The invention relates to golf club heads with improved mass distribution provided by novel cellular features.
When a golfer makes a shot, he or she typically wants the golf ball to travel a certain distance in a certain direction. Unfortunately, when a golfer makes a shot, the ball will sometimes travel in an unintended direction or not travel the desired distance. Existing approaches to correcting for off-center shots or tuning distance have included designing a club's mass distribution to increase moment of inertia or locate a club head center of gravity with specificity. However, these approaches are limited by the other demands on a club head. Because a club head must withstand thousands of high-impact hits, parts of the club head body and face cannot simply be made thinner. If the face or part of the club head body were simply made very thin, the club head would crack and fail soon after a golfer bought it. This would make a golfer unhappy.
i. Cells
The invention provides a golf club head with cellular mass distribution that allows mass to be distributed in a club head without compromising structural integrity. The club head includes cells defined by structural elements that give the club head strength, even where the cells are empty or occupied by other materials. The structural elements can operate as supporting walls to define the cells, and the cells can be left empty, can be filled, or can be “outie” cells from which material protrudes. Cells can be filled with or occupied by low density or neutral materials, weights, mixed materials, or materials that offer functional benefits such as elastic dampening. Because materials of any density may be distributed among any number of cells, each club head can have an optimized mass distribution for the purpose of that club head. Since the structural elements provide strength throughout the club head, the club head is durable and withstands intense use.
By providing a club head with a very low mass per unit volume near a topline or crown and a much higher mass per unit volume near a heel or a toe, a club head can have a very high moment of inertia. By having a high mass per unit volume near a sole, a club head can have a very low center of gravity.
Since a club head of the invention has a high MOI, it does not twist in space during off center hits. As a results, even off-center shots tend to send the ball in the intended direction.
Since a club head of the invention may have a very low center of gravity, it can impart high momentum to the golf ball, causing the ball to travel the intended distance. Since shots made with a golf club of the invention travel the intended direction and the intended distance, a golfer will consistently make the shots they desire to make. As a result, a golfer will experience very excellent results and benefits by playing with a club of the invention.
In some aspects, the invention provides a golf club head with a body and a face connected to the body, in which the face has a variable thickness provided by one or more cells, or recessed areas into the material of the face (e.g., on a back surface of the face). The cells may form a regular repeating pattern (e.g., like honeycomb or brickwork).
Aspects of the invention provides a golf club head with a body attached to a face, and having a medallion member inserted therein, wherein a portion of the medallion is visible inside of a cavity within the back of the body, and a portion of the medallion is visible through a window that is beneath the cavity when the club is at address. The medallion may be a polymer or a viscoelastic material such as, for example, TPU or a plastic or rubber material. The medallion may be colored, transparent, translucent, or opaque and may have indicia providing information (e.g., describing other features of the club head). The window through the metal body of the club head makes the indicia easy to find in a crowded golf bag.
In some aspects, the invention provides a golf club head with a body that includes a face insert opening for attachment of a face insert. The body has one or more pockets or cells therein accessible through the face insert opening (i.e., so that the pockets or cells are covered and concealed when the face insert is installed onto the body). The club head may include at least one insert member in the one or more pockets.
In related aspects, the invention provides a golf club head with a main body with a toe side, a heel side, a sole portion, and a top portion; a hosel extending from the heel side; and a ball striking face insert supported by an attachment perimeter defining an aperture through the main body. The club head includes one or more cells defining recesses into the body member and only accessible through the aperture.
In some aspects, the invention provides a golf club head having a main body with a toe side, a heel side, a sole portion, and a top portion. A hosel extends from the heel side and a ball striking face member is supported by the main body. The club head includes a plurality of cells with varying depths including both innie and outie cells. In some embodiments, all of the plurality of cells have substantially similar shapes and occupy a substantially similar area of the club head. In certain embodiments, the plurality of cells define a regular repeating pattern.
ii. Inserts
Additionally, facets of the invention provide cell inserts that can be set or customized by a user or by a golf pro or instructor. For example, a club head can include heel-side and toe-side cells and inserts that fit into those cells. The user can bias the mass distribution according to their druthers or a club provider can optimize the mass distribution prior to sending the club home with the user. Optionally, a club head may include a cover or plate to enclose the cells—either user-removable or fixed in place.
