Patent Publication Number: US-10780329-B2

Title: Multi-component golf club wedge

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation-in-part patent application of U.S. patent application Ser. No. 14/876,731 filed Oct. 6, 2015, the contents of which are expressly incorporated herein by reference. 
    
    
     STATEMENT RE: FEDERALLY SPONSORED RESEARCH/DEVELOPMENT 
     Not Applicable 
     BACKGROUND 
     1. Technical Field 
     The present disclosure relates generally to a golf club head, and more specifically, to a golf club head having a main body adapted to be selectively attached to one of a plurality of detachable plates or inserts to modify the structural characteristics of the club head for purposes of achieving desired performance characteristics. 
     2. Description of the Related Art 
     It is well known that the physical properties of a golf club have a significant impact on how the club “feels” during use. One particular term commonly used in the golf industry in reference to the way a club performs or feels during use is the “effective bounce” of the golf club. The effective bounce of a golf club is typically not dictated by a single physical characteristic of the golf club. Rather, the effective bounce relates to several club head factors, such as the sole length, sole width, “take-off angle” (as described in further detail below), etc. A golfer&#39;s preferred effective bounce may be dictated by the golfer&#39;s particular swing characteristics, as well as the playing conditions of the golf course. For instance, low bounce wedges may be preferred for shots off tight lies and in bunkers with very little or very firm sand, as well as for golfers with very steep swings. High bounce wedges may be preferred from the rough, soft lies, bunkers with lots of sand or very soft sand, as well as for golfers with generally flat swings. 
     In view of the variability associated with effective bounce, golf club manufacturers have designed various club heads having different bounce characteristics. Bounce variability in club heads is particularly prevalent in relation to the design of wedge-type golf clubs. Along these lines, many currently commercially available wedges of a prescribed loft are provided in separate low, medium and high bounce models, the design of any particular wedge being limited to a prescribed effective bounce. Thus, if a golfer wants, for example, to take advantage of high bounce and low bounce wedges to accommodate e.g., differing course conditions, typically several different wedges of the same loft much be purchased since, as indicated above, current conventional wedge designs do not accommodate any bounce variability. Furthermore, players desiring to be fit for proper club head sole characteristics, e.g., bounce angle, are typically inconvenienced by a lack of test clubs have simple back and forth sole adjustment to accommodate such fitting. 
     Accordingly, there is a need for a club head, and more particularly a wedge, which provides adaptability in the effective bounce associated with the club head. Various aspects of the present disclosure address this particular need, as will be discussed in more detail below. 
     BRIEF SUMMARY 
     In accordance with one embodiment of the present disclosure, there is provided an iron-type (and more particularly a wedge-type) golf club head assembly kit including a main body, a first sole component and a second sole component interchangeably associable with the main body. The main body includes a striking face having a face center, a leading edge, a virtual striking face plane. The main body also has a rear surface opposite the striking face, and a hosel defining a hosel axis. When the first sole component is associated with the main body, the main body and the first sole component collectively form a first club head comprising a sole surface having a first parting line formed between the first sole component and the main body, and a first sole contour. When the first club head is oriented in a reference position, in a virtual central vertical plane passing through the face center and perpendicular to the striking face plane, in a direction perpendicular to the virtual striking face plane, the parting line is spaced rearwardly from the striking face by a distance D1 and the club head has a maximum depth D2 such that D1/D2 is no less than 0.40. When the second sole component is associated with the main body, the main body and the second sole component collectively form a second club head comprising a second sole surface having a second parting line, formed between the second sole component and the main body, and a second sole contour that differs from the first sole contour. 
     The golf club head assembly kit may further include a screw member having a screw head and a screw shaft that defines a screw shaft axis. The screw member may be configured to secure one of the first or second sole components to the main body to form a corresponding one of the first and second club heads such that when either of the first and second club heads is oriented in the reference position, the screw shaft axis intersects a virtual vertical hosel plane that contains the hosel axis at a screw shaft angle of between about 75° and about 110°. 
     When the golf club head assembly is configured as first club head, and such first club head is oriented in the reference position, in the virtual central vertical plane, and measured in the direction perpendicular to the virtual striking face plane: (a) the first sole component may further comprise a forward-most point defining a sole component forward plane parallel to the striking face plane and a rearward-most point defining a sole component rearward plane parallel to the striking face plane; (b) a plane passing through the first parting line and parallel to the striking face plane may be rearwardly spaced from the sole component forward plane by a distance D3; and (c) the sole component rearward plane may be rearwardly spaced from the sole component forward plane by a distance D4 such that D3/D4 is no less than 0.30. 
     When the first club head is oriented in the reference position, in the virtual central vertical plane, the parting line may be rearwardly spaced from the leading edge by a horizontal distance of no less than 0.35 in. 
     The first club head may further comprise a loft angle no less than 38°. 
     When respectively oriented in the reference position, the first club head may include a first leading edge height and the second club head may include a second leading edge height that differs from the first leading edge height by at least 0.15 mm. 
