The present disclosure relates generally to golf equipment, and more particularly, to flexure structures for improved performance characteristics of hollow body irons and methods to manufacture hollow body irons with flexure structures.
Hollow body irons, ideally, operate as a diving board, flexing rearward during impact. In club design, the degree to which a hollow body iron behaves as a diving board, or spring is constrained by peak stress values. To ensure that traditional golf clubs do not exceed maximum stress limits, the face and sole are thickened such that the club is made more rigid. The rigidity of the traditional golf clubs results in a degradation to the diving board, or spring behavior of the club head. Therefore, there is a need in the art to produce a golf club head having a construction which expands the limit of modifications to the face to improve energy transfer from the club to the ball at impact.
For simplicity and clarity of illustration, the drawing figures illustrate the general manner of construction, and descriptions and details of well-known features and techniques may be omitted to avoid unnecessarily obscuring the invention. Additionally, elements in the drawing figures are not necessarily drawn to scale. For example, the dimensions of some of the elements in the figures may be exaggerated relative to other elements to help improve understanding of embodiments of the present invention. The same reference numerals in different figures denote the same elements.
The terms “first,” “second,” “third,” “fourth,” and the like in the description and in the claims, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms “include,” and “have,” and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, device, or apparatus that comprises a list of elements is not necessarily limited to those elements, but may include other elements not expressly listed or inherent to such process, method, system, article, device, or apparatus.
The terms “left,” “right,” “front,” “back,” “top,” “bottom,” “over,” “under,” and the like in the description and in the claims, if any, are used for descriptive purposes and not necessarily for describing permanent relative positions. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments of the invention described herein are, for example, capable of operation in other orientations than those illustrated or otherwise described herein.
The terms “couple,” “coupled,” “couples,” “coupling,” and the like should be broadly understood and refer to connecting two or more elements or signals, electrically, mechanically and/or otherwise.
The terms “loft” or “loft angle” of a hollow body golf club (hererafter “hollow body” or “hollow body iron” or “iron-type golf club head” or “golf club head”), as described herein, refers to the angle formed between the club face and the shaft, as measured by any suitable loft and lie machine. A loft plane lies tangent to the strikeface at the geometric center. A loft angle is measured between the ground plane and the loft plane. In many embodiments, the loft angle of the club head is less than approximately 50 degrees, less than approximately 49 degrees, less than approximately 48degrees, less than approximately 47 degrees, less than approximately 46 degrees, less than approximately 45 degrees, less than approximately 44 degrees, less than approximately 43 degrees, less than approximately 42 degrees, less than approximately 41 degrees, less than approximately 40 degrees, less than approximately 39 degrees, less than approximately 38 degrees, less than approximately 37 degrees, less than approximately 36 degrees, less than approximately 35 degrees, less than approximately 34 degrees, less than approximately 33 degrees, less than approximately 32 degrees, less than approximately 31 degrees, less than approximately 30 degrees, less than approximately 29 degrees, less than approximately 28 degrees, less than approximately 27 degrees, less than approximately 26 degrees, less than approximately 25 degrees, less than approximately 24 degrees, less than approximately 23 degrees, less than approximately 22 degrees, less than approximately 21 degrees, less than approximately 20 degrees, less than approximately 19 degrees, less than approximately 18 degrees, 17, or less than approximately 16 degrees. Further, in many embodiments, the loft angle of the club head is greater than approximately 16 degrees, greater than approximately 17 degrees, greater than approximately 18 degrees, greater than approximately 19 degrees, greater than approximately 20 degrees, greater than approximately 21 degrees, greater than approximately 22 degrees, greater than approximately 23 degrees, greater than approximately 24 degrees, greater than approximately 25 degrees, greater than approximately 26 degrees greater than approximately 27 degrees, greater than approximately 28 degrees, greater than approximately 29 degrees, greater than approximately 30 degrees, greater than approximately 31 degrees, greater than approximately 32 degrees, greater than approximately 33 degrees, greater than approximately 34 degrees, greater than approximately 35 degrees, greater than approximately 36 degrees, greater than approximately 37 degrees, or greater than approximately 38 degrees.