The invention further includes the insight that mass distribution can have a maximal effect on MOI where inserts are shaped and located with a particular relationship to one or more rotational axes. Weight inserts that have mass concentrated within a cylindrical shell defined by an outer radius and an inner radius of a rotational axis will increase MOI more than equivalent masses that extend substantially within the inner radius. Inserts that have regular geometric shapes such as arcs or parallelograms provide for ease of insertion and also can concentrate their mass within a cylindrical shell if oriented in certain ways. Insert sets of the invention can be set by a club provider or adjusted by a user to optimize MOI, particularly where the inserts and the corresponding cells are configured with shapes that concentrate within a cylindrical shell concentric with a relevant rotational axis such as, for example, an axis that is vertical when the club head is at address.
In certain aspects, the invention provides a golf club head having a body with a top line, a heel portion, a toe portion, and a sole portion. A hosel extends up from the heel portion and a ball striking face is supported by the body. A back portion extends between the heel portion and the toe portion and up from the sole portion. The club head includes a plurality of recesses into the back portion and an insert disposed within each of the plurality of recesses. Preferably, the plurality of recesses includes at least a recess into the heel portion and a recess into the toe portion. The plurality of recesses may include two outer recesses flanking two inner recesses, the four recesses being distributed along the back portion. In some embodiments, the plurality of recesses comprises at least two outer recesses, each of the two outer recesses having a shape that is substantially a mirror image of the a shape of the other one. The club head may be a cavity back club with an undercut—i.e., at least part of the back portion is spaced away from a back of the ball striking face to define an undercut in communication with a cavity in a back of the club head.
Preferably, each recess and each insert has a skewed shape comprising faces that are not orthogonal to one another, oriented to concentrated a majority of the mass of each insert into a cylindrical shell coaxial with an axis of rotation of the club head that is vertical when the club head is at address. One, some, or all of the faces may be planar. In some embodiments, at least one of the inserts has a parallelepiped shape. Each insert may be dimensioned to be inserted into the recess into the heel portion and removed and rotated and insert into the recess into the toe portion.
A surface of each insert may be mounted to the club head through an adhesive. In some embodiments, the adhesive connects to the insert through a viscoelastic dampening layer.
iii. Speed Channel
A further discovery and application of facets of the invention includes the insight that providing a channel at a base of a back of a ball-striking face may greatly increase ball speed and reduce materials fatigue in what was, in the prior art, a common place of breakage. A channel, or groove, near the sole (e.g., within an undercut of a cavity in a cavity-back iron) provides a smooth transition allowing face flexure and gives a club head without a substantial material discontinuity. This channel may prevent breakage by allowing greater flexure and also increase a club face coefficient of restitution, thus greatly increasing ball speed and distance.
Aspects of the invention provide a golf club head having a body with a toe side, a heel side, a sole portion, and a top portion; a hosel extending from the heel side; a ball striking face member supported by the main body; and a channel in a surface of the sole and adjacent to a back surface of the face member. The channel may have a semi-circular cross-section and may extend from heel to toe. In some embodiments, the channel is in an upward-facing, inner surface of the sole. The channel may have a maximum cross-sectional dimension between about 0.5 mm and about 4 mm.
In certain embodiments, the ball striking face member is a face insert comprising a first material and the body comprises a second material. Further, the club head may include one more recesses into a back side of the body. The club head may also include a set of inserts of varying densities dimensioned to fit into the recesses.
The perimeter body includes a top line 2, a toe portion 4, a heel portion 6, and a sole portion 8 and provides mass distribution of golf club head 101 that increases the moment of inertia by concentrating the mass of the club head at the perimeter of face panel 103. Sole portion 8 may further include mass concentrations to further tune the mass properties of club head 1. For example, in the present embodiment, sole portion 8 includes a heel mass 16 and a toe mass 18 and a back portion 20. Back portion 20 is spaced away from a back of face insert 103 to create an undercut 115. A center of back portion 20 has a reduced height that combines with heel mass 16 and toe mass 18 to increase the moment of inertia about a Y-axis extending through the center of gravity of golf club head 101.
