The invention relates to golf clubs, and more particularly, to golf club heads having a movable weight.
The trend of lengthening golf courses to increase their difficulty has resulted in a high percentage of amateur golfers constantly searching for ways to achieve more distance from their golf shots. The golf industry has responded by providing golf clubs specifically designed with distance and accuracy in mind. The size of wood-type golf club heads has generally been increased while multi-material construction and reduced wall thicknesses have been included to provide more mass available for selective placement through the head. The discretionary mass placement has allowed the club to possess a higher moment of inertia (MOI), which translates to a greater ability to resist twisting during off-center ball impacts and less of a distance penalty for those off-center ball impacts.
Various methods are used to selectively locate mass throughout golf club heads, including thickening portions of the body casting itself or strategically adding separate weight element during the manufacture of the club head. An example, shown in U.S. Pat. No. 7,186,190, discloses a golf club head comprising a number of moveable weights attached to the body of the club head. The club head includes a number of threaded ports into which the moveable weights are screwed. Though the mass characteristics of the golf club may be manipulated by rearranging the moveable weights, the cylindrical shape of the weights and the receiving features within the golf club body necessarily moves a significant portion of the mass toward the center of the club head, which may not maximize the peripheral weight of the club head or the MOI.
Alternative approaches for selectively locating mass in a club head utilize composite multi-material structures. These composite structures utilize two, three, or more materials that have different physical properties including different densities. An example of this type of composite club head is shown in U.S. Pat. No. 5,720,674. The club head comprises an arcuate portion of high-density material bonded to a recess in the back-skirt. Because composite materials like those found in the club head must be bonded together, for example by welding, swaging, or using bonding agents such as epoxy, they may be subject to delamination or corrosion over time. This component delamination or corrosion results in decreased performance in the golf club head and can lead to club head failure.
Further alternatives include a weight that is positioned within a channel formed in a golf club head. Generally, the weight must be inserted into an enlarged portion of the channel and then a plug inserted so that the weight is not ejected from the channel during use.
Though many methods of optimizing the mass properties of golf club heads exist, there remains a need in the art for a golf club head comprising at least a removable weight having secure attachment and a low-profile so that the weight does not protrude into the center of the club head and negatively affect the location of the center of gravity.
The present invention is directed to a golf club head having a portion comprising at least one movable weight member. The movable weight member is preferably structured so that it can be locked into multiple locations in a weight mount.
In an embodiment, a golf club head comprises a hosel, a ball striking face, a sole, a crown, a skirt, a weight mount, and a weight member. The sole extends aftward from a lower edge of the ball striking face. The crown extends aftward from an upper edge of the ball striking face. The skirt extends between the sole and the crown. The weight mount is disposed on at least one of the sole, the crown and the skirt, and includes a sidewall, an elongate rail, and a mount locking feature disposed on the sidewall. The rail defines a longitudinal axis extending parallel to the rail, and is suspended away from the sidewall by a plurality of rail supports spaced by a distance D1. At each of at least two locations along the rail the weight mount defines a first radial dimension RL1 between the center of the rail and the sidewall, and a second radial dimension RL2 between the center of the rail and the sidewall, and the magnitude of RL1 is greater than the magnitude of RL2. The weight member includes a first slot and a second slot. The first slot includes an opening and a cavity that receives the rail at the innermost end of the first slot. The second slot extends into the weight member to define a cantilevered lock tab that has a width D2, and the width D2 is less than distance D1 between adjacent rail supports. The lock tab includes an outer surface that defines a weight locking feature. The weight member defines a radial dimension RW1 between a center of the cavity and the outermost portion of the weight locking feature, and when the weight member is in a free state the magnitude of RW1 is greater than the magnitude of RL2. The weight member is rotatable about the rail between an unlocked orientation and a locked orientation, wherein in the unlocked orientation the first slot is aligned with the rail supports so that the weight member is slidable along the rail in the direction of the longitudinal axis of the rail. In the locked orientation, the lock tab of the weight member extends into the space defined by adjacent rail supports to prevent movement of the weight member longitudinally along the rail and the lock tab abuts the sidewall of the mount so that the weight locking feature forcibly engages the mount locking feature to prevent rotation of the weight member about the rail. The magnitude of the radial dimension RW1 of the weight member changes when the weight member is rotated between the unlocked orientation and the locked orientation such that the magnitude of RW1 is smaller when the weight member is in the locked orientation than when the weight member is in the free state.
