Abstract
A golf club with a multi-piece adjustable and interchangeable modular hosel system comprises a shaft tip connector portion, an upper hosel portion, and optional, intermediate interchangeable hosel adjustment spacer(s). The modular hosel system can be used, for example, with no spacers in place, or one or more risers in each of the hosel adjustability regions. The adjustment spacers can be used to increase the hosel length and shaft axis to head center of gravity offset or intersection. Angled risers can be oriented to adjust the shaft axis relative to club head orientation to fit and adjust specifications including loft and lie angle, alone or in combination. The modular hosel construction provides a quick and efficient means of fitting the putter specification to a large number of golfer requirements and also adjusting the specifications for changing user needs or course conditions.
Claims
1. A golf club assembly, comprising, in combination: a discrete head portion having a hosel port; an interchangeable modular hosel portion having a hosel cup at its upper end; a combination of a shaft and a grip attached to the shaft forming a shaft and grip portion having an axis; a first discrete upper hosel adjustment spacer portion positioned along the axis between the upper end of the hosel cup and the shaft and grip portion, wherein the first discrete hosel adjustment portion has a top female mortised recess, the top female mortised recess having an opening along a first plane, and a male tenon section, the male tenon section having an opening along a second plane; and a second discrete lower hosel adjustment spacer portion positioned between the interchangeable modular hosel portion and the discrete head portion; the interchangeable modular hosel portion adapted to receive and retain accessibly and adjustably the first and second discrete hosel adjustment spacer portions.
2. The assembly as described in claim 1 wherein the first discrete hosel adjustment spacer portion has a spacer length that differs from a length of the second discrete hosel adjustment spacer portion.
3. The assembly as described in claim 1 wherein the first discrete hosel adjustment spacer portion has a spacer length and angle that differ from a length and angle of the second discrete hosel adjustment spacer portion.
4. The assembly as described in claim 1 wherein the discrete head portion is associated with one of: a putter type club head, an iron type club head, a hybrid wood-iron type club head, and a wood type club head.
5. The assembly as described in claim 1 wherein each of the first and second discrete hosel adjustment spacer portions includes a length, and a shaft axis to head offset, at least one of the first and second discrete hosel adjustment spacer portions includes one of a different length, and a different shaft axis to head offset.
6. The assembly as described in claim 1 wherein the first discrete hosel adjustment spacer portion has a characteristic that differs from the characteristic of the second discrete hosel adjustment spacer portion, the characteristic being one of: axis angle, length, material, weight, and marking.
7. The assembly as described in claim 1 wherein at least one of the first and second discrete hosel adjustment spacer portions comprises a round-cornered square exterior geometry having a mortised joint, and a round inner pass-through port.
8. The assembly as described in claim 1 wherein the first plane and the second plane are parallel or non-parallel to one another.
9. The assembly as described in claim 1 wherein the shaft and grip portion is interchangeable with a second shaft and grip portion.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
(1) For a more complete understanding of the disclosed subject matter, and the advantages thereof, reference is now made to the following description taken in conjunction with the accompanying drawings, in which:
(2) FIG. 1A illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric view, that embodies features of the disclosed subject matter; where the adjustable, selectable interchangeable modular hosel section has a selection of optional lower adjustment spacers between the hosel and the head, and a selection of optional upper adjustment spacers between the shaft and hosel;
(3) FIG. 1B illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric view, that embodies features of the disclosed subject matter; where the adjustable, selectable interchangeable modular hosel section has a selection of optional upper adjustment spacers between the shaft and hosel.
(4) FIG. 1C illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric view, that embodies features of the disclosed subject matter; where the adjustable, selectable interchangeable modular hosel section has a selection of optional lower adjustment spacers between the head and hosel.
