The present disclosure relates generally to golf equipment, and more particularly, to iron and putter golf club heads methods to manufacture the same.
Described herein are iron and putter-type golf club heads. The forgiveness of an iron-type golf club head corresponds to the moment of inertia (MOT) values of the club head. A higher MOT will result in greater shot accuracy for off-center strikes on the face of the club head, particularly strikes made closer to the heel or toe ends of the face. Furthermore, off-axis moment of inertia values, often called products of inertia (POI), affect the sidespin response for strikes made closer to the top rail or sole. Often, iron-type golf club head bodies are formed from a single material that comprises a uniform density throughout. However, in some iron designs, the MOT is increased by employing multiple materials in a single head design or attaching high-density weights to the periphery of the club head. However, these means of positioning mass are limited in their ability to increase MOT, approach optimal POI, and desirably place the center of gravity (CG). There is a need in the art for an iron-type golf club head that can achieve a high MOT for forgiveness and a desirable POI for sidespin benefits, all without compromising durability.
Similar to iron-type club heads, putters often comprise solid bodies formed from a single material. The performance of a putter can be quantified by horizontal launch angle, which correlates to the offline movement of the ball during a putt. The horizontal launch angle can be affected by the position of the center of gravity (CG) of the putter head. Positioning the CG within a putter can be achieved by shifting mass. To shift mass, material must be added to the perimeter or removed from the center. There is a need in the art for an iron-type golf club head that can achieve a high MOT and a beneficial CG position, all without compromising durability.
The golf club heads described herein comprise a lattice structure that allows a golf club head to consistently achieve high MOI values, desirable POI values, and/or a beneficial CG position. A body of the golf club head can comprise an internal cavity that can be occupied by the lattice structure, which strategically distributes mass to reduce sidespin on high and low mis-hits on irons and reduce horizontal launch angle on heel and toe mis-hits on putters.
For the iron-type club heads, described herein, a lattice structure can occupy an internal cavity and distribute mass, creating a variable density profile within the cavity that achieves Ixy and Ixz product of inertia (POI) values that improve by 15%-50% and 5%-45%, respectively, over a similar club head lacking the lattice structure. The variable density lattice structure allows mass to be increased or reduced in different quadrants or regions of the club head to provide a desired asymmetry. More specifically, the iron-type golf club head can be weighted in high-toe and low-heel regions, by increasing the beam thickness of the lattice structure within those quadrants or regions. The beam thickness of each lattice unit correlates to an effective density of the lattice unit. In some designs, the beam thickness, and thus effective density, is varied in one or more of a sole-to-top rail direction and a front-to-rear direction. The effective density profile of the lattice structure, across the internal cavity, can cause the club head to functionally achieve an Ixy product of inertia value between −10 g·in2 and −40 g·in2 and an Ixz product of inertia value between −45 g·in2 and −65 g·in2. These POI values can reduce sidespin by up to 40% on mis-hits above and below the center of the strikeface.
For the putter-type club heads, described herein, particularly mallets and mid-mallets, a lattice structure can at least partially occupy an internal cavity, distributing mass forward and away from a baseline center of gravity (CG′), which is where the center of gravity would be located without the inclusion of the lattice structure. A portion of the internal cavity can be void of the lattice structure. This void can be defined as a central reference shape. By increasing the size of the central reference shape (void), the lattice structure can be pushed further towards the perimeter of the club head, thus increasing the moment of inertia (MOI) values. By shifting the central reference shape (void) rearwards, more of the lattice structure and golf club head material can be positioned towards the face, moving the center of gravity (CG) forward.
By using a lattice structure to move the CG forwards, the gearing effect on heel and toe off-center impacts is reduced. The reduction of gearing leads to a smaller horizontal launch angle and, therefore, straighter putts. For example, in a mallet type club head, the inclusion of a lattice structure that pushes the CG forward and towards the periphery of the club head (away from the CG) can reduce the magnitude of the horizontal launch angle, compared to a similar mallet club head lacking a lattice structure. Therefore, the mallet and mid-mallet-type golf club heads, described herein, can achieve straighter putts by approaching the minimal horizontal launch angles of blade-type putters, while retaining the highly valued feel, appearance, and sound qualities of mallet and mid-mallet-type putters. Any of the putter-type club heads described herein can be designed with a center of gravity position that favors a certain putt stroke type.
Definitions
The term “strikeface,” as used herein, can refer to a club head front surface that is configured to strike a golf ball. The strikeface is sometimes referred to simply as the “face.”
The term “strikeface perimeter,” as used herein, can refer to an edge of the strikeface. The strikeface perimeter can be located along an outer edge of the strikeface where the curvature deviates from a bulge and/or roll of the strikeface.
The term “face height,” as used herein, can refer to a distance measured parallel to loft plane between a top end of the strikeface perimeter and a bottom end of the strikeface perimeter.
The term “geometric centerpoint,” as used herein, can refer to a geometric centerpoint of the strikeface perimeter, and at a midpoint of the face height of the strikeface. In the same or other examples, the geometric centerpoint also can be centered with respect to an engineered impact zone, which can be defined by a region of grooves on the strikeface. As another approach, the geometric centerpoint of the strikeface can be located in accordance with the definition of a golf governing body such as the United States Golf Association (USGA). For example, the geometric centerpoint of the strikeface 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”).
The term “center” of the face (or “face center”), as used herein, can refer to a point on the face that is a projection of the CG, wherein the center and the CG lie on a common line that is approximately perpendicular to the loft plane (as defined below). Shots that impact above the face center cause dynamic lofting. Shots that impact below the face center cause dynamic de-lofting.
The term “center region,” as used herein, can refer to a region of the strikeface that is located both in front of and above the CG. In other words, a vertical line (along the Y-axis, as defined below) extending up from the CG and a horizontal line (along the X-axis, as defined below) extending forward from the CG towards the strikeface intersect the strikeface at the boundary of the center region. The center region extends from an end of the strikeface near the toe to an opposite end of the strikeface near the heel.
The term “ground plane,” as used herein, can refer to a reference plane associated with the surface on which a golf ball is placed.
The term “loft plane,” as used herein, can refer to a reference plane that is tangent to the geometric centerpoint of the strikeface.
The term “loft angle,” as used herein, can refer to an angle measured between the ground plane and the loft plane.
The term “lie angle,” as used herein, can refer to an angle between a hosel axis, extending through the hosel, and the ground plane. The lie angle is measured from a front view.
The term “iron,” as used herein, can, in some embodiments, refer to an iron-type golf club head having a loft angle that is less than approximately 50 degrees, less than approximately 49 degrees, less than approximately 48 degrees, 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, or less than approximately 40 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, or greater than approximately 25 degrees.
In many embodiments, such as game improvement irons or regular irons, the volume of the club head is less than approximately 65 cc, less than approximately 60 cc, less than approximately 55 cc, or less than approximately 50 cc. In some embodiments, the volume of the club head can be approximately 50 cc to 60 cc, approximately 51 cc-53 cc, approximately 53 cc-55 cc, approximately 55 cc-57 cc, or approximately 57 cc-59 cc.
In many embodiments, such as for tour irons, the volume of the club head is less than approximately 45 cc, less than approximately 40 cc, less than approximately 35 cc, or less than approximately 30 cc. In some embodiments, the volume of the club head can be approximately 31 cc-38 cc (1.9 cubic inches to 2.3 cubic inches), approximately 31 cc-33 cc, approximately 33 cc-35 cc, approximately 35 cc-37 cc, or approximately 37 cc-39 cc.
In some embodiments, the iron can comprise a total mass ranging between 180 grams and 260 grams, 190 grams and 240 grams, 200 grams and 230 grams, 210 grams and 220 grams, or 215 grams and 220 grams. In some embodiments, the total mass of the club head is 215 grams, 216 grams, 217 grams, 218 grams, 219 grams, or 220 grams.
The term “putter,” can, in some embodiments, refer to a putter-type club head having a loft angle less than 10 degrees. In many embodiments, the loft angle of the putter can be between 0 and 5 degrees, between 0 and 6 degrees, between 0 and 7 degrees, or between 0 and 8 degrees. For example, the loft angle of the club head can be less than 10 degrees, less than 9 degrees, less than 8 degrees, less than 7 degrees, less than 6 degrees, or less than 5 degrees. For further example, the loft angle of the club head can be 0 degrees, 1 degree, 2 degrees, 3 degrees, 4 degrees, 5 degrees, 6 degrees, 7 degrees, 8 degrees, 9 degrees, or 10 degrees. The putter-type golf club head can be a blade type putter, a mid-mallet type putter, a mallet type putter. It should be understood that the principles and structures described for the mid-mallet type putter can be applied in a blade type putter and/or a mallet type putter without departing from the scope of this disclosure.
In some embodiments, the putter can be a mid-mallet type club head comprising a total mass ranging between 320 grams and 400 grams, 330 grams and 390 grams, 340 grams and 380 grams, 350 grams and 380 grams, or 365 grams and 370 grams. In some embodiments, the total mass of the club head is 365 grams, 366 grams, 367 grams, 368 grams, 369 grams, or 370 grams.
The term “golf club head,” as used herein, can refer to a golf club element comprising a face, a sole, a crown or top rail, a toe end, and a heel end. The golf club head can also comprise an external surface and an internal surface. The internal surface bounds an interior cavity or hollow portion. The lattice structures and benefits described herein with respect to the golf club head are not intended to apply to wood-type club heads, such as driver, fairway, or hybrid-type golf club heads.
The golf club head comprises a coordinate system centered about the center of gravity. The coordinate system comprises an X-axis, a Y-axis, and a Z-axis. The X-axis extends in a heel-to-toe direction. The X-axis is positive towards the heel and negative towards the toe. The Y-axis extends in a sole-to-crown direction and is orthogonal to both the Z-axis and the X-axis. The Y-axis is positive towards the crown and negative towards the sole. The Z-axis extends front-to-rear, parallel to the ground plane and is orthogonal to both the X-axis and the Y-axis. The Z-axis is positive towards the front and negative towards the rear.
The golf club head further comprises a secondary coordinate system, centered about an origin point just off a leading edge of the strikeface. The origin point is located where the loft plane intersects the ground plane. The origin point is also within a vertical, front-to-rear plane that intersects the geometric centerpoint of the strikeface and is perpendicular to the ground plane. This secondary coordinate system comprises an X′-axis, a Y′-axis, and a Z′-axis. The X′-axis extends in a heel-to-toe direction and is positive towards the heel end of the club head. The Y′-axis extends in a sole-to-crown (or sole-to-top rail) direction and is positive towards the crown (or top rail). The Z′-axis extends in a front-to-rear direction and is positive towards the front.
The term “moment of inertia” (hereafter “MOI”) can refer to values measured about the CG. The term “Ixx” can refer to the MOI measured in the heel-to-toe direction, parallel to the X-axis. The term “Iyy” can refer to the MOI measured in the sole-to-top rail (or sole-to-crown) direction, parallel to the Y-axis. The term “Izz” can refer to the MOI measured in the front-to-back direction, parallel to the Z-axis. The MOI values Ixx, Iyy, and Izz determine how forgiving the club head is for off-center impacts with a golf ball.
The term “products of inertia” (hereafter “POI”) can relate the symmetry of the golf club head about a first axis, to the symmetry of the club head about a second axis. The closer the product of inertia about two axes is near zero in magnitude, the less likely the golf club head is to rotate about those respective axes simultaneously, since the golf club head is symmetrically balanced. Products of inertia can have either positive or negative values. For a positive product of inertia, a positive rotation of the golf club head about the first axis creates a negative rotation of the golf club head about the second axis. Conversely, for a negative product of inertia, a positive rotation of the golf club head about the first axis creates a positive rotation of the golf club head about the second axis.
The terms “favorable POI”, “desirable POI”, or “improved POI” can refer to one or more product of inertia values of the club head that approach a target POI when compared to a control club head comprising similar features, but lacking lattice structures.