The present disclosure describes technologies for an improved hollow body iron-type golf club head (hererafter “hollow body” or “hollow body iron” or “iron-type golf club head” or “golf club head”) having a sole and ballast configured to relieve stress within a forward portion of the sole. In a first configuration, the golf club head comprises a ballast undercut for relieving stress. In other configurations, the ballast undercut is combined with additional stress relief features, such as a cascading sole near the face sole juncture, for further reductions to face thickness.
The hollow body can comprise a strikeface, a rear portion, opposite the strikeface, a heel portion, a toe portion, opposite the heel, a sole, and a top rail to define an interior cavity. The rear portion can further include a ballast extending forward from the rear portion and into the interior cavity. In many embodiments, the ballast is an internal component such that it is not visible from the exterior of the golf club. The ballast can further comprise a geometry configured to increase the interior surface area of the sole. For example, the ballast can comprise a top surface, a forward surface, and a bottom surface defined as an undercut region. When viewed from a toe side cross section, an undercut is formed by the bottom surface's concave geometry relative to the face. The undercut allows the thinner, forward portion of the sole to extend beneath the ballast. A ballast comprising a bottom undercut surface, as opposed to a front surface that meets the interior surface of the sole at a right angle, (1) prevents stress from concentrating along the sole between the face and the ballast and (2) increases the portion of the sole capable of storing strain energy. Hollow body irons comprising an undercut, therefore, comprise sole and face geometries with greater range of thinning, as compared to hollow irons without an undercut.
The sole of the hollow body iron can be divided into two regions, the forward portion and the rear portion. The forward portion defines the thin region of the sole adjacent the strikeface, which can store strain energy. The rear portion of the sole describes the region of the sole adjacent to the to the rear portion of the of the body, which does not store strain energy. In other words, the forward portion of the sole 132 is the portion of the sole 110 that behaves as a spring. Hollow body irons having a thinner face and extended forward sole portion, as a result of the ballast undercut, store more strain energy (i.e., potential energy) than the face and forward sole portion of a club without an undercut. Consequently, the undercut improves the spring-like energy transfer between the club body and the golf ball (as compared to a golf club without and undercut). This energy transfer can be further improved in hollow body irons when the forward sole portion also comprises a cascade, in addition to the undercut. The cascading sole improves the flow of stress within the forward portion of the sole near the face sole juncture, while the undercut improves the flow of stress near the ballast. Accordingly, the application of the undercut and/or the combined application of the undercut and cascading sole can result in a golf club head, which can tolerate a 3-8% thinner face. Thus, the thinner face, which had been previously unattainable, results in an improved flight trajectory and distance.
Continuing to refer to
Referring to
The undercut depth 134, between the ballast forward plane 20 and the undercut juncture 130, has a range of 0.010 inch to 0.100 inch. For example, the undercut depth 134 can be 0.010 inch, 0.015 inch, 0.020 inch, 0.025 inch, 0.030 inch, 0.035 inch, 0.040 inch, 0.045 inch, 0.050 inch, 0.055 inch, 0.060 inch, 0.065 inch, 0.070 inch, 0.075 inch, 0.080 inch, 0.085 inch, 0.090 inch, 0.095 inch, or 0.100 inch. Alternatively, an undercut face depth 131 can be measured as the perpendicular distance between an interior surface of the strikeface 106 and the undercut juncture 130. In some embodiments, the undercut depth from the face ranges from 0.200 inch to 0.500 inch. For example, the undercut depth from the face can be 0.200 inch, 0.220 inch, 0.240 inch, 0.260 inch, 0.280 inch, 0.300 inch, 0.320 inch, 0.340 inch, 0.360 inch, 0.380 inch, 0.400 inch, 0.420 inch, 0.440 inch, 0.460 inch, 0.480 inch, or 0.500 inch.
The undercut height 136, measured between the undercut bottom edge 137 and undercut top edge 139, can range from 0.030 inch to 0.200 inch. For example, the undercut height 136 range from 0.030 inch to 0.040 inch, 0.040 inch to 0.050 inch, 0.050 inch to 0.060 inch, 0.060 inch to 0.070 inch, 0.070 inch to 0.080 inch, 0.080 inch to 0.090 inch, 0.090 inch to 0.100 inch, 0.100 inch to 0.110 inch, 0.110 to 0.120 inch, 0.120 inch to 0.130 inch, 0.130 inch to 0.140 inch, 0.140 inch to 0.150 inch, 0.150 inch to 0.160 inch, 0.160 inch to 0.170 inch, 0.170 inch to 0.180 inch, 0.180 inch to 0.190 inch, or 0.190 inch to 0.200 inch.
