Patent Application
20210322838
The present invention relates to sports equipment; particularly, to a high volume aerodynamic golf club head.
Modern high volume golf club heads, namely drivers, are being designed with little, if any, attention paid to the aerodynamics of the golf club head. This stems in large part from the fact that in the past the aerodynamics of golf club heads were studied and it was found that the aerodynamics of the club head had only minimal impact on the performance of the golf club. The drivers of today have club head volumes that are often double the volume of the most advanced club heads from just a decade ago. In fact, virtually all modern drivers have club head volumes of at least 400 cc, with a majority having volumes right at the present USGA mandated limit of 460 cc. Still, golf club designers pay little attention to the aerodynamics of these large golf clubs; often instead focusing solely on increasing the club head's resistance to twisting during off-center shots.
The modern race to design golf club heads that greatly resist twisting, meaning that the club heads have large moments of inertia, has led to club heads having very long front-to-back dimensions. The front-to-back dimension of a golf club head, often annotated the FB dimension, is measured from the leading edge of the club face to the furthest back portion of the club head. Currently, in addition to the USGA limit on the club head volume, the USGA limits the front-to-back dimension (FB) to 5 inches and the moment of inertia about a vertical axis passing through the club head's center of gravity (CG), referred to as MOIy, to 5900 g*cm2. One of skill in the art will know the meaning of “center of gravity,” referred to herein as CG, from an entry level course on mechanics. With respect to wood-type golf clubs, which are generally hollow and/or having non-uniform density, the CG is often thought of as the intersection of all the balance points of the club head. In other words, if you balance the head on the face and then on the sole, the intersection of the two imaginary lines passing straight through the balance points would define the point referred to as the CG.
Until just recently the majority of drivers had what is commonly referred to as a “traditional shape” and a 460 cc club head volume. These large volume traditional shape drivers had front-to-back dimensions (FB) of approximately 4.0 inches to 4.3 inches, generally achieving an MOIy in the range of 4000-4600 g*cm2. As golf club designers strove to increase MOIy as much as possible, the FB dimension of drivers started entering the range of 4.3 inches to 5.0 inches. The graph of
While increasing the FB dimension to achieve higher MOIy values is logical, significant adverse effects have been observed in these large FB dimension clubs. One significant adverse effect is a dramatic reduction in club head speed, which appears to have gone unnoticed by many in the industry. The graph of
This significant decrease in club head speed is the result of the increase in aerodynamic drag forces associated with large FB dimension golf club heads. Data obtained during extensive wind tunnel testing shows a strong correlation between club head FB dimension and the aerodynamic drag measured at several critical orientations. First, orientation one is identified in
Secondly, orientation two is identified in
Thirdly, orientation three is identified in
Now referring back to orientation one, namely the orientation identified in
Still referencing
The results are much the same in orientation two, namely the orientation identified in
Again, the results are much the same in orientation three, namely the orientation identified in
Further, the graph of
The drop in club head speed just described has a significant impact on the speed at which the golf ball leaves the club face after impact and thus the distance that the golf ball travels. In fact, for a club head speed of approximately 100 mph, each 1 mph reduction in club head speed results in approximately a 1% loss in distance. The present golf club head has identified these relationships, the reason for the drop in club head speed associated with long FB dimension clubs, and several ways to reduce the aerodynamic drag force of golf club heads.
The claimed aerodynamic golf club head having a large projected area of the face portion (Af) and large drop contour area (CA) has recognized that the poor aerodynamic performance of large FB dimension drivers is not due solely to the large FB dimension; rather, in an effort to create large FB dimension drivers with a high MOIy value and low center of gravity (CG) dimension, golf club designers have generally created clubs that have very poor aerodynamic shaping. Several problems are the lack of proper shaping to account for airflow reattachment in the crown area trailing the face, the lack of proper shaping to promote airflow attachment after is passes the highest point on the crown, and the lack of proper trailing edge design. In addition, current driver designs have failed to obtain improved aerodynamic performance for golf club head designs that include a large projected area of the face portion (Af).
The present aerodynamic golf club head having a large projected area of the face portion (Af) and large drop contour area (CA) solves these issues and results in a high volume aerodynamic golf club head having a relatively large FB dimension with beneficial moment of inertia values, while also obtaining superior aerodynamic properties unseen by other large volume, large FB dimension, high MOI golf club heads. The golf club head obtains superior aerodynamic performance through the use of unique club head shapes and the incorporation of crown section having a drop contour area (CA) that is sufficiently large in relation to the projected area of the face portion (Af) of the golf club head.
The club head has a large projected area of the face portion (Af) and a crown having a large drop contour area (CA). The drop contour area (CA) is an area defined by the intersection of the crown with a plane that is offset toward the ground plane from the crown apex. In several embodiments, the relationship between the projected area of the face portion (Af) and the drop contour area (CA) is defined in part by linear boundary equation. The relatively large drop contour area (CA) for a given relatively large projected area of the face portion (Af) aids in keeping airflow attached to the club head once it flows past the crown apex thereby resulting in reduced aerodynamic drag forces and producing higher club head speeds.
Without limiting the scope of the present aerodynamic golf club head as claimed below and referring now to the drawings and figures:
These drawings are provided to assist in the understanding of the exemplary embodiments of the high volume aerodynamic golf club head as described in more detail below and should not be construed as unduly limiting the present golf club head. In particular, the relative spacing, positioning, sizing and dimensions of the various elements illustrated in the drawings are not drawn to scale and may have been exaggerated, reduced or otherwise modified for the purpose of improved clarity. Those of ordinary skill in the art will also appreciate that a range of alternative configurations have been omitted simply to improve the clarity and reduce the number of drawings.
The claimed high volume aerodynamic golf club head (100) enables a significant advance in the state of the art. The preferred embodiments of the club head (100) accomplish this by new and novel arrangements of elements and methods that are configured in unique and novel ways and which demonstrate previously unavailable but preferred and desirable capabilities. The description set forth below in connection with the drawings is intended merely as a description of the presently preferred embodiments of the club head (100), and is not intended to represent the only form in which the club head (100) may be constructed or utilized. The description sets forth the designs, functions, means, and methods of implementing the club head (100) in connection with the illustrated embodiments. It is to be understood, however, that the same or equivalent functions and features may be accomplished by different embodiments that are also intended to be encompassed within the spirit and scope of the club head (100).
The present high volume aerodynamic golf club head (100) has recognized that the poor aerodynamic performance of large FB dimension drivers is not due solely to the large FB dimension; rather, in an effort to create large FB dimension drivers with a high MOIy value and low center of gravity (CG) dimension, golf club designers have generally created clubs that have very poor aerodynamic shaping. The main problems are the significantly flat surfaces on the body, the lack of proper shaping to account for airflow reattachment in the crown area trailing the face, and the lack of proper trailing edge design. In addition, current large FB dimension driver designs have ignored, or even tried to maximize in some cases, the frontal cross sectional area of the golf club head which increases the aerodynamic drag force. The present aerodynamic golf club head (100) solves these issues and results in a high volume aerodynamic golf club head (100) having a large FB dimension and a high MOIy.
The present high volume aerodynamic golf club head (100) has a volume of at least 400 cc. It is characterized by a face-on normalized aerodynamic drag force of less than 1.5 lbf when exposed to a 100 mph wind parallel to the ground plane (GP) when the high volume aerodynamic golf club head (100) is positioned in a design orientation and the wind is oriented at the front (112) of the high volume aerodynamic golf club head (100), as previously described with respect to
With general reference to
The relatively large FB dimension of the present high volume aerodynamic golf club head (100) aids in obtaining beneficial moment of inertia values while also obtaining superior aerodynamic properties unseen by other large volume, large FB dimension, high MOI golf club heads. Specifically, an embodiment of the high volume aerodynamic golf club head (100) obtains a first moment of inertia (MOIy) about a vertical axis through a center of gravity (CG) of the golf club head (100), illustrated in
The golf club head (100) obtains superior aerodynamic performance through the use of unique club head shapes. Referring now to
The center of the face (200) shall be determined in accordance with the USGA “Procedure for Measuring the Flexibility of a Golf Clubhead,” Revision 2.0, Mar. 25, 2005, which is incorporated herein by reference. This USGA procedure identifies a process for determining the impact location on the face of a golf club that is to be tested, also referred therein as the face center. The USGA procedure utilizes a template that is placed on the face of the golf club to determine the face center.
Secondly, a portion of the crown section (400) between the crown apex (410) and the back (114) of the hollow body (110) has an apex-to-rear radius of curvature (Ra-r) that is less than 3.75 inches. The apex-to-rear radius of curvature (Ra-r) is also measured in a vertical plane that is perpendicular to a vertical plane passing through the shaft axis (SA), and the apex-to-rear radius of curvature (Ra-r) is further measured at the point on the crown section (400) between the crown apex (410) and the back (114) that has the smallest the radius of curvature. In one particular embodiment, at least fifty percent of the vertical plane cross sections taken perpendicular to a vertical plane passing through the shaft axis (SA), which intersect a portion of the face top edge (210), are characterized by an apex-to-rear radius of curvature (Ra-r) of less than 3.75 inches. In still a further embodiment, at least ninety percent of the vertical plane cross sections taken perpendicular to a vertical plane passing through the shaft axis (SA), which intersect a portion of the face top edge (210), are characterized by an apex-to-rear radius of curvature (Ra-r) of less than 3.75 inches. In yet another embodiment, one hundred percent of the vertical plane cross sections taken perpendicular to a vertical plane passing through the shaft axis (SA), which intersect a portion of the face top edge (210) between the center of the face (200) and the toeward most point on the face (200), are characterized by an apex-to-rear radius of curvature (Ra-r) of less than 3.75 inches.
Lastly, as seen in
With reference now to
The top edge (210) and lower edge (220) are identifiable as curves that mark a transition from the curvature of the face (200) to adjoining regions of the club head (100), such as the crown section (400), the sole section (300), or a transition region (230) between the face (200) and the crown section (400) or sole section (300) (see, e.g.,
One of many significant advances of this embodiment of the present club head (100) is the design of an apex ratio that encourages airflow reattachment on the crown section (400) of the golf club head (100) as close to the face (200) as possible. In other words, the sooner that airflow reattachment is achieved, the better the aerodynamic performance and the smaller the aerodynamic drag force. The apex ratio is the ratio of apex height (AH) to the maximum top edge height (TEH). As previously explained, in many large FB dimension golf club heads the apex height (AH) is no more than the top edge height (TEH). In this embodiment, the apex ratio is at least 1.13, thereby encouraging airflow reattachment as soon as possible.
Still further, this embodiment of the club head (100) has a frontal cross sectional area that is less than 11 square inches. The frontal cross sectional area is the single plane area measured in a vertical plane bounded by the outline of the golf club head (100) when it is resting on the ground plane (GP) at the design lie angle and viewed from directly in front of the face (200). The frontal cross sectional area is illustrated by the cross-hatched area of
In a further embodiment, a second aerodynamic drag force is introduced, namely the 30 degree offset aerodynamic drag force, as previously explained with reference to
Yet another embodiment introduces a third aerodynamic drag force, namely the heel normalized aerodynamic drag force, as previously explained with reference to
A still further embodiment has recognized that having the apex-to-front radius of curvature (Ra-f) at least 25% less than the apex-to-rear radius of curvature (Ra-r) produces a particularly aerodynamic golf club head (100) further assisting in airflow reattachment and preferred airflow attachment over the crown section (400). Yet another embodiment further encourages quick airflow reattachment by incorporating an apex ratio of the apex height (AH) to the maximum top edge height (TEH) that is at least 1.2. This concept is taken even further in yet another embodiment in which the apex ratio of the apex height (AH) to the maximum top edge height (TEH) is at least 1.25. Again, these large apex ratios produce a bulbous crown section (400) that facilitates airflow reattachment as close to the face (200) as possible, thereby resulting in reduced aerodynamic drag forces and resulting in higher club head speeds.