The golf club head can be divided into a high-toe quadrant, a low-toe quadrant, a high-heel high heel quadrant, and a low-heel low heel quadrant. The quadrants are divided by the X-axis and the Y-axis from a front view, and extend rearward in a direction orthogonal to the loft plane. Specifically, the term “high-toe quadrant” refers to a section of the golf club head where the X-axis is negative and the Y-axis is positive. The term “low-toe quadrant” refers to a section of the golf club head where the X-axis is negative and the Y-axis is negative. The term “high-heel quadrant” refers to a section of the golf club head where the X-axis is positive and the Y-axis is positive. The term “low-heel quadrant” refers to a section of the golf club head where the X-axis is positive and the Y-axis is negative.
Described herein is a solid portions of the body. The effective density of the lattice structure can vary or remain constant across different regions of the golf club head. A varying density profile can be achieved by altering the beam thickness of the unit scaffolding within each lattice unit. The lattice structure can be used in either an iron-type or putter-type golf club head. In some iron-type golf club heads, the lattice structure density profile can be designed to add mass to high-toe and low-heel quadrants or regions, while reducing mass in the low-toe and high-heel quadrants or regions. Similarly, for some irons, the lattice structure density profile can be designed to add mass to the front-toe and rear-heel regions, while reducing mass in the rear-toe and front-heel quadrants or regions. By distributing mass with the lattice structure, certain product of inertia values can be achieved that result in improved spin properties on high and low mis-hits.
In some putter-type golf club heads, the lattice structure can be designed to add mass to the perimeter of the body and remove mass from a center of the body. The interior cavity can be partially or fully latticed. In partially latticed embodiments, the lattice structure can be excluded from a central reference shape, pushing mass towards the perimeter of the club head. Additionally, the lattice structure can be used to remove mass from a rear of the club head, shifting the center of gravity forward, compared to a similar putter head lacking the lattice structure. A putter head with a forward-positioned CG can exhibit a horizontal launch angle of a lower magnitude than a putter head with a CG positioned rearward in comparison. In particular, a mallet or mid-mallet putter head with a forward-positioned CG can perform more like a blade-type putter than a mallet or mid-mallet lacking a lattice structure. Thus, the lattice structure described herein can be implemented in a mallet or mid-mallet type putter head to create a putter head that looks, feels, and sounds like a mallet or mid-mallet, while having desirable performance benefits similar to a blade-type putter.
Described below is the lattice structure, followed by a description of iron embodiments with a lattice structure and putter embodiments with a lattice structure. The performance benefits achieved by inclusion of the lattice structure differs between iron-type club heads and putter-type club heads. However, the ability to strategically redistribute mass through a lattice structure is common across all the exemplary golf club heads described below.
Lattice Structure
As shown in
The lattice structure 130 can also be called a lattice array, a structural array, a gridwork, a mesh, a framework, a skeleton, or an internal lattice. The lattice structure 130 can occupy a latticed region. The lattice structure 130 (or latticed region) can comprise a total lattice volume and a filled volume. The total lattice volume is the volume occupied by the lattice 130, more specifically, bounded by a surface that is defined by the perimeter-most points 135 (or beam ends) of the lattice structure 130. In other words, the lattice structure 130 (or latticed region) covers, occupies, or spreads across the total lattice volume. The total lattice volume can include empty space 138. The lattice structure 130 (or latticed region) can cover between 20% and 100% of a volume of the interior cavity 120. In some embodiments, the lattice structure 130 (or latticed region) covers between 20% and 30%, 30% and 40%, 40% and 50%, 50% and 60%, 60% and 70%, 70% and 80%, 80% and 90%, or 90% and 100% of the volume of the interior cavity 120. In some embodiments, the total lattice volume can be between 0 cubic inches and 4 cubic inches (0 cubic centimeters (cc) and 65.5 cc). The total lattice volume can be between 0 cubic inches and 1 cubic inch (0 cc and 16.4 cc), 1 cubic inch and 2 cubic inches (16.4 cc and 32.8 cc), 2 cubic inches and 2.5 cubic inches (32.8 cc and 41.0 cc), 2.5 cubic inches and 3.0 cubic inches (41.0 cc and 49.2 cc), or 3.0 cubic inches and 4 cubic inches (49.2 cc and 65.5 cc). In some embodiments, the total lattice volume can be about 2.6 cubic inches (42.6 cc).
The filled volume is the volume that is occupied by the unit scaffolding 136 of the plurality of lattice units 134 (i.e. not including empty space 138). The filled volume can be approximately 5% to 90% of the total lattice volume. In other words, the unit scaffolding 136 can occupy approximately 5% to 90% of the total lattice volume. In some embodiments, the filled volume can be approximately 20% to 80%, 30% to 70%, 40% to 60%, 5% to 15%, 5% to 20%, 5% to 30%, 5% to 40%, 5% to 50%, or 45% to 75% of the total lattice volume.
An effective density of the lattice structure 130 (or of the latticed region) can equal the total mass of the unit scaffolding 136 divided by the total lattice volume. The effective density is determined by the beam thickness of the unit scaffolding. As described below, a greater beam thickness will result in a higher effective density. The effective density is less than the material density of the unit scaffolding 136. The effective density of the lattice structure 130 can range inclusively between 0 g/mm3 and 0.0075 g/mm3. In some embodiments, the effective density can range inclusively between 0 g/mm3 and 0.001 g/mm3, 0.001 g/mm3 and 0.002 g/mm3, 0.002 g/mm3 and 0.003 g/mm3, 0.003 g/mm3 and 0.004 g/mm3, 0.004 g/mm3 and 0.005 g/mm3, 0.005 g/mm3 and 0.006 g/mm3, 0.006 g/mm3 and 0.007 g/mm3, 0.007 g/mm3 and 0.0075 g/mm3, 0 g/mm3 and 0.004 g/mm3, 0.002 g/mm3 and 0.006 g/mm3, or 0.004 g/mm3 and 0.0075 g/mm3. The lattice structure 130 effective density can correlate to a beam thickness of the unit scaffolding, as described below.
The lattice structure 130 can have an effective density profile. The effective density can either be constant (and uniform) throughout the lattice structure 130 or it can vary (and be non-uniform). In some embodiments, the effective density can vary radially. For example, the effective density can increase as the distance from the CG increases. In some embodiments, the effective density can vary in only one direction. For example, the lattice structure effective density can vary in one of the following directions: heel-to-toe (parallel to X-axis), front-to-back (parallel to Z-axis), or top-to-bottom (parallel to Y-axis). In some embodiments, the density profile can vary in a single direction that is a combination of two or more of the following directions: heel-to-toe, front-to-back, or top-to-bottom. In other embodiments, the effective density can vary in more than one direction. Furthermore, the lattice structure effective density can vary linearly or non-linearly. In some embodiments, the lattice structure effective density can vary linearly in a first direction and non-linearly in a second direction.
In some embodiments, the effective density can vary at an average rate of inclusively between approximately 0.0005 g*mm3 per cm and approximately 0.0015 g*mm3 per cm (approximately 0.0013 g*mm3 per inch and approximately 0.0038 g*mm3 per inch). For example, the effective density can vary at an average rate of approximately 0.001 g*mm3 per cm (approximately 0.0025 g*mm3 per inch).
Beams
Referring to
The beams 137 of each unit scaffolding 136 can form geometric structures including but not limited to: simple cubic, body centered cubic, face centered cubic, column, columns, diamond, fluorite, octet, truncated cube, truncated octahedron, kelvin cell, IsoTruss, re-entrant, weaire-phelan, triangular honeycomb, triangular honeycomb rotated, hexagonal honeycomb, re-entrant honeycomb, square honeycomb rotate, square honeycomb, face centered cubic foam, body centered cubic foam, simple cubic foam, hex prism diamond, hex prism edge, hex prism vertex centroid, hex prism central axis edge, hex prism laves phase, tet oct vertex centroid, and oct vertex centroid.
The fluorite structure comprises interconnecting beams 137, arranged as illustrated in
Referring to
Referring to the graph in
In embodiments with a varying effective density profile, the beam thickness 144 can vary throughout the lattice structure 130. In some embodiments, the beam thickness 144 can increase in any direction by approximately two-fold (double), three-fold (triple), four-fold (quadruple), five-fold (quintuple), six-fold, seven-fold, eight-fold, nine-fold or ten-fold across the lattice structure 130. In some embodiments, the beam thickness 144 can increase in any direction by approximately 0% to 50%, 50% to 100%, 100% to 200%, 200% to 300%, 300% to 400%, 400% to 500%, 500% to 600%, 600% to 700%, 700% to 800%, 800% to 900%, or 900% to 1000% across the lattice structure 130. In some embodiments, the beam thickness 144 increases by the same factor in all directions. In other embodiments, the beam thickness 144 increases by different factors in some directions.
Unit Scaffolding
The plurality of beams 144 can form the unit scaffolding 136. Each lattice unit 134 of the plurality of lattice units can comprise a unit scaffolding 136. The unit scaffolding 136 can also be called the unit structure, the unit skeleton, or the unit frame. The unit scaffolding 136 is the structural portion of each lattice unit 134. The unit scaffolding 136 bears the stresses and loads placed on the lattice structure 130. The remainder of each lattice unit 134 is void, empty, and/or vacant of structural material. The portion of the lattice unit 134 that is devoid of the unit scaffolding 136 can be referred to as the unit void 138. The volume occupied by the unit scaffolding 136, compared to the volume of the unit void 138, determines the effective density of each lattice unit 134. The effective density of the lattice units 134 can vary within different parts of the latticed region. The varying effective densities of the lattice units 134 enables mass concentration towards the periphery of the club head 100. Since the plurality of lattice units 134 makes up the lattice structure 130, an overall effective density profile of the lattice structure 130 is determined by the densities of individual lattice units 134.
Lattice Units
The lattice structure 130 can comprise a plurality of lattice units 134. Each lattice unit 134 can comprise a unit scaffolding 136, formed of a plurality of beams 137, and a unit void 138. The unit void 138 can often be empty space surrounding the unit scaffolding 136. The plurality of lattice units 134 can have any shape which can be tessellated in three dimensions, such as a cube (most common), a rhombic dodecahedron, a truncated octahedron, a triangular prism, a quadrilateral prism, a hexagonal prism, or any other suitable plesiohedron (shape-filling polyhedron).
Similar to the overall lattice structure 130 (or latticed region), each lattice unit 134 comprises a total unit volume and a filled unit volume. The total unit volume is the volume occupied by a lattice unit 134. Each lattice unit 134 can comprise a total unit volume between approximately 0.007 cubic inch and 1.700 cubic inches. In some embodiments, each lattice unit 134 can comprise a total unit volume between approximately 0.007 cubic inch and 0.010 cubic inch, 0.010 cubic inch and 0.050 cubic inch, 0.050 cubic inch and 0.100 cubic inch, 0.100 cubic inch and 0.150 cubic inch, 0.150 cubic inch and 0.200 cubic inch, 0.200 cubic inch and 0.300 cubic inch, 0.300 cubic inch and 0.400 cubic inch, 0.400 cubic inch and 0.500 cubic inch, 0.500 cubic inch and 0.600 cubic inch, 0.600 cubic inch and 0.700 cubic inch, 0.700 cubic inch and 0.800 cubic inch, 0.800 cubic inch and 0.900 cubic inch, 0.900 cubic inch and 1.000 cubic inch, 1.0 cubic inch and 1.1 cubic inch, 1.1 cubic inch and 1.2 cubic inch, 1.2 cubic inch and 1.3 cubic inch, 1.3 cubic inch and 1.4 cubic inch, 1.4 cubic inch and 1.5 cubic inch, 1.5 cubic and 1.6 cubic inch, or 1.6 cubic inch and 1.7 cubic inch. The total unit volume of the lattice unit 134 can affect the supporting strength and the weight of the lattice structure 130. The total unit volume determines the number of lattice units 134 within the plurality of lattice units.