The undercut length 138, measured as the distance between the undercut heel and toe ends, may further define a percent of the ballast length 124, to describe the portion of the ballast 114 comprising the undercut 102. In embodiments of iron type golf club heads comprising an undercut 102, the undercut 102 can increase the surface area experiencing impact loading. The percent ballast length can be calculated as the undercut length 138 divided by the ballast length 124. In some embodiments, the undercut percent ballast length ranges from 20% to 100%. The length of the undercut can range from 10% the length of the ballast length up to the same length as the ballast length (i.e., 100%). For example, the percent ballast length is 20%, 25%, 30%, 40%, 45%, 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, or 95%.
In addition, an undercut transition height 142, as shown in
As discussed above, the undercut 102 and undercut region 128 can be considered as a region of ballast material that has been removed, when compared to iron-type golf club heads lacking an undercut. An undercut volume 146 is defined by a surface 146 of the undercut region 128 and the ballast forward plane 20. For example, in one embodiment, the surface 146 of the undercut region and the ballast forward plane 20 define an undercut volume 146 of 0.018 cubic inches. In other embodiments, the undercut volume ranges from 0.018 cubic inches to 0.050 cubic inches. For example, the undercut volume 146 can be 0.018 cubic inches, 0.020 cubic inches, 0.022 cubic inches, 0.024 cubic inches, 0.026 cubic inches, 0.028 cubic inches, 0.030 cubic inches, 0.032 cubic inches, 0.034 cubic inches, 0.036 cubic inches, 0.038 cubic inches, 0.040 cubic inches, 0.042 cubic inches, 0.044 cubic inches, 0.046 cubic inches, 0.048 cubic inches, or 0.050 cubic inches. The undercut volume 146 can be used to calculate mass removed from the ballast 114 by the undercut region 128. Mass is calculated by multiplying the undercut volume 146 by the material density of the ballast 114. For example, an undercut volume ranging from 0.018 cubic inches to 0.030 cubic inches. The undercut volume can be 0.018 cubic inches, 0.020 cubic inches, 0.022 cubic inches, 0.024 cubic inches, 0.026 cubic inches, 0.028 cubic inches, or 0.030 cubic inches. The amount of material removed from the ballast to form the undercut with a material density ranging from 6.0 g/cm3 to 7.75 g/cm3 or a range of mass from 1.75 grams to 2.40 grams. The amount of material removed from the ballast to form the undercut with a material density of 6.0 g/cm3, 6.5 g/cm3, 7.0 g/cm3, or 7.75 g/cm3 or a mass of 1.75 grams, 2.0 grams, 2.20 grams, 2.32 grams or 2.40 grams from the ballast 114.
The forward portion 132 of the sole 110 extending from the strikeface 106 to the ballast 114 affects the impact response of golf club head 100 with a golf ball. As shown in
Alone, the above decrease in stress, within the sole 110 and strikeface 106, can translate to an improved wear life of golf club head 100. In other words, golf club head 100 comprising ballast 114 with undercut 102 can be hit more times and played longer than a traditional golf club head without an undercut. For example, a hollow body golf club comprising an undercut 102 can have a failure count increase of 50 hits, 100 hits, 150 hits, 200 hits, 250 hits, or 300 hits. Fatigue failure in a cyclically loaded golf club occurs over time in locations of peak stress where small cracks form in the material. Cracks, in turn, amplify stress. Therefore, golf club head 100, with reduced peak stresses, experiences the crack growth and eventual fatigue failure at a slower rate.
