf club head 600 includes a feature to alter the perceived angle of the face 110 for the user. In the current embodiment, a top tangent 610 that is aligned at an angle 615 with respect to the face angle tangent 505 such that the perceived angle of the face (Perceived Face Angle, PFA) is different from the actual alignment of the face angle tangent 505. In the current embodiment, the angle 615 is about 4°. In various embodiments, the angle 615 may be 2°-6°. In various embodiments, the angle 615 may be less than 7°. In various embodiments, the angle 615 may be 5-10°. In various embodiments, the angle 615 may be less than 12°. In various embodiments, the angle 615 may be up to 15°. As indicated with respect to top tangent 510, the top tangent 610 is an indicator of the alignment of an edge of an area of contrasting paint or shading of the crown 120 delineated by a masking line between the painted crown and the unpainted face relative to the color or shading of the face 110 and is the line that is tangent to an edge 614 of the contrasting crown paint or crown shading at a point 612 where the edge 614 intersects a line parallel to the y-axis 207.

In various embodiments, a perceived angle may be determined by finding a linear best-fit line of various points. For such approximation, a perceived angle tangent may be determined by best fitting points on the edge 614 at coordinates of the x-axis 208 that are coincident with center face 205—point 612—and at points±5 mm of CF 205 (points 622a,b), at points±10 mm of CF 205 (points 624a,b), at points±15 mm of CF 205 (points 626a,b), and at points±20 mm of CF 205 (points 628a,b). As such, nine points are defined along the edge 614 for best fit of the top tangent 610. In the current embodiment, the perceived angle tangent is the same as the top tangent 610.

However, such method for determining the perceived angle tangent may be most useful in cases where the edge 614 of an area of contrasting paint or shading of the crown 120 relative to the color or shading of the face 110 includes different radii of relief along the toe portion and the heel portion. In such an embodiment, a line that is tangent to the edge 614 at point 612 may not adequately represent the appearance of the alignment of the golf club head 600. Such an example can be seen with reference to FIG. 4.

As seen in FIG. 4, a golf club head 700 includes an edge 714 of an area of contrasting paint or shading of the crown 120 relative to the color or shading of the face 110 that is more aggressively rounded proximate the toe 185 than prior embodiments. As such, a line 711 that is literally tangent to the edge 714 at a point 712 that is coincident with the y-axis 207 may not adequately describe the perception. Such a line would be the top tangent 710. However as noted previously with reference to golf club head 600, points 712, 722a,b, 724a,b, 726a,b, and 728a,b, can be used to form a best fit line 730 that is aligned at a perceived angle 735 that is greater than an angle 715 of the top tangent 710. In various embodiments, the perceived angle 735 may be within the increments of angle 615, above, or may be up to 20° in various embodiments. In most embodiments, the perceived angle 735 may be 8-10°. In various embodiments, the perceived angle 735 may be 9-10°. In various embodiments, the perceived angle 735 may be 7-11°. In various embodiments, the perceived angle 735 may be 7-8.5°. In various embodiments, alignment may be influenced by the inclusion of an alignment feature that does not invoke an edge such as edges 614, 714. As seen with reference to FIG. 5, various embodiments of alignment features may be suggestive of the face angle and, as such, provide an appearance of alignment to the golfer without modifying paint lines.

A golf club head 800, as seen in FIG. 5, includes an alignment feature 805. The alignment feature 805 of the current embodiment includes at least one elongate side 807—and in the current embodiment, two elongate sides 807a and 807b are included. The alignment feature 805 of the current embodiment also includes two additional sides 808a and 808b. As can be seen, the alignment feature 805 is arranged such that the at least one elongate side 807 is aligned about parallel to the x-axis. As such, a golfer is able to use the alignment feature 805 by aligning the direction of the elongate side 807 in an orientation that is about perpendicular to the intended target. The alignment feature 805 has a length 847 as measured parallel to the x-axis 208. In the current embodiment, the length 847 is about the same as the diameter of a golf ball, or about 1.7 inches. However, in various embodiments, the length 847 may be 0.5 inches, 0.75 inches, 1 inch, 1.25 inches, 1.5 inches, 1.75 inches, 2 inches, 2.25 inches, 2.5 inches, or various lengths therein. If the length 847 of the dominant elongate side 807a or 807b is less than about 0.3 inches, the impact of the alignment feature 805 on biasing the golfer's perception decreases substantially.

However, with sufficient use, the alignment feature 805 can become the primary focus of the golfer's attention and, as such, modifications to the arrangement of the alignment feature 805 with respect to the x-axis 208 (which is coincident with the face angle tangent 505) may allow the golfer to bias his or her shots and thereby modify his or her outcome.

As seen with reference to FIG. 6, a golf club head 900 includes an alignment feature 905. The alignment feature 905 of the current embodiment includes one elongate side 907a on a side of the alignment feature 905 that is proximate the face 110. The alignment feature 905 includes several potential rear portions. Similar to golf club head 800, golf club head 900 includes the alignment feature 905 having a potential second elongate side 907b in one embodiment. In another embodiment, an extended rear portion 907c may also be included or may be included separately from elongate side 907b. In the current embodiment, the elongate side 907b is oriented at an angle 915 with respect to the face angle tangent 505.

For the embodiment including second elongate side 907b, the second elongate side 907b is about parallel to the elongate side 907a. As such, the embodiment is similar to golf club head 800 but is oriented at angle 915. With respect to extended rear portion 907c, the orientation of such an embodiment may appear less askew and, consequently, may be more effective at modifying the golfer's perception of the club's alignment. A perpendicular reference line 918 is seen as a reference for being orthogonal to the elongate side 907a. The perpendicular reference line 918 intersects the elongate side 907a at a point 919 that bisects the elongate side 907a. Further, the perpendicular reference line 918 intersects the x-axis 208 at an intersection point 921 that is heelward of the center face 205. In the current embodiment, the intersection point 921 is heelward of center face 205 by about 2 mm. In various embodiments, the intersection point 921 may be about the same as center face 205. In various embodiments, the intersection point 921 may be up to 2 mm heelward of center face 205. In various embodiments, the intersection point 921 may be up to 5 mm heelward of center face 205. In various embodiments, the intersection point 921 may be somewhat toeward of center face 205. In various embodiments, the intersection point 921 may be ±2 mm of the center face 205.

Another embodiment of a golf club head 1100, shown in FIG. 7, includes an alignment feature 1105. The alignment feature has a first elongate side 1107a and a second elongate side 1107b. In the current embodiment, however, the first elongate side 1107a is about parallel with the face angle tangent 505 and the x-axis 208. However, the second elongate side 1107b is oriented at an angle 1115 with respect to the face angle tangent 505 such that the golfer's perception of alignment may be altered.

A preferred method for measuring the perceived face angle observed by a golfer further takes into account the fact that most golfers have a dominant left eye and when they address the ball with the club head, a direct line between the left eye and center face would actually cross the topline heel ward of center face and thus this is where an alignment feature which includes an edge of an area of contrasting paint or shading of the crown 120 relative to the color or shading of the face 110 would exert the most effect on the golfer's perception of the face angle. This perceived face angle is thus called a Sight Adjusted Perceived Face Angle (SAPFA) and is measured using the apparatus shown in FIGS. 8A-8C.

The apparatus used is shown in FIGS. 8A, 8B and 8C and includes a frame 1203 which holds a fixture 1205 for holding and aligning a golf club shaft 1207 and attached golf club head 1209 at a Lie Angle of 45°. The face of the golf club head 1209 is also set at a face angle of 0° using a face angle gauge 1211. The face angle gauge may be any commonly used in the industry such as a De la Cruz face angle gauge). After setting the loft and lie angle the club is clamped in the fixture using a screw clamp 1213. The frame 1203 also includes an attachment point 1215 for mounting two cameras 1217 and 1219 and a Calpac Laser CP-TIM-230-9-1L-635 (Fine/Precise Red Line Laser Diode Module Class II: 1m W/635 nm), 1221. The center of the lens of camera 1219 is situated at the x, y and z coordinates (namely 766 mm, 149 mm, 1411 mm) using the previously defined x y and z axes with USGA center face (as measured using the procedure in U.S.G.A. “Procedure for Measuring the Flexibility of a Golf Clubhead,” Revision 2.0, Mar. 25, 2005, “USGA Center Face”) as the origin, and where a positive x coordinate represents a position heel ward of center face, a positive y coordinate represent a position rearward of center face and a positive z coordinate represents a position above center face. The laser is situated between the two cameras.

As shown in FIG. 8C the laser produces a line 1223 having an axis parallel to the camera axis and projecting along the y axis which is adjusted such that the line intersects USGA Center Face 1225. The point 1227 at which the line then intersects the edge of an area of contrasting paint or shading of the crown 120 relative to the color or shading of the face 110 which in this case corresponds to the white paint line of the crown 1229 is then physically marked on the paint line using a marker and acts a the datum or reference point. A camera is then activated to take an image of the club head including the datum or reference point 1227 and the paint line 1229.

The image from the camera is then analyzed using an image analyzer software package (which can be any of these known in the art able to import an image and can fit a line to the image using a curve fitting function). A best fit line to the paint line is then determined. For most embodiments the best fit to the paint line results from fitting the line to a quadratic equation of the form y=ax²+bx+c. Two points are then selected on this best fit line at arc length between +/−0.25 mm from the datum point. A straight line is then drawn between the two points and a line perpendicular to this line is then drawn through the datum. The Sight Adjusted Perceived Face Angle (SAPFA) is then measured as the angle between the perpendicular line and they axis.

Using this method the Sight Adjusted Perceived Face Angle (SAPFA) of the golf clubs of the present invention may be from −2 to 10, preferably from 0 to 6, more preferably from 0.5 to 4 even more preferably from 1 to 2.5 and most preferably from 1.5 to 2 degrees.