The filled unit volume is the volume occupied by the unit scaffolding 136. The filled unit volume can be between 5% and 95% of the total unit volume. In some embodiments, the filled unit volume can be approximately 20% to 80%, 30% to 70%, 40% to 60%, 5% to 15%, 5% to 20%, 5% to 30%, 5% to 40%, 5% to 50%, or 45% to 75% of the total unit volume. A ratio of filled unit volume to total unit volume can vary between lattice units 134 within the same lattice structure 130 (or latticed region).
The plurality of lattice units 134 can comprise between 2 and 600 lattice units 134. In some embodiments, the plurality of lattice units 134 can comprise between 2 and 10, 4 and 8, 5 and 8, 5 and 10, 10 and 20, 10 and 50, 50 and 100, 100 and 150, 150 and 200, 200 and 250, 250 and 300, 300 and 350, 350 and 400, 400 and 450, 450 and 500, 500 and 550, or 550 and 600 lattice units 134. In some embodiments, the plurality of lattice units comprises more than 10, more than 20, more than 50, more than 100, more than 200, more than 300, more than 400, or more than 500. The number of lattice units 134 can affect the supporting strength, weight, and manufacturability of the lattice structure 130.
In some embodiments, each lattice unit 134 of the plurality of lattice units 134 can comprise a side length (not illustrated) between 5 mm and 30 mm (0.197 inch and 1.181 inch). In some embodiments, each lattice unit 134 can comprise a side length between 5 mm and 10 mm, 10 mm and 15 mm, 15 mm and 20 mm, 20 mm and 25 mm, 25 mm and 30 mm. In some embodiments, each lattice unit 134 can comprise a side length measuring equal to or less than: 8 mm (about 0.31 inch), 10 mm (about 0.39 inch), 12 mm (about 0.47 inch), 14 mm (about 0.55 inch), 16 mm (about 0.63 inch), 18 mm (about 0.71 inch), 20 mm (about 0.79 inch), 25 mm (about 0.98 inch), or 30 mm (about 1.18 inches). In a cubic shaped lattice unit 134, the side lengths are equal across the three-dimensional (3D) shape. In other shapes, the side lengths can differ.
Ultra-Lightweight Filler
In some embodiments, the unit void 138 of each lattice unit 134 can be filled with an ultra-lightweight filler. In other words, the ultra-lightweight filler can surround or fill around the unit scaffolding 136. The ultra-lightweight filler can be a polymer resin, a foam, a rubber, an absorptive material, or any other low-density filler material.
Reference Shape Devoid of Lattice
Referring to
Referring to
The lattice structure 530 can extend radially or in a grid-like pattern away from the central reference point 552 towards the periphery of the club head 500. In embodiments with non-uniform lattice structure density, the density profile of the lattice structure 530 can vary with respect to a distance from the central reference point 552.
The central reference shape 550 can be a sphere, a cylinder, a polyhedron, a prism, a cube, or any other three-dimensional shape. The central reference shape 550 can comprise a border surface 554, which bounds a volume of the central reference shape 550. The border surface 554 of the central reference shape 550 can form an inner boundary of the latticed region 530. In embodiments with non-uniform lattice structure density, the density profile of the lattice structure 530 can vary with respect to a distance from the central reference shape 550. The MOI of the club head 500 is increased by excluding the lattice structure 530 from the central reference shape 550 and/or by optionally varying the lattice structure density profile.
When the central reference shape 550 is larger, the lattice structure 530 volume decreases. Furthermore, a larger central reference shape 550 can result in a higher total club head MOI, because the lattice structure 530 (and its inherent mass) is concentrated near or adjacent the periphery of the club head 500. In embodiments where the central reference shape 550 is a sphere shape, the central reference sphere 550 can comprise various diameter values. In some embodiments, the central reference sphere 550 can comprise a diameter between 0 inches and 3.0 inches (7.62 centimeters). In some embodiments the central reference sphere diameter can be between 0 inches and 1.5 inches (3.81 centimeters), 1.5 inches (3.81 centimeters) and 3.0 inches (7.62 centimeters), 0 inches and 1.0 inches (2.54 centimeters), 1.0 inch (2.54 centimeters) and 2.0 inches (5.08 centimeters), 2.0 inches (5.08 centimeters) and 3.0 inches (7.62 centimeters), 0.5 inch (1.27 centimeters) and 1.5 inch (3.81 centimeters), 0 inches and 0.5 inch (1.27 centimeters), 0.5 inch (1.27 centimeters) and 1.0 inch (2.54 centimeters), 1.0 inch (2.54 centimeters) and 1.5 inch (3.81 centimeters), 1.5 inch (3.81 centimeters) and 2.0 inch (5.08 centimeters), 2.0 inch (5.08 centimeters) and 2.5 inch (6.35 centimeters), or 2.5 inch (6.35 centimeters) and 3.0 inch (7.62 centimeters). Although the embodiment of
Materials
The golf club head 100 comprises a face material and a body material. In most embodiments, the strike face 104 comprises the face material, while the body comprises the body material. In most embodiments, the face material is different than the body material, however in some embodiments, the face material can be the same as the body material. In some embodiments, the body can comprise multiple metal materials.
The face material and the body material can comprise a metal alloy, such as a titanium alloy, a steel alloy, an aluminum alloy, an amorphous metal alloy, or any other metal or metal alloy. Examples of steels or steel alloys may include, but are not limited to: stainless steel, stainless steel alloy, C300, C350, Ni (Nickel)-Co (Cobalt)-Cr (Chromium)-Steel Alloy, 8620 alloy steel, S25C steel, 303 SS, 17-4 SS, carbon steel, maraging steel, 565 Steel, AISI type 304 stainless steel, and AISI type 630 stainless steel. Examples of titanium alloys may include, but are not limited to: Ti-6-4, Ti-3-8-6-4-4, Ti-10-2-3, Ti 15-3-3-3, Ti 15-5-3, Ti185, Ti 6-6-2, Ti-7s, Ti-9s, Ti-92, and Ti-8-1-1 Titanium alloy.
Iron
As discussed above, lattice structures 130 can be utilized in an iron-type golf club head 100 to optimize one or more mass properties of the club head 100, including increasing moments of inertia (MOI), products of inertia (POI), and CG positioning. Described below are embodiments of various iron-type golf club heads comprising lattice structures to improve the products of inertia and produce a reduction in sidespin of up to 40% of high or low mis-hits. Each club head 100 embodiment can comprise a face 104, a sole 110, a top rail 108, a toe end 112, a heel end 114, a hosel 105, an external surface 122, and an internal surface 124. The internal surface 124 bounds an interior cavity 120 (or hollow portion). The interior cavity 120 can be fully latticed, completely occupied by the lattice structure 130. Subsequent embodiments of the iron-type club head 200, 300, 400 can comprise similar features, labeled similarly to the first iron-type club head embodiment 100, but with a 200, 300, or 400 numbering scheme (i.e. club head 200 comprises a strike face 204, a sole 210, a top rail 208, etc.). The various club head embodiments 100, 200, 300, 400 are all similar but for the arrangement of the lattice structure 130, specifically the effective density profile of each particular lattice structure 130, and other features for the reallocation of mass.
Referring to
Referring to
As mentioned above, the high-toe, low-toe, high-heel, and low-heel boundary lines 184, 185, 186, 187 delimit the high-toe, low-toe, high-heel, and low-heel regions 181, 182, 183, 184, respectively. In the embodiment of
Conversely, the low-toe boundary line 185 and the high-heel boundary line 186 are defined by the following equation, with respect to position along the x-axis 1050 and the y-axis 1060:
In other embodiments, the shape and/or size of the various regions can change. For example, the factors with values “0.35” and “−0.35,” in the equations above, can take various values, so long as the resulting regions remain suitable for creating favorable asymmetry and improving POI by adding or removing mass in such regions. In other words, the boundary lines can curve more or less sharply. The overall design of the club head 100 can affect the optimal regions for adding or removing mass to improve POI.
The POI about the x-axis 1050 and y-axis 1060 (hereafter “Ixy”) of the iron-type club head 100 can be improved by increasing the amount of mass located within certain high and/or low regions and reducing the amount of mass in other high/and or low regions. The club head 100 comprises asymmetric weighting with respect to the x-axis 1050 and the y-axis 1060. In many embodiments, the high-toe region 180 and the low-heel region 183 comprise added mass regions, while the low-toe region 181 and the high-heel region 182 comprise reduced mass regions. The mass of each region can be increased or reduced by the inclusion of the lattice structure 130. The high-toe region 180 and the low-heel region 183 can comprise lattice structures 130 with relatively high effective densities to increase the overall amount of mass in said regions. Conversely, the low-toe region 181 and the high-heel region 182 can comprise lattice structures 130 with relatively low effective densities or no lattice structures at all, such that the mass in said regions is reduced. In some embodiments, the low-toe region 181 and the high-heel region 182 can comprise portions of the perimeter of the club head 100 that are mined out by the lattice structure 130, further reducing the mass in said regions.
The club heads 100, 200, 300, 400 comprise lattice structures 130 arranged to allocated high amounts of mass in the high-toe region 180 and low-heel region 183 and lower amounts of mass in the low-toe region 181 and the high-heel region 182. This specific arrangement accomplished by varying the effective density of the lattice structure 130 results in an increase Ixy that leads to a reduction in sidespin. In many embodiments, the high-toe region 180 and/or the low-heel region 183 can comprise an effective density greater than the low-toe region 181 and/or the high-heel region 182. In some embodiments, the effective density of the lattice structure 130, 230, 330, 430 in the high-toe region 180 and/or low-heel region 183 can range between approximately 0.006 g/mm3 and approximately 0.0075 g/mm3. In some embodiments, the effective density of the lattice structure 130230, 330, 430 in the high-toe region 180 and/or the low-heel region 183 can range between 0.006 g/mm3 and 0.00625 g/mm3, between 0.00625 g/mm3 and 0.00650 g/mm3, between 0.00650 g/mm3 and 0.00675 g/mm3, between 0.00675 g/mm3 and 0.007 g/mm3, between 0.007 g/mm3 and 0.00725 g/mm3, or between 0.00725 g/mm3 and 0.0075 g/mm3. In some embodiments, the effective density of the lattice structure 130, 230, 330, 430 in the high-toe region 180 and/or the low-heel region 183 can range between 0.006 g/mm3 and 0.00675 g/mm3, between 0.00625 g/mm3 and 0.007 g/mm3, between 0.0065 g/mm3 and 0.00725 g/mm3, or between 0.00675 g/mm3 and 0.0075 g/mm3.
As discussed above, the effective density in the low-toe region 181 and/or the high-heel region 182 can be significantly less than the effective density in the high-toe region 180 and/or the low-heel region 183. In some embodiments, the effective density of the lattice structure 130, 230, 330, 430 in the low-toe region 181 and/or high-heel region 182 can range between approximately 0.0001 g/mm3 and approximately 0.00075 g/mm3. In some embodiments, the effective density of the lattice structure 130, 230, 330, 430 in the low-toe region 181 and/or the high-heel region 182 can range between 0.0001 g/mm3 and 0.0002 g/mm3, between 0.0002 g/mm3 and 0.0003 g/mm3, between 0.0003 g/mm3 and 0.0004 g/mm3, between 0.0004 g/mm3 and 0.0005 g/mm3, between 0.0005 g/mm3 and 0.0006 g/mm3, or between 0.0006 g/mm3 and 0.00075 g/mm3. In some embodiments, the effective density of the lattice structure 130, 230, 330, 430 in the low-toe region 181 and/or the high-heel region 182 can range between 0.0001 g/mm3 and 0.0005 g/mm3, between 0.0002 g/mm3 and 0.0006 g/mm3, between 0.0003 g/mm3 and 0.0007 g/mm3, or between 0.0004 g/mm3 and 0.00075 g/mm3.