Reducing aerodynamic drag by encouraging airflow reattachment, or conversely discouraging extended lengths of airflow separation, may be further obtained in yet another embodiment in which the apex-to-front radius of curvature (Ra-f) is less than the apex-to-rear radius of curvature (Ra-r), and the apex-to-rear radius of curvature (Ra-r) is less than the heel-to-toe radius of curvature (Rh-t). Such a shape is contrary to conventional high volume, long FB dimension golf club heads, yet produces a particularly aerodynamic shape.
Taking this embodiment a step further in another embodiment, a high volume aerodynamic golf club head (100) having the apex-to-front radius of curvature (Ra-f) less than 2.85 inches and the heel-to-toe radius of curvature (Rh-t) less than 3.85 inches produces a reduced face-on aerodynamic drag force. Another embodiment focuses on the playability of the high volume aerodynamic golf club head (100) by having a maximum top edge height (TEH) that is at least 2 inches, thereby ensuring that the face area is not reduced to an unforgiving level. Even further, another embodiment incorporates a maximum top edge height (TEH) that is at least 2.15 inches, further instilling confidence in the golfer that they are not swinging a golf club head (100) with a small striking face (200).
The foregoing embodiments may be utilized having even larger FB dimensions. For example, the previously described aerodynamic attributes may be incorporated into an embodiment having a front-to-back dimension (FB) that is at least 4.6 inches, or even further a front-to-back dimension (FB) that is at least 4.75 inches. These embodiments allow the high volume aerodynamic golf club head (100) to obtain even higher MOIy values without reducing club head speed due to excessive aerodynamic drag forces.
Yet a further embodiment balances all of the radii of curvature requirements to obtain a high volume aerodynamic golf club head (100) while minimizing the risk of an unnatural appearing golf club head by ensuring that less than 10% of the club head volume is above the elevation of the maximum top edge height (TEH). A further embodiment accomplishes the goals herein with a golf club head (100) having between 5% to 10% of the club head volume located above the elevation of the maximum top edge height (TEH). This range achieves the desired crown apex (410) and radii of curvature to ensure desirable aerodynamic drag while maintaining an aesthetically pleasing look of the golf club head (100).
The location of the crown apex (410) is dictated to a degree by the apex-to-front radius of curvature (Ra-f); however, yet a further embodiment identifies that the crown apex (410) should be behind the forwardmost point on the face (200) a distance that is a crown apex setback dimension (412), seen in
Additionally, the heel-to-toe location of the crown apex (410) also plays a significant role in the aerodynamic drag force. The location of the crown apex (410) in the heel-to-toe direction is identified by the crown apex ht dimension (414), as seen in
The present high volume aerodynamic golf club head (100) has a club head volume of at least 400 cc. Further embodiments incorporate the various features of the above described embodiments and increase the club head volume to at least 440 cc, or even further to the current USGA limit of 460 cc. However, one skilled in the art will appreciate that the specified radii and aerodynamic drag requirements are not limited to these club head sizes and apply to even larger club head volumes. Likewise, a heel-to-toe (HT) dimension of the present club head (100), as seen in
As one skilled in the art understands, the hollow body (110) has a center of gravity (CG). The location of the center of gravity (CG) is described with reference to an origin point, seen in
Several more embodiments, seen in
As with the prior embodiments, the embodiments containing the post apex attachment promoting region (420) include a maximum top edge height (TEH) of at least 2 inches and an apex ratio of the apex height (AH) to the maximum top edge height (TEH) of at least 1.13.
As seen in
In this particular embodiment, the crown section (400) includes a post apex attachment promoting region (420) on the surface of the crown section (400). Many of the previously described embodiments incorporate characteristics of the crown section (400) located between the crown apex (410) and the face (200) that promote airflow attachment to the club head (100) thereby reducing aerodynamic drag. The post apex attachment promoting region (420) is also aimed at reducing aerodynamic drag by encouraging the airflow passing over the crown section (400) to stay attached to the club head (100); however, the post apex attachment promoting region (420) is located between the crown apex (410) and the back (114) of the club head (100), while also being above the maximum top edge height (TEH), and thus above the maximum top edge plane (MTEP).
Many conventional high volume, large MOIy golf club heads having large FB dimensions have crown sections that often never extend above the face. Further, these prior clubs often have crown sections that aggressively slope down to the sole section. While these designs appear as though they should cut through the air, the opposite is often true with such shapes achieving poor airflow reattachment characteristics and increased aerodynamic drag forces. The present club head (100) has recognized the significance of proper club head shaping to account for rapid airflow reattachment in the crown section (400) trailing the face (200) via the apex ratio, as well as encouraging the to airflow remain attached to the club head (100) behind the crown apex (410) via the apex ratio and the post apex attachment promoting region (420).
With reference to
Incorporating a post apex attachment promoting region (420) that has the claimed length (422) and width (424) establishes the amount of the club head (100) that is above the maximum top edge plane (MTEP) and behind the crown apex (410). In the past many golf club heads sough to minimize, or eliminate, the amount of club head (100) that is above the maximum top edge plane (MTEP) While the post apex attachment promoting region (420) has both a length (422) and a width (424), the post apex attachment promoting region (420) need not be rectangular in nature. For instance,
Like the previous embodiments having aerodynamic characteristics in front of the crown apex (410), the present embodiment incorporating the post apex attachment promoting region (420) located behind the crown apex (410) also has a face-on normalized aerodynamic drag force of less than 1.5 lbf when exposed to a 100 mph wind parallel to the ground plane (GP) when the high volume aerodynamic golf club head having a post apex attachment promoting region (100) is positioned in a design orientation and the wind is oriented at the front (112) of the high volume aerodynamic golf club head having a post apex attachment promoting region (100), as previously explained in detail.
In a further embodiment, a second aerodynamic drag force is introduced, namely the 30 degree offset aerodynamic drag force, as previously explained with reference to
Yet another embodiment introduces a third aerodynamic drag force, namely the heel normalized aerodynamic drag force, as previously explained with reference to
Just as the embodiments that don't incorporate a post apex attachment promoting region (420) benefit from a relatively high apex ratio of the apex height (AH) to the maximum top edge height (TEH), so to do the embodiments incorporating a post apex attachment promoting region (420). After all, by definition the post apex attachment promoting region (420) is located above the maximum top edge plane (MTEP), which means that if the apex ratio is less than 1 then there can be no post apex attachment promoting region (420). An apex ratio of at least 1.13 provides for the height of the crown apex (410) that enables the incorporation of the post apex attachment promoting region (420) to reduce aerodynamic drag forces. Yet another embodiment further encourages airflow attachment behind the crown apex (410) by incorporating an apex ratio that is at least 1.2, thereby further increasing the available area on the crown section (400) above the maximum top edge height (TEH) suitable for a post apex attachment promoting region (420). The greater the amount of crown section (400) behind the crown apex (410), but above the maximum top edge height (TEH), and having the claimed attributes of the post apex attachment promoting region (420); the more likely the airflow is to remain attached to the club head (100) as it flows past the crown apex (410) and reduce the aerodynamic drag force.
With reference to
In a further embodiment seen in
Yet another embodiment focuses not solely on the size of the post apex attachment promoting region (420), but also on the location of it. It is helpful to define a new dimension to further characterize the placement of the post apex attachment promoting region (420); namely, as seen in
Another embodiment builds upon the post apex attachment promoting region (420) by having at least 7.5 percent of the club head volume located above the maximum top edge plane (MTEP), illustrated in
As previously mentioned, in order to facilitate the post apex attachment promoting region (420), at least a portion of the crown section (400) has to be relatively flat and not aggressively sloped from the crown apex (410) toward the ground plane (GP). In fact, in one embodiment, a portion of the post apex attachment promoting region (420) has an apex-to-rear radius of curvature (Ra-r), seen in
Further embodiments incorporate a post apex attachment promoting region (420) in which a majority of the cross sections taken from the face (200) to the back (114) of the club head (100), perpendicular to the vertical plane through the shaft axis (SA), which pass through the post apex attachment promoting region (420), have an apex-to-rear radius of curvature (Ra-r) that is greater than 5 inches. In fact, in one particular embodiment, at least seventy five percent of the vertical plane cross sections taken perpendicular to a vertical plane passing through the shaft axis (SA), which pass through the post apex attachment promoting region (420), are characterized by an apex-to-rear radius of curvature (Ra-r) that is greater than 5 inches within the post apex attachment promoting region (420); thereby further promoting airflow attachment between the crown apex (410) and the back (114) of the club head (100).
Another embodiment incorporates features that promote airflow attachment both in front of the crown apex (410) and behind the crown apex (410). In this embodiment, seen in
The attributes of the claimed crown section (400) tend to keep the crown section (400) distant from the sole section (300). One embodiment, seen in
In this particular embodiment the rearwardmost SSTR point (512) and the rearwardmost SCTR point (522) need not be located vertically in-line with one another, however they are both located within the profile region angle (552) of
In a further embodiment, illustrated best in
Another embodiment advancing this principle has the rearwardmost SSTR point (512) is located on the heel (116) side of the center of gravity, and the rearwardmost SCTR point (522) is located on the toe (118) side of the center of gravity, as seen in
Several more high volume aerodynamic golf club head embodiments, seen in and described by reference to
As discussed above, the present high volume aerodynamic golf club heads have a face (200) that is intended to hit the golf ball. In a transition zone (230) of a club head the face (200) transitions to the external contour of the body (110), as shown in
For consideration of the high volume aerodynamic golf club heads seen in and described in relation to
As noted above, the face center (660) of the face (200) is determined in accordance with the USGA “Procedure for Measuring the Flexibility of a Golf Clubhead,” Revision 2.0, Mar. 25, 2005, which is incorporated herein by reference. A typical face center (660) is shown in
The club head desirably is cut first along the offset bulge radius cut plane (664) (
To determine the projected area of the face portion Af, and turning now to
A
f
=P
f*(Ar/Pr)
wherein Af is the projected area of the face portion, Pf is the pixel count in the face portion (670), Ar is the area of the reference portion (672), and Pr is the pixel count in the reference portion (672). In the example, if Ar=7.77 in2, Pf=298,890 pixels, and Pr=259,150 pixels, then Af=9.14 in2.
It will be understood that the pixel-counting technique described above is an example of a technique capable of measuring area accurately and precisely. Other area-measurement techniques can be employed in alternative methods
In various embodiments, the projected area of the face portion Af is generally greater than 8.3 in2, desirably in the range of 8.3 to 15.5 in2, more desirably in the range of 9.0 to 12.5 in2, and most desirably in the range of 9.5 to 10.5 in2.