(5) FIG. 1D illustrates the example putter of FIG. 1A with a set of two lower modular hosel adjustment spacers, and where the shaft is assembled directly into the hosel cup;
(6) FIG. 2A illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric exploded view, that embodies features of the disclosed subject matter; where the adjustable, selectable interchangeable modular hosel section has a selection of optional lower adjustment spacers between the hosel and the head, and a selection of optional upper adjustment spacers between the hosel shaft connector portion and the main hosel upper section;
(7) FIG. 2B illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric exploded cutaway view, that embodies features of this disclosure;
(8) FIG. 2C illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric assembled cutaway view, that embodies features of the disclosed subject matter; where the adjustable, selectable interchangeable modular hosel section has a selection of optional lower adjustment spacers between the hosel and the head, and a selection of optional upper adjustment spacers between the shaft and hosel;
(9) FIG. 3A illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club nearer the heel in an isometric assembled cutaway view, that embodies features of the disclosed subject matter; where the head, optional lower adjustment spacers and hosel lower stem are joined together with a mechanical screw entering the under side of the head, and where the hosel shaft connector, upper adjustment spacers and hosel upper section are joined together with a mechanical screw located under the hosel upper section's underside;
(10) FIG. 3B illustrates a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric exploded cutaway view, that embodies features of the disclosure;
(11) FIG. 3C shows the example putter from FIG. 3A, and shown here with an alternative means to secure the modular hosel lower stem via a hosel connection bolt located in a heel portion of the head;
(12) FIG. 4A illustrates a selection of modular lower hosel spacers of different angles in accordance with one embodiment where the varying angles are all located on the top portion of the spacer. FIG. 4B illustrates an alternative design where both the top and bottom of the spacer are angled;
(13) FIG. 4B illustrates a cutaway view of a selection of modular lower hosel spacers of different adjustment angles in accordance with one embodiment where the varying angles are all located on the bottom portion of the adjustment spacer while all the top angles are square.
(14) FIG. 4C illustrates an alternative design where both the top and bottom of the spacer are angled;
(15) FIG. 4D illustrates an alternative design where both the top and bottom of the spacer are angled;
(16) FIG. 5A illustrates a golf club, in this case a driver or fairway wood, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an assembled, isometric view, that embodies features of the disclosure; where the adjustable, selectable interchangeable modular hosel section has a selection of optional lower adjustment spacers between the main portion of the hosel and the head, and a selection of optional upper adjustment spacers between the upper hosel portion and a hosel shaft connector portion;
(17) FIG. 5B illustrates a golf club, in this case a fairway wood, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an isometric view;
(18) FIG. 5C illustrates a golf club, in this case a fairway wood or hybrid wood—iron, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an exploded isometric view;
(19) FIG. 6A illustrates a golf club, in this case an iron, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in an assembled cutaway isometric view;
(20) FIG. 6B illustrates a golf club, in this case an iron, having a multi-piece adjustable, modular hosel system, shaft and grip section (not shown), shown from the front of the club in a cutaway exploded isometric view;
(21) FIG. 7 illustrates an exploded view of a golf club, in this case a putter, having a multi-piece adjustable, modular hosel system, shaft and optional grip section (partially shown), shown from the front of the club, where there is a selection of interchangeable shafts assembled with hosel shaft tip connectors, a selection of upper hosel adjustment spacers, a selection of hosels of varying length, the medium length being installed in the head with a pair of lower hosel adjustment spacers, and a selection of optional lower hosel length adjustment spacers;
(22) FIG. 8A illustrates an assembled isometric cutaway view of a golf club, in this case a putter, having ahead with through head “center shafted” hosel port with a cylindrical multi-piece adjustable, modular hosel system, optional lower hosel adjustment spacers, hosel shaft connector, shaft and optional grip section (not shown), shown from the face of the club, nearer the toe;
(23) FIG. 8B illustrates an exploded isometric view of a golf club, in this case a putter, having a head with recessed hosel port in the top of the club head, a multi-piece adjustable, modular hosel system, optional lower hosel adjustment spacers, hosel shaft connector, shaft and optional grip section (not shown), shown from the face of the club;
(24) FIG. 8C illustrates an assembled cutaway isometric view from nearer the heal of a golf club, in this case a putter, having a head with recessed hosel port in the top of the club head with at least one flat to engage and restrict the hosel shaft connector piece, a multi-piece adjustable, modular hosel system, optional lower hosel adjustment spacers, hosel shaft connector, shaft and optional grip section (not shown), shown from the face of the club;