The asymmetry caused by increasing the mass in the high-toe region 180 and low-heel region 183 while reducing mass in the low-toe region 181 and high-heel region 182 improves the Ixy of the club head 100. This specific asymmetry in the club head 100 is desirable for providing an increased (i.e. more positive or less negative) Ixy. As will be discussed in further detail below, a more positive Ixy generates less undesirable sidespin on shots mis-hit above or below center.
Referring to
As mentioned above, the front-toe, rear-toe, front-heel, and rear-heel boundary lines 192, 193, 194, 195, delimit the front-toe, rear-toe, front-heel, and rear-heel regions 188, 189, 190, 191, respectively. In the embodiment of
Conversely, the front-toe boundary line 192 and the rear-heel boundary line 195 are defined by the following equation, with respect to position along the x-axis 1050 and the z-axis 1070:
In other embodiments, the shape and/or size of the various regions can change. For example, the factors with values “0.35” and “−0.35,” in the equations above, can take various values, so long as the resulting regions remain suitable for improving POI by adding or removing mass in such regions. In other words, the boundary lines can curve more or less sharply. The overall design of the club head can affect the optimal regions for adding or removing mass to improve POI.
The POI about the x-axis 1050 and z-axis 1070 (hereafter “Ixz”) of the iron-type club head 100 can be improved by increasing the amount of mass located within certain front and/or rear regions and reducing the amount of mass in other front and/or rear regions. The club head 100 comprises asymmetric weighting with respect to the x-axis 1050 and the z-axis 1070. In many embodiments, the front-toe region 188 and the rear-heel region 191 comprise added mass regions, while the rear-toe region 189 and the front-heel region 190 comprise reduced mass regions. The mass of each region can be increased or reduced by the inclusion of the lattice structure 130. The front-toe region 188 and the rear-heel region 191 can comprise lattice structures 130 with relatively high effective densities to increase the overall amount of mass in said regions. Conversely, the rear-toe region 189 and the front-heel region 190 can comprise lattice structures 130 with relatively low effective densities or no lattice structures at all, such that the mass in said regions is reduced. In some embodiments, the rear-toe region 189 and the front-heel region 190 can comprise portions of the perimeter of the club head 100 that are mined out by a lattice structure 130, further reducing the mass in said regions.
The asymmetry caused by increasing the mass in the front-toe region 188 and rear-heel region 191 and reducing mass in the rear-toe region 189 and front-heel region 190 improves the Ixz of the club head 100. Typically, club heads 100 comprise drastically negative Ixz values. This specific asymmetry in the club head 100 is desirable for providing an increased (i.e. less negative) Ixz that more closely matches an optimal target value. A more optimal Ixz generates less undesirable sidespin on shots mis-hit above or below center.
As can be seen from
Further, at some portions of the club head 100, an added mass region and a reduced mass region can intersect. The effective density of such portions can be somewhere in between the lowest effective density and the highest effective density of the club head 100. For example, portions of the club head wherein the high-toe region 180 and the rear-toe region 189 intersect can comprise a lattice structure 130 with an effective density less than that of portions wherein the low-heel region 183 and the rear-heel region 191 intersect, yet greater than that of portions wherein the low-toe region 181 and the rear-toe region 189 intersect.
Mass can be increased in the high-toe, rear-toe, low-heel, and front heel regions and decreased in the low-toe, front-toe, high-heel, and rear-heel regions the club head 100 by the arrangement of a variable effective density lattice structure 130 to improve POI. In general, redistributing mass to create the necessary asymmetry for increasing Ixy and/or Ixz can have negative effects on other mass properties of the iron-type golf club head 100, such as MOI. However, the strategic arrangement of the lattice region 130 can increase Ixy and Ixz while retaining high MOI values about the X-axis (Ixx), the Y-axis (Iyy), and the Z-axis (Izz). Due to the location of the added mass regions being located away from the CG, the club head 100 retains high perimeter weighting, even as mass is redistributed. As such, the iron-type club head 100 comprising lattice structures 130 comprises increased Ixy and Ixz over a similar club head without such lattice structures, and yet comprises similar MOI compared to the club head without lattice structures.
For the sake of comparison, a club head similar to club head 100, but without lattice structures can comprise an MOI about the X-axis (Ixx) between approximately 100 g*in2 and 120 g*in2. In comparison, the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 can comprise an MOI about the X-axis (Ixx) greater than approximately 80 g*in2, greater than approximately 85 g*in2, greater than approximately 90 g*in2, greater than approximately 95 g*in2, greater than approximately 100 g*in2, greater than approximately 105 g*in2, greater than approximately 110 g*in2, greater than approximately 115 g*in2, or greater than approximately 120 g*in2. In some embodiments, the club head 100, 200, 300, 400 comprises an Ixx value between approximately 80 g*in2 and approximately 120 g*in2. In some embodiments, the club head 100, 200, 300, 400 comprises an Ixx value between approximately 80 g*in2 and 90 g*in2, between approximately 85 g*in2 and 95 g*in2, between approximately 90 g*in2 and 100 g*in2, between approximately 95 g*in2 and 105 g*in2, between approximately 100 g*in2 and 110 g*in2, between approximately 105 g*in2 and 115 g*in2, or between approximately 110 g*in2 and 120 g*in2. In some embodiments, the Ixx value of the club head 100, 200, 300, 400 can be approximately 105 g*in2, 106 g*in2, 107 g*in2, 108 g*in2, 109 g*in2, or 110 g*in2.
For the sake of comparison, a club head similar to club head 100, but without lattice structures can comprise an MOI about the Y-axis (Iyy) between approximately 500 g*in2 and 550 g*in2. In comparison, the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 can comprise an MOI about the Y-axis (Iyy) greater than approximately 400 g*in2, greater than approximately 425 g*in2, greater than approximately 450 g*in2, greater than approximately 475 g*in2, greater than approximately 500 g*in2, greater than approximately 525 g*in2, or greater than approximately 550 g*in2. In some embodiments, the club head 100, 200, 300, 400 comprises an Iyy value between approximately 400 g*in2 and approximately 550 g*in2. In some embodiments, the club head 100, 200, 300, 400 comprises an Ixx value between approximately 400 g*in2 and 450 g*in2, between approximately 425 g*in2 and 475 g*in2, between approximately 450 g*in2 and 500 g*in2, between approximately 475 g*in2 and 525 g*in2, or between approximately 500 g*in2 and 550 g*in2. In some embodiments, the Iyy value of the club head 100, 200, 300, 400 can be approximately 420 g*in2, 430 g*in2, 440 g*in2, 450 g*in2, 460 g*in2, 470 g*in2, 480 g*in2, 490 g*in2, 500 g*in2, 510 g*in2, 520 g*in2, 530 g*in2, 540 g*in2, or 550 g*in2.
For the sake of comparison, a club head similar to club head 100 but without lattice structures can comprise an MOI about the Z-axis (Izz) between approximately 550 g*in2 and 600 g*in2. In comparison, the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 can comprise an MOI about the Z-axis (Izz) greater than approximately 450 g*in2, greater than approximately 475 g*in2, greater than approximately 500 g*in2, greater than approximately 525 g*in2, greater than approximately 550 g*in2, or greater than approximately 575 g*in2. In some embodiments, the club head 100 comprises an Izz value between approximately 450 g*in2 and approximately 575 g*in2. In some embodiments, the club head 100, 200, 300, 400 comprises an Ixx value between approximately 450 g*in2 and 500 g*in2, between approximately 475 g*in2 and 525 g*in2, between approximately 500 g*in2 and 550 g*in2, or between approximately 525 g*in2 and 575 g*in2. In some embodiments, the Izz value of the club head 100, 200, 300, 400 can be approximately 450 g*in2, 460 g*in2, 470 g*in2, 480 g*in2, 490 g*in2, 500 g*in2, 510 g*in2, 520 g*in2, 530 g*in2, 540 g*in2, 550 g*in2, 560 g*in2, 570 g*in2, or 575 g*in2.
Iron Embodiment 1
Referring to
Referring to
In the
Referring to
The effective density profile of the first iron club head 100 can result in favorable POI values, particularly Ixy. The asymmetric weighting with respect to the X-axis and the Y-axis is caused by increasing the mass within the high-toe quadrant 174 and low-heel quadrant 177, while simultaneously reducing mass within the low-toe quadrant 175 and the high-heel quadrant 176. This specific asymmetry in the club head 100 is desirable for providing an increased (i.e. more positive or less negative) Ixy. As will be discussed in further detail below, a more positive Ixy generates less undesirable sidespin on shots mis-hit above or below the face center.
Iron Embodiment 2
Referring to
Referring to
Referring to
Referring to
As evident from the illustrated beam thicknesses,
As evident from the illustrated beam thicknesses,
The varying density profile in a front-to-rear direction can be further described in relation to box regions (or reference boxes).
The box regions correspond to one another throughout
Referring to
The effective density profile of the second iron club head 200 creates asymmetric weighting with respect to the X-axis, the Y-axis, and the Z-axis. Such asymmetric weighting is caused by increasing the mass toward the rear on the heel side 214 and decreasing the mass toward the rear on the toe side 212, all while retaining a relatively high mass in the low-heel 177 and/or high-toe 174 quadrants. This specific asymmetry in the club head 200 is desirable for providing an increased (i.e. more positive or less negative) Ixy and Ixz with respect to similar club head lacking lattice structures. As will be discussed in further detail below, increasing both Ixy and Ixz values with respect to a similar club creates less undesirable sidespin on shots mis-hit above or below face center C.
Iron Embodiment 3
Referring to
As illustrated by
In addition to the lattice structure 330, mass can be distributed by the plurality of internal masses 378. The plurality of internal masses 378 can be integrally formed with the club head 300 and can protrude from the internal surface 324 and into the interior cavity 320. The plurality of internal masses 378 can be made of the same material as the remainder of the club head 300. The plurality of internal masses 378 can be solid masses of material and can comprise an effective density greater than the effective density of any portion of the lattice structure 330. As illustrated in
Although the maximum effective density 358 of the lattice structure 330 alone is located within the horizontal reference cylinder 397, the effective density within the interior cavity 320 as a whole is influenced by internal masses 378. Thus, the overall greatest effective density within the interior cavity 320 is located in the high-toe quadrant 174 and/or the low-toe quadrant 175. The minimum effective density within the interior cavity 320 is located within the high-heel quadrant 176 and/or the low-heel quadrant 177, specifically in areas of the high-heel quadrant 176 and low-heel quadrant 177 that are not located within the horizontal reference cylinder 397.
The density profile of the third iron club head 300 can result in increased POI values, particularly Ixy and Ixz, over a club head with no lattice structure or internal masses. The asymmetric weighting with respect to the X-axis, the Y-axis, and the Z-axis is caused by providing a relatively high effective density in the high-toe quadrant 174 and a relatively low effective density in the high-heel quadrant 176. This specific asymmetry in the club head 100 leads to increased (i.e. more positive or less negative) Ixy and Ixz. As will be discussed in further detail below, increasing both Ixy and Ixz values creates less undesirable sidespin on shots mis-hit above or below face center C.
The intent of the third club head embodiment 300 was to improve POI and move the CG position simultaneously. The inclusion of the internal weight members 378 was designed to produce a CG position toe-ward of the previously described embodiments 100, 200. Additional arrangements of the lattice structure 330 and/or the internal weight members 378 can achieve a combined balance of improved POI at a desirable CG position.
Iron Embodiment 4
Referring to
The effective density profile of the fourth iron club head 400 can result in favorable POI values, particularly Ixy, while allowing for the maximized deflection of the face 404 upon impact with a golf ball. The asymmetric weighting with respect to the X-axis 1050 and the Y-axis 1060 is caused by increasing the mass within the high-toe quadrant 174 and low-heel quadrant 177, while simultaneously reducing mass within the low-toe quadrant 175 and the high-heel quadrant 176. This specific asymmetry in the club head 400 is desirable for providing an increased (i.e. more positive or less negative) Ixy. As will be discussed in further detail below, a more positive Ixy creates less undesirable sidespin on shots mis-hit above or below face center. Further, the space between the face 404 and the lattice structure 400 allows the face to flex more upon impact with a golf ball, compared to a similar lattice structure that contacts the face 404. By allowing for maximum flexure of the face 404, the club head 400 retains high ball speeds while also possessing the benefit of improved Ixy due to the density profile of the lattice structure 430.