EXAMPLES

Four identical club heads were taken and the paint line edge of an area of contrasting paint or shading of the crown 120 relative to the color or shading of the face 110 was varied and the Sight Adjusted Perceived Face Angles (SAPFA) measured.

In addition to the Sight Adjusted Perceived Face Angles (SAPFA) four additional measurements were taken to describe the paint line edge alignment feature of the four clubs and these values are summarized in Table 1.

In addition to the SAPFA, three additional angles were measured at different points as measured from the datum along the best fit line to the paint line edge alignment feature determined as for the SAPFA. The first angle was obtained at a point along the best fit line at an arc length 25 mm heelward of the datum. Again as for the SAPFA measurement, two points at arc length between +/−0.25 mm from the 25 mm point were selected. A straight line is then drawn between these two points and a line perpendicular to this line is then drawn at the 25 mm point. The angle is then measured between this perpendicular line and they axis. This angle is reported as the Sight Adjusted Perceived Face Angle 25 mm Heelward (“SAPFA_25H”).

The second angle was obtained at a point along the best fit line at an arc length 25 mm toeward of the datum. Again as for the SAPFA measurement, two points at arc length between +/−0.25 mm from the 25 mm point were selected. A straight line is then drawn between the two points and a line perpendicular to this line is then drawn at the 25 mm point. The angle is then measured between this perpendicular line and the y axis. This angle is reported as the Sight Adjusted Perceived Face Angle 25 mm Toeward (“SAPFA_25T”).

In addition, to capture any effect of greater rounding of the paint line edge alignment feature towards the toe of the golf club head, a third angle was obtained at a point along the best fit line at an arc length 50 mm toeward of the datum. Again as for the SAPFA measurement, two points at arc length between +/−0.25 mm from the 25 mm point were selected. A straight line is then drawn between the two points and a line perpendicular to this line is then drawn at the 50 mm point. The angle is then measured between this perpendicular line and the y axis. This angle is reported as the Sight Adjusted Perceived Face Angle 50 mm Toeward (“SAPFA_25H”).

Finally, in an attempt to describe more of the paint line edge alignment feature, the image of the paint line edge alignment feature imported into the image analyzer as for the SAPFA measurement was also fit to a circle using the formula (x−a)²(y−b)²=r², and the radius of curvature of this circular fit line determined and reported in Table I as the Radius of Curvature (circle fit).

TABLE 1

Sight

Adjusted

Perceived
Radius of
Angle
Angle
Angle

Face Angle
Curvature
25 mm
25 mm
50 mm

Example
(SAPFA)
(circle
Heelward
Toeward
Toeward

No.
(degrees)
fit, mm)
(degrees)
(degrees)
(degrees)

1
3.5722
570.47
1.1377
5.9453
8.2757

2
5.2813
419.53
1.7509
8.6871
11.9168

3
0.2927
781.02
−1.4461
2.0189
3.7129

4
−0.5925
568.21
−3.06
1.8533
4.245

Each club was then hit between 6 to 12 times by 10 different players into a blank screen with no trajectory or other feedback available to the player, and a Trackman 3e launch monitor and the TPS software package were used to calculate the total dispersion from a center target line with a positive total dispersion indicating the number of yards right of the center target line and a negative total dispersion indicating the number of yards left of the center target line. Thus, a player who has a tendency to slice the ball i.e. produce a ball flight right of the target line would be assisted in producing a shot closer to the target line if the golf club tended to yield a more negative dispersion.

The graph in FIG. 9 plots the Sight Adjusted Perceived Face Angle (SAPFA) versus the average total dispersion of each club when hit 6-12 times by each player. The data show that adjustment of the edge of an area of contrasting paint or shading of the crown relative to the color or shading of the face such that the Sight Adjusted Perceived Face Angle (SAPFA) of the golf club goes from −0.88 degrees through 0.5 degrees through 3.34 degrees to 5.55 degrees results in an overall change in total dispersion from 8.6 yards to the right of the target line to 24.2 yards to the left of the target i.e. an absolute change in total dispersion of 32.8 yards from the same club head by solely manipulating the appearance of the paint line comprising the primary alignment feature.

The golf club heads of the present invention have a Sight Adjusted Perceived Face Angle (SAPFA) of from about −2 to about 10, preferably of from about 0 to about 6, more preferably of from about 0.5 to about 4 even more preferably of from about 1 to about 2.5 and most preferably of from about 1.5 to about 2 degrees.

The golf club heads of the present invention also have a Sight Adjusted Perceived Face Angle 25 mm Heelward (“SAPFA_25H”) of from about −5 to about 2, more preferably of from about −3 to 0, even more preferably of from about −2 to about −1 degrees.

The golf club heads of the present invention also have a Sight Adjusted Perceived Face Angle 25 mm Toeward (“SAPFA2sT”) of from 0 to about 9, more preferably of from about 1 to about 4.5, even more preferably of from about 2 to about 4 degrees.

The golf club heads of the present invention also have a Sight Adjusted Perceived Face Angle 50 mm Toeward (“SAPFA_50T”) of from about 2 to about 9, more preferably of from about 3.5 to about 8, even more preferably of from about 4 to about 7 degrees.

The golf club heads of the present invention also have a Radius of Curvature (circle fit) of from about 300 to about 1000, more preferably of from about 400 to about 900, even more preferably of from about 500 to about 775 mm.

In other embodiments, the golf club head in addition to having a first or primary alignment feature as described earlier with reference to FIGS. 1-4, may also have a second or secondary alignment feature including the alignment features as described earlier with reference to FIGS. 5, 6 and 7.

In an especially preferred embodiment, shown in FIG. 10A and FIG. 10B, the golf club head 1400 of the present invention can have a crown having a first portion having a first color or shade and a second portion having a second color or shade, and a primary alignment feature consisting of a an edge 1402 of an area of contrasting paint or shading of the first portion of the crown 120 relative to the color or shading of the face 110 as described earlier and illustrated in FIGS. 3 and 4. In addition the club head has a secondary alignment feature 1404 proximate the face but rearward of the primary alignment feature and delineated by a second paint or masking line which delineates the transition between the first portion of the crown having an area of contrasting shade or color with the shade or color of the face; and a second portion of the crown having an area of contrasting shade or color with the shade or color of the first portion. The secondary alignment feature a comprises an elongate side 1406 having a length of from about 0.5 inches to about 1.7 inches, and a second and third elongate side 1408a and 1408b extending back from the face and at an angle to elongate side 1406 and rearward of elongate side 1406.

The Sight Adjusted Perceived Face Angle Secondary Alignment Feature, (“SAPFA_SAF”) of the secondary alignment feature constituting elongate side 1406 and the second and third elongate sides 1408a and 1408b may be measured by importing the image of the club head obtained as per the measurement for the SAPFA. Points 1410b and 1410a are selected which are the innermost ends of the radii connecting lines 1408b and 1408 a with elongate side 1406 as shown in FIG. 10B. A best fit quadratic line is then fit for the secondary alignment feature between point 1410 a and 1410b and then a datum 1412 is determined as the center point along the arc length of the best fit line, again as for the SAPFA measurement, two points at arc length between +/−0.25 mm from the datum were selected. A straight line is then drawn between these two points and a line perpendicular to this line is then drawn at the datum. The Sight Adjusted Perceived Face Angle Secondary Alignment Feature, (“SAPFA_SAF”) is then measured as the angle between this perpendicular line and they axis.

In some embodiments, the golf club heads of the present invention also have a Sight Adjusted Perceived Face Angle Secondary Alignment Feature, (“SAPFA_SAF”) of from about −2 to about 6, more preferably of from 0 to about 5, even more preferably of from about 1.5 to about 4 degrees.

The primary and secondary alignment features as described herein typically utilize paint lines which demark the edge of an area of contrasting paint or shading of the crown relative to the color or shading of the face. Preferably the contrasting colors are white in the crown area and black in the face area. Typically painting or shading of golf club heads is performed at the time of manufacture and thus are fixed for the lifetime of the club absent some additional painting performed after purchase by the owner. It would be highly advantageous if the profile of the alignment feature could be adjusted by the user using a simple method which would allow adjustment of the perceived face angle by the user in response to the golfer's observed ball direction tendency on any given day.

In some embodiments of the golf club heads of the present invention the crown comprises a rotatable or otherwise movable portion, with one side of said portion including the edge of an area of contrasting paint or shading of the crown relative to the color or shading of the face or the color or shading of the second portion of the crown which can be rotated or moved sufficient to yield the desired Perceived Face Angle, PFA and/or Sight Adjusted Perceived Face Angle (SAPFA) and/or Sight Adjusted Perceived Face Angle Secondary Alignment Feature, (“SAPFA_SAF”) to produce the desired ball flight. The movable portion of the crown is held in position by a fastening device such as a screw or bolt which is loosened to allow for rotation or movement and then subsequently tightened to fix the position of the crown after adjustment.

In addition to a portion of the crown being movable other embodiments include a movable layer or cover on top of the crown with one side of said movable layer or cover including the edge of an area of contrasting paint or shading of the crown relative to the color or shading of the face or the color or shading of the second portion of the crown which can be rotated or moved sufficient to yield the desired Perceived Face Angle, PFA and/or Sight Adjusted Perceived Face Angle (SAPFA) and/or Sight Adjusted Perceived Face Angle Secondary Alignment Feature, (“SAPFA_SAF”). The movable portion of the layer or cover is again held in position by a fastening device such as a screw or bolt or other fastening means which is loosened to allow for rotation or movement and then subsequently tightened to fix the position of the movable layer or cover after adjustment.

In other embodiments a portion of the crown may comprise electronic features which can be selectively activated to generate the required appearance including but not limited to light emitting diodes (LED), organic LED's (OLED), printed electronics with illumination devices, embedded electronics with illumination devices, electroluminescent devices, and so called quantum dots.

In other embodiments, a portion of the crown may comprise a coating that alters its characteristics when exposed to external conditions including but not limited to thermochromic coatings, photochromic coatings, electrochromic coatings and paramagnetic paint.