The golf club head (100) embodiments shown in and described in relation to
Using the foregoing methods for measuring projected area of the face portion (Af) and the 8 mm drop contour area (CA), swing path data was investigated for a number of example golf clubs. For a given golf club head orientation, the drag force of the club head moving through air can be calculated according to the following equation:
Drag Force=0.5*ρ*u2*Cd*A
where ρ is the air density, u is the airspeed of the club head, Cd is the drag coefficient, and A is the projected area of the golf club head. Resolving the equation for the product Cd*A provides the following:
Cd*A=Drag Force/0.5*ρ*u2
Through swing path analysis, it was found that the range along the swing path between 6 degree and 12 degree pitched up orientations of the golf club head were the most important for contributing to club head aerodynamics because it is within this range of club head orientation that the club head aerodynamic performance will have the most impact on club head speed. A drag force for the number of example golf clubs described above was measured experimentally under known conditions of air speed and air density. Values for the product of Cd*A were then determined for the golf club heads. These results were then plotted against the measured 8 mm drop contour area for the golf club heads in the 6 degree pitched up orientation. The results are provided in the graph shown in
Turning next to
In particular, as shown in
CA=−1.5395*Af+19.127 Eq. 1
In Equation 1, CA is the 8 mm drop contour area (at the 12 degree pitched orientation), expressed in square inches, and Af is the projected area of the face portion (as defined hereinabove), also expressed in square inches. The novel club head region extends between a projected area of the face portion (Af) of 8.3 in2 to 11.25 in2 on the x-axis, and extends between about 6.5 in2 down to the boundary of Equation 1 described above on the y-axis. A narrower novel club head region extends between about 6.0 in2 and the boundary of Equation 1 on the y-axis, and has an x-axis limit between a projected area of the face portion (Af) of 8.5 in2 to 10.75 in2, 8.75 in2 to 10.75 in2, 9.0 in2 to 10.5 in2, or 9.0 in2 to 10.25 in2.
Turning to
CA=−1.5395*Af+19.627 Eq. 2
In Equation 2, CA is the 8 mm drop contour area (at the 12 degree pitched orientation), expressed in square inches, and Af is the projected area of the face portion (as defined hereinabove), also expressed in square inches. The novel club head region shown in
Turning to
CA=−1.5395*Af+19.877 Eq. 3
In Equation 3, CA is the 8 mm drop contour area (at the 12 degree pitched orientation), expressed in square inches, and Af is the projected area of the face portion (as defined hereinabove), also expressed in square inches. The novel club head region shown in
Turning next to
CA=−1.5395*Af+17.625 Eq. 4
In Equation 4, CA is the 8 mm drop contour area (at the 12 degree pitched orientation), expressed in square inches, and Af is the projected area of the face portion (as defined hereinabove), also expressed in square inches. The novel club head region shown in
Turning next to
CA=−1.5395*Af+18.725 Eq. 5
In Equation 5, CA is the 8 mm drop contour area (at the 12 degree pitched orientation), expressed in square inches, and Af is the projected area of the face portion (as defined hereinabove), also expressed in square inches. The novel club head region shown in
Turning next to
CA=−1.5395*Af+19.825 Eq. 6
In Equation 6, CA is the 8 mm drop contour area (at the 12 degree pitched orientation), expressed in square inches, and Af is the projected area of the face portion (as defined hereinabove), also expressed in square inches. The novel club head region shown in
In several embodiments, the larger projected area of the face portion (Af) may be achieved by providing a golf club head (100) that includes one or more parts formed from a lightweight material, including conventional metallic and nonmetallic materials known and used in the art, such as steel (including stainless steel), titanium alloys, magnesium alloys, aluminum alloys, carbon fiber composite materials, glass fiber composite materials, carbon pre-preg materials, polymeric materials, and the like. For example, in some embodiments, the face (200) may be provided as a face insert formed of a composite material.
According to several additional embodiments, a desired combination of a relatively large projected area of the face portion (Af) and relatively large 8 mm drop contour area (CA) may be obtained by the provision of thin wall construction for one or more parts of the golf club head. Among other advantages, thin wall construction facilitates the redistribution of material from one part of a club head to another part of the club head. Because the redistributed material has a certain mass, the material may be redistributed to locations in the golf club head to enhance performance parameters related to mass distribution, such as CG location and moment of inertia magnitude. Club head material that is capable of being redistributed without affecting the structural integrity of the club head is commonly called discretionary weight. In some embodiments of the presently described high volume aerodynamic golf club head, thin wall construction enables discretionary weight to be removed from one or a combination of the striking plate, crown, skirt, or sole and redistributed in the form of weight ports and corresponding weights.
Thin wall construction can include a thin sole construction, e.g., a sole with a thickness less than about 0.9 mm but greater than about 0.4 mm over at least about 50% of the sole surface area; and/or a thin skirt construction, e.g., a skirt with a thickness less than about 0.8 mm but greater than about 0.4 mm over at least about 50% of the skirt surface area; and/or a thin crown construction, e.g., a crown with a thickness less than about 0.8 mm but greater than about 0.4 mm over at least about 50% of the crown surface area. In one embodiment, the club head is made of titanium and has a thickness less than 0.65 mm over at least 50% of the crown in order to free up enough weight to achieve the desired CG location.
The thin wall construction can be described according to areal weight as defined by the equation below:
AW=ρ·t
In the above equation, AW is defined as areal weight, p is defined as density, and t is defined as the thickness of the material. In one exemplary embodiment, the golf club head is made of a material having a density, p, of about 4.5 g/cm3 or less. In one embodiment, the thickness of a crown or sole portion is between about 0.04 cm and about 0.09 cm. Therefore the areal weight of the crown or sole portion is between about 0.18 g/cm2 and about 0.41 g/cm2. In some embodiments, the areal weight of the crown or sole portion is less than 0.41 g/cm2 over at least about 50% of the crown or sole surface area. In other embodiments, the areal weight of the crown or sole is less than about 0.36 g/cm2 over at least about 50% of the entire crown or sole surface area.
In certain embodiments, the thin wall construction may be implemented according to U.S. patent application Ser. No. 11/870,913 and/or U.S. Pat. No. 7,186,190, which are incorporated by reference herein in their entirety.
Several of the features of the high volume aerodynamic golf club heads described herein—including the provision of a relatively large projected area of the face portion (Af) and relatively large 8 mm drop contour area (CA)—will tend to cause the location of the center of gravity (CG) to be relatively higher (i.e., larger Ycg value) than a comparably constructed golf club head that does not include these features. Through the provision of one or more of the features described above, such as a lightweight face and/or lightweight construction in other parts of the golf club head, along with relocation of discretionary weight to other parts of the club head, several embodiments of the presently described high volume aerodynamic golf club heads may obtain a desirable downward shift in the location of the center of gravity (CG).
As noted above, the hollow body (110) has center of gravity coordinates (Xcg, Ycg, Zcg) that are described with reference to the origin point, seen in
Several of the high volume aerodynamic golf club embodiments described above in relation to
The high volume aerodynamic golf club head (100) described in relation to
Moreover, several embodiments of the high volume aerodynamic golf club head (100) described in relation to
Still other embodiments of the high volume aerodynamic golf club head (100) described in relation to
Ra-f<Ra-r<Rh-t.
Still other embodiments of the club head described in relation to
Several additional embodiments may include a crown apex setback dimension (412) that is less than 1.75 inches. Still other embodiments may include a crown apex (410) location that results in a crown apex ht dimension (414) that is greater than 30% of the HT dimension and less than 70% of the HT dimension, thereby aiding in reducing the period of airflow separation. In an even further embodiment, the crown apex (410) may be located in the heel-to-toe direction between the center of gravity (CG) and the toe (118).
Moreover, the high volume aerodynamic golf club head embodiments described above in relation to
All of the previously described aerodynamic characteristics with respect to the crown section (400) apply equally to the sole section (300) of the high volume aerodynamic golf club head (100). In other words, one skilled in the art will appreciate that just like the crown section (400) has a crown apex (410), the sole section (300) may have a sole apex. Likewise, the three radii of the crown section (400) may just as easily be three radii of the sole section (300). Thus, all of the embodiments described herein with respect to the crown section (400) are incorporated by reference with respect to the sole section (300).
The various parts of the golf club head (100) may be made from any suitable or desired materials without departing from the claimed club head (100), including conventional metallic and nonmetallic materials known and used in the art, such as steel (including stainless steel), titanium alloys, magnesium alloys, aluminum alloys, carbon fiber composite materials, glass fiber composite materials, carbon pre-preg materials, polymeric materials, and the like. The various sections of the club head (100) may be produced in any suitable or desired manner without departing from the claimed club head (100), including in conventional manners known and used in the art, such as by casting, forging, molding (e.g., injection or blow molding), etc. The various sections may be held together as a unitary structure in any suitable or desired manner, including in conventional manners known and used in the art, such as using mechanical connectors, adhesives, cements, welding, brazing, soldering, bonding, and other known material joining techniques. Additionally, the various sections of the golf club head (100) may be constructed from one or more individual pieces, optionally pieces made from different materials having different densities, without departing from the claimed club head (100).
Until noted otherwise, the element numbers in the following disclosure is directed to
The crown 12 is defined as an upper portion of the club head (1) above a peripheral outline 34 of the club head as viewed from a top-down direction; and (2) rearwards of the topmost portion of a ball striking surface 22 of the striking face 18 (see
A golf club head, such as the club head 2, is at its proper address position when the longitudinal axis 21 of the hosel 20 or shaft is substantially normal to the target direction and at the proper lie angle such that the scorelines are substantially horizontal (e.g., approximately parallel to the ground plane 17) and the face angle relative to target line is substantially square (e.g., the horizontal component of a vector normal to the geometric center of the striking surface 22 substantially points towards the target line). If the faceplate 18 does not have horizontal scorelines, then the proper lie angle is set at an approximately 60-degrees. The loft angle 15 is the angle defined between a face plane 27, defined as the plane tangent to an ideal impact location 23 on the striking surface 22, and a vertical plane 29 relative to the ground 17 when the club head 2 is at proper address position. Lie angle 19 is the angle defined between a longitudinal axis 21 of the hosel 20 or shaft and the ground 17 when the club head 2 is at proper address position. The ground, as used herein, is assumed to be a level plane.
The skirt 16 includes a side portion of the club head 2 between the crown 12 and the sole 14 that extends across a periphery 34 of the club head, excluding the striking surface 22, from the toe portion 28, around the rear portion 32, to the heel portion 26.
In the illustrated embodiment, the ideal impact location 23 of the golf club head 2 is disposed at the geometric center of the striking surface 22 (see
A club head origin coordinate system may be defined such that the location of various features of the club head (including, e.g., a club head center-of-gravity (CG) 50 (see
Referring to
Referring to
Referring to
A moment of inertia about the golf club head CG x-axis 90 is calculated by the following equation
Ixx=∫(y2+z2)dm
where y is the distance from a golf club head CG xz-plane to an infinitesimal mass dm and z is the distance from a golf club head CG xy-plane to the infinitesimal mass dm. The golf club head CG xz-plane is a plane defined by the golf club head CG x-axis 90 and the golf club head CG z-axis 85. The CG xy-plane is a plane defined by the golf club head CG x-axis 90 and the golf club head CG y-axis 95.
A moment of inertia about the golf club head CG z-axis 85 is calculated by the following equation
Izz=∫(x2+y2)dm
where x is the distance from a golf club head CG yz-plane to an infinitesimal mass dm and y is the distance from the golf club head CG xz-plane to the infinitesimal mass dm. The golf club head CG yz-plane is a plane defined by the golf club head CG y-axis 95 and the golf club head CG z-axis 85.