(25) FIG. 8D illustrates an exploded cutaway isometric view from nearer the toe of a golf club, in this case a putter, having a head with recessed hosel port in the top of the club head with at least one flat to engage and restrict the hosel shaft connector piece, a multi-piece adjustable, modular hosel system, optional lower hosel adjustment spacers, hosel shaft connector, optional screw retaining ring, optional locking washer, mechine screw shaft and optional grip section (not shown);
(26) FIG. 8E illustrates an exploded cutaway isometric view from nearer the toe of a golf club, in this case a putter, having a head with recessed hosel port in the top of the club head with a flat to engage and restrict the hosel shaft connector piece, a multi-piece adjustable, a modular hosel system, optional lower hosel adjustment spacers, hosel shaft connector, small machine screw to connect the mid hosel section and the hosel shaft connector, and a large machine screw to connect the head and the lower portion of the hosel section, and optional grip section (not shown);
(27) FIG. 9A illustrates an isometric exploded view of a selection of alternative design optional adjustment spacers, shown here positioned above one another, where the upper female mortised section has a number of locating ports in the recessed lower floor wall, and on the opposing lower male sides have at least one locating pin;
(28) FIG. 9B illustrates an alternative design for the adjustment spacers where a locating pin in the under side of the male tenon joint mates with a series of locator pin holes in the upper female mortised joint in the clubhead, hosel or hosel shaft connector piece section and the head hosel;
(29) FIG. 9C illustrates an isometric view of the underside of an alternative design adjustment spacers, where the male mortised section has a locating pin extending from the lower floor wall;
(30) FIG. 9D illustrates an isometric view of the upper side of an alternative design adjustment spacer with a round exterior and modified round cornered square interior wall, where a series of notches are formed in the sides of the walls forming the interior dimension of the spacer;
(31) FIG. 9E illustrates an isometric view of an alternative design hosel shaft connector piece with a modified round cornered square exterior male adapter, where an external rib is located on one of the flat sides of the adaptor;
(32) FIG. 10A illustrates a close up isometric exploded cutaway view of hosel in head port construction, including an orientation flat on the hosel stem, a corresponding locating flat in the head's hosel port, as well as optional washer and screw retaining rings in the construction;
(33) FIG. 10B illustrates a close up isometric exploded cutaway view of an alternative hosel in head port construction, including an orientation flat on the hosel stem, a corresponding locating flat in the head's hosel port, an alternative screw located at the base of the lower hosel stem, as well as optional washer, and locking nut in the construction;
DETAILED DESCRIPTION
(34) Referring to FIG. 1A of the drawings, the reference numeral 100 generally designates a golf club embodying features of subject disclosure, in this case a putter. The golf club head 100 may generally comprise abase head portion 110, a face portion 112, optional grooves 212, a heel portion, 114, a toe portion 116, a sole portion 118 atop portion 119, and a modular hosel portion 120.
(35) The golf club head 100 is shown in a generally finished state and includes an optional interchangeable flange 115 on the back of the putter head. The head 110 or flange 115 can include optional adjustable weights 215 in the head, such as described in U.S. Pat. Nos. 7,828,672 and 7,566,276.
(36) In one embodiment shown in FIG. 1A, the multi-piece modular hosel system comprises a shaft tip 132 at the upper end, a hosel shaft connector piece 140, two optional adjustment spacer ring pieces 150, a hosel cup 126, a hosel elbow 128, a hosel shank 123, and two optional lower hosel adjustment spacer square pieces 160.
(37) FIG. 1B of the drawings shows the same putter 100 as shown in FIG. 1A, with a set of upper modular hosel adjustment spacers, where the hosel 120′ is assembled directly into the putter head 110′. FIG. 1C of the drawings shows the example putter from FIG. 1A, shown here with a set of two lower modular hosel adjustment spacer squares 160′, where the shaft 132 and hosel shaft connector piece 140 are assembled directly into the hosel cup 126.
(38) Referring to FIG. 1D of the drawings shows the example putter from FIG. 1A, shown here with a set of two lower modular hosel adjustment spacers 160′, where the shaft 132 is assembled directly into the hosel cup 126.
(39) Referring to FIG. 2A of the drawings shows the golf club head 100, shaft 132 and a preferred embodiment of an adjustable modular hosel assembly 120 in an exploded view where the individual components are more easily seen, including the hosel shaft connector piece 140, two upper adjustable spacers 150, hosel cup 126, upper connection screw 170, hosel shank 123, lower adjustable spacers 160, head 110′ (including face portion 112, grooves 113, heel portion 114, toe portion 116, sole portion 118, and top portion 119), rear flange 115 and lower connection screw 180.