In one preferred embodiment, at least a portion of the crown of the golf club head or a layer covering at least a portion of the crown of the golf club head comprises an electronic graphic display. The display provides active color and graphic control for either the entire top portion of the crown or layer covering at least a portion of the crown or a portion thereof. The display may be constructed from flexible organic light-emitting diodes (OLED) displays, e-ink technology, digital fabrics, or other known means of active electronic color and graphic display means. For example, an organic light emitting diode (OLED) (e.g., a light emitting polymer (LEP), and organic electro luminescence (OEL)) is a light-emitting diode (LED) whose emissive electroluminescent layer is composed of a film of organic compounds. The layer usually contains a polymer substance that allows suitable organic compounds to be deposited in rows and columns onto a carrier substrate such as the at least a portion of the crown of the golf club head or a layer covering at least a portion of the crown of the golf club head, by a simple “printing” process. The resulting matrix of pixels can emit light of different colors.

In some embodiments, the at least a portion of the crown of the golf club head or a layer covering at least a portion of the crown of the golf club head is segmented into portions which may be controlled differently from each other. For example, one side of the alignment feature has a static surface color and the other side a second static and contrasting surface color display capability.

The display is operatively connected to a microprocessor disposed in the golf club head (e.g., via wires). The microprocessor is further operatively connected to a data port, for example a universal serial bus (USB) port (e.g., via wires). The data port allows transfer and retrieval of data to and from the microprocessor. Data ports and data transfer protocols are well known to one of ordinary skill in the art. The data port (USB port) may be disposed in the rearward area of the golf club head.

Data can be obtained from a variety of sources. In some embodiments, an Internet website is dedicated to support of the golf club head of the present invention. For example, the website may contain downloadable data and protocols (e.g., colors, color patterns, images, video content, logos, etc.) that can be uploaded into the microprocessor of the golf club head (via the data port, via a cable, via a computer). As an example, the website may have a gallery for choosing colors to be displayed, as well as patterns of the colors.

In some embodiments, data can be uploaded from other sources, for example DVDs, CDs, memory devices (e.g., flash memory), and the like. Sources may also include cellular phones, smart phones, personal digital assistants (PDAs), digital vending kiosks, and the like. In some embodiments, the data can be uploaded and downloaded via other mechanisms, for example wired or wireless mechanisms. Such mechanisms may include Bluetooth™, infrared datalink (IrDa), Wi-Fi, UWB, and the like.

In some embodiments, one or more control buttons are disposed on the golf club head allowing a user to manipulate the display as desired. The control buttons are operatively connected to the microprocessor. The microprocessor is configured to receive input signals from the control buttons and further send output commands to manipulate the. The control buttons may be operatively connected to the display and/or the microprocessor via one or more wires.

The microprocessor and/or display are operatively connected to a power source, for example a battery. The battery may be rechargeable. In some embodiments, the battery comprises a control means for turning on and off the device. All wires and data ports and other electronic systems are adapted to sustain the impact forces incurred when a golfer hits a golf ball with the golf club head.

In other embodiments of the golf club heads of the present invention a method to accomplish user adjustably of the alignment feature would involve at least a portion of the crown of the golf club head or a layer covering at least a portion of the crown of the golf club head being covered by a dielectric electroluminescent coating system using as one example the materials and methods as described in U.S. Pat. No. 6,926,972 by M. Jakobi et al., issuing on Aug. 9, 2005 and assigned to the BASF Corporation, the entire contents of which are incorporated by reference herein. Using this technology an electric current (provided by a small battery fixed securely in the golf club head cavity) could be selectively employed to use electroluminescence to highlight (or eliminate) a particular color thereby adjusting the alignment feature orientation.

Now, with reference to FIGS. 12A-40, typical examples are described below that include bright white diffusing top surfaces that are more readily perceived by a golfer. In addition, such top surfaces produce an appearance of increased size, promoting golfer confidence. By providing a contrasting club face, the face/crown interface that is used for club alignment becomes more visually apparent.

Examples of wood type and iron type golf clubs and club heads are provided below. In addition, examples of putters and putter heads are provided. For convenient description, standard golf illumination is defined herein as illumination associated with common outdoor playing conditions in natural lighting, i.e., full sun, partial sun, partial shade, full shade, and overcast conditions at times a few hours after sunrise and a few hours before sunset. Golf club and club head features are described with reference to a club head position at an address position, i.e., a customary position from which a golfer initiates a swing sequence. For convenience, if needed, directions are referenced to an address position for a right handed golfer addressing a right handed club. A rearward direction is a direction from a striking surface opposite an intended line of ball flight. An upward direction is a direction upward from a playing surface.

Metal wood clubs as described herein can have bare metallic striking or other surface. Textured surfaces can be provided with a texture finish such as a tumble finish or sand blasted finish. Coatings can be applied to striking faces, and a durable coating such as produced with plasma vapor deposition (PVD) or ion plating (IP) is preferred, as paint can chip after use and may cause spin degradation. Clubs can have titanium alloy (Ti) faces or steel alloy (Steel), or other faces. The range of ion plating finish colors available to coat these faces is limited. One face coating for Ti or steel (and more durable than some other colors) is a black IP finish. Crown paints are available in a large variety of colors.

With reference to FIGS. 12A-12E, a putter includes a putter head 2102 and a shaft mounting bore 2104 provided in the putter head 2102 for attachment of a putter shaft. The putter head 2102 has a shape that can be referred to as a mallet type as the putter head 2102 has a substantial depth from a putter striking face 2106 to a backmost surface 2108. This configuration permits the putter head 2102 to have a relatively larger putter head mass and a larger moment of inertia than so-called blade type putter heads. Another benefit of the putter head 2102 having a larger head would be to set the center of gravity location farther back for improved roll or launch performance upon impact with the ball. The putter head 2102 includes a series of alignment indices 2111, 2112, 2113 situated on a top or crown surface 2114 and extending substantially perpendicularly from about the putter striking face 2106 to a rear arc 2116. The alignment index 2112 (the central alignment index) is substantially aligned with a geometrical center of a striking surface 2120 situated on the putter striking face 2106 of the putter head 2102. In some examples, the striking face 2106 is provided with an insert 2120 that is secured to the putter head in a recess provided in the putter head 2102.

The rear arc 2116 corresponds to a boundary between a first portion 2122 of the putter head 2102 having a full thickness, and a stepped down portion 2124. The indices 2111, 2112, 2113 noted above promote visual alignment but occupy less that about 5%, 6%, 7%, 8%, or 10% of the surface area of the first portion 2122 which is typically covered with a white diffusively reflecting surface treatment. The stepped down portion includes a circular aperture 2126 having a radius that is between about 0.8 and 1.2 times a golf ball diameter, 0.9 and 1.1 times a golf ball diameter, or 0.95 and 1.05 times a golf ball diameter. Typically, the diameter of the aperture 2126 is selected to be approximately equal to a golf ball diameter. In some examples, a golf ball diameter is about 41.67 mm. In other examples, the aperture 2126 has a diameter of between about 20 mm and 75 mm, 30 mm and about 60 mm, 36 mm and about 44 mm, or 38 mm and about 41 mm. A partial cylindrical bore 2127 is situated about the aperture 2126 and can have a diameter that is between about 0.1 mm and 5 mm greater that the diameter of the aperture 2126. The partial bore 2127 typically has a depth of between 0.1 mm and 5 mm. The aperture 2126 and the bore 2127 are generally circular, but other shapes can be used, but situated so as to be symmetric about the central alignment index 2112 to facilitate alignment of the club head. In addition, the rear arc 2116 is situated so as to be bisected by the central alignment index 2112. The putter head 2102 also has a perimeter that is symmetric with respect to the central alignment index 2112, but perimeter symmetry can be adjusted to provide apparent symmetry when the putter head 2102 is viewed in address position as shaft attachment or other putter features can provide apparent distortion. As shown in FIG. 12C, a bottom portion of the putter head 2102 can have relief regions 2130, 2131 that can have a different surface finish than other portions of the putter head.

Because putting (as well as other golf strokes) requires precise alignment, the putter head 2102 is provided with suitable surface treatments to promote visibility and alignment. In one example (and as shown in FIGS. 12A-12E), the putter head 2102 is substantially provided with a diffusing, white surface treatment. Such a surface treatment provides superior visibility with respect to the common putting surface backgrounds with which a putter is used. With such a surface treatment, the putter head 2102 appears substantially brighter than a putting surface and putting surface color provides an additional contrast with respect to a neutral white surface. Not only does a diffusing white surface treatment provide superior visibility with respect to a putting surface, such a diffusing surface reduces or eliminates specular reflections of the sun that are responsible for glare or bright spots experienced by a golfer when using a putter. The combination of increased apparent brightness of a putter head due to white surface treatment and diminished specular reflectance due to the diffusing surface substantially reduces distracting glare.

A diffused surface treatment is defined as a surface treatment applied to a club head base material to change the color or glossiness of the surface so as to control, reduce, or minimize any glare spots located on the crown of the golf club head. Diffused surface treatments include coatings located on top of the base material of the club head. In some embodiments, the diffuse surface treatment is a white color. Examples of diffuse surface treatments include paints, matte clear coats, clear coats, powder coatings, PVD, CVD, platings, ion platings, electroplatings, ceramic coatings. Examples of paints include urethane base coatings, pearl coats, epoxy based coatings, decals, inks, and primer coatings.

While providing a diffusing white surface for a putter head top surface is beneficial, such a surface is preferably used in conjunction with alignment indices that are provided with a surface treatment that establishes a dark, highly diffusing surface. In one embodiment, the putter can include a first primer layer being 50 μm thick, a second paint layer being about 85 μm thick, and a clear coat being about 115 μm thick. In one embodiment, the clear coat layer is thicker than the other individual layers. For example, a glossy black surface treatment tends to exacerbate visibility problems when used with a light colored top surface, because the absence (or reduction) in glare elsewhere on the top surface causes attention to be undesirably brought to specular reflections associated with alignment indices such as the alignment indices 2111, 2112, 2113. Thus, a white or neutral diffusing top surface is preferably accompanied with a diffusing surface treatment for alignment indices.