As the moment of inertia about the CG z-axis (Izz) is an indication of the ability of a golf club head to resist twisting about the CG z-axis, the moment of inertia about the CG x-axis (Ixx) is an indication of the ability of the golf club head to resist twisting about the CG x-axis. The higher the moment of inertia about the CG x-axis (Ixx), the greater the forgiveness of the golf club head on high and low off-center impacts with a golf ball. In other words, a golf ball hit by a golf club head on a location of the striking surface 18 above the ideal impact location 23 causes the golf club head to twist upwardly and the golf ball to have a higher trajectory than desired. Similarly, a golf ball hit by a golf club head on a location of the striking surface 18 below the ideal impact location 23 causes the golf club head to twist downwardly and the golf ball to have a lower trajectory than desired. Increasing the moment of inertia about the CG x-axis (Ixx) reduces upward and downward twisting of the golf club head to reduce the negative effects of high and low off-center impacts.
In some implementations, the striking surface 122 golf club head 100 has a height (Hss) between approximately 45 mm and approximately 65 mm, and a width (Wss) between approximately 75 mm and approximately 105 mm. In one specific implementation, the striking face 122 has a height (Hss) of approximately 54.4 mm, width (Wss) of approximately 90.6 mm, and total striking surface area of approximately 4,098 mm2.
In some implementations, the golf club head 100 has a height (Hch) between approximately 48 mm and approximately 72 mm, a width (Wch) between approximately 100 mm and approximately 130 mm, and a depth (Dch) between approximately 100 mm and approximately 130 mm. In one specific implementation, the golf club head 100 has a height (Hch) of approximately 62.2 mm, width (Wch) of approximately 119.3 mm, and depth (Dch) of approximately 103.9 mm.
In at least one implementation, the golf club head 100 includes a weight port 140 formed in the skirt 116 proximate the rear portion 132 of the club head (see
Now having defined the coordinate system for CG location and definition of moments of inertia, we turn our attention away from
As used herein, the singular forms “a,” “an,” and “the” refer to one or more than one, unless the context clearly dictates otherwise.
As used herein, the term “includes” means “comprises.” For example, a device that includes or comprises A and B contains A and B but may optionally contain C or other components other than A and B. A device that includes or comprises A or B may contain A or B or A and B, and optionally one or more other components such as C.
Referring first to
Both Hss and Wss are determined using the striking face curve (Sss). The striking face curve is bounded on its periphery by all points where the face transitions from a substantially uniform bulge radius (face heel-to-toe radius of curvature) and a substantially uniform roll radius (face crown-to-sole radius of curvature) to the body (see e.g.,
As shown in
As shown in
As shown in
The lie angle 10 and/or the shaft loft can be modified by adjusting the position of the shaft 50 relative to the club head. Traditionally, adjusting the position of the shaft has been accomplished by bending the shaft and the hosel relative to the club head. As shown in
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. 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.
Now with reference to
By way of example, the club head 300 comprises the head of a “wood-type” golf club. All of the embodiments disclosed in the present specification can be implemented in all types of golf clubs, including but not limited to, drivers, fairway woods, utility clubs, putters, wedges, etc. As used herein, a shaft that is “removably attached” to a club head means that the shaft can be connected to the club head using one or more mechanical fasteners, such as a screw or threaded ferrule, without an adhesive, and the shaft can be disconnected and separated from the head by loosening or removing the one or more mechanical fasteners without the need to break an adhesive bond between two components.
The sleeve 100 is mounted to a lower, or tip end portion 90 of the shaft 50. The sleeve 100 can be adhesively bonded, welded or secured in equivalent fashion to the lower end portion of the shaft 50. In other embodiments, the sleeve 100 may be integrally formed as part of the shaft 50. As shown in
As best shown in
To restrict rotational movement of the shaft 50 relative to the head 300 when the club head 300 is attached to the shaft 50, the sleeve 100 has a rotation prevention portion that mates with a complementary rotation prevention portion of the insert 200. In the illustrated embodiment, for example, the shaft sleeve has a lower portion 150 having a non-circular configuration complementary to a non-circular configuration of the hosel insert 200. In this way, the sleeve lower portion 150 defines a keyed portion that is received by a keyway defined by the hosel insert 200. In particular embodiments, the rotational prevention portion of the sleeve comprises longitudinally extending external splines 500 formed on an external surface 160 of the sleeve lower portion 150, as illustrated in
In the illustrated embodiment of
It is desirable that a golf club employing a removable club head-shaft connection assembly as described in the present application have substantially similar weight and distribution of mass as an equivalent conventional golf club so that the golf club employing a removable shaft has the same “feel” as the conventional club. Thus, it is desired that the various components of the connection assembly (e.g., the sleeve 100, the hosel insert 200 and the screw 400) are constructed from light-weight, high-strength metals and/or alloys (e.g., T6 temper aluminum alloy 7075, grade 5 6Al-4V titanium alloy, etc.) and designed with an eye towards conserving mass that can be used elsewhere in the golf club to enhance desirable golf club characteristics (e.g., increasing the size of the “sweet spot” of the club head or shifting the center of gravity to optimize launch conditions).
The golf club having an interchangeable shaft and club head as described in the present application provides a golfer with a club that can be easily modified to suit the particular needs or playing style of the golfer. A golfer can replace the club head 300 with another club head having desired characteristics (e.g., different loft angle, larger face area, etc.) by simply unscrewing the screw 400 from the sleeve 100, replacing the club head and then screwing the screw 400 back into the sleeve 100. The shaft 50 similarly can be exchanged. In some embodiments, the sleeve 100 can be removed from the shaft 50 and mounted on the new shaft, or the new shaft can have another sleeve already mounted on or formed integral to the end of the shaft.
In particular embodiments, any number of shafts are provided with the same sleeve and any number of club heads is provided with the same hosel configuration and hosel insert 200 to receive any of the shafts. In this manner, a pro shop or retailer can stock a variety of different shafts and club heads that are interchangeable. A club or a set of clubs that is customized to suit the needs of a consumer can be immediately assembled at the retail location.
With reference now to
As shown in
As noted above, the rotation prevention portion of the sleeve 100 for restricting relative rotation between the shaft and the club comprises a plurality of external splines 500 formed on an external surface of the lower portion 150 and gaps, or keyways, between adjacent splines 500. Each keyway has an outer surface 160. In the illustrated embodiment of
Embodiments employing the spline configuration depicted in
The non-circular configuration of the sleeve lower portion 150 can be adapted to limit the manner in which the sleeve 100 is positionable within the hosel insert 200. In the illustrated embodiment of
The sleeve lower portion 150 can have a generally rougher outer surface relative to the remaining surfaces of the sleeve 100 in order to provide, for example, greater friction between the sleeve 100 and the hosel insert 200 to further restrict rotational movement between the shaft 50 and the club head 300. In particular embodiments, the external surface 160 can be roughened by sandblasting, although alternative methods or techniques can be used.
The general configuration of the sleeve 100 can vary from the configuration illustrated in
With reference now to
With reference to the features of
Selected surfaces of the hosel insert 200 can be roughened in a similar manner to the exterior surface 160 of the shaft. In some embodiments, the entire surface area of the insert can be provided with a roughened surface texture. In other embodiments, only the inner surface 240 of the hosel insert 200 can be roughened.
With reference now to
The head 410 of the screw can be configured to be compatible with a torque wrench or other torque-limiting mechanism. In some embodiments, the screw head comprises a “hexalobular” internal driving feature (e.g., a TORX screw drive) (such as shown in
The club head-shaft connection desirably has a low axial stiffness. The axial stiffness, k, of an element is defined as
K=(E*A)/L
where E is the Young's modulus of the material of the element, A is the cross-sectional area of the element and L is the length of the element. The lower the axial stiffness of an element, the greater the element will elongate when placed in tension or shorten when placed in compression. A club head-shaft connection having low axial stiffness is desirable to maximize elongation of the screw 400 and the sleeve, allowing for greater preload to be applied to the screw 400 for better retaining the shaft to the club head. For example, with reference to
The axial stiffness of the club head-shaft connection, keff, can be determined by the equation
(1/keff)=(1/kscrew)+(1/(ksleeve+kshaft)
where kscrew, kshaft and ksleeve are the stiffnesses of the screw, shaft, and sleeve, respectively, over the portions that have associated lengths Lscrew, Lshaft, and Lsleeve, respectively, as shown in
Accordingly, kscrew, kshaft and ksleeve can be determined using the lengths in Equation 7. Table 1 shows calculated k values for certain components and combinations thereof for the connection assembly of
The components of the connection assembly can be modified to achieve different values. For example, the screw 400 can be longer than shown in
In the illustrated embodiment of
In certain embodiments, a shaft sleeve can have 4, 6, 8, 10, or 12 splines. The height H of the splines of the shaft sleeve in particular embodiments can range from about 0.15 mm to about 0.95 mm, and more particularly from about 0.25 mm to about 0.75 mm, and even more particularly from about 0.5 mm to about 0.75 mm. The average diameter D of the spline portion of the shaft sleeve can range from about 6 mm to about 12 mm, with 8.45 mm being a specific example. As shown in
The length L of the splines of the shaft sleeve in particular embodiments can range from about 2 mm to about 10 mm. For example, when the connection assembly is implemented in a driver, the splines can be relatively longer, for example, 7.5 mm or 10 mm. When the connection assembly is implemented in a fairway wood, which is typically smaller than a driver, it is desirable to use a relatively shorter shaft sleeve because less space is available inside the club head to receive the shaft sleeve. In that case, the splines can be relatively shorter, for example, 2 mm or 3 mm in length, to reduce the overall length of the shaft sleeve.
The ratio of spline width W1 (at the midspan of the spline) to average diameter of the spline portion of the shaft sleeve in particular embodiments can range from about 0.1 to about 0.5, and more desirably, from about 0.15 to about 0.35, and even more desirably from about 0.16 to about 0.22. The ratio of spline width W1 to spline H in particular embodiments can range from about 1.0 to about 22, and more desirably from about 2 to about 4, and even more desirably from about 2.3 to about 3.1. The ratio of spline length L to average diameter in particular embodiments can range from about 0.15 to about 1.7.
Tables 2-4 below provide dimensions for a plurality of different spline configurations for the sleeve 100 (and other shaft sleeves disclosed herein). In Table 2, the average radius R is the radius of the spline portion of a shaft sleeve measured at the mid-span of a spine, i.e., at a location equidistant from the base of the spline at surface 160 and to the outer surface 550 of the spline (see
Table 2 shows the spline arc angle, average radius, average diameter, arc length, arc length, arc length/average radius ratio, width at midspan, width (at midspan)/average diameter ratio for different shaft sleeves having 8 splines (with two 33 degree gaps as shown in
The specific dimensions provided in the present specification for the shaft sleeve 100 (as well as for other components disclosed herein) are given to illustrate the invention and not to limit it. The dimensions provided herein can be modified as needed in different applications or situations.