(40) FIG. 2B shows a cutaway view of the same putter head 110 in FIG. 2A with the modular hosel components sliced down the axis of the shaft to reveal the inner construction of the head, hosel and shaft assembly. FIG. 2C shows the same head, modular hosel and shaft in an assembled cutaway view illustrating the fully assembled components.
(41) Referring to FIG. 3A of the drawings shows the golf club 100 in a cutaway view, a head 110, shaft tip end 132, and an adjustable modular hosel assembly 120, including the hosel shaft connector piece 140, two upper adjustable spacers 150, hosel cup 126, upper connection screw 170, hosel shank 123, lower adjustable spacers 160, lower hosel stem 122, lower hosel stem flat 222, head hosel port flat 195, rear flange 115 and lower connection screw 180.
(42) FIG. 3B of the drawings shows the same golf club 100 in 3A, here in an exploded cutaway view showing the club head 110, shaft 132 the hosel shaft connector piece 140, two upper adjustable spacers 150, hosel cup 126, upper connection screw 170, hosel shank 123, lower adjustable spacers 160, the head's hosel port 190, lower hosel stem 122, lower hosel stem flat 222, head hosel port flat 195, rear flange 115, the head's hosel port counter sink 218 in the sole 118, and lower connection screw 180. Note that the hosel port 190′ can be located in a variety of locations in the head, as seen in FIG. 3C where a hosel connection bolt 181 is located in the heel portion 114 of the head, for instance, instead of the sole 118. Additionally, a side screw or pin can be threaded through the head and compress against the hosel stem, or a pass-through clearance bore and threaded into the hosel stem. The hosel port counter sink 218 could be located in the flange 115, or other portions of a multi-piece head design, especially in putters where the USGA and R&A Rules governing club design allow various hosel positions. Additionally, there could be multiple hosel connection ports and screws to provide a redundant system that can provide another means for locating the hosel in the correct orientation with the head to confirm to the Rules, and to provide extra strength and reliability of the parts remaining connected for play and over time. Similarly, the hosel port countersink 218 and lower connection screw 180 or bolt 181 can also be located under or adjacent the hosel port in whatever location the two can be connected allowing access and a secure mechanical construction.
(43) FIG. 4A illustrates an isometric view of a selection of lower adjustment spacers 160. Adjustment spacer 162 has no marking on its outermost surface designating zero angle change. Adjustment spacer 164 has ½ degree of change and is marked with a hash mark 264 on the outer surface adjacent the direction of lean. Adjustment spacer 166 has one degree of change and is marked with a single dot 266. Adjustment spacer 168 has two degrees of angle change and is therefore marked with two dots 268 to designate its geometry and orientation.
(44) FIG. 4B illustrates a cutaway side view of a selection of lower adjustment spacers 162, 164, 166 and 168, manufactured according to the preferred embodiment. Adjustment spacer 162 is square with no angle differentiation between the top female mortised recess 152 and the lower male tenon section 154. Preferably, the selection of different angled spacers is provided with angles by CNC machining the female mortised joints uniformly on all pieces from a larger stock piece. The lower male tenon section is then milled in a second operation to produce the amount of change. Thus, the adjustment spacer has a top female mortised recess having an opening along a first plane 147, and a male tenon section having an opening along a second plane 149. Alternate designs can be seen in FIG. 4C and FIG. 4D. In 4C, the amount of change is milled into the upper mortice recess and surrounding walls, with the result that the planes 147 and 149 may be parallel or non-parallel as also indicated. In FIG. 4D, change is provided in both the upper and lower sides of the adjustment spacers simultaneously. It should be noted that the adjustment spacers could also be manufactured with a compound angle where the degree of change is orientated in two directions simultaneously, providing both loft and lie angle changes in one adjustment spacer, in addition to changes in balance of the head relative to the shaft axis depending tip on the spacer length and location. However, for simplicity and ease of use across a broad spectrum if customers and end users, a single angle of change orientated to a single marked side is preferred.
(45) FIG. 5A illustrates a driver or fairway wood club 100 (grip not shown), and where the modular hosel section 120 can have a smooth flush construction where all the exterior surfaces can generally have the same outer shape and diameter from the shaft tip 132 to the club head hosel section 219 as also shown in FIG. 5B showing a fairway wood head 110 that embodied features of a preferred embodiment. FIG. 5C shows an exploded view of a fairway wood or hybrid wood-iron type head 110, and a hosel shaft connector 142, a set of upper adjustment spacers 150, a hosel mid-section 129 an upper connection machine screw 170, a lower set of adjustment spacers 160 the club head 110 and a lower connection screw 180. The lower adjustment spacers 150 and upper adjustment spacers 160 can be the same size and shape and be interchangeable for efficiency of manufacture, inventory, distribution, sale, utility and use.