The putter head 2102 of FIGS. 12A-12E includes a plurality of alignment features that aid in alignment in addition to an enhanced contrast top surface and alignment indices with reduced specular reflectance. The aperture 2126 (and the partial bore 2127), alignment indices 2111, 2112, 2113, the rear arc 2116, as well as the overall shape of the putter head are configured so that the golfer receives numerous apparent visual cues as to putter head alignment. In other examples, at least some of these features are omitted to provide greater design flexibility.

Surface treatments can be provided by applying a diffusing white paint to a club head, typically over a gray or other non-white primer coat. Alignment indices can be formed as grooves in the putter head 2102 that are then partially filed with a black diffusing material such as a flat black paint. Because the putter striking face 2106 is not visible (or barely visible) to a golfer, the striking face 2106 can be configured as desired. Alternatively, the surfaces of the striking face can be partially or completely treated as indicated above. In addition, putter faces can be visible based on the degree loft in the putter head. In preferred embodiments, the face has a high contrast to the remaining club color for alignment purposes. In one embodiment, the face is a black or dark color aiding in alignment while also minimizing the amount of color reflection created on the ball at the address position.

An alternative putter head 2202 is illustrated in FIGS. 13A-13B. The putter head 2202 is a modified blade-type design that includes a blade 2204 that includes a striking surface 2206 and a rear surface 2208. The blade 2204 extends upwardly from a sole 2210 that is provided with an alignment index 2212 that extends from a rear surface of the sole 2210 to the rear surface 2208 of the blade 2204. An insert 2214 is provided in the striking surface 2206 to provide a striking area. The alignment index 2212 is generally aligned perpendicular to and centered on the striking surface. Shoulders 2220, 2221 extend upwardly from the sole 2210 and are coupled to or unitary with the blade 2204, and permit mass to be distributed away from the center of the striking surface so as to increase moment of inertia. The shoulders 2220, 2221 can be made of a more dense material than other portions of the putter head 2202, or can be provided with bores or other relieved volumes configured to receive additional weights. Inner surfaces 2222, 2223 of the shoulders 2220, 2221 are generally situated so as to provide a separation corresponding to a golf ball diameter. Typically, the separation is between about 0.8 and 1.2 times a golf ball diameter, 0.9 and 1.1 times a golf ball diameter, or 0.95 and 1.05 times a golf ball diameter. In some examples, a golf ball diameter is about 41.67 mm. In other examples, the separation is between about 30 mm and 75 mm, about 35 mm and about 60 mm, about 36 mm and about 44 mm, or about 38 mm and about 41 mm. To promote alignment and visibility, at least some portions of the putter body 2202 are provided with a suitable surface appearance. For example, upward facing portions of the putter head 2202 can be provided with a diffuse, white appearing coating or other surface treatment as described above. In addition, the alignment index 2212 can be provided with a dark, diffusing coating.

As used herein, a white reflecting surface is a surface that reflects at least about 50%, 60%, 70%, 80%, 85%, 90%, 95%, or 97% of an incident light flux corresponding to full sun, partial sun, partial shade, or shade daylight conditions or daylight cloud cover conditions. Such reflectances are such that the apparent color of the resulting reflected light is not appreciably different from that of the incident light flux. Reflectance for colored surfaces can be similarly defined. For example, a red surface is a surface that that reflects at least about 50%, 60%, 70%, 80%, or 85% of a red portion of incident light flux corresponding to full sun, partial sun, partial shade, shade daylight conditions, or daylight cloud cover conditions. An effective diffusing surface as used herein is a surface for which a ratio of luminous intensity produced by the diffusing surface with respect to a luminous intensity of a perfect (Lambertian) diffuser in response to illumination at normal incidence to the diffusing surface is at least 0.2, 0.4, 0.6, 0.8, or 0.9 at an angle of 20 degrees, 30 degrees, 40 degrees, or 45 degrees. As used herein, effective diffusing surfaces can be characterized with an effective diffusing ratio corresponding to the above ratios and a related diffusing angle. Contrasting surfaces can be provided based on total reflectance of less than 20%, 10%, or 5% of an incident light flux corresponding to full sun, partial sun, partial shade, shaded, or daylight cloud cover conditions.

While white appearing surface treatments can provide the greatest reflectances, off-white, eggshell white, and red, green, yellow, or other colors or tinted whites can be used. In some cases, whites corresponding to golf ball appearances are used, and can include brightening agents. In some examples, color contrast can be provided between club head features and a playing surface to increase contrast, but the examples below are described with reference to white or other almost color neutral surface treatments. For example, red surface portions can be contrasted with cyan surface portions, green surface portions with magenta surface portions, and blue surface portion with yellow surface portions, but other color combinations can be used. In addition, while selected portions of a club head can be provided with a selected contrast enhancing (or specular reflection reducing) surface treatment, such treatments can be provided as solid treatments that cover an entire surface portion, or stippling or patterns such as checks, stripes, or other periodic or aperiodic arrangements. Finally, neutral grays or darker colors can be used in which reflectances are less than those listed above. In some examples, only surface areas at or near selected club head edges are provided with white or other contrast enhancing or diffusing surface treatments.

Other types of golf clubs can be configured similarly. Referring to FIGS. 14A-14D, characteristics of wood type golf clubs such as drivers, fairway woods, and rescues are shown by way of reference to a golf club head 2300 having a removable shaft 2050. The club head 2300 comprises a centerface, or striking face, 2310, scorelines 2320, a hosel 2330 having a hosel opening 2340, and a sole 2350. The hosel 2330 has a hosel longitudinal axis 2060 and the shaft 2050 has a shaft longitudinal axis. In the illustrated embodiment, the ideal impact location 2312 of the golf club head 2300 is disposed at the geometric center of the striking surface 2310 (see FIG. 14A). The ideal impact location 2312 is typically defined as the intersection of the midpoints of a height (H_ss) and width (W_ss) of the striking surface 2310.

As shown in FIG. 14A, a lie angle 2010 (also referred to as the “scoreline lie angle”) is defined as the angle between the hosel longitudinal axis 2060 and a playing surface 2070 when the club is in the grounded address position. The grounded address position is defined as the resting position of the head on the playing surface when the shaft is supported at the grip (free to rotate about its axis) and the shaft is held at an angle to the ground such that the scorelines 2320 are horizontal (if the club does not have scorelines, then the lie shall be set at 60-degrees). The centerface target line vector is defined as a horizontal vector which is perpendicular to the shaft when the club is in the address position and points outward from the centerface point. The target line plane is defined as a vertical plane which contains the centerface target line vector. The square face address position is defined as the head position when the sole is lifted off the ground, and the shaft is held (both positionally and rotationally) such that the scorelines are horizontal and the centerface normal vector completely lies in the target line plane (if the head has no scorelines, then the shaft shall be held at 60-degrees relative to ground and then the head rotated about the shaft axis until the centerface normal vector completely lies in the target line plane). The actual, or measured, lie angle can be defined as the angle 2010 between the hosel longitudinal axis 2060 and the playing surface 2070, whether or not the club is held in the grounded address position with the scorelines horizontal. Studies have shown that most golfers address the ball with actual lie angle that is 10 to 20 degrees less than the intended scoreline lie angle 2010 of the club. Studies have also shown that for most golfers the actual lie angle at impact is between 0 and 10 degrees less than the intended scoreline lie angle 2010 of the club.

As shown in FIG. 14B, a loft angle 2020 of the club head (referred to as “square loft”) is defined as the angle between the centerface normal vector and the ground plane when the head is in the square face address position. As shown in FIG. 14D, a hosel loft angle 2072 is defined as the angle between the hosel longitudinal axis 2060 projected onto the target line plane and a plane 2074 that is tangent to the center of the centerface. The shaft loft angle is the angle between plane 2074 and the longitudinal axis of the shaft 2050 projected onto the target line plane. The “grounded loft” 2080 of the club head is the vertical angle of the centerface normal vector when the club is in the grounded address position (i.e., when the sole 2350 is resting on the ground), or stated differently, the angle between the plane 2074 of the centerface and a vertical plane when the club is in the grounded address position.

As shown in FIG. 14C, a face angle 2030 is defined by the horizontal component of the centerface normal vector and a vertical plane (“target line plane”) that is normal to the vertical plane which contains the shaft longitudinal axis when the shaft 2050 is in the correct lie (i.e., typically 60 degrees+/−5 degrees) and the sole 2350 is resting on the playing surface 2070 (the club is in the grounded address position).

The lie angle 2010 and/or the shaft loft can be modified by adjusting the position of the shaft 2050 relative to the club head. Adjusting the position of the shaft can be accomplished by bending the shaft and the hosel relative to the club head. As shown in FIG. 14A, the lie angle 2010 can be increased by bending the shaft and the hosel inward toward the club head 2300, as depicted by shaft longitudinal axis 2064. The lie angle 2010 can be decreased by bending the shaft and the hosel outward from the club head 2300, as depicted by shaft longitudinal axis 2062. As shown in FIG. 14C, bending the shaft and the hosel forward toward the striking face 2310, as depicted by shaft longitudinal axis 2066, increases the shaft loft. Bending the shaft and the hosel rearward toward the rear of the club head, as depicted by shaft longitudinal axis 2068, decreases the shaft loft. It should be noted that in a conventional club the shaft loft typically is the same as the hosel loft because both the shaft and the hosel are bent relative to the club head. In certain embodiments disclosed herein, the position of the shaft can be adjusted relative to the hosel to adjust shaft loft. In such cases, the shaft loft of the club is adjusted while the hosel loft is unchanged. Such clubs are described in US Patent Application Publication 2010/0197424, which is incorporated herein by reference.