Iron Advantages
The lattice structures 130 advantageously allow for the redistribution of mass to provide an iron-type club head 100 with improved products of inertia (POI). Improvement of the products of inertia (POI) can lead to improved performance in the iron-type club head 100, such as a reduction or negation of the sidespin imparted to the golf ball upon impact above or below the center C of the face 104. The iron-type club head embodiments 100, 200, 300, 400 described above follow the principles described below relating to negation of sidespin on high and low mis-hits by the improvement of iron-type club head products of inertia.
The iron-type golf club head 100 comprises an inertia tensor. The inertia tensor for the club head 100 is represented by equation (1) below. Generally, for greatest performance, the inertia tensor principal axis (Ixx, Iyy, Izz) is maximized. The tensors along the inertia tensor principal axis are referred to as the club head's moments of inertia (MOT) about the x-axis (Ixx), the y-axis (Iyy), and the z-axis (Izz). The greater the MOT, the less likely it is for the club head 100 to experience rotation when a torque is applied (i.e., not striking the golf ball in the geometric centerpoint 116 of the strike face 104). It is often assumed that if the MOT of the club head 100 is maximized, and the golf ball is struck near the face center C, the golf ball will fly straight. However, the golf club head 100 still experiences three main rotational effects due to the dynamics of an individual's golf swing that effect the trajectory of the ball.
Referring to
Further, in addition to the three main user generated rotational effects, a path the golf club 100 is swung on and a face angle of the golf club head 100 at impact are also user generated dynamics of an individual's swing that affect the amount of spin imparted to the golf ball. The face angle of the golf club 100 at impact is the angle formed between a target line (a line formed from the golf ball to the desired end point of the golf ball) and a face line (a direction vector extending perpendicularly from the center C of the strike face 104, when projected onto the ground plane). The golf club path is the angle formed between the target line and a velocity vector of the golf club head 100, at the point of impact with the golf ball. Any difference between face angle and club path generates unwanted sidespin. The greater the difference in face angle and club path, the greater the sidespin generated.
Referring to
In addition to the sidespin generated by the natural closing rotation ωy and drooping rotation ωz of the club head 100, sidespin is also generated by angular accelerations experienced by the club head 100 at impact. Such angular accelerations are generated by moments associated with the force of impact between the ball and the club head 100 on an off-center strike. When a golfer strikes the ball just below or just above the center C of the strike face 104 (in a top rail 108 to sole 110 direction), the force of impact between the ball and the club head 100 imparts a lofting moment (−Mx), a closing moment (My), and a drooping moment (Mz) on the club head 100 that create a lofting acceleration −αx (or de-lofting acceleration ax), a closing acceleration αy (or opening acceleration −αy), and a drooping acceleration αz (or a toe-up acceleration −αz). The angular accelerations experienced by the club head 100 when struck just above or below center C can be represented by equations (2), (3), and (4) below. These angular accelerations create a gearing effect between the ball and the strike face 104 that influences the amount of spin imparted to the ball. Assuming the golf ball is being struck above or below the x-axis 1050, but on (contacting) the y-axis 1060, the moments applied about the y-axis 1060 and z-axis 1070 are approximately zero (My≈0, Mz≈0), and thus are not illustrated. The moment applied about the x-axis 1050 (Mx) is directly proportional to how far the impact location of the golf ball is above or below face center (i.e., the farther above center C the ball is struck the greater the moment about the x-axis Mx).
In order to minimize angular accelerations of the golf club head 100 at impact, the moment of inertia about the x-axis 1050, y-axis 1060, and z-axis 1070 can be increased, subsequently increasing the forgiveness of the golf club head 100, since the golf club head 100 better resists rotational moments about the principal axes (x-axis, y-axis, z-axis). If the golf club head 100 better resists rotational moments about the principal axes, the club head 100 is more forgiving for off-center impacts. However, even when MOI is maximized and a golf ball is struck above or below center C (with desirable delivery parameters), the golf ball will still have unwanted sidespin due to the natural closing rotation ωy and drooping rotation ωz of the club head 100.
In general, prior art club heads seek to minimize the angular accelerations experienced by the club head at impact in an attempt to produce straight shots. However, simply minimizing the angular accelerations does not take into account the sidespin generated by the natural closing rotation ωy and drooping rotation ωz of the club head. Rather than simply minimizing the angular acceleration in the club head 100, the present club head 100 products of inertia (POI) can be optimized to strategically manipulate the angular accelerations at impact. Specifically, the present club head 100 comprises a lattice structure 130 that increases Ixy and Ixz relative to a similar club head without such lattice structures by providing a maximum effective density 158 in the high-toe and low-heel quadrants 174, 177. The improved products of inertia (POI) can cause the moment Mx about the X-axis 1050 to create favorable angular accelerations at impact about the Y-axis 1060 and the Z-axis 1070. These favorable angular accelerations counteract the unwanted sidespin from the natural closing rotation ωy and drooping rotation ωz for high and low face hits, while maintaining forgiveness in a heel 114 to toe 112 direction. The POI of the club head 100 can be optimized by the strategic inclusion of lattice structures 130 to create favorable angular accelerations that influence the ball to spin opposite the direction of the sidespin caused by the closing rotation ωy and drooping rotation ωz on a high or low mis-hit. Thus, the influence on sidespin due to the favorable angular accelerations at impact and the sidespin due to the natural closing rotation ωy and drooping rotation ωz of the club head 100 can counteract each other. Therefore, the sidespin caused by the POI of the club head 100 can minimize or negate the overall sidespin on a high or low mis-hit.
Optimally, the iron-type club head 100 can comprise Ixy and Ixz products of inertia that are both non-zero. Referring to
As discussed above, the effects of Ixy or Ixz individually are not sufficient to eliminate sidespin on high or low mis-hits. As illustrated by
To negate sidespin caused by high or low mis-hits, a combination of a positive Ixy and a negative Ixz is required. An optimal combination of a positive Ixy value and a negative Ixz value must be achieved that not only negates the sidespin imparted to the ball due by the closing rotation ωy and drooping rotation ωz of the club head 100, but also balances the negative influences of Ixy and Ixz on certain shots (i.e. the draw influence of a positive Ixy on a high mis-hit and the fade influence of a negative Ixz on a low mis-hit).
It should be noted that the need for a positive, non-zero Ixy and a negative, non-zero Ixz for negating sidespin on high and low mis-hits is specific to iron-type club heads. For example, driver-type, fairway wood-type, and hybrid-type golf club heads all comprise undesirable sidespin on high and low mis-hits due to the closing rotation ωy and the drooping rotation ωz of the club head at impact, just like iron-type club heads do. However, to counteract such undesirable sidespin, driver-type, fairway wood-type, and hybrid-type club heads simply require a positive non-zero Ixy value. In other words, there is no need to achieve a non-zero Ixz value to balance the Ixy value.
Referring to
Therefore, due to the fact that a driver-type club head comprising a positive Ixy can influence a low mis-hit to draw and a high mis-hit to fade, the sidespin on a high or low mis-hit can be negated by only having a positive Ixy. Thus, for driver-type club heads, it is not necessary to provide a negative Ixz. In fact, in driver-type club heads, it is desirable to minimize Ixz (i.e. provide Ixz as close to zero as possible) in order to minimize any other angular accelerations. In contrast, as discussed above, the iron-type golf club head comprises both a positive Ixy and a negative Ixz that work in combination to negate sidespin caused by high and low mis-hits.
SR=bRh (5)
wherein bR is the slope of the linear response.
SIxy=axyh2+bxyh (6)
wherein axy and bxy are coefficients of the parabolic response determined by the magnitude of Ixy. Increasing the magnitude of Ixy creates a steeper parabola, while decreasing the magnitude of Ixy creates a shallower parabola.
Similarly, the sidespin (SIxz) generated by Ixz alone at every impact height (h) is represented by curve SIxz in
SIxz=axzh2+bxzh (7)
wherein axz and bxz are coefficients of the parabolic response determined by the magnitude of Ixz. Similar to Ixy, increasing the magnitude of Ixz creates a steeper parabola, while decreasing the magnitude of Ixz creates a shallower parabola. By the principle of superposition, equations (6) and (7) can be added together, as illustrated in
In order for the Ixy and Ixz sidespin responses SIxy, SIxz to counteract the sidespin of the closing rotation ωy and drooping rotation ωz and create zero sidespin on high and low mis-hits (given desirable delivery characteristics), the sum of equations (5), (6), and (7) must equal zero for all impact heights (h). Equation (8) characterizes the solution to the sum of equations that produce zero sidespin on high and low mis-hits:
bR=2axy(mxy−mxz) (8)
Referring back to
The iron-type golf club head 100 can comprise a “target” value for both Ixy and Ixz. The target values for Ixy and Ixz are the values that, in combination, represent the optimal POI for the club head 100 in terms of reducing sidespin on high and low mis-hits. A club head 100 comprising the target values for both Ixy and Ixz will comprise negligible sidespin on high and low mis-hits, given desirable delivery parameters and average swing characteristics (i.e. average swing speed, average closure rate, etc.). It is generally very difficult to achieve the optimal Ixy and Ixz products of inertia, while retaining other desirable mass properties (MOI, CG location, etc.). However, the closer the Ixy and Ixz products of inertia in a golf club are to the target value, the greater the reduction in sidespin.
The iron-type club head 100, 200, 300, 400 comprises a target Ixy value that is non-zero and positive. In many embodiments, the target Ixy can be between approximately 20 g·in2 and approximately 130 g·in2. In some embodiments, the target Ixy is between 20 g·in2 and 40 g·in2, between 30 g·in2 and 50 g·in2, between 40 g·in2 and 60 g·in2, between 50 g·in2 and 70 g·in2, between 60 g·in2 and 80 g·in2, between 80 g·in2 and 100 g·in2, between 100 g·in2 and 120 g·in2, between 110 g·in2 and 130 g·in2. In some embodiments, the target Ixy can be approximately 20 g·in2, approximately 25 g·in2, approximately 30 g·in2, approximately 35 g·in2, approximately 40 g·in2, approximately 45 g·in2, approximately 50 g·in2, approximately 55 g·in2, approximately 60 g·in2, approximately 65 g·in2, approximately 70 g·in2, approximately 75 g·in2, or approximately 80 g·in2. In some embodiments, the target Ixy can be greater than approximately 0 g·in2, greater than approximately 5 g·in2, greater than approximately 10 g·in2, greater than approximately 15 g·in2, greater than approximately 20 g·in2, greater than approximately 25 g·in2, greater than approximately 30 g·in2, greater than approximately 35 g·in2, greater than approximately 40 g·in2, greater than approximately 45 g·in2, greater than approximately 50 g·in2, greater than approximately 60 g·in2, greater than approximately 70 g·in2, greater than approximately 80 g·in2, greater than approximately 90 g·in2, greater than approximately 100 g·in2, greater than approximately 110 g·in2, or greater than approximately 120 g·in2.
The iron-type club head 100, 200, 300, 400 comprises a target Ixz value that is non-zero and negative. In many embodiments, the target Ixz can be between approximately −10 g·in2 and approximately −40 g·in2. In some embodiments, the target Ixz is between −10 g·in2 and −15 g·in2, between −15 g·in2 and −20 g·in2, between −20 g·in2 and −25 g·in2, between −25 g·in2 and −30 g·in2, between −30 g·in2 and −35 g·in2, or between −35 g·in2 and −40 g·in2. In some embodiments, the target Ixz can be approximately −10 g·in2, approximately −15 g·in2, approximately −20 g·in2, approximately −25 g·in2, approximately −30 g·in2, approximately −35 g·in2, or approximately −40 g·in2.