Face panel 103 is disposed on the perimeter body and provides a front ball striking surface. Face panel 103 may have an overall equivalent thickness, e.g., between about 1.5 mm and about 4.0 mm while also having a variable thickness defined by cells. For example, the face may have regions of greater thickness provided as an outie cell 107. Additionally, face panel 103 may be formed integral with perimeter body or as a separate component that is coupled to the perimeter body. Face insert construction is discussed in U.S. Pat. No. 7,771,288; U.S. Pub. 2013/0065706; U.S. Pub. 2012/0258820; and U.S. Pub. 2003/0119602, the contents of which are incorporated by reference. Face panel 103 may be constructed from the same or a different material than the perimeter body and hosel 10, and it combines with the perimeter body to define a rear cavity.
The invention provides cell structures that alter the perimeter body to free up or to consume discretionary mass. As shown in
Hosel 10 is disposed on a heel end of face 14 and the perimeter body, and provides an attachment to a shaft so that club head 101 may be assembled into a complete golf club. Hosel 10 may be constructed integral with face 14 and/or the perimeter body. Hosel 10 may also be constructed from the same, or a different, material than face 14 and/or the perimeter body.
The invention generally provides club heads with optimized mass distribution properties. An approach to distributing mass involves the placement of cells in or on the surfaces of club head materials. Cells can be recessed or protruding areas of material having less or more, respectively, material than the surrounding areas.
In some embodiments, face insert 103 having a combination of cells provides a club head with a greater coefficient of restitution than would otherwise be possible if the face insert 103 had a constant thickness. In some embodiments, club head 103 has a coefficient of restitution that ranges from approximately 0.825-0.855 while maintaining acceptable durability of the face. In some embodiments, the club head 103 can have a coefficient of restitution that ranges from approximately 0.800 to 0.900. Other ranges and values are also possible.
Selective removal of cells of material can decrease the weight of the material without substantially decreasing the strength or rigidity. Cell size and depth can be optimized to provide a material that is lightweight, strong, and has a desired rigidity. Pieces of material with cell patterns function as though they were the same thickness as smooth sheets of material. They provide strength and flexibility/restitution properties as well as, or better than, smooth pieces of material of functionally equivalent thickness. Cell-surfaced materials can exhibit greater springiness and resistance to bending or deformation than expected, while being surprisingly light. Forging, routing, CNC milling, molding, and embossing, for example, provide inexpensive methods for manufacturing cell-surfaced material. Club head structures are discussed in U.S. Pat. No. 6,319,150; U.S. Pat. No. 5,735,755; U.S. Pat. No. 5,711,722; and U.S. Pat. No. 4,681,322, the contents of which are incorporated by reference herein in their entirety for all purposes.
In certain embodiments, each innie cell is a hole through more than about 10% of the thickness of the material. Greater weight savings are had by deeper cells so, in some embodiments, each cell is a hole through more than about 25% of the thickness of the material (e.g., more than about 50% of the thickness). In very light-weight embodiments, each cell is a hole through more than about 75% of the thickness of the material. In strength-optimized, each cell is a hole through about 30% to about 70% of the thickness of the material.
In certain aspects, the invention provides club heads with inserts and methods of attaching inserts to club heads. Attachment according to the invention allows for attaching inserts to club heads of dissimilar materials (i.e., two materials that can or cannot be welded together). The invention provides pockets for inserts that give a club designer control over the visibility of an insert in a finished club and the ability to add inserts with or without welding.
In some embodiments, the invention provides a club head body with one or more pockets for receiving an insert through the face area of a club head body.
A significant benefit of pockets with through-face access is that inserts may be added easily during manufacture, but made not visible in a finished club head. Many irons are made with a body member that is attached to a separate face insert. Through-face pockets capture dual additional functionalities from the face insert by using the attachment of the face insert to retain insert members as well as to conceal them.