Alternatively, the stress reduction achieved by the above ballast 114 and undercut 102 can be leveraged to improve club performance and ball speed. In some embodiments, the ballast 114 with undercut 102 can be provided in conjunction with a thinned strikeface 106. The extent to which the strikeface of a golf club head without the undercut 102 has been constrained by peak stress levels at the face-to-sole transition. Said another way, it is not possible to improve the performance of traditional golf clubs with a thinner face because the added stress from the thinner face results in peak stresses that exceed the critical K value. Golf club head 100, as discussed above, comprises ballast 114 with undercut 102 for stress reduction. Therefore, in some embodiments, strikeface 106 can be thinned without raising peak stress values beyond the critical K value at the sole-to-face transition.
The thinness reductions can be applied throughout the face. For example, in the geometric center of the face of the undercut club, the thickness at this region of the face can range between 0.080 to 0.150 inches. The thickness of the face at the geometric center of said face can be 0.150 inches, 0.140 inches, 0.130 inches, 0.120 inches, 0.110 inches, 0.100 inches, 0.090 inches, or 0.080 inches. In the perimeter toe region of the face of the undercut iron club, the thickness of the face can range from 0.050 to 0.090 inches. The thickness of the face at the perimeter toe region can be 0.050 inches, 0.060 inches, 0.065 inches, 0.070 inches, 0.071 inches, 0.074 inches, 0.076 inches, 0.077 inches, 0.079 inches, 0.080 inches, 0.082 inches, 0.084 inches, 0.086 inches, 0,088 inches, or 0.090 inches. The thickness of the face at the heel perimeter end of the undercut iron club can range from 0.045 inches to 0.090 inches. The thickness of the face at the heel perimeter end can be 0.045 inches, 0.050 inches, 0.055 inches, 0.060 inches, 0.065 inches, 0.070 inches, 0.075 inches, 0.080 inches, 0.085 inches, or 0.090 inches.
In some examples, the ballast 114 with undercut 102 reduces face thickness by 0.003 inches. In other examples the undercut 102 can allow the strikeface 106 to be thinned by 0.004 inches, 0.005 inches, 0.006 inches, 0.007 inches, 0.007 inches, 0.008 inches, 0.009 inches, or 0.010 inches. In an already thin strikeface 106, this reduction equates to a thinning of roughly 6%, or an increase in ball speed of 0.5 mph to 0.7 mph. In some examples, the undercut 102 allows the strikeface to be 3 to 8% thinner than the strikeface of a golf club head without an undercut. For example, the strikeface 106 can be 3% thinner, 4% thinner, 5% thinner, 6% thinner, 7% thinner, or 8% thinner.
As discussed above, the undercut region 128 has a volume 146 representative of mass removed from ballast 114. Ballast 114 functions as a mass pad for controlling the center of gravity (CG) for golf club head 100, such that the undercut 102 can alter club head CG. The CG can be defined relative to a geometric center 126 of the strikeface 106. The geometric center 126 of the strikeface 118 can be determined in accordance with Section 6.1 of the USGA's Procedure for Measuring the Flexibility of a Golf Clubhead (USGA-TPX3004, Rev. 1.0.0, May 1, 2008) (available at http://www.usga.org/equipment/testing/protocols/Procedure-For-Measuring-The-Flexibility-Of-A-Golf-Club-Head/) (the “Flexibility Procedure”). A front-rear CG depth 144 can be defined as a horizontal distance between the geometric center 126 the CG. For example, the front-rear CG depth 144 can range from 0.080 to 0.110 inches. The front-rear CG depth can be 0.080 inches, 0.082 inches, 0.084 inches, 0.086 inches, 0.088 inches, 0.090 inches, 0.092 inches, 0.094 inches, 0.096 inches, 0.098 inches, 0.100 inches, 0.105 inches, or 0.110 inches.
A ratio of undercut face depth 146 to the front-rear CG position is constrained between 3.0 and 5.5. For example, the face depth ratio 3.0, 3.1, 3.2, 3.3, 3.4, 3.5, 3.6, 3.7, 3.8, 3.9, 4.0, 4.1, 4.2, 4.3, 4.4, 4.5, 4.6, 4.7, 4.8, 4.9, or 5.0. In this range, the undercut 102 improves peak stress within the forward sole portion 132 without removing material from the ballast to the extent that CG position is compromised.