Now with reference to
The shaft sleeve 900 can be adhesively bonded, welded or secured in equivalent fashion to the lower end portion of the shaft 800. In other embodiments, the shaft sleeve 900 may be integrally formed with the shaft 800. As best shown in
Rotational movement of the shaft 800 relative to the club head 700 can be restricted by restricting rotational movement of the shaft sleeve 900 relative to the hosel sleeve 1000 and by restricting rotational movement of the hosel sleeve 1000 relative to the club head 700. To restrict rotational movement of the shaft sleeve 900 relative to the hosel sleeve 1000, the shaft sleeve has a lower, rotation prevention portion 950 having a non-circular configuration that mates with a complementary, non-circular configuration of a lower, rotation prevention portion 1096 inside the hosel sleeve 1000. The rotation prevention portion of the shaft sleeve 900 can comprise longitudinally extending splines 1400 formed on an external surface 960 of the lower portion 950, as best shown in
To restrict rotational movement of the hosel sleeve 1000 relative to the club head 700, the hosel sleeve 1000 can have a lower, rotation prevention portion 1050 having a non-circular configuration that mates with a complementary, non-circular configuration of a rotation prevention portion of the hosel insert 1100. The rotation prevention portion of the hosel sleeve can comprise longitudinally extending splines 1500 formed on an external surface 1090 of a lower portion 1050 of the hosel sleeve 1000, as best shown in
Accordingly, the shaft sleeve lower portion 950 defines a keyed portion that is received by a keyway defined by the hosel sleeve inner surface 1096, and hosel sleeve outer surface 1050 defines a keyed portion that is received by a keyway defined by the hosel insert inner surface 1140. In alternative embodiments, the rotation prevention portions can be elliptical, rectangular, hexagonal or other non-circular complementary configurations of the shaft sleeve lower portion 950 and the hosel sleeve inner surface 1096, and the hosel sleeve outer surface 1050 and the hosel insert inner surface 1140.
Referring to
The hosel sleeve 1000 is configured to support the shaft 50 at a desired orientation relative to the club head to achieve a desired shaft loft and/or lie angle for the club. As best shown in
Consequently, the hosel sleeve 1000 can be positioned in the hosel insert 1100 in one or more positions to adjust the shaft loft and/or lie angle of the club. For example,
Referring to
Similarly, the shaft sleeve 900 can be inserted into the hosel sleeve at various angularly spaced positions around longitudinal axis A. Consequently, if the orientation of the shaft relative to the club head is adjusted by rotating the position of the hosel sleeve 1000, the position of the shaft sleeve within the hosel sleeve can be adjusted to maintain the rotational position of the shaft relative to longitudinal axis A. For example, if the hosel sleeve is rotated 90 degrees with respect to the hosel insert, the shaft sleeve can be rotated 90 degrees in the opposite direction with respect to the hosel sleeve in order to maintain the position of the shaft relative to its longitudinal axis. In this manner, the grip of the shaft and any visual indicia on the shaft can be maintained at the same position relative to the shaft axis as the shaft loft and/or lie angle is adjusted.
In another example, a connection assembly can employ a hosel sleeve that is positionable at eight angularly spaced positions within the hosel insert 1100, as represented by cross hairs A1-A8 in
The connection assembly embodiment illustrated in
Thus, the use of a hosel sleeve in the shaft-head connection assembly allows the golfer to adjust the position of the shaft relative to the club head without having to resort to such traditional methods such as bending the shaft relative to the club head as described above. For example, consider a golf club utilizing the club head-shaft connection assembly of
In particular embodiments, the replacement hosel sleeves could be purchased individually from a retailer. In other embodiments, a kit comprising a plurality of hosel sleeves, each having a different offset angle can be provided. The number of hosel sleeves in the kit can vary depending on a desired range of offset angles and/or a desired granularity of angle adjustments. For example, a kit can comprise hosel sleeves providing offset angles from 0 degrees to 3 degrees, in 0.5 degree increments.
In particular embodiments, hosel sleeve kits that are compatible with any number of shafts and any number of club heads having the same hosel configuration and hosel insert 1100 are provided. In this manner, a pro shop or retailer need not necessarily stock a large number of shaft or club head variations with various loft, lie and/or face angles. Rather, any number of variations of club characteristic angles can be achieved by a variety of hosel sleeves, which can take up less retail shelf and storeroom space and provide the consumer with a more economic alternative to adjusting loft, lie or face angles (i.e., the golfer can adjust a loft angle by purchasing a hosel sleeve instead of a new club).
With reference now to
The shaft sleeve 900 further comprises an opening 944 extending the length of the shaft sleeve 900, as depicted in
In particular embodiments, the rotation prevention portion of the shaft sleeve comprises a plurality of splines 1400 on an external surface 960 of the lower portion 950 that are elongated in the direction of the longitudinal axis of the shaft sleeve 900, as shown in
With reference now to
The hosel sleeve 1000 further comprises an opening 1040 extending the length of the hosel sleeve 1000. The hosel sleeve opening 1040 has an upper portion 1094 with internal sidewalls 1095 that are complementary configured to the configuration of the shaft sleeve middle portion 910, and a lower portion 1096 defining a rotation prevention portion having a non-circular configuration complementary to the configuration of shaft sleeve lower portion 950.
The non-circular configuration of the hosel sleeve lower portion 1096 comprises a plurality of splines 1600 formed on an inner surface 1650 of the opening lower portion 1096. With reference to
The splines 1600 in the illustrated embodiment have sidewalls 1620 extending radially inwardly from the inner surface 1650 and arcuate inner surfaces 1630.
The external surface of the lower portion 1050 defines a rotation prevention portion comprising four splines 1500 elongated in the direction of and are parallel to longitudinal axis B defined by the external surface of the lower portion, as depicted in
The splined configuration of the shaft sleeve 900 dictates the degree to which the shaft sleeve 900 is positionable within the hosel sleeve 1000. In the illustrated embodiment of
The external surface of the shaft sleeve lower portion 950, the internal surface of the hosel sleeve opening lower portion 1096, the external surface of the hosel sleeve lower portion 1050, and the internal surface of the hosel insert can have generally rougher surfaces relative to the remaining surfaces of the shaft sleeve 900, the hosel sleeve 1000 and the hosel insert. The enhanced surface roughness provides, for example, greater friction between the shaft sleeve 900 and the hosel sleeve 1000 and between the hosel sleeve 1000 and the hosel insert 1100 to further restrict relative rotational movement between these components. The contacting surfaces of shaft sleeve, the hosel sleeve and the hosel insert can be roughened by sandblasting, although alternative methods or techniques can be used.
With reference now to
With reference now to
The head 1330 of the screw 1300 can be similar to the head 410 of the screw 400 (
As best shown in
For example, in the illustrated embodiment of
The hosel opening 3004 is also adapted to receive a hosel insert 200 (described in detail above), which can be positioned on an annular shoulder 3012 inside the club head. The hosel insert 200 can be secured in place by welding, an adhesive, or other suitable techniques. Alternatively, the insert can be integrally formed in the hosel opening The club head 3000 further includes an opening 3014 in the bottom or sole of the club head that is sized to receive a screw 400. Much like the embodiment shown in
If desired, a screw capturing device, such as in the form of an o-ring or washer 3036, can be placed on the shaft of the screw 400 above shoulder 3012 to retain the screw in place within the club head when the screw is loosened to permit removal of the shaft from the club head. The ring 3036 desirably is dimensioned to frictionally engage the threads of the screw and has a outer diameter that is greater than the central opening in shoulder 3012 so that the ring 3036 cannot fall through the opening. When the screw 400 is tightened to secure the shaft to the club head, as depicted in
The shaft sleeve 3006 is shown in greater detail in
Unlike the embodiment shown in
As best shown in
As further shown in
Other shaft sleeve and hosel insert configurations can be used to vary the number of possible angular positions for the shaft sleeve relative to the longitudinal axis B.
As can be appreciated, the assembly shown in
The shaft sleeve 3056 has a lower portion 3058 including splines that mate with the splines of the hosel insert 200, an intermediate portion 3060 and an upper head portion 3062. The intermediate portion 3060 and the head portion 3062 define an internal bore 3064 for receiving the tip end portion of the shaft. In the illustrated embodiment, the intermediate portion 3060 of the shaft sleeve has a cylindrical external surface that is concentric with the inner cylindrical surface of the hosel opening 3054. In this manner, the lower and intermediate portions 3058, 3060 of the shaft sleeve and the hosel opening 3054 define a longitudinal axis B. The bore 3064 in the shaft sleeve defines a longitudinal axis A to support the shaft along axis A, which is offset from axis B by a predetermined angle 3066 determined by the bore 3064. As described above, inserting the shaft sleeve 3056 at different angular positions relative to the hosel insert 200 is effective to adjust the shaft loft and/or the lie angle.
In this embodiment, because the intermediate portion 3060 is concentric with the hosel opening 3054, the outer surface of the intermediate portion 3060 can contact the adjacent surface of the hosel opening, as depicted in
As discussed above, the grounded loft 80 of a club head is the vertical angle of the centerface normal vector when the club is in the address position (i.e., when the sole is resting on the ground), or stated differently, the angle between the club face and a vertical plane when the club is in the address position. When the shaft loft of a club is adjusted, such as by employing the system disclosed in
Conventional clubs do not allow for adjustment of the hosel/shaft loft without causing a corresponding change in the face angle.
The bottom portion 2022 comprises an adjustable sole 2010 (also referred to as an adjustable “sole portion”) that can be adjusted relative to the club head body 2002 to raise and lower at least the rear end of the club head relative to the ground. As shown, the sole 2010 has a forward end portion 2012 and a rear end portion 2014. The sole 2010 can be a flat or curved plate that can be curved to conform to the overall curvature of the bottom 2022 of the club head. The forward end portion 2012 is pivotably connected to the body 2002 at a pivot axis defined by pivot pins 2020 to permit pivoting of the sole relative to the pivot axis. The rear end portion 2014 of the sole therefore can be adjusted upwardly or downwardly relative to the club head body so as to adjust the “sole angle” 2018 of the club (
The club head can have an adjustment mechanism that is configured to permit manual adjustment of the sole 2010. In the illustrated embodiment, for example, an adjustment screw 2016 extends through the rear end portion 2014 and into a threaded opening in the body (not shown). The axial position of the screw relative to the sole 2010 is fixed so that adjustment of the screw causes corresponding pivoting of the sole 2010. For example, turning the screw in a first direction lowers the sole 2010 from the position shown in solid lines to the position shown in dashed lines in
Moreover, other techniques or mechanisms can be implemented in the club head 2000 to permit raising and lowering of the sole angle of the club. For example, the club head can comprise one or more lifts that are located near the rear end of the club head, such as shown in the embodiment of
In particular embodiments, the hosel 2008 of the club head can be configured to support a removable shaft at different predetermined orientations to permit adjustment of the shaft loft and/or lie angle of the club. For example, the club head 2000 can be configured to receive the assembly described above and shown in
Varying the sole angle of the club head changes the address position of the club head, and therefore the face angle of the club head. By adjusting the position of the sole and by adjusting the shaft loft (either by conventional bending or using a removable shaft system as described herein), it is possible to achieve various combinations of square loft and face angle with one club. Moreover, it is possible to adjust the shaft loft (to adjust square loft) while maintaining the face angle of club by adjusting the sole a predetermined amount.