Adjusting the shaft loft is effective to adjust the square loft of the club by the same amount. Similarly, when shaft loft is adjusted and the club head is placed in the address position, the face angle of the club head increases or decreases in proportion to the change in shaft loft. In some embodiments, the face angle and the loft are decoupled from one another by an adjustable sole plate. Hence, shaft loft is adjusted to effect changes in square loft and face angle. In addition, the shaft and the hosel can be bent to adjust the lie angle and the shaft loft (and therefore the square loft and the face angle) by bending the shaft and the hosel in a first direction inward or outward relative to the club head to adjust the lie angle and in a second direction forward or rearward relative to the club head to adjust the shaft loft. Adjustable soles are described in further detail in U.S. patent application Ser. No. 12/646,769, filed Dec. 23, 2009, which is incorporated herein by reference.

While the mechanical adjustments described about with reference to a wood-type golf club permit precise adjustment, the effectiveness of these adjustments can be limited by a golfer's ability to appropriately address and strike a golf ball. To aid in club placement, a club crown area 2325 can be provided with a surface treatment so as to contrast with the club face 2310. For example, the crown area 2325 can be made so as to have a white, diffusing appearance and the club face 2310 configured to appear black or otherwise dark. In this way the crown 2325 contrasts with the playing surface 2070 and the club face 2310.

Representative examples of a driver-type club provided with contrast enhancement are shown in FIGS. 15A-15E and FIG. 16. Referring to FIGS. 15A-15E, a club head 2402 includes a striking face 2404, a sole 2406, and a crown 2408. The crown 2408 is shown as stippled to denote a white appearing surface that provides substantial diffusion to incident light. The striking face 2404 is provided with a dark diffusing surface to aid visibility. In an example shown in FIG. 16, a club head 2502 includes a bright crown 2508 and a striking surface 2504 that includes portions 2510, 2512, either of which can be configured to contrast with the bright crown 2508. For example, the portion 2512 or the portion 2510 can be provided with a white diffusing surface treatment or a dark diffusing surface treatment. One additional advantage that can be realized with a bright or white crown is that such surface treatments can make a club head appear larger, and improve player confidence.

While providing bright diffusing areas and contrasting dark areas facilitates golfer perception of a golf club, clubs such as drivers, fairway woods, and utility clubs (“wood-style clubs”) do not typically include the substantial number of alignment aids that are available on putter heads such as shown in FIGS. 12A-12B. Alignment of wood-style clubs is especially important because if the striking surface is not properly aligned at impact, then the landing position of the ball will be farther off-line than shots with irons or a putter with equivalent impact misalignments. For example, if a driver is misaligned so as to be 2 degrees open at impact, the struck ball will end up about 24 yards off-line relative to the intended path, assuming an initial ball speed of 145 mph. Similarly, if a 6-iron is 2 degrees open relative at impact, the struck ball will end up about 13 yards off-line, and a wedge at 2 degrees open would be 2 yards off-line. In order to return the club to square at impact, the club face is preferably precisely aligned at address, prior to impact. For most golfers, a repeatable swing is difficult to achieve, and without a repeatable address alignment, even a repeatable swing will not produce repeatable results.

With regards to putters, studies have shown that on a 12-foot putt, only 35% of shots are aimed inside the cup at address, meaning 65% are aimed outside the cup. The tolerance for being inside the cup at 12 feet is ±0.85 degrees.

The two primary cues for aligning a metal wood type club at address are typically the crown/face masking line and the scorelines. Referring again to FIG. 15B, for the representative driver club head 2402, a crown/face ball flight axis 2455 extends forward and perpendicular to a crown/face masking line 2450 and an scoreline ball flight axis 2460 extends forward and perpendicular to scorelines 2451 on the striking face. As shown in FIG. 15B, the axes 2455, 2460 do not point in the same direction. Typically, a scoreline-based axis such as the axis 2460 appears to point a few degrees to the left of a crown/face based axis such as the axis 2455. Crown/face masking lines associated with bright or white crowns such as those of FIGS. 15A-16 are more readily apparent to the golfer. Because the crown/face masking lines are more visible, golfers tend to rely more on the associated axis to align the club head, and tend to disregard scoreline-based alignment axes. In some examples, a durable bright white diffusing surface treatment is applied to a crown and a durable black (IP) surface treatment is applied to a striking face. It is further desirable to suitably configure scorelines to provide adequate contrast but not so much as to detract from the use of the crown/face line for club head alignment. Thus, scorelines are preferably not bright white to provide maximum contrast with respect to a black striking face, but instead are an intermediate gray so as not to confuse alignment.

While a white or reflective crown promotes more accurate alignment of a club head with respect to an intended line of flight, the visually larger club head tends to result in shots struck somewhat above the striking face center. To assist in more centered ball striking, scorelines (such as the scorelines 2451 of FIG. 15B) can be moved down the striking face with respect to the club face center, typically by no more than about 0.5 mm, 1.0 mm, 2 mm, or 3 mm.

While providing a substantial upward facing portion of a golf club crown with a white or other bright surface treatment can provide substantial increases in visibility, such treatments can also be provided on selected portions of a crown. Referring to FIG. 17, a club head 2602 includes a face 2606 and a crown having a central portion 2608 and a perimeter portion 2610. The perimeter portion 2610 is preferably provided with a white diffusing surface treatment, while the inner portion 2608 can have a different surface treatment. In other examples, only a portion of the crown 2602 at face/crown interface 2614 is provided with a white or bright contrasting surface treatment, as this portion serves as a significant alignment aid.

FIG. 18 is a graph of relative reflected light intensity from a golf club head crown as a function of position for three different surface treatments. Data were obtained by evaluating digital photographs obtained under similar lighting conditions. Curves 2702 and 2704 correspond to glossy and matte black surfaces, respectively, and curve 2706 corresponds to a white matte surface. The relatively intensities associated with the curve 2706 are based on a digital photograph at an effective shutter speed that was twice that used to obtain data for the curves 2702, 2704. The curve 2706 shows that the reflected light intensity for a white surface is substantially greater than that of the glossy or matte black dark surfaces associated with the curves 2702, 2704, and the intensity is varies by less than about 20% over the crown, while both dark surfaces have much narrower distributions that vary at least 90% over the same area.

Iron-type clubs can also be provided with visibility enhancements based on diffusely reflecting surfaces. FIG. 19 is a top plan view of one embodiment of an iron type golf club head 2800 at normal address position. The club head 2800 is a unitary club head that includes a hosel 2802 and a striking face 2804. At normal address position, the club head 2800 rests on a ground plane that is parallel to the ground. In this “normal address position” a vector normal to the striking face 2804 lies in a first vertical plane 2808 (i.e., a vertical plane that is perpendicular to the ground plane), a centerline axis 2810 of the club shaft lies in a second vertical plane, and the first vertical plane 2108 and the second vertical plane perpendicularly intersect.

To aid alignment of the club head 2800 and to provide the club head 2800 with a larger appearance, the striking face 2804 can be provided with white, off-white, eggshell-white or other surface treatments. Selected portions of the striking surface or the entire striking surface can be provided with such a treatment. The top line 2806 can have a similar surface treatment. However, referring to FIG. 19, it is apparent that edges 2813, 2814 of the top line 2806 are generally not perpendicular to an expected line of flight that is perpendicular to the striking surface. Thus, white surface treatment of the top line 2806 may be combined with enhanced visibility scorelines (or an enhanced visibility portion of the striking face) to provide alignment aids for the golfer. As shown in FIG. 19, a portion 2816 of the striking face 2804 is provided with a white contrast enhancing surface treatment.

Representative Embodiments

In the following description of embodiments, some club head surfaces are described with reference to surface gloss. Smooth, polished surfaces generally exhibit a high gloss, and directly reflect light received, and depending on surface curvatures, can form one or more magnified, demagnified, real, or virtual images. Rough surfaces scatter light diffusely, and generally do not form clear images as do smooth surfaces. Surface gloss can be characterized by illuminating a surface at a specific angle, and measuring light intensity received in a range of reflection angles. Gloss measurements can be made with reference to the amount of light reflected from a black glass standard having a specified refractive index. In this way, gloss measurements can be established without direct reference to input light intensity. Standard gloss measurement geometries are specified for three gloss ranges: semigloss for surface glosses between 10 and 70 gloss units measured with a standard 60 degree geometry, high gloss for surface glosses greater than 70 gloss units measured with a standard 20 degree geometry, and low gloss for surface glosses that are less than 10 gloss units measured with a standard 80 degree geometry.

In some disclosed examples, surface gloss is referred to as semigloss or low gloss. As used herein, semigloss refers to a range of 10 to 70 gloss units measured with respect to a standard 60 degree geometry. However, some examples include semigloss surfaces having surface gloss in ranges having lower limits of 10, 20, 30, 40, 50, or 60 gloss units and upper limits of 20, 30, 40, 50, 60, or 70 gloss units. Similarly, low gloss surfaces include surfaces associated with standard gloss values of less than 10, 8, 5, 4, or 2 gloss units. Semigloss surfaces are typically preferred due to a chalky appearance that can be associated with low gloss surfaces. Gloss measurements can be conveniently made with portable glossmeters such as the MICRO-TRI-GLOSS meters from BYK Additives and Instruments.

Examples are also described, for convenience, with respect to CIELab color space using L*a*b* color values or L*C*h color values, but other color descriptions can be used. As used herein, L* is referred to as lightness, a* and b* are referred to as chromaticity coordinates, C* is referred to as chroma, and h is referred to as hue. In the CIELab color space, +a* is a red direction, −a* is a green direction, +b* is a yellow direction, and −b* is the blue direction. L* has a value of 100 for a perfect white diffuser. Chroma and hue are polar coordinates associated with a* and b*, wherein chroma (C*) is a distance from the axis along which a*=b*=0 and hue is an angle measured counterclockwise from the +a* axis. The following description is generally based on values associated with standard illuminant D65 at 10 degrees. This illuminant is similar to outside daylight lighting, but other illuminants can be used as well, if desired, and tabulated data provided herein generally includes values for illuminant A at 10 degrees and illuminant F2 at 10 degree. These illuminants are noted in tabulated data simply as D, A, and F for convenience. The terms brightness and intensity are also used in the following description to refer to CIELab coordinate L*.