Furthermore, because of the CG position, the undercut does not affect the overall MOI of the club. For the purpose of determining club head moments of inertia, a coordinate system may be defined at the CG via mutually orthogonal axes (i.e., an x-axis, a y-axis, and a z-axis) (Figure not shown). The y-axis extends through the head CG from the top rail 112 to the sole 110, perpendicular to a ground plane 10 when the club head is at an address position. The x-axis extends through the head CG from the heel 103 to the toe 105 and perpendicular to the y-axis. The z-axis extends through the head CG from the strikeface 106 to the rear portion 108, and perpendicular to the x-axis and the y-axis.
Moments of inertia then exist about the x-axis Ixx (i.e. top rail-to-sole moment of inertia), about the y-axis Iyy (i.e. heel-to-toe moment of inertia) and about the z-axis (i.e., strikeface to rear). In many embodiments, the golf club head with undercut comprises a top rail-to-sole moment of inertia, Ixx, from 95 g·in2 to 130 g·in2. In many embodiments, the golf club head with undercut comprises a top rail-to-sole moment of inertia Ixx greater than approximately 95 g·in2, greater than approximately 98 g·in2, greater than approximately 100 g·in2, greater than approximately 102 g·in2, greater than approximately 103 g·in2, greater than approximately 104 g·in2, greater than approximately 105 g·in2, greater than approximately 106 g·in2, greater than approximately 110 g·in2, greater than approximately 115 g·in2, greater than approximately g·in2, greater than approximately 125 g·in2, greater than approximately 130 g·in2, greater than approximately 135 g·in2, greater than approximately 140 g·in2, greater than approximately 6750 g·in2, or greater than approximately 145 g·in2. Further, in many embodiments, the golf club head with undercut comprises a heel-to-toe moment of inertia Iyy, which may be greater than approximately 350 g·in2, greater than approximately 360 g·in2, greater than approximately 370 g·in2, greater than approximately 380 g·in2, greater than approximately 390 g·in2, greater than approximately 400 g·in2, greater than approximately 410 g·in2, greater than approximately 420 g·in2, or greater than approximately 430 g·in2. In many embodiments, the golf club head with undercut comprises a heel-to-toe moment of inertia Iyy from 350 g·in2 to 420 g·in2. Further, the club head with undercut comprises a strikeface to rear moment of inertia Izz, which may be greater than approximately 400 g·in2, greater than approximately 4100 g·in2, greater than approximately 420 g·in2, greater than approximately 430 g·in2, greater than approximately 440 g·in2, greater than approximately 450 g·in2, greater than approximately 460 g·in2, greater than approximately 470 g·in2, or greater than approximately 480 g·in2. In many embodiments, the golf club head with undercut comprises a strikeface to rear moment of inertia Izz can range from 400 g·in2 to 450 g·in2. The undercut of the golf club head does not significantly alter the moment of inertia of the Ixx, Iyy, and Izz axes over a golf club head without the undercut.
Continuing to refer to
The cascading region can comprise a first tier 266, second tier 268, a third tier (not shown), and a first tier transition 270 between the first tier 266 and second tier 268, and a second tier transition between the second tier and the third tier. As described above, the cascading region of the forward sole region with three tiers can have a thickness measured as the perpendicular distance between the exterior surface of the sole and interior surface of the sole. Again, the thickness decreases in a front to rear direction over the cascading region. As described above, the first tier can have a first thickness. The second tier can have a second thickness. The third tier can have a third thickness, wherein the third tier thickness (like the first and second tier thicknesses) is measured as the perpendicular distance between the exterior surface and interior surface of the sole. In some embodiments, the first thickness is greater than the second thickness, and in turn, the second thickness is greater than the third thickness, such that the overall thickness of the cascading region 262 decreases in the front to rear direction. The first thickness and/or the second thickness and/or third thickness can have a constant thickness over a tier length in the front to rear direction. In other embodiments, the first thickness and/or the second thickness and/or third thickness can be sloped to decrease in thickness over the tier length in the front to rear direction.