As an example, Table 5 below shows various combinations of square loft, grounded loft, face angle, sole angle, and hosel loft that can be achieved with a club head that has a nominal or initial square loft of 10.4 degrees and a nominal or initial face angle of 6.0 degrees and a nominal or initial grounded loft of 14 degrees at a 60-degree lie angle. The nominal condition in Table 5 has no change in sole angle or hosel loft angle (i.e., Asole angle=0.0 and Ahosel loft angle=0.0). The parameters in the other rows of
Table 5 are deviations to this nominal state (i.e., either the sole angle and/or the hosel loft angle has been changed relative to the nominal state). In this example, the hosel loft angle is increased by 2 degrees, decreased by 2 degrees or is unchanged, and the sole angle is varied in 2-degree increments. As can be seen in the table, these changes in hosel loft angle and sole angle allows the square loft to vary from 8.4, 10.4, and 12.4 with face angles of −4.0, −0.67, 2.67, −7.33, 6.00, and 9.33. In other examples, smaller increments and/or larger ranges for varying the sole angle and the hosel loft angle can be used to achieve different values for square loft and face angle.
Also, it is possible to decrease the hosel loft angle and maintain the nominal face angle of 6.0 degrees by increasing the sole angle as necessary to achieve a 6.0-degree face angle at the adjusted hosel loft angle. For example, decreasing the hosel loft angle by 2 degrees of the club head represented in Table 5 will increase the face angle to 9.33 degrees. Increasing the sole angle to about 2.0 degrees will readjust the face angle to 6.0 degrees.
The bottom portion 4022 further includes an adjustable sole portion 4010 that can be adjusted relative to the club head body 4002 to raise and lower the rear end of the club head relative to the ground. As best shown in
Therefore, the golfer is better able to align the club with the desired direction of the target line. In some embodiments, the top-line transition is clearly delineated by a masking line between the painted crown and the unpainted face.
The sole portion 4010 has a first edge 4018 located toward the heel of the club head and a second edge 4020 located at about the middle of the width of the club head. In this manner, the sole portion 4010 (from edge 4018 to edge 4020) has a length that extends transversely across the club head less than half the width of the club head. As noted above, studies have shown that most golfers address the ball with a lie angle between 10 and 20 degrees less than the intended scoreline lie angle of the club head (the lie angle when the club head is in the address position). The length of the sole portion 4010 in the illustrated embodiment is selected to support the club head on the ground at the grounded address position or any lie angle between 0 and 20 degrees less than the lie angle at the grounded address position. In alternative embodiments, the sole portion 4010 can have a length that is longer or shorter than that of the illustrated embodiment to support the club head at a greater or smaller range of lie angles. For example, the sole portion 4010 can extend past the middle of the club head to support the club head at lie angles that are greater than the scoreline lie angle (the lie angle at the grounded address position).
As best shown in
In an alternative embodiment, the axial position of each of the screws 4016 relative to the sole portion 4010 is fixed so that adjustment of the screws causes the sole portion 4010 to move away from or closer to the club head. Adjusting the sole portion 4010 downwardly increases the sole angle of the club head while adjusting the sole portion upwardly decreases the sole angle of the club head. When a golfer changes the actual lie angle of the club by tilting the club toward or away from the body so that the club head deviates from the grounded address position, there is a slight corresponding change in face angle due to the loft of the club head. The effective face angle, eFA, of the club head is a measure of the face angle with the loft component removed (i.e. the angle between the horizontal component of the face normal vector and the target line vector), and can be determined by the following equation:
where Δlie=measured lie angle−scoreline lie angle, GL is the grounded loft angle of the club head, and MFA is the measured face angle.
As noted above, the adjustable sole portion 4010 has a lower surface 4012 that matches the curvature of the leading edge surface portion 4024 of the club head. Consequently, the effective face angle remains substantially constant as the golfer holds the club with the club head on the playing surface and the club is tilted toward and away from the golfer so as to adjust the actual lie angle of the club. In particular embodiments, the effective face angle of the club head 4000 is held constant within a tolerance of +/−0.2 degrees as the lie angle is adjusted through a range of 0 degrees to about 20 degrees less than the scoreline lie angle. In a specific implementation, for example, the scoreline lie angle of the club head is 60 degrees and the effective face angle is held constant within a tolerance of +/−0.2 degrees for lie angles between 60 degrees and 40 degrees. In another example, the scoreline lie angle of the club head is 60 degrees and the effective face angle is held constant within a tolerance of +/−0.1 degrees for lie angles between 60 degrees and 40 degrees. In several embodiments, the effective face angle is held constant within a tolerance of about +/−0.1 degrees to about +/−0.5 degrees. In certain embodiments, the effective face angle is held constant within a tolerance of about less than +/−1 degree or about less than +/−0.7 degrees.
The components of the head-shaft connection assemblies disclosed in the present specification can be formed from any of various suitable metals, metal alloys, polymers, composites, or various combinations thereof
In addition to those noted above, some examples of metals and metal alloys that can be used to form the components of the connection assemblies include, without limitation, carbon steels (e.g., 1020 or 8620 carbon steel), stainless steels (e.g., 304 or 410 stainless steel), PH (precipitation-hardenable) alloys (e.g., 17-4, C450, or C455 alloys), titanium alloys (e.g., 3-2.5, 6-4, SP700, 15-3-3-3, 10-2-3, or other alpha/near alpha, alpha-beta, and beta/near beta titanium alloys), aluminum/aluminum alloys (e.g., 3000 series alloys, 5000 series alloys, 6000 series alloys, such as 6061-T6, and 7000 series alloys, such as 7075), magnesium alloys, copper alloys, and nickel alloys.
Some examples of composites that can be used to form the components include, without limitation, glass fiber reinforced polymers (GFRP), carbon fiber reinforced polymers (CFRP), metal matrix composites (MMC), ceramic matrix composites (CMC), and natural composites (e.g., wood composites).
Some examples of polymers that can be used to form the components include, without limitation, thermoplastic materials (e.g., polyethylene, polypropylene, polystyrene, acrylic, PVC, ABS, polycarbonate, polyurethane, polyphenylene oxide (PPO), polyphenylene sulfide (PPS), polyether block amides, nylon, and engineered thermoplastics), thermosetting materials (e.g., polyurethane, epoxy, and polyester), copolymers, and elastomers (e.g., natural or synthetic rubber, EPDM, and Teflon®).
Table 6 illustrates twenty-four possible driver head configurations between a sleeve position and movable weight positions. Each configuration shown in Table 6 has a different configuration for providing a desired shot bias. An associated loft angle, face angle, and lie angle is shown corresponding to each sleeve position shown.
The tabulated values in Table 6 are assuming a nominal club loft of 10.5°, a nominal lie angle of 60°, and a nominal face angle of 2.0° in a neutral position. In the exemplary embodiment of Table 6, the offset angle is nominally 1.0°. The eight discrete sleeve positions “L”, “N”, NU″, “R”, “N-R”, “N-L”, NU-R″, and NU-L″ represent the different spline positions a golfer can position a sleeve with respect to the club head. Of course, it is understood that four, twelve, or sixteen sleeve positions are possible. In each embodiment, the sleeve positions are symmetric about four orthogonal positions. The preferred method to locate and lock these positions is with spline teeth engaged in a mating slotted piece in the hosel as described in the embodiments described herein.
The “L” or left position allows the golfer to hit a draw or draw biased shot. The “NU” or neutral upright position enables a user to hit a slight draw (less draw than the “L” position). The “N” or neutral position is a sleeve position having little or no draw or fade bias. In contrast, the “R” or right position increases the probability that a user will hit a shot with a fade bias.
As shown in Table 6, the heaviest movable weight is about 16 g and two lighter weights are about 1 g. A total weight of 18 g is provided by movable weights in this exemplary embodiment. It is understood that the movable weights can be more than 18 g or less than 18 g depending on the desired CG location. The movable weights can be of a weight and configuration as described in U.S. Pat. Nos. 6,773,360, 7,166,040, 7,186,190, 7,407,447, 7,419,441 or U.S. patent application Ser. Nos. 11/025,469, 11/524,031, which are incorporated by reference herein. Placing the heaviest weight in the toe region will provide a draw biased shot. In contrast, placing the heaviest weight in the heel region will provide a fade biased shot and placing the heaviest weight in the rear position will provide a more neutral shot.
The exemplary embodiment shown in Table 6 provides at least five different loft angle values for eight different sleeve configurations. The loft angle value varies from about 9.5° to 11.5° for a nominal 10.5° loft (at neutral) club. In one embodiment, a maximum loft angle change is about 2°. The sleeve assembly or adjustable loft system described above can provide a total maximum loft change (Δloft) of about 0.5° to about 3° which can be described as the following expression:
0.5°>Δloft≤3°
The incremental loft change can be in increments of about 0.2° to about 1.5° in order to have a noticeable loft change while being small enough to fine tune the performance of the club head. As shown in Table 6, when the sleeve assembly is positioned to increase loft, the face angle is more closed with respect to how the club sits on the ground when the club is held in the address position. Similarly, when the sleeve assembly is positioned to decrease loft, the face angle sits more open.
Furthermore, five different face angle values for eight different sleeve configurations are provided in the embodiment of Table 6. The face angle varies from about 0.3° to 3.7° in the embodiment shown with a neutral face angle of 2.0°. In one embodiment, the maximum face angle change is about 3.4°. It should be noted that a 1° change in loft angle results in a 1.7° change in face angle.
The exemplary embodiment shown in Table 6 further provides five different lie angle values for eight different sleeve configurations. The lie angle varies from about 59° to 61° with a neutral lie angle of 60° . Therefore, in one embodiment, the maximum lie angle change is about 2°.
In an alternative exemplary embodiment, an equivalent 9.5° nominal loft club would have similar face angle and lie angle values described above in Table 6. However, the loft angle for an equivalent 9.5° nominal loft club would have loft values of about 1° less than the loft values shown throughout the various settings in Table 6. Similarly, an equivalent 8.5° nominal loft club would have a loft angle value of about 2° less than those shown in Table 6.
According to some embodiments of the present application, a golf club head has a loft angle between about 6 degrees and about 16 degrees or between about 13 degrees and about 30 degrees in the neutral position. In yet other embodiments, the golf club has a lie angle between about 55 degrees and about 65 degrees in the neutral position.
Table 7 illustrates another exemplary embodiment having a nominal club loft of 10.5°, a nominal lie angle of 60°, and a nominal face angle of 2.0°. In the exemplary embodiment of Table 7, the offset angle of the shaft is nominally 1.5°.
The different sleeve configurations shown in Table 7 can be combined with different movable weight configurations to achieve a desired shot bias, as already described above. In the embodiment of Table 7, the loft angle ranges from about 9.0° to 12.0° for a 10.5° neutral loft angle club resulting in a total maximum loft angle change of about 3°. The face angle in the embodiment of Table 7 ranges from about −0.5° to 4.5° for a 2.0° neutral face angle club thereby resulting in a total maximum face angle change of about 5°. The lie angle in Table 7 ranges from about 58.5° to 61.5° for a 60° neutral lie angle club resulting in a total maximum lie angle change of about 3°.
A golf club head has a head mass defined as the combined masses of the body, weight ports, and weights. The total weight mass is the combined masses of the weight or weights installed on a golf club head. The total weight port mass is the combined masses of the weight ports and any weight port supporting structures, such as ribs.
In one embodiment, the rear weight 6304 is the heaviest weight being between about 15 grams to about 20 grams. In certain embodiments, the lighter weights can be about 1 gram to about 6 grams. In one embodiment, a single heavy weight of 16 g and two lighter weights of 1 g is preferred.