In many embodiments, the target Ixz product of inertia is less than approximately −5 g·in2, less than approximately −10 g·in2, less than approximately −15 g·in2, less than approximately −20 g·in2, less than approximately −25 g·in2, less than approximately −30 g·in2, less than approximately −35 g·in2, or less than approximately −40 g·in2.
In many functional embodiments of the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430, the iron-type club head 100, 200, 300, 400 can comprise an Ixy product of inertia between −10 g·in2 and −40 g·in2. In some embodiments, the iron-type club head 100, 200, 300, 400 comprising lattice structures can comprise an Ixy product of inertia between −10 g·in2 and −20 g·in2, between −20 g·in2 and −30 g·in2, or between −30 g·in2 and −40 g·in2. In some embodiments, the iron-type club head 100, 200, 300, 400 comprising lattice structures can comprise an Ixy product of inertia between −10 g·in2 and −30 g·in2, between −15 g·in2 and −35 g·in2, or between −20 g·in2 and −40 g·in2. In some embodiments, the club head 100, 200, 300, 400 comprises an Ixy product of inertia is greater than approximately −50 g·in2, greater than approximately −45 g·in2, greater than approximately −40 g·in2, greater than approximately −35 g·in2, greater than approximately −30 g·in2, greater than approximately −25 g·in2, greater than approximately −20 g·in2, greater than approximately −15 g·in2, greater than approximately −10 g·in2, or greater than approximately −5 g·in2.
In many functional embodiments of the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430, the iron-type club head 100, 200, 300, 400 comprises an Ixz product of inertia between −45 g·in2 and −65 g·in2. In some embodiments, the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 comprises an Ixz product of inertia between −45 g·in2 and −50 g·in2, between −50 g·in2 and −55 g·in2, between −55 g·in2 and −60 g·in2, or between −60 g·in2 and −65 g·in2. In some embodiments, the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 comprises an Ixz product of inertia between −45 g·in2 and −55 g·in2, between −50 g·in2 and −60 g·in2, between −55 g·in2 and −65 g·in2, between −45 g·in2 and −60 g·in2, or between −50 g·in2 and −65 g·in2. In some embodiments, the golf club head 100, 200, 300, 400 can comprise a Ixz product of inertia that is less than approximately −45 g·in2, less than approximately −50 g·in2, less than approximately −45 g·in2, less than approximately −50 g·in2, less than approximately −55 g·in2, less than approximately −60 g·in2, or less than approximately −65 g·in2.
In many embodiments, the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 has products of inertia much nearer to the optimal target values than similar club heads lacking such lattice structures 130, 230, 330, 430. In many embodiments, a club head similar to iron-type club head 100, but lacking lattice structures comprises an Ixy product of inertia between approximately −50 g·in2 and −70 g·in2. In many embodiments, the Ixy product of inertia of the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 is between 15% and 50% closer to the target Ixy product of inertia than a similar club head lacking such lattice structures 130. In some embodiments, the Ixy product of inertia of the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 can be closer to the target Ixy product of inertia, than a similar club head lacking such lattice structures, by between 15% and 25%, between 25% and 35%, between 35% and 45%, between 45% and 50%, between 15% and 35%, between 20% and 40%, between 25% and 45%, or between 30% and 50%.
In many embodiments, a club head similar to iron-type club head 100, but lacking lattice structures comprises an Ixz product of inertia between approximately −75 g·in2 and −90 g·in2. In many embodiments, the Ixz product of inertia of the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 is between 5% and 45% closer to the target Ixz product of inertia than a similar club head lacking such lattice structures 130. In some embodiments, the Ixz product of inertia of the iron-type club head 100, 200, 300, 400 comprising lattice structures 130, 230, 330, 430 can be closer to the target Ixz product of inertia, than a similar club head lacking such lattice structures, by between 5% and 15%, between 15% and 25%, between 25% and 35%, between 35% and 40%, between 40% and 45%, between 5% and 25%, between 10% and 30%, between 15% and 35%, between 20% and 40%, or between 25% and 45%.
The target values for Ixy and Ixz can vary for iron-type club heads 100 designed for different categories of players. Because the natural closure rate and drooping rate can change from player to player, the amount of sidespin generated by the closing rotation ωy and drooping rotation ωz on high and low mis-hits can vary for different types of players. For example, clubs designed for players with slow swing speeds (who typically have lower closure rates) can comprise target values for Ixy and Ixz that differ from the target values of club heads 100 designed for players with higher swing speeds. The target value for Ixy moves closer to zero as the swing speed increases, because the effect of Ixy is more pronounced at higher impact speeds. In other words, a positive target Ixy value decreases as swing speed increases. Conversely, the target value for Ixz moves closer to zero as swing speed increases, because the effect of Ixz is more pronounced at higher impact speeds. In other words, a negative target Ixz value increases as swing speed increases. The difference in target values for Ixy and Ixz makes up for the difference in spin imparted for such players on high and low mis-hits due to the closing rotation ωy and drooping rotation ωz of the club head.
In many embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with slow swing speeds (i.e. swing speeds between 60 and 75 mph when swinging an iron-type club head) can comprise a slow-swing-speed Ixy target between approximately 75 g·in2 and 130 g·in2. In some embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with slow swing speeds can comprise an Ixy target between approximately 75 g·in2 and 85 g·in2, 85 g·in2 and 95 g·in2, 95 g·in2 and 115 g·in2, or 115 g·in2 and 130 g·in2. Iron-type club heads with different loft angles α can target slightly different ranges of Ixy values, for a given swing-speed player. For example, 7-iron golf club heads 100, 200, 300, 400 designed for players with slow-swing speeds can comprise an Ixy target between approximately 90 g·in2 and 127 g·in2, whereas 4-iron golf club heads 100, 200, 300, 400 designed for players with slow-swing speeds can comprise an Ixy target between approximately 77 g·in2 and 108 g·in2.
In many embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with slow swing speeds (i.e. swing speeds between 60 and 75 mph when swinging an iron-type club head) can comprise a slow-swing-speed Ixz target between approximately −70 g·in2 and −30 g·in2. In some embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with slow swing speeds can comprise an Ixz target between approximately −70 g·in2 and −60 g·in2, −60 g·in2 and −50 g·in2, −50 g·in2 and −40 g·in2, −40 g·in2 and −30 g·in2. Iron-type club heads 100 with different loft angles α can target slightly different ranges of Ixz values, for a given swing-speed player. For example, 7-iron golf club heads 100, 200, 300, 400 designed for players with slow-swing speeds can comprise an Ixz target between approximately −69 g·in2 and −49 g·in2, whereas 4-iron golf club heads 100, 200, 300, 400 designed for players with slow-swing speeds can comprise an Ixz target between approximately −48 g·in2 and −34 g·in2.
In many embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with average swing speeds (i.e. swing speeds between 75 and 85 mph when swinging an iron-type club head) can comprise an average-swing-speed Ixy target between approximately 50 g·in2 and 95 g·in2. In some embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with average swing speeds can comprise an Ixy target between approximately 50 g·in2 and 65 g·in2, 65 g·in2 and 75 g·in2, 75 g·in2 and 85 g·in2, 85 g·in2 and 95 g·in2. Iron-type club heads 100, 200, 300, 400 with different loft angles α can target slightly different ranges of Ixy values, for a given swing-speed player. For example, 7-iron golf club heads 100, 200, 300, 400 designed for players with average-swing speeds can comprise an Ixy target between approximately 63 g·in2 and 90 g·in2, whereas 4-iron golf club heads 100, 200, 300, 400 designed for players with average-swing speeds can comprise an Ixy target between approximately 55 g·in2 and 75 g·in2.
In many embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with average swing speeds (i.e. swing speeds between 75 and 85 mph when swinging an iron-type club head) can comprise an average-swing-speed Ixz target between approximately −55 g·in2 and −20 g·in2. In some embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with average swing speeds can comprise an Ixz target between approximately −55 g·in2 and −45 g·in2, −45 g·in2 and −35 g·in2, −35 g·in2 and −25 g·in2, or −25 g·in2 and −20 g·in2. Iron-type club heads 100, 200, 300, 400 with different loft angles α can target slightly different ranges of Ixz values, for a given swing-speed player. For example, 7-iron golf club heads 100, 200, 300, 400 designed for players with average-swing speeds can comprise an Ixz target between approximately −49 g·in2 and −36 g·in2, whereas 4-iron golf club heads 100, 200, 300, 400 designed for players with average-swing speeds can comprise an Ixz target between approximately −34 g·in2 and −25 g·in2.
In many embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with high swing speeds (i.e. swing speeds between 85 and 105 mph when swinging an iron-type club head) can comprise a high-swing-speed Ixy target between approximately 1 g·in2 and 70 g·in2. In some embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with high swing speeds can comprise an Ixy target between approximately 1 g·in2 and 20 g·in2, 20 g·in2 and 40 g·in2, 40 g·in2 and 60 g·in2, or 50 g·in2 and 70 g·in2. Iron-type club heads 100, 200, 300, 400 with different loft angles α can target slightly different ranges of Ixy values, for a given swing-speed player. For example, 7-iron golf club heads 100, 200, 300, 400 designed for players with high-swing speeds can comprise an Ixy target between approximately 12 g·in2 and 64 g·in2, whereas 4-iron golf club heads 100, 200, 300, 400 designed for players with high-swing speeds can comprise an Ixy target between approximately 4 g·in2 and 55 g·in2.
In many embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with high swing speeds (i.e. swing speeds between 85 and 105 mph when swinging an iron-type club head) can comprise a high-swing-speed Ixz target between approximately −40 g·in2 and −1 g·in2. In some embodiments, iron-type golf club heads 100, 200, 300, 400 designed for players with high swing speeds can comprise an Ixz target between approximately −40 g·in2 and −30 g·in2, −30 g·in2 and −20 g·in2, −20 g·in2 and −10 g·in2, −10 g·in2 and −1 g·in2. Iron-type club heads 100, 200, 300, 400 with different loft angles α can target slightly different ranges of Ixz values, for a given swing-speed player. For example, 7-iron golf club heads 100, 200, 300, 400 designed for players with high-swing speeds can comprise an Ixz target between approximately −36 g·in2 and −8 g·in2, whereas 4-iron golf club heads 100, 200, 300, 400 designed for players with high-swing speeds can comprise an Ixz target between approximately −25 g·in2 and −2 g·in2.
In addition to the swing speed affecting the target Ixy and Ixz values, the closure rate and drooping rate of the club head also alters the target Ixy and Ixz values. Players with a common swing speed can impart different closure rates to a club head. When a player swings with a higher closing rotation ωy, higher magnitude Ixy and Ixz values are needed to offset the natural spin imparted by the closing rotation ωy. As described above, the closing rotation ωy naturally imparts a fade spin to the golf ball below face center and a draw spin above center. Additionally, players tend to impact the golf ball with a slight toe-down rotation (i.e. a positive drooping rotation ωz). Drooping rotation ωz induces the same natural spin directions as the closing rotation ωy. Depending on a player's unique swing parameters, the golf club head can experience higher or lower drooping rotation ωz. Higher magnitude target Ixy and Ixz values can assist in offsetting higher drooping rotations ωz.
In addition to mass property benefits, the lattice structure 130 can also increase the durability of the golf club head 100. Because iron-type golf club heads 100 endure high impact stresses, the durability provided by the lattice structure 130 is especially valuable in the iron-type club head 100. In some embodiments, the lattice structure 130 can brace and connect the rear 106 of the strike face 104 of the iron 100 to a rear wall. The strike face 104 can be thinned because the lattice 130 provides additional support against material failure at impact. In other embodiments, the lattice structure 130 can be disconnected from the rear of the strike face 104, to promote unhindered bending of the strike face 104.
Putter
The lattice structures described above, can also be implemented in putter-type golf club heads. Within putters, the position and effective density profile of the lattice structure can be used to improve moment of inertia (MOI) values and to position the center of gravity (CG) in a desirable location. The CG can be positioned forward from a baseline CG location (CG′), which is where the CG would be located without the lattice structure influencing mass distribution (i.e. for a solid body putter). Using a lattice structure within a mallet or mid-mallet type putter can maintain structural durability, while improving MOI and CG position. As described above for the lattice structure, the desired effective density can be achieved by altering the beam thickness of each unit scaffolding within its respective lattice unit.