The tier transition 270, between a rear edge of the first tier and a forward edge of the second tier, can be declined in a front to rear direction to steadily decrease the cascading region thickness between the first thickness 272 and second thickness 274. Alternatively, in a cascading region with two tier transitions (i.e., a first transition between the first tier and second tier, and a second transition between the second tier and third tier), the transitions can be declined in a front to rear direct to steadily decrease the cascading region thickness between the first thickness, second thickness and third thickness (or first tier, second tier and third tier). In some embodiments, such as
As mentioned above, the forward sole portion 232 further comprises inner region 260 between the cascading region 262 and ballast undercut 202. The uniform inner region 260 also comprises an inner thickness 276 defined as the perpendicular distance between the exterior surface of the sole 221 and the inner surface of the sole 222. The inner thickness 276 is less than the thickness of an adjacent tier, or final tier within the cascading region 262. As shown in
Continuing to refer to
In many embodiments, performance improvements from cascading sole 262 and undercut 202 are compounding. In other words, golf club heads having both a cascading region and undercut 202, such as hollow body club 202, have a greater reduction in peak stress than golf club heads comprising one of a cascading region or an undercut. Reduction of peak stress within forward sole portion 232 increases the region's tolerance to modifications for improving ball speeds. Specifically, hollow body club 200 comprising forward sole region 232, which is defined by undercut 202 and comprising cascading region, can comprise a thinner face (as compared to a hollow body club lacking either or both of the undercut and cascading sole). This results in better ball speeds and flight distance. In some embodiments, the undercut 202 and cascading sole 242 allow the forward portion of the sole 232 to be made more reactive. Rather than remaining rigid, the forward portion 232 can be thinned, such that the forward portion 232 behaves as a spring under impact loads. This means that the golf club head 200 is more efficient at transferring swing energy to the golf ball. The ultimate increase in ball speed via reduction in average thickness of the forward portion 232 of the sole is the result of stress reduction at the face-to-sole transition 226. The undercut and the cascading sole work together to improve the flow of stress within the forward portion 232, thereby reducing stress concentration levels at impact.
As described in detail above, the ballast and undercut can be applied to a golf club head alone and in conjunction with other features, such as a cascading sole, to improve club performance. In the example below, performance improvements generated by the undercut 102 were studied by comparing a golf club head without an undercut (golf club A, hereafter “Club A”), a golf club head with an undercut (golf club B, hereafter “Club B”), a golf club head without an undercut and with a cascading sole (golf club C, hereafter “Club C”), and a golf club head with an undercut and with a cascading sole (golf club D, hereafter “Club D”). Performance improvements were measured and analyzed using finite element analysis (FEA). Specifically, FEA was used to measure peak stress values within the forward portion. Average peak stress, along with a measured surface area experiencing peak stress, were used to determine the potential for each club to efficiently transfer impact energy back to the ball. Reductions in average peak stress serve as an indicator for improved durability and potential performance enhancement via face thinning and sole thinning.
Each of the example Clubs A, B, C, and D were substantially similar having the same overall mass, material construction, and loft angle. Impact loading in each club was simulated at 105 mph. The example clubs each comprise unique internal cavity configurations, described above. Average peak stress between the strikeface and ballast, within the forward portion of the sole, was calculated for each example. Likewise, an area of average peak stress was calculated for each example. Finally, average peak stress within the strikeface was calculated for each example. Table 1 below, shows the peak face stress, peak stress of the forward sole portion, and the peak stress area within the forward portion of the sole, for each of the example clubs discussed below. Stress values were used to determine the undercut's effect on club performance through face and sole thinning. Example Club A was compared to Club B. Example Club C was compared to Club D. The control club head was similar to the example club heads, but devoid of any stress relieving features.
Club A was representative of a prior art golf club head lacking all stress relieving features and was similar to
As shown in Table 1, FEA analysis was used to calculate a value for peak stress within the strikeface of the Club A. Under a 105 mph impact load, the peak stress of the strikeface was 218469 psi. Under the same impact load, the forward portion of the strikeface had a peak stress of 157440 psi.
Club B was representative of a hollow body golf club head with an undercut stress relieving feature. Hollow body Club B was similar to Club A, but Club B included an undercut as stress relieving feature. Rather than meeting at a right angle, the undercut allowed the forward portion of the sole to extend beneath the ballast. The undercut of Example 1 comprised a depth of 0.065 inch, a height of 0.083 inch, an undercut transition height of 0.185 inches, and 1.16 inches.