Club Head Intensity Profiling

Some disclosed examples are described with respect to “hot spots” or other optical intensity profiles that are apparent on a wood-type club head crown, or a top surface of any club type with the club in a standard address position. Hot spots are visually distracting, and tend to promote club head misalignment or reduce golfer confidence in club head alignment. Suitable methods are described for reducing or eliminating such hot spots, typically so as to produce substantial areas of uniform visual intensity as viewed by a player with a club in a normal address position. As used herein, a “light diffusing region” of a club head refers to a portion of a club head surface over which reflected/diffused light intensity directed to a golfer with the golf club in a normal address position is at least 20%, 30%, 40%, 50%, 60%, 70%, 80%, or 90% of a maximum intensity of such reflected or diffused light. To promote accurate club head alignment without the visual impairment and distraction associated with hot spots, such diffusing regions can occupy substantial portions of an upward facing club head surface. A representative method for determining such light diffusing regions used in characterizing some embodiments is described below.

Referring to FIG. 20A, a club or club head 2902 is situated on a flat surface (typically a work surface such as a table top or floor) with a club crown 2904 or other club top surface facing a light source 2906 such as a FEIT Electric 15 W compact fluorescent lamp (CFL) having an A-type bulb and emitting light with a color temperature of 2700 K. The club head 2902 is adjusted so that a hot spot or center of specular reflection or diffuse reflection from the crown 2904 or club top surface appears near the center of the surface. The crown 2904 can be imaged with a digital SLR camera 908 such as a CANON EOS REBEL XTi with an f/5.6 zoom lens set to have a focal length of between 56 and 64 mm. Image resolution of 1936 (w)×1288 (h) pixels is convenient. Shutter speed can be varied based on the intensity of light received from the club head to avoid detector saturation as described below. Images can be captured in an sRGB color format. The camera is secured to a tripod, and the camera, club head, and light source is enclosed in a black light tent to reduce the effects of light from sources other than the light source 906.

For a putter type club, the arrangement of FIG. 20A is used and the light source 2906 is situated so as to provide an illumination distance of about 27 inches from the club along an axis 2912, and the club head surface is situated about 23 inches from the camera sensor along an axis 2914. The light source 2906 and the camera sensor 2908 are separated by a distance 2916 of about 24 inches.

FIG. 20B illustrates a second test setup for metalwood club heads where the light source 2906 is positioned virtually directly over the club head 2902. The light source 2906 is situated so as to provide an illumination distance of about 22 inches from the club along an axis 2918, and the club head surface is situated about 27 inches from the camera sensor along an axis 2922. The light source 2906 and the camera sensor 2908 are separated by a distance 2920 of about 18 inches.

Image data from the camera 2908 is provided to a computer system 2918 or other processing system for analysis using MATLAB mathematical analysis software, but other processing systems and software can be used.

Exposures are set by adjusting image intensity so that maximum pixel intensity value is non-saturated and within a range of greater than 90% and less than 100% of maximum intensity value for the camera sensor. The camera 2908 can be set to provide RGB values in a range of 0 to 255. A saturated pixel would have pixel values (255, 255, 255) while a non-saturated pixel would have values of, for example, (254, 254, 254). Intensity is computed as a weighted sum 0.2989*R+0.5870*G+0.1140*B based on R, G, B values provided by the camera 2908 using MATLAB's rgb2gray function which converts image data to to HSV color space, and produces “V” values or luminance values which are referred to herein as intensities. Pixel intensities can be deemed acceptable when peak pixel intensity is greater than 229.5 and less than 255. To obtain suitable image intensities, images can be obtained using auto focus and averaging metering mode, and the shutter speed set for Exposure Value (EV) 0. An image is then obtained, and camera histogram mode used to identify saturation. If any saturated pixels are detected, the shutter speed can be doubled (i.e. the exposure time halved), and a new image acquired. This process can be repeated as needed. Even after saturation is eliminated, additional images could be acquired at a faster shutter speed to confirm that saturation has been eliminated.

Intensity images can be evaluated by selecting a pixel having a maximum intensity and establishing an image radius that is the longest radius that can be extended from the maximum intensity pixel to the image border. A pixel radius can be defined as a horizontal distance from the crown location associated with the maximum intensity pixel to an edge of the crown surface along an image radius. For convenience, this distance can also be referred to as an effective plan radius (EPR) as this distance is associated with an apparent crown extent as shown in a plan view of a club head (i.e., looking downward with the club in standard address position). In certain embodiments, a crown effective length can be defined as a length of a longest of a plurality of pixel radii from the brightest intensity location to the edge of a crown surface. In other embodiments, an effective crown region or zone can be defined as being a region of the crown surface that contains the longest pixel radius and the surface area between the longest pixel radius and the two adjacent pixel radii at angles of ±30 degrees with respect to the longest pixel radius so as to form a “slice” or triangular area wherein a secondary location on the crown a distance of at least 50% at any given pixel radius within the effective crown region is associated with an reflected intensity that is at least 20%, 30%, 40% or 50% of the highest reflected intensity. In other words, a zone of crown intensity is defined from the crown effective length in a direction of 30 degrees and negative 30 degrees from the crown effective length orientation, the zone of crown intensity being greater that at least 20%, 30%, 40% or 50% of the highest reflected intensity

Intensity values can be scaled by dividing by 255 to be positive and less than 1. Point values along lines at angles of 0, 30, 60, 90, 120, 150, 180, 210, 240, 270, 300, and 330 degrees extending from the maximum value pixel a distance of the image radius are obtained by interpolation of pixel values. These point values can be plotted to characterize a light diffusing region or to locate undesirable hot spots. Unless stated otherwise, image intensities were obtained in this manner for the examples described below. It will be appreciated that an image radius established in this manner generally extends beyond a club head surface. A crown effective length can be defined as a longest distance from the crown location associated with the maximum intensity pixel to a crown perimeter along which a light intensity is measured. In other embodiments, the crown effective length can be defined as a specific pixel radius selected from a plurality of pixel radii according to orientation or length characteristics of the pixel radii. In addition, the crown effective length can be selected to define a ratio of a second point location (number of points) along the crown effective length from the maximum intensity point to a total number of points along the crown effective length to the crown perimeter.

Selected Wood Type Club Head Intensity Profiles

For purposes of illustration, intensity profile results for selected club heads are described. For convenience, examples include both contrast-enhanced clubs and conventional clubs to illustrate differences. In addition, CIELab data and gloss values are provided for selected embodiments associated with contrast-enhancement as well as some conventional club heads.

A representative intensity contour map associated with a conventional glossy black club head crown (club 1) is provided in FIG. 21. The graph of FIG. 21 plots relative image intensity about axes extending along a plurality of angles (0 to 330 degrees in 30 degree increments) on the club head crown as shown in FIG. 22. In addition, FIG. 22 also includes representative contour lines associated with constant relative surface brightness. The contour lines are provided for convenient illustration only, and actual contour line locations are based on data such as that used in FIG. 21. FIG. 21 show that relative surface intensity declines from its maximum value to near zero in fewer than about 5 points along the pixel radius. A crown portion in which relative intensity is greater than about 0.7 has a radius of less than about 4 points, indicative of a hot spot associated with this conventional club's glossy crown. The remainder of the crown appears dark, having a relative intensity of less than 0.004. Thus, this conventional crown has a pronounced hot spot on an otherwise dark surface.

FIGS. 23-24 illustrate hot spot reduction and an enlarged light diffusing area associated with application of a matte coating to a crown (club 2) similar to that associated with FIGS. 21-22. Considerable spreading of the crown hot spot is apparent, with relative intensity dropping to near zero over about a 20 point radius, and a crown effective length associated with an intensity of greater than about 0.7 is based on a distance corresponding to about 10 points in FIGS. 23-24. Nevertheless, a substantial portion of this matte crown has low intensity (less than 0.05 at points greater than 25) with the exception of a slight increase in intensity near the crown perimeter.

FIG. 25 is a graph of crown intensity and FIG. 26 is an intensity contour map for a metal wood driver (club 3) crown surface that is provided by a contrast-enhancing coated that includes a primer layer, a white base coat of thickness 0.00125 in. or about 0.001-0.002 in., a pearl layer of thickness 0.0008 in. or about 0.0007-0.0009 in., and a topmost matte clear layer of thickness 0.0008 in. or about 0.0007-0.0009 inches. Representative club heads have volumes greater than 400 cm³and crown thicknesses of between 0.7 and 1.0 mm, or 0.8 and 0.9 mm. In some examples, metalwoods have volumes of at least 400 cm³and crowns of thickness less than or equal to about 0.8 mm over more than 40%, 50%, or 60% of the crown surface area. Alternatively, crown thickness can be less than 1.0 mm, 0.9 mm, or 0.85 mm over 40%, 50%, or 60% of the crown surface area. In one embodiment, the base coat thickness is the thickest layer of the individual coating layers to achieve a desired diffusivity. In another embodiment, the primer coat has a thickness of about 40-60 μm, the paint layer has a thickness of about 75-95 μm, and the clear coat layer has a thickness of about 105-125 μm.

Considerable improvement is apparent, with relative intensity dropping to about 0.7 of a maximum value at about 20-40 points, and not approaching zero except when the club head perimeter is reached. With reference to FIG. 26, it will be appreciated that along radii at some angles, the relative intensity reduction is primarily associated with proximity to the crown perimeter, indicating that such a crown would have a substantially uniform light diffusing appearance over a large surface portion. Indeed, crown intensity does not drop to zero as with a conventional, glossy crown. The diffusing surface of this crown tends to reduce hot spots and the white surface treatment tends to increase surface intensity over that of a black crown, producing the substantially uniform crown intensity.