In another embodiment, a golf club head comprises a hosel, a ball striking face, a sole, a crown, a skirt, a weight mount, and a weight member. The sole extends aftward from a lower edge of the ball striking face. The crown extends aftward from an upper edge of the ball striking face. The skirt extends between the sole and the crown. The weight mount is disposed on at least one of the sole, the crown and the skirt, and the weight mount includes a sidewall, an elongate rail, a tool engagement feature, and a mount locking feature disposed on the sidewall that is a ridge that projects from the sidewall of the weight mount. The rail defines a longitudinal axis extending parallel to the rail, and the rail is suspended away from the sidewall by a plurality of rail supports and adjacent rail supports are spaced by a distance D1. At each of at least two locations along the rail the weight mount defines a first radial dimension RL1 between the center of the rail and the sidewall, and a second radial dimension RL2 between the center of the rail and the sidewall, and a magnitude of RL1 is greater than a magnitude of RL2. The weight member includes a first slot and a second slot. The first slot defines an opening and a cavity that receives the rail at the innermost end of the first slot, and the second slot extends into the weight member to define a cantilevered lock tab that has a width D2, and the width D2 is less than distance D1 between adjacent rail supports. The lock tab includes an outer surface that defines a weight locking feature that is an elongate recess that extends across the lock tab. The weight member defines a radial dimension RW1 between a center of the cavity and the outermost portion of the weight locking feature. When the weight member is in a free state a magnitude of RW1 is greater than the magnitude of RL2. The weight member is selectively rotatable about the rail between an unlocked orientation and a locked orientation. In the unlocked orientation the first slot is aligned with the nearest rail supports so that the weight member is slidable along the rail in the direction of the longitudinal axis of the rail, and in the locked orientation the lock tab of the weight member extends into the space defined by adjacent rail supports to prevent movement of the weight member longitudinally along the rail and the lock tab abuts the sidewall so that the weight locking feature forcibly engages the mount locking feature to prevent rotation of the weight member about the rail. The magnitude of radial dimension RW1 of the weight member changes when the weight member is rotated between the unlocked orientation and the locked orientation such that the magnitude of RW1 is smaller when the weight member is in the locked orientation than when the weight member is in the free state.
In another embodiment, a golf club head comprises a hosel, a ball striking face, a sole, a crown, a skirt, a weight mount, and a weight member. The sole extends aftward from a lower edge of the ball striking face. The crown extends aftward from an upper edge of the ball striking face. The skirt extends between the sole and the crown. The weight mount is disposed on at least one of the sole, the crown and the skirt, and includes a sidewall, an elongate rail, a tool engagement feature, and a mount locking feature. The mount locking feature is disposed on the sidewall and is an elongate channel that is recessed into the sidewall of the weight mount. The rail defines a longitudinal axis extending parallel to the rail, and the rail is suspended away from the sidewall by a plurality of rail supports. Adjacent rail supports are spaced by a distance D1. At each of at least two locations along the rail the weight mount defines a first radial dimension RL1 between the center of the rail and the sidewall, a second radial dimension RL2 between the center of the rail and the sidewall, and a third radial dimension RL3 between the center of the rail and the elongate channel, dimension RL2 is disposed between dimensions RL1 and RL3, a magnitude of RL1 is greater than a magnitude of RL3, and the magnitudes of RL1 and RL3 are greater than a magnitude of RL2. The weight member includes a first slot and a second slot. The first slot defines an opening and a cavity that receives the rail at the innermost end of the first slot. The second slot defines a cantilevered lock tab that has a width D2, and the width D2 is less than distance D1 between adjacent rail supports. The lock tab includes an outer surface that defines a weight locking feature that is an elongate ridge that extends across the lock tab. The weight member defines a radial dimension RW1 between a center of the cavity and the outermost portion of the weight locking feature. The weight member is slidable on the rail and rotatable about the rail. When the weight member is in a free state a magnitude of RW1 is greater than the magnitude of RL2 and the magnitude of Ru. The weight member is selectively rotatable about the rail between an unlocked orientation and a locked orientation. In the unlocked orientation the first slot is aligned with the nearest rail supports so that the weight member is slidable along the rail in the direction of the longitudinal axis of the rail. In the locked orientation the lock tab of the weight member extends into the space defined by adjacent rail supports to prevent movement of the weight member longitudinally along the rail and the lock tab abuts the sidewall of the mount so that the weight locking feature engages the mount locking feature to prevent rotation of the weight member about the rail. The magnitude of dimension RW1 changes when the weight member is rotated between the unlocked orientation and the locked orientation such that the magnitude of RW1 is smaller in the locked orientation than in the free state of the weight member.