The values for peak face stress, peak forward sole stress, and peak stress area were determined with FEA analysis and simulated impact with a golf ball at 105 mph. The peak face stress was 217117 psi and the peak forward sole stress 156257 psi. When compared to the Club A, the undercut reduced peak stress within the strikeface by 1352 psi and reduced peak stress within the forward portion of the sole by 1183 psi. This club showed that the ballast and undercut allow the both the strikeface and forward portion of the sole to store more strain energy. This means that Club B showed improved durability and improved spring response to impact loading.
The hollow body Club C was representative of a club head comprising a forward portion of the sole with a cascade, only. Club C was similar to Club A and B, but comprised a cascading sole as a singular form of stress relief. The transition from face to sole comprised first tier, a second tier and a tier transition between the first tier and the second tier. The first tier had a first tier thickness and second tier thickness, less than the first tier thickness. The tier transition was sloped to gradually transition the first tier thickness to the second tier thickness. The example did not comprise an undercut and the forward portion of the sole and ballast met at a substantially right angle.
Referring again to Table 1, the Example 2 hollow body golf club head had a peak face stress of 213311 psi, or a 5158 psi reduction of peak stress within the strikeface. The Example 2 club had a peak forward sole stress of 154742 psi (pounds per square inch), or a reduction in peak forward sole stress of 2698 psi This example showed that cascading sole reduced stress through increased storage of strain energy for improved durability and spring response under impact loading.
Club D (shown as
Club D was also subjected to FEA analysis under simulated ball impact at 105 mph. The peak face stress was 209851 psi, for a reduction of peak stress in the strikeface of 8618 psi. In other words, the Club D had a 4% reduction in peak stress within the strikeface. The peak stress of the forward sole portion was 154689 psi. The forward sole portion had a peak stress reduction of 3480 psi, or a 2.2% reduction from the Club A. This example showed that the undercut and cascading sole worked together to reduce peak stresses. Further, this example indicated that the forward portion of the sole could tolerate additional loading without reaching fatigue failure. The example showed that ball speed could be improved by thinning the face and sole to match the loading capacity of the forward sole portion.
The peak stresses of the forward sole portion in each of the club heads, specifically, indicated the potential for adjusting sole and face thickness and the resulting changes to ball speed. The peak stress of the forward sole portion was compared to the critical K yield stress value of the forward sole portion. Stresses that indicated that the strikeface and sole must be thickened, signaled that the internal cavity configuration would have reduced ball speed. Stresses that indicated that the strikeface and sole could be thinned, signaled that the internal cavity configuration would have increased ball speed.
Club A and Club B were compared to each other relative to a critical K value of 156 ksi. The peak stress of Club A, without an undercut, was 158169 psi. This peak stress value suggested that the sole and face would have needed to be thickened by roughly 2.5% in order to achieve stress values that did not exceed 156 ksi. The thickened face and sole indicated that the internal cavity configuration that would degrade ball speed. Club B, which comprised an undercut, improved peak stress within the forward sole portion. Club B had a peak stress of 156868 psi. The lower peak stress of Club B indicated Club B required the sole and face to be thickened less than the sole and face of Club A. These results showed that, after modifications, Club B and the undercut indicated better ball speed over Club A, without an undercut.
Similarly, Club C and Club D were compared to each other relative to the same critical K value of 156 ksi. The peak stress of Club C, with a cascading sole and without an undercut, was 155416 psi. Club C, with peak stress slightly less than the critical K stress, indicated that no modifications for improving or degrading ball speed would have been necessary. The slightly lower peak stress did indicate that the cascading sole in Club C would have increased durability. Club D comprised an undercut in addition to the cascading sole and had a peak stress of 154689 psi. Club D showed that the undercut provided further reduction to peak stress. This reduction in stress indicated that Club D had a face and sole that could tolerate thinning in order to improve ball speed.
The comparison of Club A and Club B and the comparison of Club C and Club D showed that the undercut reduced peak stress within the forward portion of the sole. These results further showed that the undercut could be applied to hollow body golf club heads to improve ball speed by leveraging stress reduction to thin the face and sole.