General characteristics of the putter-type golf club head are described below, followed by description of specific putter embodiments. Referring to
In some embodiments, the outer shell 560 can have a uniform thickness. In other embodiments, the crown (central, toe, and heel portions 562, 564, 566) can be thinner than the skirt portion 568. The putter head 500 can also comprise a hosel 505 or a hosel bore configured to attach to a golf club shaft.
The central crown portion 562 can be lower than the toe crown portion 564 and the heel crown portion 566. The skirt portion 568 connects the crown portions 562, 564, 566 to the sole 510. Together, the outer shell 560 and the sole 510 can form an interior cavity 520. The putter head 500 can comprise an exterior surface 522 and an interior surface 524, the interior surface 524 forming a boundary of (or enveloping) the interior cavity 520. The interior cavity 520 can house a lattice structure 530. The lattice structure 530 can fully or partially fill the interior cavity 520. The lattice structure 530 can connect to the interior surface 524 of the interior cavity 520. The lattice structure 530 can affect mass distribution, thus altering MOI, POI, and CG location.
The face 504 can comprise a thickness measured rearward and orthogonal from the face 504 at the strike face centerpoint 516. A thick face can move the CG forward, while a thin face can shift the CG rearward. The putter head 500 can further comprise a front portion 570 and a rear portion 572. In thick face embodiments, the face forms the front portion 570 of the golf club head 500 and everything rearward of the face 504 forms the rear portion 572 of the golf club head 500. In thin face embodiments, a section of the club head 500 forward of a boundary wall 525 is the front portion 570 of the club head 500, and the remainder of the club head, rearward of the boundary wall, forms the rear portion 572 of the club head. The boundary wall 525 can be defined behind the hosel 505, offset a distance from the face 504.
The rear portion 572 of the club head 500 can comprise a total rear portion volume, measured as the solid volume contained by the exterior surface 522 of the rear portion 572. The interior cavity 520 can comprise a cavity volume, measured as the volume contained by the interior surface 524. The interior cavity volume can be a percentage of the rear portion volume, the percentage ranging between 20% and 80%. In some embodiments, the interior cavity volume is the between following percentages of the rear portion volume: 20% and 30%, 30% and 40%, 40% and 50%, 50% and 60%, 60% and 70%, or 70% and 80%. In some embodiments, the interior cavity volume is 66%, or 71% of the rear portion volume.
The outer shell 560 can comprise a thickness measured between the exterior and interior surfaces 524, 522, respectively, of the club head 500. The thickness of the outer shell 560 can be uniform or varying. The outer shell thickness can be between 0.010 inch and 0.050 inch. In some embodiments, the outer shell thickness can be between 0.010 inch and 0.020 inch, 0.020 inch and 0.030 inch, 0.030 inch and 0.040 inch, or 0.040 inch and 0.050 inch. A thinner outer shell results in a lighter weight outer shell, particularly the crown. The weight which is not placed in the crown can be distributed to the periphery of the club head 500 to increase the MOI of the club head 500. In some embodiments, a portion of the crown can be removed to expose the lattice structure, further removing mass from the crown (562, 564, and 566).
The sole 510 of the golf club head 500 can comprise a sole thickness can range between 0.030 inch and 0.080 inch. In some embodiments, the sole thickness can range between 0.030 inch and 0.040 inch, 0.040 inch and 0.050 inch, 0.050 inch and 0.060 inch, 0.060 inch and 0.070 inch, or 0.070 inch and 0.080 inch. In some latticed embodiments, the sole thickness can be equal to or less than approximately 0.040 inch, equal to or less than approximately 0.050 inch, or equal to or less than approximately 0.060 inch.
The lattice structure 530 can support the outer shell 560, allowing the outer shell 560 to be thinner than in an embodiment lacking the lattice structure 530. The lattice structure 530 can provide support to the sole 510, allowing the sole 510 to be thinner than in embodiments lacking the lattice structure 530. The thin outer shell and thin sole, both enabled by the supportive lattice structure 530, can free up discretionary mass. The discretionary mass can be moved to the periphery of the club head for MOI improvements, POI improvements, and/or can be incorporated into the lattice structure to control the CG location.
In some embodiments, the lattice structure 530 can be exposed and visible on the exterior surface 522 of the golf club head 500. The lattice structure 530 can be exposed on the crown 562, 564, and 566, on the sole 510, or on the skirt 568. For example, the lattice structure 530 can be exposed across a section of the toe crown portion 564 and/or the heel crown portion 566. Alternately, the lattice 530 can be exposed across the entire toe crown portion 564 and the entire heel crown portion 566. Exposing the lattice structure 530 can further free discretionary weight by removing portions of the exterior surfaces 522. Additionally, exposing the lattice structure 530 can improve the aesthetics of the club head 500 and allow the technology to be visible to the player. In some embodiments, the lattice structure 530 can appear differently across different regions of the exterior surface 522 due to the varying shape or density profile of the lattice structure 530.
In some putter embodiments, such as mallet and mid-mallet type putters, the Ixx value can be between 400 g*in2 and 460 g*in2, the Iyy value can be between 590 g*in2 and 670 g*in2; and the Izz value can be between 230 g*in2 and 270 g*in2. In some putter embodiments, the Ixx value can be between 450 g*in2 and 460 g*in2; the Izz value can be between 645 g*in2 and 670 g*in2; and the Izz can be between 240 g*in2 and 265 g*in2.
In some mallet and mid-mallet latticed putter embodiments, the CG can be positioned between −0.020 inch and −0.035 inch along the X′-axis, between −0.800 inch and −1.000 inch along the Y′-axis, and between 0.850 inch and 0.900 inch along the Z′-axis. Referring to
In some embodiments, including the interior cavity 520 and the lattice structure 530 into the golf club head 500 can shift the CG forward by a CG-shift distance of between 0 inches and 1.6 inches. The distance is measured in the Z′-axis direction between the baseline CG position (CG′) and the lattice-included CG position. In some embodiments, the CG-shift distance can be between 0 inches and 0.2 inch, 0.2 inch and 0.4 inch, 0.4 inch and 0.6 inch, 0.6 inch and 0.8 inch, 0.8 inch and 1.0 inch, 1.0 inch and 1.2 inch, 1.2 inch and 1.4 inch, or 1.4 inch and 1.6 inch.
First Putter Embodiment
Referring to
Referring to
The lattice structure 530 comprises a density profile which increases from the central reference sphere border surface 554 to the periphery of the club head 500. As described above, the lattice structure 530 comprises a plurality of lattice units 534, each unit 534 having a unit scaffolding 536. The unit scaffolding 536 is formed from connected beams 537 (or scaffolding rods). For the embodiment illustrated in
In the embodiment of
In the embodiment of
Second Putter Embodiment
Referring to
Referring to
Each unit scaffolding 636 of the plurality of lattice units 634 can comprise beams 637 (or scaffolding rods) interconnecting to form a shape known as fluorite. The beams 637 comprise a beam thickness. The beam thickness of the lattice units 634 is uniform across the plurality of lattice units 634. In some embodiments, the beam thickness is approximately 0.043 inch (1.1 mm).
The outer shell crown thicknesses of the second putter embodiment 600 can be the same as for the first putter embodiment 500. The second putter embodiment club head 600 can comprise a sole thickness that is approximately 0.060 inch (thicker than in the first putter embodiment). The beam thickness, the outer shell thickness, and the sole thickness all affect the durability of the club head 600. The inclusion of the lattice structure 630 within portions of the internal cavity 620 can help brace and connect the crown and the sole, to increase durability without adding mass. In other words, one or both of the crown and sole can be thinner since the lattice structure 630 supports the crown and sole.
Putter Advantages
The lattice structure 530, 630, described herein, allows forward CG placement in a putter head 500, 600. The lattice structure 530, 630 can mine out or replace solid mass with a lower effective density lattice structure 530, 630. The lattice structure 530, 630 can further support the outer shell 560, 660, thus maintaining durability despite the repositioning of mass.
A CG closer to the strikeface (a lower CGz value) reduces a horizontal launch angle on off-center face impacts. The horizontal launch angle is measured off a desired centerline putt path. In other words, the horizontal launch angle quantifies how much the golf ball's initial path away from the strikeface is angled left or right of the hole. A putt with a horizontal launch angle closer to zero will have less offline movement (i.e. a straighter roll) than a putt with a horizontal launch angle further from zero. Therefore, more putts will reach the hole when the horizontal launch angle is closer to zero.
The CG position affects the horizontal launch angle because of the gearing effect that occurs when a golf ball strikes the face. In a putter with a forward CG, a moment arm between the putter CG and the golf ball CG will be shorter than a corresponding moment arm in a putter with a rearward CG. The shorter moment arm reduces the gearing (or rotation) of the club head at impact, thus resulting in less twisting of the strikeface and consequently a less extreme horizontal launch angle. Bringing horizontal launch angle closer to zero also lowers the sidespin imparted to the golf ball at impact, thus further reducing offline movement of the golf ball during the putt.
Blade-type putter heads have CGs that are close to the face due to the narrow geometry of the club head design. Thus, by nature, blade-type putters achieve horizontal launch angles closer to zero than traditional mallet-type putters. The putters with lattice structures, described herein, exhibit near blade-like performance (i.e. blade-like launch, while maintaining the look and feel of a mallet-type putter.
Both the CG depth (−CGz) and the Iyy value can influence the horizontal launch angle. In the graph of
The contour lines represent lines of constant change in horizontal launch angle per horizontal impact location. The horizontal launch performance is the same along a contour line. As the CG is moved rearward (a more negative CGz, upwards on the graph), Iyy must be increased to achieve the same horizontal launch performance. For example, when a CG is shifted rearwards by half an inch on a putter with an Iyy of approximately 700 g*in2, offsetting the horizontal launch performance would require increasing Iyy to approximately 1000 g*in2.
In the graph of
Referring to the graph of
CGz=0.0017*Iyy+0.85
CGz is measured in inches, and Iyy is measured in g*in2. Some embodiments of the putters described herein can fall within performance regions below the contour line 1500b defined by the following equation:
CGz=0.0016*Iyy+0.74
CGz is measured in inches, and Iyy is measured in g*in2. Some embodiments of the putters described herein can fall within performance regions below the contour line 1500c defined by the following equation:
CGz=0.0014*Iyy+0.62
CGz is measured in inches, and Iyy is measured in g*in2. Falling within performance regions below contour lines 1500a, 1500b, and/or 1500c indicates that a putter will have a straighter roll.
The club head comprising the lattice structure can be formed through any suitable manufacturing process to form a metal body. The club head comprising the lattice structure can be formed from a metal using processes such as casting, die casting, co die casting, additive manufacturing, or metallic 3D printing.
The POI values Ixy and Ixz were compared between a first exemplary club head 100, a second exemplary club head 200, a third exemplary club head 300, and a control club head. The first exemplary club head 100 was similar to iron-type club head 100 described above. The first exemplary club head comprised an internal cavity with a lattice region comprising a plurality of lattice units of varying density. The density of the plurality of lattice units in the first exemplary club head increased from the sole to the top rail near the toe end of the club head and decreased from the sole to the top rail near the heel end of the club head. Thus, the first exemplary club head comprised a maximum lattice unit density in the high-toe and low-heel regions and a minimum density of lattice units in the low-toe and high-heel regions.
The second exemplary club head 200 was similar to iron-type club head 200 described above. The second exemplary club head comprised an interior cavity with a lattice region comprising a plurality of lattice units of varying density. The density of the plurality of lattice units in the second exemplary club head increased from the strikeface to the rear in the high-heel and low-heel quadrants and decreased from the strikeface to the rear in the high-toe and low-toe quadrants.