(46) FIG. 6A illustrates a hybrid, utility-iron or standard iron-type head 110 in an exploded cutaway view showing a preferred embodiment with a shaft connector piece 142, a hosel mid-section 140, a set of two lower adjustment spacers 150, the club head hosel stem portion 219, hosel port 190 and lower connection screw 180.
(47) FIG. 6B illustrates a hybrid, utility-iron or standard iron-type head 110 in an exploded cutaway view showing an alternative embodiment with an upper hosel shaft connector piece 142, a hosel upper mid-section 140, a set of two upper adjustment spacers 150, a hosel mid-section connector piece 129, an upper connection screw 170, a set of lower adjustment spacers 160, a hosel port 190, a head hosel stem portion 219, the club head hosel stem portion 219, hosel port 190 and lower connection screw 180;
(48) FIG. 7 illustrates an exploded view of a golf club 100, showing a selection of interchangeable hosel shaft connectors 140 assembled with shaft tips 132 and 132′ (and the associated grips 133 and 133′), a selection of upper adjustment spacers 150 in different lengths 252, 352 and 452, a hosel 120 assembled with a pair of lower hosel spacers 160, and an additional selection of different length hosels including a longer hosel 320 and shorter hosel 220, the medium length being installed in the head with a pair of lower hosel adjustment spacers, a selection of optional lower hosel length adjustment spacers 162 with 262 being 1/16″ high, 362 being ¼″ high and 462 being ½″ high net adjustment length when assembled, and an axis 139 of the shaft and grip portion that is formed by a combination of the shaft and the grip;
(49) As noted, adjustment spacers are provided in different lengths, and different degrees of change, and can be used alone or stacked, allowing the club to be adjusted for loft and lie angles independent of one another, or in combination. The orientation of the angled side of the adjustment spacer determines the specification change to the assembled golf club. For instance, with the degree of angle change from level, positioned toward the toe 116 will cause the shaft angle to change one degree upright. If a two degree spacer is oriented towards the face, that will create two degrees more effective. As can be seen in FIG. 4A the preferred embodiment includes a selection of spacers that include one square lower adjustment spacer 162, one 0.5 (½) degree of change lower adjustment spacer 164, one degree (1°) 166, and two degrees (2°) 168. Other degrees of change such as 0.25 degree (¼°), 0.75 degree (¾°) or 1.5° or three degree (3.0°), for instance, are all possible. By stacking the adjustment spacers in the same direction, it is possible to increase the adjustment.
(50) The shaft can be connected to the golf club directly with a standard or specialized tip section, either formed as part of the shaft or affixed or connected to the shaft tip. The shaft tip or tip section can then be connected to the head or with a hosel, with optional upper or lower adjustable modular spacers between the shaft tip or shaft tip connector and the head or hosel. An optional hosel portion can be modular and interchangeable with the head as taught in Billings' '276, '604 and '991, providing further levels of customization, fitting options and adjustment.
(51) FIG. 8A illustrates a golf club 100 with a shaft tip 132, a hosel shaft connector piece 144, a pair of cylindrical lower hosel adjustment spacers 160 a head 110 and a flange 115. FIG. 8B illustrates an exploded view of the same club, showing the same components and their relationship to one another, plus the addition of optional gaskets. FIG. 8C illustrates the same club in an assembled cutaway view from nearer the heel. FIG. 8D shows an alternative embodiment of a center shafted putter design with a hosel shaft connector 140, a pair of upper adjustment spacers 150, an upper connection screw 170, a hosel mid-section 129, a pair of lower adjustment spacers 160 the head 110 and flange 115 and lower connection screw 180. FIG. 8E illustrates yet another embodiment showing an optional longer length hosel mid-section 129. An alternative embodiment replaces the upper screw 170 and lower screw 180 with a long bolt connecting the head 110 to the hosel shaft connector piece 140. It is contemplated that the hosel mid-section could take many shapes to provide different hosel geometries, including curved to provide more offset, lie angle and balance adjustment options. In such cases, the upper screw could be made of a flexible steel cable with threaded terminal end and drive head end permanently affixed by welding for instance.