Other than in the operating examples, or unless otherwise expressly specified, all of the numerical ranges, amounts, values and percentages such as those for amounts of materials, moments of inertias, center of gravity locations, loft and draft angles, and others in the following portion of the specification may be read as if prefaced by the word “about” even though the term “about” may not expressly appear with the value, amount, or range. Accordingly, unless indicated to the contrary, the numerical parameters set forth in the following specification and attached claims are approximations that may vary depending upon the desired properties sought to be obtained by the present invention. At the very least, and not as an attempt to limit the application of the doctrine of equivalents to the scope of the claims, each numerical parameter should at least be construed in light of the number of reported significant digits and by applying ordinary rounding techniques.
Notwithstanding that the numerical ranges and parameters setting forth the broad scope of the invention are approximations, the numerical values set forth in the specific examples are reported as precisely as possible. Any numerical value, however, inherently contains certain errors necessarily resulting from the standard deviation found in their respective testing measurements. Furthermore, when numerical ranges of varying scope are set forth herein, it is contemplated that any combination of these values inclusive of the recited values may be used.
The golf club head of the present invention is preferably hollow, such as a metal wood type golf club head, but may include any club head type, such as iron-type club heads. The golf club head generally includes a hosel, a hitting face, a crown, a sole, and a skirt that combine to define a hollow interior cavity.
An exemplary golf club head is shown in
The weight mount 24 is generally constructed from a locking portion and a rail. In the present embodiment, weight mount 24 is an elongate recessed channel portion of the golf club head that includes a longitudinal rail 25. The recessed channel is defined by a sidewall 31 that extends from an outer surface of the golf club head toward an interior of the golf club head 10, and a portion of the sidewall 31 forms the locking portion. The sidewall 31 includes generally parallel portions and a generally curved innermost portion at the deepest portion of the channel that extends between the parallel portions. In the illustrated embodiment, the weight mount 24 is disposed on the sole 12, but it should be appreciated that the weight mount of any of the embodiments described herein may be located on any portion of the golf club head including the sole, crown, skirt, hosel, and/or face. The weight mount 24 defines an inner surface that is exposed to the exterior of the golf club head. The locking portion is defined by the curved portion of the sidewall 31 and the distance between the rail and the locking portion varies to deflect a portion of the weight member 22 as will be described in greater detail below.
The rail 25 of weight mount 24 is disposed inside the interior of the elongate recessed channel and is held in a spaced relationship relative to the sidewall of the channel. The rail 25 is suspended in the weight mount 24 by a plurality of rail supports 26 that are spaced from each other by a predetermined distance D1 that is generally based on the dimensions of the weight member 22. In the present embodiment, the rail supports 26 are coupled to a portion of the sidewall 31 that defines the locking portion. As will be described in greater detail below, the rail 25 and rail supports 26 interact with the weight member 22 to restrict relative motion between the weight member and the weight mount in directions longitudinally along the weight mount, and in a direction generally normal to the weight mount, as shown by the longitudinal (“L”) and normal (“N”) axes illustrated in
Generally, the weight member may be rotated about the rail 25 between an unlocked orientation and a locked orientation. In the unlocked orientation, the weight member is movable along the elongate weight mount along the longitudinal axis L by sliding it along the rail. In the locked configuration, a first portion of the weight member is disposed between the nearest spaced rail supports to restrict longitudinal movement of the weight member along the rail, relative to the weight mount. Additionally, the first portion of the weight member extends between the lower wall of the weight mount and the rail to restrict relative movement between the weight member and the weight mount in a direction normal to the weight mount. Finally, a lock tab on the weight member engages the locking portion of the weight mount to provide a détente when the weight member is in the locked orientation. The force required to rotate the weight member about the rail may be tuned by altering the interaction between the locking portion of the weight mount and the weight member, and preferably is tuned to prevent the ability of a user to lock or unlock the weight member without the use of a tool. The force is also tuned to prevent the weight member from becoming unlocked during use because of the force of impact with a golf ball.
In an embodiment, the weight member 22 has a single piece construction formed from a monolithic body that is shaped to be disposed in the weight mount 24 and to engage the rail 25. Weight member 22 includes a slot 34 that receives rail 25 and is shaped so that the weight member 22 is snapped onto the rail 25, and requires additional force to remove the weight member 22 from the rail 25. The slot 34 is shaped so that after the weight member 22 is installed on the rail, the weight member 22 may be slid along the rail 25. Slot 34 generally forms an opening into a cavity 35 that receives the rail 25. The slot 34 is sized with a width W1 that is about equal to the width W2 of rail 25 so that the rail 25 may be forcibly slid through the slot 34 into cavity 35. As an alternative, the rail may include a reduced width portion that allows the weight member 22 to be installed at only that reduced width location.