The third exemplary club head 300 was similar to iron-type club head 300 described above. The third exemplary club head comprised an internal cavity with a lattice region comprising a plurality of lattice units of varying density. The density of the plurality of lattice units in the third exemplary club head was greatest within a horizontal reference cylinder extending along the X-axis. The third exemplary club head further comprised a first internal mass located within the high-toe quadrant and a second internal mass located within the low-toe quadrant.
The control club head was similar in structure to the first, second and third exemplary club heads. The control club head comprised a body forming a hollow interior cavity. The control head was devoid of any lattice regions within the hollow cavity or other portions of the club head.
The comparison of the products of inertia for the control club and the first, second, and third exemplary club heads is displayed below in Table 1. Table 1 also displays a target value for both Ixy and Ixz that represents the POI values that would create negligible sidespin on shots mis-hit above or below center, given desirable delivery characteristics. For the sake of comparison, all club heads measured were 7-irons.
As displayed by the above table, the lattice regions of exemplary club 1 created an increase of Ixy product of inertia of 44.31 g*in2 over the control club. The Ixy product of inertia of exemplary club 1 was 38.9% closer to the “optimized” Ixy product of inertia target value than that of the control club. Exemplary club 1 also resulted in a slight increase in Ixz product of inertia by 0.93 g*in2. The Ixz product of inertia of exemplary club 1 was 1.9% closer to the “optimized” Ixz product of inertia target value than that of the control club.
As further displayed by the above table, the lattice regions of exemplary club 2 created an increase of Ixy product of inertia of 20.89 g*in2 over the control club. The Ixy product of inertia of exemplary club 2 was 18.3% closer to the “optimized” Ixy product of inertia target value than that of the control club. The lattice regions of exemplary club 2 also created an increase of Ixz product of inertia of 19.58 g*in2 over the control club. The Ixz product of inertia of exemplary club 2 was 40.6% closer to the “optimized” Ixz product of inertia target value than that of the control club.
As further displayed by the above table, the lattice regions of exemplary club 3 created a slight increase of Ixy product of inertia by 5.33 g*in2 over the control club. The Ixy product of inertia of exemplary club 3 was 4.7% closer to the “optimized” Ixy product of inertia target value. The lattice regions of exemplary club 3 also created a slight increase of Ixz product of inertia by 7.38 g*in2. The Ixz product of inertia of exemplary club 3 was 15.3% closer to the “optimized” Ixz product of inertia target value.
The increase in product of inertia (both Ixy an Ixz) from the control club to the first, second, and third exemplary clubs resulted changes in the amount of sidespin generated for each club on high and low mis-hits. For each club head, the sidespin of shots struck at different locations in a top-rail-to-sole direction were compared. For each club, the sidespin was measured for shots hit between 0.7 inches above and below center, in increments of 0.1 inch.
On average, exemplary club head 100 displayed an 84.1 RPM reduction in sidespin over the full range of impact locations (A 27.3% decrease in sidespin over the control club). Further, exemplary club head 1 displayed a 119.7 RPM reduction on low mis-hits (i.e. shots mis-hit between the center of the face and the sole). This is a decrease in sidespin of 38.9% compared to the average sidespin on low mis-hits with the control club. Exemplary club head 1 comprised a 15.1 RPM increase on high mis-hits (a 9.2% increase in sidespin as compared to the control club head). However, the increase in sidespin on high mis-hits is not detrimental to club head performance. When striking a ball with an iron-type club head, players miss low on the face far more often than they miss high. Further, the overall magnitude of sidespin is much more drastic for low mis-hits than for high mis-hits. The large decrease in sidespin on low mis-hits for exemplary club head 1 is worth the trade-off of a small increase in sidespin for high-mis-hits.
On average, exemplary club head 200 displayed an 87.0 RPM reduction in sidespin over the full range of impact locations (A 28.2% decrease in sidespin over the control club). Further, exemplary club head 2 displayed a 55.7 RPM reduction in sidespin on high mis-hits (a 33.8% decrease in sidespin over the control club) and a 119.5 RPM reduction in sidespin on low mis-hits (a 24.7% decrease) when compared to the control club head.
On average, exemplary club head 3 displayed a 35.9 RPM increase in sidespin over the full range of impact locations (An 11.6% increase over the control club). Further, exemplary club head 300 displayed a 17.2 RPM reduction in sidespin on high mis-hits (a 10.4% decrease over the control club) and a 86.9 RPM increase in sidespin on low mis-hits (a 17.9% increase over the control club). Although exemplary club head 300 displayed slight increases to the Ixy and Ixz products of inertia, the overall increase in sidespin demonstrates that the lattice structures must be placed in areas of the club head strategically in order to provide performance benefits.
The decreased sidespin observed in the first exemplary club head 100 and the second exemplary club head 200 will generally result in mis-hits that will travel further and straighter. For the first exemplary club head 100, which comprised an increased Ixy but a similar Ixz in comparison to the control club, the increased Ixy influenced the ball to draw on both high and low mis-hits. Without an increase in Ixz to provide a fade influence, high mis-hits on exemplary club head 100 comprised more fade spin than the control club. However, as stated above, the exemplary club head 100 is still desirable over the control club due to the fact that low mis-hits are far more common in an iron-type club head than high mis-hits.
The second exemplary club head 200 comprised improvements to both Ixy and Ixz with respect to the control club. The combination of the improved Ixy and Ixz lead to reduction in spin for both high and low mis-hits. The combination of the draw influence of improving Ixy and the fade influence of improving Ixz resulted in reduced sidespin at every impact location.
These decreased sidespin values of the first and second exemplary club heads 100, 200 are a direct result of the enhanced mass properties (specifically increased products of inertia that more closely match predetermined target values) of the exemplary club heads achieved by the inclusion of the various lattice regions. By further increasing the products of inertia of the club head through other lattice arrangements, undesirable sidespin can be reduced even further.
Although exemplary club head 300 displayed slight increases to both Ixy and Ixz, the average sidespin increased relative to the control club. As discussed above, the intent of exemplary club head 300 was to increase Ixy and Ixz while providing a CG position toe-ward of the other embodiments. However, reposition the CG resulted in adverse effects on the sidespin. The sidespin results of exemplary club head 300 illustrate the challenge of balancing POI with other desirable design parameters.
A mallet control putter and a blade control putter were compared to four examples (or variations) of the first putter embodiment, described above, to determine MOI values, CG position, and simulated horizontal launch angle. The mallet control putter was a stock putter that lacked a hollow interior cavity and lacked a lattice structure. The mallet control putter was roughly the same size and shape as the four exemplary putters, described below. The mallet control putter and the four example putters were all mallet-type putters. The mallet putters were also compared to the blade control.
When comparing properties related to weight distribution within a golf club head, it is desirable to maintain a similar total mass across the compared club heads. As shown in Table III below, the studied mallet club heads had roughly equivalent masses. The blade control has a lower mass due to its size.
A first example putter was a version of the first putter embodiment, described above and illustrated in
A second example putter, not illustrated, was a version of the first putter embodiment, described above. The second example putter was the same as the first example putter, except that the central reference sphere was centered about a point in front of the baseline CG position. This position of the central reference sphere moved the CG rearwards, as indicated in Table III below. The unit scaffolding comprised a fluorite beam structure. The density of the lattice structure increased linearly towards the skirt or perimeter of the putter.
A third example putter, not illustrated, was a version of the first putter embodiment, described above. The third example putter was the same as the first example putter, except that the unit scaffolding comprised a re-entrant beam structure in the third example putter. The density of the lattice structure increased linearly towards the skirt of the putter.
A fourth example putter, not illustrated, was a version of the first putter embodiment, described above. The fourth example putter was the same as the first example putter, except that the unit scaffolding comprised a diamond beam structure in the fourth example putter. The density of the lattice structure increased linearly towards the skirt of the putter.
Relative to the mallet control putter, all four exemplary putters exhibited higher MOIs and CG positions closer to the strikeface. Referring to Table III, the MOI in the x-axis direction (heel-to-toe), Ixx, was greater in the first, second, third, and fourth putter heads than in the mallet control putter head. A greater Ixx value results in more forgiveness when a golf ball impacts the face off-center. In some embodiments, the increased forgiveness can lower the offline carry of the golf ball during the putt.
Referring to Table III, the MOI in the y-axis direction (sole-to-crown), Iyy, was greater in the first, second, third, and fourth example putter heads than in the control putter head. A greater Iyy value results in more forgiveness when a golf ball impacts the strikeface above or below the engineered impact location, which is typically at the geometric centerpoint of the strikeface.
Referring to Table III, the MOI in the z-axis direction (front-to-rear), Izz, was greater in the first, second, third, and fourth putter heads than in the control putter head. A greater Izz value is caused by concentrating more weight in the extreme front and extreme rear of the putter head. The internal cavity with a lattice structure in the first, second, third, and fourth example putter heads removed mass from the center of the club head and redistributed it towards the periphery to increase the Izz compared to the control putter head. A higher Izz can benefit players with certain putt stroke types.
Referring to Table III, the CGs of the first, second, third, and fourth example putter heads were closer to the strikeface than the rear, compared to the CG position of the mallet control putter head.
Industry models were used to correlate CG location to horizontal launch angle. As described above, placing the CG closer to the strikeface (a lower CGz value) reduced the horizontal launch angle on off-center face impacts, which in turn reduced the sidespin imparted to the golf ball.
In
As illustrated in
There was minimal performance difference between the example club heads, showing that various lattice types can be used to achieve the desired launch angle characteristics. The first, second, third, and fourth example club heads achieved beneficial horizontal launch angle values close to that of blade-type putters, while maintaining the look and feel of mallet-type putters.
A mallet control putter and a blade control putter were compared to an example of the first putter embodiment and an example of the second putter embodiment, described above, to determine MOI values, CG position, and simulated horizontal launch angle. The mallet control putter was similar to the mallet control putter described above in Example 2. The blade control putter was similar to the putter control putter in Example 2. The first example putter was similar to the first example putter described above in Example 2. The second example putter was similar to the second embodiment of a putter, described above.
The second example putter comprised a lattice structure with a uniform density. The lattice structure filled the internal cavity of the putter. The second example putter comprised a solid face, a 1 mm thick crown, and a 1.5 mm thick sole. When comparing properties related to weight distribution within a golf club head, it is desirable to maintain a similar total mass across the compared club heads. As shown in Table IV below, the studied mallet club heads had roughly equivalent masses.
Referring to Table IV, the MOIs (Ixx, Iyy, and Izz) of the first and second example putter heads were higher than the respective MOIs of the mallet control putter head. Since the first example putter head has a lattice with a varying density that increases towards the periphery, the first example putter head has slightly higher MOIs than the second example putter head, which has a uniform lattice density. The CGs of the first and second example putter heads were closer to the strikeface than the rear, compared to the CG position of the mallet control putter head.
Industry models were used to correlate CG location to horizontal launch angle. As illustrated in the graph of
A simulation study was done to assess horizontal launch angle performance of a first mallet control, a second mallet control, a third mallet control, a blade control, and an example putter head. The first mallet control was similar to the first mallet controls of Examples 2 and 3 above (“Oslo” putter). The second mallet control comprised heel and toe weights that yielded a higher Iyy value than the first mallet control (“Ketch” putter). The third mallet control was a multi-material, aluminum and steel, club head with extreme heel and toe weighting (“Tomcat 14” putter). The third mallet control exhibited an Iyy value higher than both the first and second example mallets. The blade control was similar to the blade controls of Examples 2 and 3 above (“Anser” putter).
In the graph of
The example club head comprised a CG location between that of the blade control and the mallet controls. Therefore, the example club head exhibited a horizontal launch per horizontal impact location better than the mallet controls and slightly worse than the blade control. The example club head performed partially like a blade-type putter, while maintaining the look and feel of a mallet-type putter.
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 claims the benefit to U.S. Provisional Application No. 63/078,257 filed on Sep. 14, 2020, the contents of which are incorporated herein by reference.
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