In some embodiments, a golf club head is provided with three weight ports having a total weight port mass between about 1 g and about 12 g. In certain embodiments, the weight port mass without ribs is about 3 g for a combined weight port mass of about 9 g. In some embodiments, the total weight port mass with ribbing is about 5 g to about 6 g for a combined total weight port mass of about 15 g to about 18 g.
In one embodiment, the addition of the sleeve assembly 6418 and hosel recess walls 6422 increase the weight in the heel region by about 10 g to about 12 g. In other words, a club head construction without the hosel recess walls 6422 and sleeve assembly 6418 would be about 10 g to about 12 g lighter. Due to the increase in weight in the heel region, a mass pad or fixed weight that might be placed in the heel region is unnecessary. Therefore, the additional weight from the hosel recess walls 6422 and sleeve assembly 6418 provides a sufficient impact on the center of gravity location without having to insert a mass pad or fixed weight.
In one exemplary embodiment, the weight port walls are roughly 0.6 mm to 1.5 mm thick and has a mass between 2 g to about 5 g. In one embodiment, the weight port walls alone weigh about 3 g to about 4 g. A hosel insert (as described above) has a weight of between 1 g to about 4 g. In one embodiment, the hosel insert is about 2 g. The sleeve that is inserted into the hosel insert weighs about 5 g to about 8 g. In one embodiment, the sleeve is about 6 g to about 7 g. The screw that is inserted into the sleeve weighs about 1 g to 2 g. In one exemplary embodiment, the screw weighs about 1 g to about 2 g.
Therefore, in certain embodiments, the hosel recess walls, hosel insert, sleeve, and screw have a combined weight of about 10 g to 15 g, and preferably about 14 g.
In some embodiments of the golf club head with three weight ports and three weights, the sum of the body mass, weight port mass, and weights is between about 80 g and about 220 g or between about 180 g and about 215 g. In specific embodiments the total mass of the club head is between 200 g and about 210 g and in one example is about 205 g.
The above mass characteristics seek to create a compact and lightweight sleeve assembly while accommodating the additional weight effects of the sleeve assembly on the CG of the club head. Preferably, the club head has a hosel outside diameter 6428 (shown in
The golf club head of the present application has a volume equal to the volumetric displacement of the club head body. In several embodiments, a golf club head of the present application can be configured to have a head volume between about 110 cm3 and about 600 cm3. In more particular embodiments, the head volume is between about 250 cm3 and about 500 cm3, 400 cm3 and about 500 cm3, 390 cm3 and about 420 cm3, or between about 420 cm3 and 475 cm3. In one exemplary embodiment, the head volume is about 390 to about 410 cm3.
Golf club head moments of inertia are defined about axes extending through the golf club head CG. As used herein, the golf club head CG location can be provided with reference to its position on a golf club head origin coordinate system. The golf club head origin is positioned on the face plate at approximately the geometric center, i.e. the intersection of the midpoints of a face plate's height and width.
The head origin coordinate system includes an x-axis and a y-axis. The origin x-axis extends tangential to the face plate and generally parallel to the ground when the head is ideally positioned with the positive x-axis extending from the origin towards a heel of the golf club head and the negative x-axis extending from the origin to the toe of the golf club head. The origin y-axis extends generally perpendicular to the origin x-axis and parallel to the ground when the head is ideally positioned with the positive y-axis extending from the head origin towards the rear portion of the golf club. The head origin can also include an origin z-axis extending perpendicular to the origin x-axis and the origin y-axis and having a positive z-axis that extends from the origin towards the top portion of the golf club head and negative z-axis that extends from the origin towards the bottom portion of the golf club head.
In some embodiments, the golf club head has a CG with a head origin x-axis (CGx) coordinate between about −10 mm and about 10 mm and a head origin y-axis (CGy) coordinate greater than about 15 mm or less than about 50 mm. In certain embodiments, the club head has a CG with an origin x-axis coordinate between about −5 mm and about 5 mm, an origin y-axis coordinate greater than about 0 mm and an origin z-axis (CGz) coordinate less than about 0 mm.
More particularly, in specific embodiments of a golf club head having specific configurations, the golf club head has a CG with coordinates approximated in Table 8 below. The golf club head in Table 8 has three weight ports and three weights. In configuration 1, the heaviest weight is located in the back most or rear weight port. The heaviest weight is located in a heel weight port in configuration 2, and the heaviest weight is located in a toe weight port in configuration 3.
Table 8 emphasizes the amount of CG change that can be possible by moving the movable weights. In one embodiment, the movable weight change can provide a CG change in the x-direction (heel-toe) of between about 2 mm and about 10 mm in order to achieve a large enough CG change to create significant performance change to offset or enhance the possible loft, lie, and face angel adjustments described above. A substantial change in CG is accomplished by having a large difference in the weight that is moved between different weight ports and having the weight ports spaced far enough apart to achieve the CG change. In certain embodiments, the CG is located below the center face with a CGz of less than 0. The CGx is between about −2 mm (toe-ward) and 8 mm (heel-ward) or even more preferably between about 0 mm and about 6 mm. Furthermore, the CGy can be between about 25 mm and about 40 mm (aft of the center-face).
A moment of inertia of a golf club head is measured about a CG x-axis, CG y-axis, and CG z-axis which are axes similar to the origin coordinate system except with an origin located at the center of gravity, CG.
In certain embodiments, the golf club head of the present invention can have a moment of inertia (Ixx) about the golf club head CG x-axis between about 70 kg·mm2and about 400 kg·mm2. More specifically, certain embodiments have a moment of inertia about the CG x-axis between about 200 kg·mm2to about 300 kg·mm2 or between about 200 kg·mm2 and about 500 kg·mm2.
In several embodiments, the golf club head of the present invention can have a moment of inertia (Izz) about the golf club head CG z-axis between about 200 kg·mm2 and about 600 kg·mm2. More specifically, certain embodiments have a moment of inertia about the CG z-axis between about 400 kg·mm2 to about 500 kg·mm2 or between about 350 kg·mm2 and about 600 kg·mm2.
In several embodiments, the golf club head of the present invention can have a moment of inertia (Iyy) about the golf club head CG y-axis between about 200 kg·mm2 and 400 kg·mm2. In certain specific embodiments, the moment of inertia about the golf club head CG y-axis is between about 250 kg·mm2 and 350 kg·mm2.
The moment of inertia can change depending on the location of the heaviest removable weight as illustrated in Table 9 below. Again, in configuration 1, the heaviest weight is located in the back most or rear weight port. The heaviest weight is located in a heel weight port in configuration 2, and the heaviest weight is located in a toe weight port in configuration 3.
According to some embodiments of a golf club head of the present application, the golf club head has a thin wall construction. Among other advantages, thin wall construction facilitates the redistribution of material from one part of a club head to another part of the club head. Because the redistributed material has a certain mass, the material may be redistributed to locations in the golf club head to enhance performance parameters related to mass distribution, such as CG location and moment of inertia magnitude. Club head material that is capable of being redistributed without affecting the structural integrity of the club head is commonly called discretionary weight. In some embodiments of the present invention, thin wall construction enables discretionary weight to be removed from one or a combination of the striking plate, crown, skirt, or sole and redistributed in the form of weight ports and corresponding weights.
Thin wall construction can include a thin sole construction, i.e., a sole with a thickness less than about 0.9 mm but greater than about 0.4 mm over at least about 50% of the sole surface area; and/or a thin skirt construction, i.e., a skirt with a thickness less than about 0.8 mm but greater than about 0.4 mm over at least about 50% of the skirt surface area; and/or a thin crown construction, i.e., a crown with a thickness less than about 0.8 mm but greater than about 0.4 mm over at least about 50% of the crown surface area. In one embodiment, the club head is made of titanium and has a thickness less than 0.65 mm over at least 50% of the crown in order to free up enough weight to achieve the desired CG location.
More specifically, in certain embodiments of a golf club having a thin sole construction and at least one weight and two weight ports, the sole, crown and skirt can have respective thicknesses over at least about 50% of their respective surfaces between about 0.4 mm and about 0.9 mm, between about 0.8 mm and about 0.9 mm, between about 0.7 mm and about 0.8 mm, between about 0.6 mm and about 0.7 mm, or less than about 0.6 mm. According to a specific embodiment of a golf club having a thin skirt construction, the thickness of the skirt over at least about 50% of the skirt surface area can be between about 0.4 mm and about 0.8 mm, between about 0.6 mm and about 0.7 mm or less than about 0.6 mm.
The thin wall construction can be described according to areal weight as defined by the equation below.
AW=92 ·t
In the above equation, AW is defined as areal weight, ρ is defined as density, and t is defined as the thickness of the material. In one exemplary embodiment, the golf club head is made of a material having a density, ρ, of about 4.5 g/cm3 or less. In one embodiment, the thickness of a crown or sole portion is between about 0.04 cm to about 0.09 cm. Therefore the areal weight of the crown or sole portion is between about 0.18 g/cm2 and about 0.41 g/cm2. In some embodiments, the areal weight of the crown or sole portion is less than 0.41 g/cm2 over at least about 50% of the crown or sole surface area. In other embodiments, the areal weight of the crown or sole is less than about 0.36 g/cm2 over at least about 50% of the entire crown or sole surface area.
In certain embodiments, the thin wall construction is implemented according to U.S. patent application Ser. No. 11/870,913 and U.S. Pat. No. 7,186,190, which are incorporated herein by reference.
According to some embodiments, a golf club head face plate can include a variable thickness faceplate. Varying the thickness of a faceplate may increase the size of a club head COR zone, commonly called the sweet spot of the golf club head, which, when striking a golf ball with the golf club head, allows a larger area of the face plate to deliver consistently high golf ball velocity and shot forgiveness. Also, varying the thickness of a faceplate can be advantageous in reducing the weight in the face region for re-allocation to another area of the club head.
A variable thickness face plate 6500, according to one embodiment of a golf club head illustrated in
In some embodiments of a golf club head having a face plate with a protrusion, the maximum face plate thickness is greater than about 4.8 mm, and the minimum face plate thickness is less than about 2.3 mm. In certain embodiments, the maximum face plate thickness is between about 5 mm and about 5.4 mm and the minimum face plate thickness is between about 1.8 mm and about 2.2 mm. In yet more particular embodiments, the maximum face plate thickness is about 5.2 mm and the minimum face plate thickness is about 2 mm. The face thickness should have a thickness change of at least 25% over the face (thickest portion compared to thinnest) in order to save weight and achieve a higher ball speed on off-center hits.
In some embodiments of a golf club head having a face plate with a protrusion and a thin sole construction or a thin skirt construction, the maximum face plate thickness is greater than about 3.0 mm and the minimum face plate thickness is less than about 3.0 mm. In certain embodiments, the maximum face plate thickness is between about 3.0 mm and about 4.0 mm, between about 4.0 mm and about 5.0 mm, between about 5.0 mm and about 6.0 mm or greater than about 6.0 mm, and the minimum face plate thickness is between about 2.5 mm and about 3.0 mm, between about 2.0 mm and about 2.5 mm, between about 1.5 mm and about 2.0 mm or less than about 1.5 mm.