In certain aspects, the invention provides a club head with a window for showing, for example, a medallion material, a word or other indicia, an inside of a club head cavity, or a combination thereof. A window allows a club manufacturer to customize a cell-based club head and then provide indicia communicating the function of the particular club in a location that is fixed into a regular and expected location. The window provides a benefit in the form of emphasis and regularity for the useful piece of information. Since a golfer may become accustomed to glancing at clubs in a bag and looking for informative indicia in the regular and expected spot, and since a window can contrast usefully with the surrounding material, the golfer can select the right club rapidly with ease. For example, two clubs that are alike but for heel versus toe cell weighting in each may have an indicia in the window of each, one of which says “fade” and the other of which says “draw”.
In certain embodiments, insert 721, or medallion portion 107, is opaque, translucent, or transparent. Where the portion is translucent or transparent, an inside part of club head 701 may be visible or partially visible through window 711. This provides information to a golfer about materials, design, and construction of the club head. In this way, the invention surmounts existing challenges about communicating to golfers the features and functions of their club heads. In prior art clubs, two club heads may have significantly different mass distributions or playability characteristics but may appear exactly the same to a golfer. Here, where club heads of the invention have distinct mass distributions, the invention provides mechanisms for revealing aspects of the materials to a golfer in a controlled, even understated, fashion. For example, a transparent insert will allow a golfer to observe the different mass distributions through window 711.
Further, the invention provides windows for the display of mechanisms such as inserts in the pockets shown and discussed with reference to
Further, as shown in
Revealing a portion of the weight insert solves problems with prior art clubs associated with the need to communicate to a golfer the present effective setting of a tunable club or communicate to a golfer the mass distribution and other playability factors of a club head. Concealing a significant portion of the weight provides significant benefits in terms of manufacturing costs, time, and difficulty, as a weight insert needs only have a small portion of its surface finished for golfer visibility.
Turning now to the mass distribution control afforded by cell technology, the invention provides innie and outie cells that can reach to extremes of the club head volume to maximize a designer's ability to distribute mass.
In certain aspects and embodiments, the invention provides recesses that play cell roles and pocket rolls for decreasing mass, accommodating inserts to increase mass, or both. Pocket cells can be designed to conceal an insert or themselves be concealed within a finished club head or to be fully or partially accessible or visible.
In certain aspects and embodiments, the invention provides a club head body 1901 with optimized mass distribution through the inclusion of cells, both innie and outie, on a surface of the material of club head body 1901.
In certain aspects and embodiments, the invention provides an iron-type club head with a channelized cell in a floor of a cavity that provides high-speed shots and unexpectedly good coefficient of restitution.
When an exemplary club head is made and played, it exhibits unexpectedly good ball speed. Without being bound by any mechanism, it is theorized that the channel increases a coefficient of restitution of the face. Accordingly, in some aspects, the invention provides a club head with novel geometry comprising a cutaway, groove, recess, or channel directly behind the face that allows the body of the iron to flex with the face.
In some embodiments, the geometry of the invention thins the body of the iron in the proximity of the face and changes the way the iron behave on impact. The geometry distributes the stress from the face into the iron body, reducing the stress levels experience by the face, allowing for thinner and more resilient face designs. Additionally, the geometry increases iron performance by increasing the club's COR, which in turn increases ball speed and shot distance.
An abrupt transition of thickness from the iron face to the iron body puts the burden of impact mainly on the face material itself. The result is a face that flexes, with high levels of localized stress. The body of the iron mainly supports the face and does little to mitigate the stress or add to the flexion performance.
In the new proposed geometry, the thickness of the iron body directly behind the iron face is reduced with a non-flat (e.g., curved or circular) groove 2117. This reduces sole thickness in this region. With the new geometry, upon impact with a golf ball, the face and the body flex. The iron face flexes inward, and the iron body rotates counter clockwise (CCW) as shown in
In tests with a 21 degree iron, peak face stress levels in finite element analysis (FEA) simulations dropped from 1191 MPa (abrupt iron to body transition) to 1069 MPa with the new proposed geometry. This reduction in stress improves the durability of iron designs or allows for thinner, higher performing face designs to be used while maintaining current durability levels.
Another added benefit of the new geometry is an increase in the coefficient of restitution of the club head. By adding sole flexion, the overall rigidity of the club head is reduced. The result is more club head flex under load and greater COR values. In initial FEA simulations, the COR of an iron went from 0.79 (abrupt iron to body transition) to 0.804 with the new proposed geometry.