(52) FIG. 9A illustrates an alternative embodiment of a set of cylindrical adjustment spacers 150 with a locating pin 156 in each spacer's lower wall. The degree of angle change can be seen in markings 159 on the side of the spacer where the angle change is oriented. The pins 156 engage with pin ports 158 to allow precise location of the spacers in relation to the golf club and other modular hosel components and help lock the entire system in place for use. FIG. 9B shows a single spacer from 9A, where the features including the pin ports, in this case four pin ports 158 can more easily be seen. FIG. 9C shows the underside of the same spacer where the locating pin 156 can more clearly be seen. FIG. 9D illustrates another alternative embodiment of the adjustment spacer 155 where indents or notches 255 are formed in the interior side walls of the spacer that engage with the hosel shaft connector piece, for instance. FIG. 9E illustrates a matching alternative embodiment hosel shaft connector piece 240 that features a rib 340 on the exterior of the hosel shaft connector stem 242 that will mate with and ride inside the curved notches 255 in the adjustment spacer 155 shown in FIG. 9D.
(53) FIG. 10A illustrates a cutaway close up view of hosel in head port construction showing the hosel shank 123, hosel lower stem 122, hosel lower stem flat 222, a pair of optional lower adjustment spacers 160, a head hosel port 190, an optional lower connection screw retaining ring 172 (cut away), a hosel port connection screw through bore 318, a washer 182 and a lower connection screw 180.
(54) As can be seen in the close up cutaway view in FIG. 10A, the counter bore 196 is preferably made with an end mill, where the cutting edges of the tool extend further at the ends and shallower toward the middle, which is common for these tools, and thus produces a convex upper wall 198 to the counter bore 196. Some putters have hosel connection screw port counter bores that are deeper on the outside of the counter bore and are more shallow towards the center through bore. This creates a semi-convex surface for the screw head, or washer to contact, and facilitates the various angles the screw is positioned in when the angled spacers change the axis of the hosel and shaft, providing a larger surface area and less load bearing stresses on the screw head and shank and/or washer or locking washer.
(55) FIG. 10B shows an alternative embodiment, utilizing a screw 280 inserted into or formed with the hosel stem 122, shown inside the head's hosel port 172, and optional adjustment spacers 160. An optional washer 182 or locking washer (not shown) can be utilized in the construction with a nut or locking nut used to complete the assembly for use. An alternative to a bolt 181 or screw 180 would be a hosel shaft connector piece or portion of the shaft tip that is stepped down and threaded and replaces the reverse direction bolt, but still being assembled with a nut, locking nut, nut and locking washer, etc.
(56) Alternately, a pin, set screw or key can be inserted from the outside, for instance the face, back or heel, or from an adjacent position on the sole, to orient and secure the hosel in a redundant manner from the main central screw connection. Alternatively, the stem could be firmly affixed with a latch or tab, a locating pin or pins, one or more set screws either with or without the use of a flat, channel or rib associated with or within the mortised section between the stem and the head hosel port sections.
(57) As an alternative to a modular hosel, the shaft, or optional shaft tip connector can be a female “shaft over” version that connects to a male spud or stud that is either formed as part of the head or affixed or connected to the head. If the later connected version, the stud can be connected from the side or underneath the head and thus be interchangeable for length, for instance, providing similar benefits to the hosel connected through a port in the heel of the head as previously described.
(58) The addition of additional spacer sections to the upper and/lower hosel portion are performed in a “fixed” manner with a specialized tool as dictated by the rules of golf so it can be deemed conforming under the Rules of Golf. To make the assembly conforming to the current Rules of Golf as administered by the USGA and R&A, and secured for continuous play and lessening the chance of the screw working loose, a small amount of epoxy can be placed on the tip of the screw after all changes are made to the configuration of components. Alternatively, a thread locking compound such as Locktite® brand thread locker can be placed on the screw tip. For additional strength and durability, epoxy can be used inside the lower hosel and/or upper hosel ports to provide a semi-permanent construction. Some customers may prefer this solution once all specifications have been fit and if they don't intend to make adjustments afterwards. However, these epoxy bonds can be heated and disassembled later if so desired.