The weight member 22 also includes a lock tab 36 that engages a locking portion of the sidewall of the weight mount 24 to lock the weight member into a location. The lock tab 36 is generally a flexible cantilevered tab defined by a second slot 39 extending into the weight member, and includes a weight locking feature, such as recess 38. It should be appreciated that the weight locking feature may be a recess or a projection, but is selected to complement a mount locking feature. The lock tab 36 also has a width D2 that is selected so that the lock tab 36 is able to extend through the spacing between adjacent rail supports 26 when the weight member is rotated between the unlocked orientation and the locked orientation. The locking portion of the sidewall of the weight mount is a portion that abuts the lock tab 36, causing the lock tab 36 to deflect, and includes the mount locking feature, such as ridge 40 that is received by recess 38. In the present embodiment, the weight locking feature is an elongate recess that receives the mount locking feature which is a ridge, but it should be appreciated that the weight locking feature may be a dimple and the mount locking feature may be a plurality of discrete projections forming a group of bumps that complement the dimple. Additionally, it should be appreciated that, as an alternative, the recess may be included as a mount locking feature and a complementary projection may be included as the weight locking feature, as will be described in greater detail below. After the weight member 22 is installed on the rail 25, it may be rotated about the rail 25 to orient it in a locked configuration, shown in
In the illustrated embodiment, the weight locking feature, recess 38, extends from an outer surface of the lock tab 36 and receives the ridge 40 that is disposed in the locking portion of the sidewall 31 of weight mount 24. The weight member 22 is preferably rotated about the rail 25 using a tool that is temporarily coupled to a tool engagement feature 42 included in weight member 22. It should be appreciated that the weight member 22 may be constructed from multiple pieces, but those pieces need not move relative to each other after the weight is constructed. For example, portions of the weight member may be constructed from pieces having different densities to alter the mass of the weight member.
Referring to
The first step during installation of weight member 52 in weight mount 54 is to rotate the weight member 52 so that the slot 56 is aligned with the rail 58 and insert the weight member 52 into the weight mount 54 until the rail 58 is fully received by slot 56. The shape of slot 56 is selected so that there is a press fit between a portion of the slot 56 and the rail 58 before the rail snaps into place through the weight member 52.
The weight member 52 includes an alignment tab 64 that engages one of a plurality of alignment slots 66 included in the sidewall of the weight mount 54. When the alignment tab 64 is aligned with one of the slots 66, the weight member 52 may be rotated about rail 58 between the locked and unlocked orientations. If the weight member 52 is positioned so that the alignment tab 64 is misaligned with a slot 66, then the weight member 52 is prevented from rotating around the rail 58 toward the locked orientation. The alignment slots 66 assist a user in positioning the weight member 52 so that the lock tab 60 is positioned between rail supports 62 prior to attempting to rotate the weight member 52 toward the locked orientation.
After the alignment tab 64 is aligned with an alignment slot 66, the weight member 52 is rotated toward the locked orientation, as shown in the progression through views
Additionally, when the weight member 52 is installed on rail 58 it defines dimensions RW1 and RW2. Dimension RW1 extends from the center of the slot 56 that receives rail 58 to recess 68 of the lock tab 60. Dimension RW2 extends from the center of the slot 56 that receives rail 58 to recess 68 of the lock tab 60. Dimensions RW1 and RW2 change during rotation of the weight member 52 between the unlocked orientation and the locked orientation as a portion of lock tab 60 contacts ridge 70 and lock tab 60 is deflected. In the free state (i.e., before the lock tab 60 abuts the ridge 70) RW2 is preferably smaller than RL1 so that the lock tab 60 first contacts the locking portion 67 at ridge 70. Additionally, in the free state, RW1 is preferably larger than RL2 so that the lock tab 60 is deflected by the locking portion and remains deflected when the recess 68 engages the ridge 70 so that the features forcibly abut. As an alternative, and as will be further described below, the locking portion may have a contour that results in the distance between the rail and sidewall varying over a greater portion of the sidewall.