FIGS. 27-28 are graphs of crown intensity for two conventional metal wood type clubs (club 4 and club 5, respectively) that are provided with surfaces that are not black. As with the conventional glossy black crown of FIGS. 21-22, crown intensity decreases rapidly from a relative intensity maximum to about 0.7 at less than about 5-8 points. In addition, perimeter portions of the crown (points greater than about 15) have intensities of less than about 0.1. Thus, these conventional clubs also exhibit pronounced and visually distracting hot spots.

FIGS. 29-30 provide intensity data and contour maps for a conventional solid composite construction fairway wood (club 6). By virtue of its composite construction and a cream-colored appearance, hot spots do not appear. As this club is a solid composite, its club face is also a composite face of similar appearance to the crown, in contrast to the metal woods described above that have metallic striking faces.

FIG. 31 is a graph of intensity data for another conventional metal type driver (club 7) having a light (non-black) crown. As is readily apparent, this club too exhibits a significant hot spot.

FIG. 32 is a summary graph illustrating crown reflected light intensity for a variety of wood type club heads as described above. For each club head, data along a pixel radius at 0 degrees was selected.

Selected Wood Type Club Head Colorations

CIELab coordinates for the club head crowns associated with FIGS. 21-31 are provided in Tables 2A-2B below. Larger L* values appear brighter, and smaller absolute values of a* and b* are associated with more color neutral appearance. In addition, small values of chroma (C*) are accordingly also associated with a more color neutral appearance. As noted above, the composite club head associated with FIGS. 29-30 has relatively large b* and C* values, as well as a relatively low L* value. Thus, this club appears cream colored, and not white. The remaining conventional club crowns also have low L* values, and thus do not have a bright white appearance, and do not provide the contrast-enhancement available with the diffusing white club associated with FIGS. 25-26 which has an L* value of 93 and a C* value of less than 1.3, indicating a bright white, color neural appearance. This club head can also be configured to have a semigloss surface with gloss values in ranges from 10-70, 20-60, 30-50, or 35-45 gloss units or any other sub-range within the semigloss range defined above. In addition, club head crowns can also be configured to have lower gloss values (in the low gloss range). While such club head crowns can provide enhanced contrast and do not tend to exhibit hot spots, such low glosses tend to appear chalky and may not appeal to some golfers for this reason.

TABLE 2A

CIELab values or crowns of selected wood-type golf clubs.

Club Identifier

4
3

Illuminant
D65
A
F2
D65
A
F2

L*
75.74
76.03
75.98
93.17
93.04
93.11

a*
0.40
1.12
0.23
−1.22
−1.06
−0.74

b*
3.59
3.87
4.14
0.20
−0.28
0.03

C*
3.62
4.03
4.15
1.24
1.10
0.74

h
83.64
73.81
86.80
170.83
195.04
177.97

TABLE 2B

CIELab values for crowns of selected wood-type golf clubs.

Club Identifier

6
7

Illuminant
D65
A
F2
D65
A
F2

L*
67.06
67.95
67.76
81.44
81.74
81.71

a*
−2.09
1.99
−1.60
1.02
1.38
0.66

b*
17.97
17.74
20.43
2.68
3.10
3.14

C*
18.09
17.85
20.50
2.87
3.39
3.21

h
96.63
83.60
94.49
69.19
66.02
78.14

Striking Face Characteristics

A contrast-enhanced crown provides the golfer with superior visibility of a club head at address, increases the apparent (visual) size of the club head, and eliminates or reduces distracting hot spots. With such a club head, the golfer can better visualize ball/club alignment at address. To further improve golfer perception, a club head with a contrast enhanced crown can be provided with a contrasting striking face so that a top portion of a crown/striking face boundary becomes more apparent. For a white, diffusing crown, a dark or black appearing striking face can be used. CIELab values for a representative black striking face as well as several conventional clubs referred to above are included in Table 3.

TABLE 3

CIELab values for various club striking faces.

Club Identifier

4
3
6

Illuminant
D65
A
F2
D65
A
F2
D65
A
F2

L*
39.66
39.91
39.82
25.39
25.32
25.35
66.12
67.01
66.80

a*
0.43
1.18
0.26
−0.20
−0.38
−0.15
−1.78
2.18
−1.40

b*
2.93
3.16
3.36
−0.65
−0.73
−0.72
17.47
17.34
19.87

C*
2.96
3.37
3.37
0.67
0.82
0.74
17.56
17.48
19.92

h
81.55
69.49
85.58
252.97
242.67
258.53
95.81
82.82
94.04

Referring to Tables 2-3, a contrast enhanced club crown coupled with a black or other contrasting striking face can have a crown-face brightness difference ΔL of about 68, but greater or lesser differences can be used, for example, differences of about 20, 40, 50, 60, or 70 can be provided. The higher the ΔL value between the crown and face, the easier it will be for the golfer to align the face angle at the address position. In one embodiment, a ΔL of greater than 40 is preferred. In another embodiment, a ΔL of greater than about 50 or 60 is even more preferred to provide a very high contrast from the crown to face.

With reference to FIG. 33, a representative club head 3000 includes a hosel end 3002, a crown 3004, and a striking face 3005. A top edge 3006 of the striking surface is adjacent a portion of the crown 3004 that is forward facing and defines an upper crown/striking face boundary. As shown in FIG. 33, the club head is situated in an address position with reference to a horizontal surface 3010. A second plane 3012 is parallel to a first plane 3014. The first plane 3014 is tangent to the hosel end 3002 and the second plane 3012 is offset towards the horizontal surface 3010 along a hosel axis 3016 by an offset distance of 15 mm. The hosel axis 3016 is contained within a hosel plane that is perpendicular to the horizontal surface 3010. In other words, the hosel plane is parallel to the page surface and contains the hosel axis 3016. The hosel axis 3016 and the second plane 3012 intersect at a first intersection point. A first vertical plane s0 is taken through the first intersection point p0. The first vertical plane s0 is perpendicular to the hosel plane. As shown in FIG. 21, the first intersection point p0 corresponds to an intersection of the first vertical plane s0, the second plane 3012, and the striking face 3005 surface. In other words, the first face intersection point p0 is contained within the striking face 3005, the second plane 3012, and the first vertical plane s0. A plurality of crown/striking face boundary points p1, . . . p6 can be evenly or otherwise spaced along the top edge 3006 of the striking surface 3005. In some examples, such points are equidistant as measured along a horizontal direction parallel to the horizontal surface 3010. A point p7 identifies a most distant portion of the club head 3000 on the toe end of the club head 3000. A toe-end plane or seventh vertical plane s7 is defined to be tangent at the toe end point p7 and is perpendicular to the hosel plane.

With the first vertical plane s0 and the seventh vertical plane s7 defined as above, a face distance f_dbetween the two planes s0, s7 is determined in a horizontal direction along the ground plane 3010. The face distance f_dis evenly divided into seven horizontally equidistant regions by planes s1 . . . s6. As shown in FIG. 33, planes s0, . . . s7 are defined as planes perpendicular to the hosel plane and the horizontal plane 3010 and contain points p0, . . . , p7 located on the striking surface 3005, respectively. Each dividing plane s1 . . . s6 contains a respective contrast point p1 . . . p6 located near the face to crown transition region. The contrast points p1 . . . p6 correspond to points on the face associated with color transitions from a dark color to a light color of the crown. A transition from a dark color to a light color can be defined as “high contrast” if the L* values between face and the crown differ by more than 50. In some embodiments, the L* values between the crown color and the face color differ by more than 60 or 65.

In some embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 14.3% of the face distance fa (at least one of the equidistant regions is high contrast). In other embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 28.6% of the face distance fa (at least two of the equidistant regions are high contrast). In other embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 42.9% of the face distance f_d(at least three of the equidistant regions are high contrast). In other embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 57.1% of the face distance fa (at least four of the equidistant regions are high contrast). In other embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 71.4% of the face distance f_d(at least five of the equidistant regions are high contrast). In other embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 85.7% of the face distance fa (at least six of the equidistant regions are high contrast). In other embodiments, the difference in L* values between the crown and the face is high contrast, as defined above, for more than about 99% of the face distance f_d(at least six of the equidistant regions are high contrast along with a significant portion of the seventh equidistant region)

The equidistant regions of high contrast mentioned above can be contiguous across the face to crown transition or they can be spaced apart from one another in alternating or random fashion across the face to crown transition. In one embodiment, six out of the seven equidistant regions contain a high contrast crown to face transition across the entire horizontal distance (measured along f_d) within each region. In some embodiments, two, three, four, or five out of the seven equidistant regions contain a high contrast crown to face transition across the entire horizontal distance within each region.

In the view of FIG. 33, the planes s0, . . . s6 define respective projection crown lengths 3031-3036 and striking face projection lengths 3041-3046 that extend along the projections of the crown and the striking surface into the hosel plane (i.e., into a plane parallel to the drawing sheet. In typical examples, the crown 3004 is configured to be a white diffuser as described above, and the striking face 3005 is configured to be a dark or black diffuser with the exception of scorelines or striking face ornamentations. In representative examples, a set of such crown and striking face projection lengths includes projection lengths for which ratios of a striking face projection length to a corresponding crown projection length are in a range of from about 3:2 to about 10:1, and a set of evenly space projections includes ratios in this range, or ranges of 2:1 to 8:1 or 3:1 to 7:1.

Selected Putter Intensity Profiles and Colorations

Some representative putter intensity profiles, CIELab color values, and gloss data are provided below for contrast-enhanced putters as well as conventional putters. In some embodiments, putter top surfaces are painted, coated, or otherwise prepared to have color values similar to those associated with a golf ball. Representative CIELab values for golf balls are provided in Table 4 below.