(59) Referring back to FIG. 3A shows an embodiment with a modified design of the lower hosel stem 122 that provides a user-adjustable construction wherein the hosel can only be assembled in the correct orientation with the head. This is necessitated by Rules of Golf that require all forms of adjustment to be within conforming specifications, including the orientation of hosel and especially shaft lean in relation to the striking face, if the parts are to be user-adjustable. In particular, the Rules do not allow a club's shaft to lean forward or rearward more than 10 degrees. Therefore, a flat, rib, key, pin, screw, channel or other similar feature will restrict the orientation of the hosel to the correct alignment only, while still allowing the optional spacers to be assembled, rotated and adjusted without restriction.
(60) The exterior rounded comer square matches closely visually with traditional hosel square or rectangular stem shape. A square with rounded comers facilitates milling the internal section to mate with the male stem and have large flats to resist twisting. Alternate means for locating and assembling the hosel section inside the head can also be utilized, especially where a bent-neck, plumber neck and the like are selected and for USGA conformance for user-adjustability, such as a key, tab, pin, set screw, bolt, bolts, screw or screws. A rectangular mortice joint can be used as an alternative to the square spacer with rounded comers. However, a rectangular solution is not as efficient as the adjustment spacers would have to be made differently for loft and lie adjustments since they couldn't be orientated in all four directions for stronger or weaker loft or for upright or flat lie angles.
(61) One embodiment is to manufacture the upper hosel shaft tip connector from lightweight aerospace quality alloys such as 6061, 2024 or 7075 Aluminum Alloy, preferably heat treated and then anodized after manufacture for added strength and durability. Other materials such as steel, titanium, titanium alloy, bronze, aluminum bronze, graphite composite, tungsten, ceramic, metal matrix composite or magnesium or other material compositions can be utilized for weight and strength advantages.
(62) The upper spacer adjuster sections are preferably turned on a precision lathe, such as a tool room lathe or engine lathe, or most preferably a CNC lathe. Bar stock raw material, such as 303 Stainless Steel, can be used where the outside diameter is the same net size of the finished product, and then the stepped down sections are turned down on the lathe and then parted off. Live tooling can be used to cut the inner mortised sections or those can be cut in a secondary operation on a manual or CNC mill for instance. Alternatively, the upper hosel adjustable spacers could be extruded with around or other shaped exterior, and around cornered square or other shape inner shape into a hollow tube or hollow bar stock that is then milled or turned and parted into the final shape. Another alternative manufacturing process would be to precision cast the parts.
(63) The lower spacer adjuster sections are preferably milled in a milling center, such as a CNC vertical or horizontal machining center, and commonly available bar stock is used to make a number of adjustment spacers at one time in a vice in the machining center or in a special fixture. Bar stock raw material, such as 303 Stainless Steel, can be used where the outside dimension is near net to the max dimension of the finished part, and minimal machining time is needed and there is low waste and fewer chips to be recycled. By milling all the squares flat upper surfaces, the changes can all be made in a second and final operation limiting setup and down time. Alternatively, the sides of the female mortised joint and/or the sides of the male tenon section can be machined with a slight taper to facilitate a tight bond between the parts when the screw or other tightening connection mechanism is employed. Alignment markings can be engraved during the final milling operation to permanently identify the angle orientation on the exterior surfaces of the various components.
(64) Alternatively, the lower adjustment spacers could also be turned on a lathe or CNC lathe. If the raw round bar stock's outer diameter is the same net size of the rounded corners of the finished product, and then the flat side sections could be milled off with live tooling on the lathe and then parted off. Live tooling can be used to cut the inner mortised sections or those can be cut in a secondary operation on a manual or CNC mill for instance.
(65) Alignment markings, graphics and other information and designs can be engraved, laser engraved, stamped or printed on the exterior surfaces of the various components in the assembly. Paint can be applied to the stamped or engraved portions to make them more visible.
(66) Having thus described the subject matter by reference to certain of its preferred embodiments, it is noted that the embodiments disclosed are illustrative rather than limiting in nature and that a wide range of variations, modifications, changes, and substitutions are contemplated in the foregoing disclosure and, in some instances, some features of the disclosure may be employed without a corresponding use of the other features. Many such variations and modifications may be considered obvious and desirable by those skilled in the art based upon a review of the foregoing description of preferred embodiments. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the disclosure.