The deflection of the lock tab 60 creates friction between the weight member 52 and the weight mount 54, and that deflection can be used to tune the force required to rotate the weight member 52 into, and out of, the locked orientation where the recess 68 is fully engaged with the ridge 70. Preferably, the force is sufficient to require a user to use a tool that is inserted into a tool engagement feature 72 to fully rotate the weight member 52 into the locked orientation, shown in
Referring to
The rail 86 of weight mount 84 extends outward from a portion of the perimeter of the golf club head. The rail 86 is suspended by a plurality of rail supports 26 that are spaced from each other by a predetermined distance D1. In the present embodiment, the rail supports 90 are coupled to the perimeter of the golf club head.
The locking portion 88 is a portion of the perimeter surface of the golf club head that is adjacent rail 86 and rail supports 90. The locking portion 88 is shaped so that the distances between portions of the locking portion 88 and the rail 86 vary over the locking portion 88. The distance between the rail and the locking portion varies to deflect the lock tab 36 of the weight member 22, which allows the weight member 22 to be locked in place. The locking portion 88 also includes a ridge 92 that is received by the recess 38 of the weight member 22, when the weight member 22 is in the locked orientation.
Similar to previous embodiments, the rail 86 and rail supports 90 interact with the weight member 22 to restrict relative motion between the weight member and the weight mount in directions longitudinally along the weight mount, and in a direction generally normal to the weight mount so that the weight member is retained within the weight mount.
Generally, the weight member 22 may be rotated about the rail 86 between an unlocked orientation and a locked orientation. The locking portion 88 of the weight mount 84 defines a first radius RL1 from rail 86 at a first portion of the locking portion 88, and a second radius RL2 from rail 86 at ridge 90, and RL1 is greater than RL2. Additionally, the weight member 22 defines dimensions RW1 and RW2. In general, RW1 and RW2 extend from the center of the rail to outward portions of the lock tab 36. RW1 extends from the center of the cavity that receives the rail 86 to recess 38, and RW2 extends from the center of the cavity that receives the rail 86 to the outer surface of an adjacent portion of lock tab 36. Dimensions RW1 and RW2 change during rotation of the weight member 22 between the unlocked orientation and the locked orientation. In the free state (i.e., before the lock tab 36 abuts the sidewall of the weight mount 84) RW2 is preferably smaller than RL1 so that the lock tab 36 first contacts the locking portion at ridge 92. Additionally, in the free state, RW1 is preferably larger than of RL2 so that the lock tab is deflected by the locking portion and remains deflected when the recess 38 engages the ridge 92. In the unlocked orientation, the weight member is movable along the elongate weight mount along the longitudinal axis L by sliding it along the rail. In the locked configuration, a first portion of the weight member is disposed between the spaced rail supports to restrict longitudinal movement of the weight member along the rail, relative to the weight mount.
Additionally, the weight mount 84 may be shaped to prevent the rotation of the weight member 22 past the locked orientation. For example, the locking portion 88 may also include a limit stop 94 that is shaped to limit rotation of the weight member 22. In the present embodiment, the limit stop 94 is configured to abut the end of lock tab 36 when the weight member 22 is rotated past the locked orientation. However, it should be appreciated that a portion of the locking portion may include a dimension between the rail 86 and the locking portion that requires a higher force to rotate than possible by a user.
Referring now to
The weight member 102 includes a slot 106 that is sized to receive and snap onto a rail 108 in the weight mount 104, and a lock tab 110. The lock tab 110 engages a locking portion of the sidewall of the weight mount 104 to lock the weight member 102 into a location. The lock tab 110 is generally a flexible cantilevered tab defined by a second slot 107, and the lock tab 110 includes a weight locking feature, which in the present embodiment is a ridge 116.
The weight mount 104 is generally constructed from a locking portion 111 and a rail 108. In the present embodiment, weight mount 104 is an elongate recessed channel portion of the golf club head that includes the longitudinal rail 108. The locking portion 111 of the sidewall of the weight mount 104 is a portion that abuts the ridge 116 of the lock tab 110, when the weight member 102 is rotated into the locked orientation, causing the lock tab 110 to deflect. The locking portion includes a mount locking feature that is a recess 118 that forms an elongate channel in the illustrated embodiment.
After the weight member 102 is installed on the rail 108, it may be rotated about the rail 108 to orient it in a locked configuration, shown in
While it is apparent that the illustrative embodiments of the invention disclosed herein fulfill the objectives of the present invention, it is appreciated that numerous modifications and other embodiments may be devised by those skilled in the art. Additionally, feature(s) and/or element(s) from any embodiment may be used independently or in combination with other embodiment(s) and steps or elements from methods in accordance with the present invention can be executed or performed in any suitable order. 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.
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