In certain aspects and embodiments, the invention provides inserts and insert sets for golf club heads, as well as golf club heads that include inserts for customization of mass distribution. In some embodiments, inserts are interchangeable (e.g., by a user). Additionally, inserts and their corresponding receiving cells can have easy-to-manufacture and easy-to-use geometric shapes, while also having a shape that concentrates insert mass in a location that optimizes effect on MOI.
Each of insert 2213 and 2219 may be shaped with a skew or a bend such that a substantial portion of the mass of that insert is located far away from a z axis (an axis that is vertical when the club head is at address). Additionally, the skewed shape allows the insert port, i.e., the aperture into each of recess 2203, 2205, 2207, and 2209, to be conveniently located along the back portion of the perimeter body, facing out and back and thus easily accessible for a golfer. Each insert may be easily inserted into, and removed from, club head 2201. Additionally, due to the oblique shape of the insert, a substantial amount of its mass is located away from an axis of rotation that is vertical when the club head is at address (i.e., a z axis). Significantly, due to the oblique, or “sheared” shape (in some embodiments) or to the curved or bent shape (in some embodiments), an insert of the invention has a greater proportion of its mass located away from the z axis than an insert of another shape. By moving more of the mass away from the z axis, MOI of the club head is increased.
Moment of inertia (MOI) relates to the inertia of a rotating body and is analogous to mass in linear motion. A MOI exists with respect to an axis of rotation. In a golf club head, more than one axis of rotation may have significance for the playing properties of the club head. For example, with reference to a club head that is at address, a MOI that is horizontal and extends through the heel and toe will affect how much the club head tends to “roll” (like a wheel) head-over-sole. For making off-center hits fly straight, the MOI about an axis that is vertical (a z axis) when the club head is at address is significant (e.g., IZZ is MOI about a z axis). For a continuous mass distribution (e.g., for a body that is not a regular geometric object), the MOI about the z axis is given by Equation 1.
where mass M is divided into infinitesimally small units dm, each unit dm being a distance r from axis z. An effectively similar measure can be calculated by modeling a club head as a number i of discrete mass elements and calculating IZZ as shown in Equation 2.
where mi is the mass of the ith mass element and ri is the distance of the center of mass of that mass element from the axis z. It can be noted from Equations 1 and 2 that MOI scales with the square of the distance from the axis of rotation. Thus there is particular benefit of locating mass away from the axis. Particularly where a fixed amount of mass is to be used overall in a club head, high MOI is to be had by pushing that mass into a location with a highest value for r. Given that a mass must occupy some volume, an insight of the invention is that optimizing MOI can involve pushing the mass to be concentrated within a cylindrical shell defined by an outer radius ro and an inner radius ri.
Thus as can be seen from
Use of the interchangeable inserts 2213 and 2219 allow for a number of customization options. For example, a customer can be given a set of inserts, having a variety of masses or densities, for customizing their golf club.
In certain embodiments, an insert can fit into more than one of the different recesses, even where those recesses appear at first to be mirror images of one another and thus chiral.
Club heads according to the invention can come with a variety of inserts performing a variety of functions and can include recess that are not filled by an insert. For example, a club head could include four recesses and two inserts that, taken together, sum to a desired mass. The customer (or a golf pro performing a custom fitting) could position the two inserts to bias the mass of the club in a desired fashion (e.g., heel-weighted, toe-weighted, max MOI, low CG, etc.).
Inserts may be retained in a club head by any suitable mechanism. Exemplary mechanisms that may be preferred include press-fit, adhesives, a mechanical fastener, a cover plate, or a detent mechanism. For example, inserts shown in
One benefit that arises from the use of recessed cells and inserts as described herein is that a single club head can be given different mass properties based on the particular inserts that are used and the masses and densities of those inserts (or lack thereof). A further benefit arising out of that benefit is that a baseline set of club heads can be used to provide multiple different sets of golf clubs. Further, since the mass distribution within each club head can be customized, the mass distribution across a set of clubs can be customized. For some golfers, what is needed out of their long irons is different than what is needed out of their short irons. Moreover, that difference may vary progressively across the clubs in a set. Accordingly, a set may be most beneficial to a golfer if a mass distribution property varies progressively from club to club in series in a set. Sets of clubs are described in SYSTEM AND METHOD FOR MULTI-SET COLLECTION OF GOLF CLUBS, U.S. Provisional Patent Application No. 61/764,300, filed Feb. 13, 2013, the contents of which are incorporated by reference. Further, use of inserts as described herein can provide a mass distribution that varies progressively through a set, and one golfer may have that varying mass distribution vary across their clubs differently than another golfer.