TABLE 4

CIELab values for three types of golfballs having a white appearance.

Ball Identifier

1
2
3

Illuminant
D65
A
F2
D65
A
F2
D65
A
F2

L*
91.34
90.41
90.45
91.37
90.61
90.67
91.32
90.41
90.44

a*
−1.78
−3.18
−0.77
−1.91
−2.82
−0.85
−1.81
−3.15
−0.82

b*
−9.69
−11.31
−12.03
−7.39
−8.92
−9.41
−9.40
−10.97
−11.66

C*
9.86
11.75
12.05
7.63
9.36
9.45
9.57
11.42
11.69

h
259.57
254.30
266.32
255.54
252.48
264.86
259.08
253.98
265.97

CIELab values for various putter configurations are summarized in Tables 5-6. Table 5 contains data for conventional putters, and Table 6 contains data for contrast-enhanced putter heads similar in shape to the putter head of FIGS. 12A-12D.

TABLE 5

CIELab coordinates for selected conventional putters.

Putter Identifier

14
27

Illuminant
D65
A
F2
D65
A
F2

L*
86.61
86.66
86.68
92.17
91.71
91.78

a*
−1.04
−0.36
−0.66
−2.25
−2.44
−1.53

b*
2.29
1.96
2.50
−2.90
−3.91
−3.62

C*
2.52
1.99
2.59
3.68
4.61
3.93

h
114.42
100.52
104.89
232.18
237.97
247.12

TABLE 6

CIELab coordinates for selectee contrast-enhanced putters.

Putter Identifier

9
12
10
11

Illuminant
D65
A
F2
D65
A
F2
D65
A
F2
D65
A
F2

L*
64.37
64.35
64.38
89.33
88.95
89.02
91.68
91.21
91.25
24.61
24.55
24.58

a*
−0.33
−0.27
−0.23
−1.83
−2.07
−1.19
−2.69
−2.57
−1.80
−0.04
−0.24
−0.03

b*
0.36
0.30
0.43
−2.43
−3.23
−2.97
−2.24
−3.35
−2.92
−0.72
−0.76
−0.81

C*
0.49
0.40
0.49
3.04
3.83
3.20
3.51
4.22
3.43
0.72
0.79
0.81

h
131.85
132.13
118.41
233.00
237.35
248.17
219.82
232.43
238.31
267.18
252.36
268.06

A top surface of Putter #10 is provided by a primer coating over which a base coat is applied. A top surface of Putter #12 is provided by a primer coating, followed by a base coating that is covered by a matte clear coat. Data for mechanically similar putter heads with a matte clear coat and a flat black coating are also provided in Table 6.

FIG. 34 illustrates surface brightness along 120 degree and 270 degree radii for a putter head having a matte coating and a gray diffuse appearance (Putter #9). The dips in normalized intensity around point numbers 10-15 are due to black alignment grooves, and the intensity decrease at 270 degrees for point numbers 25 and larger appears to be associated with a putter head feature corresponding to the rear arc 116 shown in FIG. 12A. Over the remainder of the putter head top surface, surface brightness remains greater than about 70% of a maximum brightness.

FIG. 35 illustrates surface brightness along 120 degree and 300 degree radii for a putter head having a white diffusing coating (Putter #12). The dips in normalized intensity around point numbers 4, 12, and 19 are due to black alignment grooves. Over the remainder of the putter head top surface, surface brightness remains greater than about 40% of a maximum brightness. FIG. 36 illustrates corresponding representative surface brightness contours and radii orientations. The contours of FIG. 36 are shown without the surface brightness decreases in the alignment grooves.

FIG. 37 illustrates surface brightness along 120 degree and 270 degree radii for a putter head having a white diffusing coating (Putter #10). The dips in normalized intensity around point numbers 2 and 15 are due to black alignment grooves. Over the remainder of the putter head top surface, surface brightness remains greater than about 65% of a maximum brightness.

The thickness of the paint coating can vary based on the type of material being painted. For example, in one embodiment, a steel body is painted with a primer layer and white paint layer having a combined thickness of about 45-60 μm and a clear coat layer of about 50-60 μm. In another embodiment, an aluminum body is painted with a primer layer and a white paint layer having a combined thickness of about 25-40 μm and a clear coat layer of about 30-40 μm. FIG. 38 illustrates surface brightness along 120 degree and 270 degree radii for a conventional putter head (Putter #13). The dip in normalized intensity around point number 14 is associated with club head markings. The surface brightness varies widely, and drops to less than 35% of a maximum value over only about 4 points, and remains less than about 25-30% of a maximum value over a substantial portion of the surface. Such a brightness curve is indicative of a pronounced hot spot.

FIG. 39 is a top perspective view of another conventional putter head 3100 (Putter #14) and FIG. 40 is a graph of surface brightness. This putter head 3100 includes a set of periodic grooves such a groove 3102 and the associated surface brightness drops periodically to near zero as a result, resulting in a reduced apparent intensity when viewed by a golfer. Brightness contour lines are shown in FIG. 39 absent the drop offs associated with the grooves.

The above describes only representative examples with reference to the shortcomings of conventional club heads. Embodiments of the disclosed club heads can provide high contrast and high visibility with respect to typical backgrounds against which a club head is viewed. For example, bright white (such as color neutral surfaces with CIELab L* of greater than 75 and less than 100, a chroma of less than 2) provides superior contrast with respect to grass playing surfaces. In addition, providing a diffusely reflecting surface such as a semigloss surface with a gloss of less than about 60 gloss units, visually distracting hot spots can be eliminated or reduced. In combination with bright white, such a surface appears to have a uniform high brightness to a golfer. Finally, a club face that contrast with a bright white upper surface provides a high face/crown contrast that can be used for shot alignment. However, it will be appreciated that there are many club head variations that offer some or all of these advantages, and the claims are not to be limited so as to require any or all of these advantages. Therefore, we claim all that is encompassed by the appended claims.

In addition to the alignment features described herein, the golf club heads of the present invention may also incorporate additional, such features including but not limited to;

- 1. movable weight features including those described in more detail in U.S. Pat. Nos. 6,773,360, 7,166,040, 7,452,285, 7,628,707, 7,186,190, 7,591,738, 7,963,861, 7,621,823, 7,448,963, 7,568,985, 7,578,753, 7,717,804, 7,717,805, 7,530,904, 7,540,811, 7,407,447, 7,632,194, 7,846,041, 7,419,441, 7,713,142, 7,744,484, 7,223,180, 7,410,425 and 7,410,426, the entire contents of each of which are incorporated by reference in their entirety herein;
- 2. slidable weight features including those described in more detail in U.S. Pat. Nos. 7,775,905 and 8,444,505, U.S. patent application Ser. No. 13/898,313 filed on May 20, 2013, U.S. patent application Ser. No. 14/047,880 filed on Oct. 7, 2013, the entire contents of each of which are hereby incorporated by reference herein in their entirety;
- 3. aerodynamic shape features including those described in more detail in U.S. Patent Publication No. 2013/0123040A1, the entire contents of which are incorporated by reference herein in their entirety;
- 4. removable shaft features including those described in more detail in U.S. Pat. No. 8,303,431, the contents of which are incorporated by reference herein in in their entirety;
- 5. adjustable loft/lie features including those described in more detail in U.S. Pat. Nos. 8,025,587, 8,235,831, 8,337,319, U.S. Patent Publication No. 2011/0312437A1, U.S. Patent Publication No. 2012/0258818A1, U.S. Patent Publication No. 2012/0122601A1, U.S. Patent Publication No. 2012/0071264A1, U.S. patent application Ser. No. 13/686,677, the entire contents of which are incorporated by reference herein in their entirety; and
- 6. adjustable sole features including those described in more detail in U.S. Pat. No. 8,337,319, U.S. Patent Publication Nos. US2011/0152000A1, US2011/0312437, US2012/0122601A1, and U.S. patent application Ser. No. 13/686,677, the entire contents of each of which are incorporated by reference herein in their entirety.

The designs, embodiments and features described herein may also be combined with other features and technologies in the club-head including;

- 1. variable thickness face features described in more detail in U.S. patent application Ser. No. 12/006,060, U.S. Pat. Nos. 6,997,820, 6,800,038, and 6,824,475, which are incorporated herein by reference in their entirety;
- 2. composite face plate features described in more detail in U.S. patent application Ser. Nos. 11/998,435, 11/642,310, 11/825,138, 11/823,638, 12/004,386, 12/004,387, 11/960,609, 11/960,610 and U.S. Pat. No. 7,267,620, which are herein incorporated by reference in their entirety;

One should note that conditional language, such as, among others, “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments include, while other embodiments do not include, certain features, elements and/or steps. Thus, such conditional language is not generally intended to imply that features, elements and/or steps are in any way required for one or more particular embodiments or that one or more particular embodiments necessarily include logic for deciding, with or without user input or prompting, whether these features, elements and/or steps are included or are to be performed in any particular embodiment.

It should be emphasized that the above-described embodiments are merely possible examples of implementations, merely set forth for a clear understanding of the principles of the present disclosure. Any process descriptions or blocks in flow diagrams should be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps in the process, and alternate implementations are included in which functions may not be included or executed at all, may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present disclosure. Many variations and modifications may be made to the above-described embodiment(s) without departing substantially from the spirit and principles of the present disclosure. Further, the scope of the present disclosure is intended to cover any and all combinations and sub-combinations of all elements, features, and aspects discussed above. All such modifications and variations are intended to be included herein within the scope of the present disclosure, and all possible claims to individual aspects or combinations of elements or steps are intended to be supported by the present disclosure.

	Number	Date	Country
Parent	17695194	Mar 2022	US
Child	17734185		US
Parent	16352537	Mar 2019	US
Child	17695194		US
Parent	16046106	Jul 2018	US
Child	16352537		US
Parent	15197551	Jun 2016	US
Child	16046106		US

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REFERENCE TO RELATED APPLICATIONS

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