Club Performance with Undercut
In a second example, player testing of physical clubs was used to study the performance benefits of the undercut. In this example, a 7 iron comprising an undercut was compared to a structurally similar 7 iron, which lacked an undercut. The sole and face of the 7 iron having the undercut were optimized and reduced in thickness. Over 700 shots were taken on each golf club to analyze ball speed, launch angle, and spin rate.
Finally, the stat area (data not shown) of the 7 iron with the undercut was compared to the 7 iron without the undercut. The stat area data was used to determine the consistency of each of the golf club heads by plotting shot distance according to the left-right deviation from a straight shot. The 7 iron without the undercut had a distance deviation of 20 m, while the 7 iron with the undercut had a distance deviation of 14 m. The data showed that the undercut 7 iron produced shots that with more consistent distance.
The player results of Example 2 highlighted the performance benefits of the undercut. Specifically, the data showed that the undercut reduced spin on low lofted golf club heads, such as a 7 iron, and improved ball speed for improved distance. Reduced spin on low lofted golf clubs was preferred due to the distance requirements and expectations of longer, low lofted golf clubs. The Example also highlighted a tighter stat area for irons with an undercut and showed that the undercut irons performed more consistently for distance.
In a third example, player testing of physical clubs was used to study the performance benefits of the undercut in varying turf conditions. In this example, a pitching wedge comprising an undercut was compared to a structurally similar pitching, which lacked an undercut. Each golf club was hit in wet conditions and dry conditions and values for average launch angle, spin rate, and ball speed were measured.
The data above showed that the pitching wedge with the undercut performed more consistently in variable turf conditions than the wedge without an undercut. The launch angle of the wedge with the undercut varied by 0.5 degrees between wet and dry conditions, while the wedge without the undercut had a launch angle that 1.5 degrees. The data showed that the launch angle of the wedge without the undercut varied three times as much as the wedge with the undercut. Similarly, the spin rate of the ball coming off the wedge with the undercut was more consistent than the spin rate of the wedge without the undercut. The spin rate varied by just 586 rpm between dry and wet conditions for the wedge with the undercut, while the spin rate varied by 1166 rpm between dry and wet conditions for the wedge without the undercut. Consistent spin rates for wet and dry conditions of the undercut wedge were preferred, as the purpose of wedge-type golf clubs is consistent ball delivery on the green regardless of weather conditions. The ball speed of the wedge with and without the undercut were substantially similar.
As the rules to golf may change from time to time (e.g., new regulations may be adopted or old rules may be eliminated or modified by golf standard organizations and/or governing bodies), golf equipment related to the methods, apparatus, and/or articles of manufacture described herein may be conforming or non-conforming to the rules of golf at any particular time. Accordingly, golf equipment related to the methods, apparatus, and/or articles of manufacture described herein may be advertised, offered for sale, and/or sold as conforming or non-conforming golf equipment. The methods, apparatus, and/or articles of manufacture described herein are not limited in this regard.
Although a particular order of actions is described above, these actions may be performed in other temporal sequences. For example, two or more actions described above may be performed sequentially, concurrently, or simultaneously. Alternatively, two or more actions may be performed in reversed order. Further, one or more actions described above may not be performed at all. The apparatus, methods, and articles of manufacture described herein are not limited in this regard.
While the invention has been described in connection with various aspects, it will be understood that the invention is capable of further modifications. This application is intended to cover any variations, uses or adaptation of the invention following, in general, the principles of the invention, and including such departures from the present disclosure as come within the known and customary practice within the art to which the invention pertains.
This is a continuation of U.S. patent application Ser. No. 17/960,061, filed on Oct. 4, 2022, which is a continuation of U.S. patent application Ser. No. 17/237,010, filed on Apr. 21, 2021, now U.S. Pat. No. 11,458,373, which claims the benefit to U.S. Provisional Patent Application No. 63/013,341, filed on Apr. 21, 2020, all of which is incorporated herein by reference.
Number | Date | Country | |
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63013341 | Apr 2020 | US |
Number | Date | Country | |
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Parent | 17960061 | Oct 2022 | US |
Child | 18680989 | US | |
Parent | 17237010 | Apr 2021 | US |
Child | 17960061 | US |