In certain embodiments, a variable thickness face profile is implemented according to 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 some embodiments of a golf club head having at least two weight ports, a distance between the first and second weight ports is between about 5 mm and about 200 mm. In more specific embodiments, the distance between the first and second weight ports is between about 5 mm and about 100 mm, between about 50 mm and about 100 mm, or between about 70 mm and about 90 mm. In some specific embodiments, the first weight port is positioned proximate a toe portion of the golf club head and the second weight port is positioned proximate a heel portion of the golf club head.
In some embodiments of the golf club head having first, second and third weight ports, a distance between the first and second weight port is between about 40 mm and about 100 mm, and a distance between the first and third weight port, and the second and third weight port, is between about 30 mm and about 90 mm. In certain embodiments, the distance between the first and second weight port is between about 60 mm and about 80 mm, and the distance between the first and third weight port, and the second and third weight port, is between about 50 mm and about 80 mm. In a specific example, the distance between the first and second weight port is between about 80 mm and about 90 mm, and the distance between the first and third weight port, and the second and third weight port, is between about 70 mm and about 80 mm. In some embodiments, the first weight port is positioned proximate a toe portion of the golf club head, the second weight port is positioned proximate a heel portion of the golf club head and the third weight port is positioned proximate a rear portion of the golf club head.
In some embodiments of the golf club head having first, second, third and fourth weights ports, a distance between the first and second weight port, the first and fourth weight port, and the second and third weight port is between about 40 mm and about 100 mm; a distance between the third and fourth weight port is between about 10 mm and about 80 mm; and a distance between the first and third weight port and the second and fourth weight port is about 30 mm to about 90 mm. In more specific embodiments, a distance between the first and second weight port, the first and fourth weight port, and the second and third weight port is between about 60 mm and about 80 mm; a distance between the first and third weight port and the second and fourth weight port is between about 50 mm and about 70 mm; and a distance between the third and fourth weight port is between about 30 mm and about 50 mm. In some specific embodiments, the first weight port is positioned proximate a front toe portion of the golf club head, the second weight port is positioned proximate a front heel portion of the golf club head, the third weight port is positioned proximate a rear toe portion of the golf club head and the fourth weight port is positioned proximate a rear heel portion of the golf club head.
As mentioned above, the distance between the weight ports and weight size contributes to the amount of CG change made possible in a system having the sleeve assembly described above.
In some embodiments of a golf club head of the present application having two, three or four weights, a maximum weight mass multiplied by the distance between the maximum weight and the minimum weight is between about 450 g·mm and about 2,000 g·mm or about 200 g·mm and 2,000 g·mm. More specifically, in certain embodiments, the maximum weight mass multiplied by the weight separation distance is between about 500 g·mm and about 1,500 g·mm, between about 1,200 g·mm and about 1,400 g·mm.
When a weight or weight port is used as a reference point from which a distance, i.e., a vectorial distance (defined as the length of a straight line extending from a reference or feature point to another reference or feature point) to another weight or weights port is determined, the reference point is typically the volumetric centroid of the weight port.
When a movable weight club head and the sleeve assembly are combined, it is possible to achieve the highest level of club trajectory modification while simultaneously achieving the desired look of the club at address. For example, if a player prefers to have an open club face look at address, the player can put the club in the “R” or open face position. If that player then hits a fade (since the face is open) shot but prefers to hit a straight shot, or slight draw, it is possible to take the same club and move the heavy weight to the heel port to promote draw bias. Therefore, it is possible for a player to have the desired look at address (in this case open face) and the desired trajectory (in this case straight or slight draw).
In yet another advantage, by combining the movable weight concept with an adjustable sleeve position (effecting loft, lie and face angle) it is possible to amplify the desired trajectory bias that a player may be trying to achieve.
For example, if a player wants to achieve the most draw possible, the player can adjust the sleeve position to be in the closed face position or “L” position and also put the heavy weight in the heel port. The weight and the sleeve position work together to achieve the greater draw bias possible. On the other hand, to achieve the greatest fade bias, the sleeve position can be set for the open face or “R” position and the heavy weight is placed in the top port.
As described above, the combination of a large CG change (measured by the heaviest weight multiplied by the distance between the ports) and a large loft change (measured by the largest possible change in loft between two sleeve positions, Aloft) results in the highest level of trajectory adjustability. Thus, a product of the distance between at least two weight ports, the maximum weight, and the maximum loft change is important in describing the benefits achieved by the embodiments described herein.
In one embodiment, the product of the distance between at least two weight ports, the maximum weight, and the maximum loft change is between about 50 mm·g·deg and about 6,000 mm·g·deg or even more preferably between about 500 mm·g·deg and about 3,000 mm·g·deg. In other words, in certain embodiments, the golf club head satisfies the following expressions:
50 mm·g·degrees<Dwp·Mhw·Δloft<6,000 mm·g·degrees
500 mm·g·degrees<Dwp·Mhw·Δloft<3,000 mm·g·degrees
In the above expressions, Dwp, is the distance between two weight port centroids (mm), Mhw, is the mass of the heaviest weight (g), and Δloft is the maximum loft change (degrees) between at least two sleeve positions. A golf club head within the ranges described above will ensure the highest level of trajectory adjustability.
With respect to
The use of a single tool or torque wrench 6600 for adjusting the movable weights, adjustable sleeve or adjustable loft system, and adjustable sole features provides a unique advantage in that a user is not required to carry multiple tools or attachments to make the desired adjustments.
The shank 6606 terminates in an engagement end i.e. tip 6610 configured to operatively mate with the movable weights, adjustable sleeve, and adjustable sole features described herein. In one embodiment, the engagement end or tip 6610 is a bit-type drive tip having one single mating configuration for adjusting the movable weights, adjustable sleeve, and adjustable sole features. The engagement end can be comprised of lobes and flutes spaced equidistantly about the circumference of the tip.
In certain embodiments, the single tool 6600 is provided to adjust the sole angle and the adjustable sleeve (i.e. affecting loft angle, lie angle, or face angle) only. In another embodiment, the single tool 6600 is provided to adjust the adjustable sleeve and movable weights only. In yet other embodiments, the single tool 6600 is provided to adjust the movable weights and sole angle only.
In other embodiments, the metallic cap 6724 does not have a rim portion 6732 but includes an outer peripheral edge that is substantially flush and planar with the side wall 6734 of the composite insert 6722. A plurality of score lines 6712 can be located on the metallic cap 6724. The composite face insert 6710 has a variable thickness and is adhesively or mechanically attached to the insert ledge 6726 located within the front opening and connected to the front opening inner wall 6714. The insert ledge 6726 and the composite face insert 6710 can be of the type described 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.
Furthermore, a sole plate rib 6736 reinforces the interior of the sole 6720. In one embodiment, the sole plate rib 6736 extends in a heel to toe direction and is primarily parallel with the face insert 6710. A similar crown interior surface rib 6738 extends in a heel to toe direction along the interior surface of the crown 6702.
The club head of the embodiments described in
A golf club having an adjustable loft and lie angle with a composite face insert can achieve the moment of inertia and CG locations listed in Table 10 and 11. In certain embodiments, the golf club head can include movable weights in addition to the adjustable sleeve system and composite face. In embodiments where movable weights are implemented, similar moment of inertia and CG values already described herein can be achieved.
The golf club head embodiments described herein provide a solution to the additional weight added by a movable weight system and an adjustable loft, lie, and face angle system. Any undesirable weight added to the golf club head makes it difficult to achieve a desired head size, moment of inertia, and nominal center of gravity location.
In certain embodiments, the combination of ultra thin wall casting technology, high strength variable face thickness, strategically placed compact and lightweight movable weight ports, and a lightweight adjustable loft, lie, and face angle system make it possible to achieve high performing moment of inertia, center of gravity, and head size values.
Furthermore, an advantage of the discrete positions of the sleeve embodiments described herein allow for an increased amount of durability and more user friendly system.
Whereas the invention has been described in connection with representative embodiments, it will be understood that the invention is not limited to those embodiments. On the contrary, the invention is intended to encompass all modifications, alternatives, and equivalents as may fall within the spirit and scope of the invention, as defined by the appended claims.
Numerous alterations, modifications, and variations of the preferred embodiments disclosed herein will be apparent to those skilled in the art and they are all anticipated and contemplated to be within the spirit and scope of the instant club head. For example, although specific embodiments have been described in detail, those with skill in the art will understand that the preceding embodiments and variations can be modified to incorporate various types of substitute and or additional or alternative materials, relative arrangement of elements, and dimensional configurations. Accordingly, even though only few variations of the present club head are described herein, it is to be understood that the practice of such additional modifications and variations and the equivalents thereof, are within the spirit and scope of the club head as defined in the following claims. The corresponding structures, materials, acts, and equivalents of all means or step plus function elements in the claims below are intended to include any structure, material, or acts for performing the functions in combination with other claimed elements as specifically claimed.
This application is a continuation of U.S. patent application Ser. No. 16/524,854, filed on Jul. 29, 2019, which is a continuation of U.S. patent application Ser. No. 15/959,467, filed on Apr. 23, 2018, (now U.S. Pat. No. 10,363,463), which is a continuation of U.S. patent application Ser. No. 15/456,630, filed on Mar. 13, 2017 (now U.S. Pat. No. 9,950,224), which is a continuation of U.S. patent application Ser. No. 15/002,471, filed on Jan. 21, 2016 (now U.S. Pat. No. 9,623,295), which is a continuation of U.S. patent application Ser. No. 14/488,354, filed on Sep. 17, 2014 (now U.S. Pat. No. 9,259,628), which is a continuation of U.S. patent application Ser. No. 13/718,107, filed on Dec. 18, 2012 (now U.S. Pat. No. 8,858,359), which is a continuation-in-part of U.S. patent application Ser. No. 13/683,299, filed on Nov. 21, 2012 (now U.S. Pat. No. 8,540,586), which is a continuation application of U.S. patent application Ser. No. 13/305,978, filed on Nov. 29, 2011 (now Abandoned), which is a continuation application of U.S. patent application Ser. No. 12/409,998, filed on Mar. 24, 2009 (now U.S. Pat. No. 8,088,021), which is a continuation-in-part of U.S. patent application Ser. No. 12/367,839, filed on Feb. 9, 2009 (now U.S. Pat. No. 8,083,609), which claims the benefit of U.S. provisional patent application Ser. No. 61/080,892, filed on Jul. 15, 2008, and U.S. provisional patent application Ser. No. 61/101,919, filed on Oct. 1, 2008, all of which are incorporated by reference as if completely written herein.
This invention was not made as part of a federally sponsored research or development project.
| Number | Date | Country | |
|---|---|---|---|
| 61080892 | Jul 2008 | US | |
| 61101919 | Oct 2008 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 16524854 | Jul 2019 | US |
| Child | 17360179 | US | |
| Parent | 15959467 | Apr 2018 | US |
| Child | 16524854 | US | |
| Parent | 15456630 | Mar 2017 | US |
| Child | 15959467 | US | |
| Parent | 15002471 | Jan 2016 | US |
| Child | 15456630 | US | |
| Parent | 14488354 | Sep 2014 | US |
| Child | 15002471 | US | |
| Parent | 13718107 | Dec 2012 | US |
| Child | 14488354 | US | |
| Parent | 13305978 | Nov 2011 | US |
| Child | 13683299 | US | |
| Parent | 12409998 | Mar 2009 | US |
| Child | 13305978 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 13683299 | Nov 2012 | US |
| Child | 13718107 | US | |
| Parent | 12367839 | Feb 2009 | US |
| Child | 12409998 | US |