As illustrated by Table 1, a set of inserts of the invention can be applied to a set of clubs in different ways to make different sets with different properties.
Inserts of the invention can each be made to have any desired density and can be made with a variety of materials and can include any of a number of additional features. For example, inserts may be tungsten, or may include tungsten along with other materials, such as a tungsten slug embedded within a polymer housing, or a tungsten powder distributed within a matrix material such as a polymer (e.g., TPU, PTFE) or rubber. Inserts can be lightweight, such as a polymer or a rubber material and can even include void space, such as by being porous or including an open void therein. Inserts can include a viscoelastic material for vibration dampening. Moreover, inserts can include materials that are renewable or recycled, thus reducing the environmental footprint of a golf club. For example, inserts may be made from wood (e.g., salvaged wood from old building projects) or a recycled plastic.
A club with at least one recess may include an insert. A club with a recess and optionally with an insert may include a channel for increased ball speed. Any one of these features may be provided alone.
For example, the invention provides a golf club head comprising a body with a toe side, a heel side, a sole portion, and a top portion. A hosel extends from the heel side and a ball striking face member is supported by the main body. This club head includes a channel in a surface of the sole and adjacent to a back surface of the face member. The channel may have a semi-circular cross-section. The channel may run from heel to toe. The channel may be in an upward-facing, inner surface of the sole. In some embodiments, the body defines a cavity in the back of the club head. The club head may include an undercut space extending towards the sole from the cavity.
In certain embodiments, wherein the channel has a maximum cross-sectional dimension between about 0.1 mm and about 4 mm. Optionally, the ball striking face member is a face insert comprising a first material and the body comprises a second material. Such a club head may optionally include one or more recesses into a back side of the body. Such a club head may optionally include one or a set of inserts of varying densities dimensioned to fit into the recesses.
In another example, the invention provides a golf club head with a body and a face connected to the body, the face having variable thickness provided by one or more recessed cells.
In another example, the invention provides a golf club head having a body with a face insert opening for attachment of a face insert, the body having one or more pockets therein accessible through the face insert opening. The club head has at least one insert member in the one or more pockets.
In a further example, the invention provides a golf club head that has a main body with a toe side, a heel side, a sole portion, and a top portion as well as a hosel extending from the heel side and a ball striking face insert supported by an attachment perimeter defining an aperture through the main body. The club head includes one or more cells defining recesses into the body member and only accessible through the aperture.
As used throughout, any reference to direction that does not otherwise specify is made with reference to a club head at address. As used herein, “or” means “and or or”, commonly seen as “and/or”, unless otherwise indicated.
While it is apparent that the illustrative embodiments of the invention disclosed herein fulfill the objectives stated above, it is appreciated that numerous modifications and other embodiments may be devised by those skilled in the art. Therefore, it will be understood that the appended claims are intended to cover all such modifications and embodiments, which would come within the spirit and scope of the present invention.
References and citations to other documents, such as patents, patent applications, patent publications, journals, books, papers, web contents, have been made throughout this disclosure. All such documents are hereby incorporated herein by reference in their entirety for all purposes.
This application is continuation of U.S. patent application Ser. No. 13/946,571, filed Jul. 19, 2013, which application is a non-Provisional claiming the benefit of, and priority to, both U.S. Provisional Patent Application Ser. No. 61/678,799, filed Aug. 2, 2012, and U.S. Provisional Patent Application Ser. No. 61/764,300, filed Feb. 13, 2013, the contents of each of which are incorporated by reference in their entirety.
Number | Date | Country | |
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61764300 | Feb 2013 | US | |
61678799 | Aug 2012 | US |
Number | Date | Country | |
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Parent | 13946571 | Jul 2013 | US |
Child | 14952027 | US |