     According to another aspect of the disclosure, there is provided an iron-type golf club head, such as a wedge-type golf club head that, when oriented in a reference position, comprises a main body and a sole component removably secured to the main body. The main body includes a striking face having a face center, a leading edge, a virtual striking face plane. The main body also includes a rear surface opposite the striking face, and a hosel defining a hosel axis. A sole surface is collectively formed by the main body and the sole component, with the sole surface having a sole contour, and a first parting line formed between the sole component and the main body. In a virtual central vertical plane passing through the face center and perpendicular to the virtual striking face plane, measured in a direction perpendicular to the striking face, the parting line is spaced rearward from the striking face by a distance D1 and the club head has a maximum depth D2 such that D1/D2 is no less than 0.50. 
     It is contemplated that D1/D2 may be no less than 0.70. 
     The golf club head may further comprise a virtual vertical hosel plane that includes the hosel axis, and a fastener configured to secure the sole component to the main body. 
     In yet another implementation of the present disclosure, there is provided an iron-type golf club head, such as a wedge-type golf club head that, when oriented in a reference position, comprises a main body and a sole component removably secured to the main body. The main body includes a striking face having a face center, a leading edge, and a virtual striking face plane. The main body also includes a rear surface opposite the striking face, and a hosel defining a hosel axis. A sole surface is collectively formed by the main body and the sole component, with the sole surface having a sole contour and a first parting line formed between the first sole component and the main body. In a virtual central vertical plane passing through the face center and perpendicular to the virtual striking face plane, the parting line is spaced rearwardly from the striking face by a horizontal distance D5 that is no less than 0.35 in. 
     D5 may be between about 0.40 in and 0.70 in. 
     In the virtual central vertical plane, the sole surface may further comprise a sole surface horizontal length D6 such that D5/D6 is no less than 0.50. D5/D6 may also be no less than 0.60. 
     According to another aspect of the disclosure, there is provided an iron-type golf club head that, when oriented in a reference position relative to a virtual ground plane, comprises a main body including a topline, and a sole in generally opposed relation to the topline, with at least a portion of the sole resting on the ground plane when the golf club head is in the reference position. The main body further includes a striking face extending between the topline and the sole and a rear face in generally opposed relation to the striking face. A rear cavity extends from the rear face toward the striking face, and a sole cavity extends into the sole. The golf club head further comprises at least one rear plate removably secured within the rear cavity along a first axis, and at least one sole plate removably secured within the sole cavity. The golf club head includes a center of gravity vertically spaced from the virtual ground plane by between 13.5 mm and 16.0 mm. 
     The rear plate may include a first pair of opposed faces which are substantially parallel to each other to define a substantially uniform rear plate thickness therebetween. The sole plate may include a second pair of opposed faces which are substantially parallel to each other to define a substantially uniform sole plate thickness therebetween. 
     In accordance with an alternative implementation, the rear plate may include a pair of opposed faces which are non-parallel to each other to define a variable rear plate thickness therebetween. Furthermore, the sole plate may include a pair of opposed faces which are non-parallel to each other to define a variable sole plate thickness therebetween. At least one of the rear plate thickness and the sole plate thickness may vary in a vertical direction when the club head is in the reference position. At least one of the rear plate thickness and the sole plate thickness may vary in the heel to toe direction when the club head is in the reference position. 
     The club head may include at least one of a rear plate fastener configured to couple the at least one rear plate to the main body, and a sole plate fastener configured to couple the at least one sole plate to the main body. At least one of the rear plate fastener and the sole plate fastener may include a threaded screw member. At least one of the rear plate fastener and the sole plate fastener may include a magnet. 
     At least one of the at least one rear plate and the at least one sole plate may be formed from tungsten. 
     The present disclosure will be best understood by reference to the following detailed description when read in conjunction with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       These and other features and advantages of the various embodiments disclosed herein will be better understood with respect to the following description and drawings, in which: 
         FIG. 1  is a rear exploded perspective view of an iron-type or wedge type golf club head having a detachable sole component exploded from a main body; 
         FIG. 2  is an assembled rear perspective view of the golf club head shown in  FIG. 1 ; 
         FIG. 3  is a front view of the golf club head shown in  FIG. 2 ; 
         FIG. 4  is a toe side view of the golf club head shown in  FIGS. 2 and 3  with the sole component being attached to the main body; 
         FIG. 5  is a rear view of the golf club head shown in  FIGS. 2-4  with the sole component being attached to the main body; 
         FIG. 6  is a side sectional view of the golf club head taken along line  6 - 6  as shown in  FIG. 5 ; 
         FIG. 7  is a side sectional view of the golf club head taken along line  7 - 7  as shown in  FIG. 5 ; 
         FIG. 8  is an exploded side sectional view of the golf club head taken along line  8 - 8  as shown in  FIG. 5 ; 
         FIGS. 9-11  are assembled side sectional views of the golf club head taken along line  9 - 9  as shown in  FIG. 5 , each highlighting different parameters of the club head; 
         FIG. 12  is an enlarged, partial side sectional view of the club head having a first sole component coupled to the main body; 
         FIG. 13  is an enlarged, partial side sectional view of the club head having a second sole component coupled to the main body; 
         FIG. 14  is an enlarged, partial side sectional view of the club head having a third sole component coupled to the main body; 
         FIGS. 15 and 16  are perspective views of a club head having a main body and a first embodiment of a rear plate and sole plate set attached to the main body; 
         FIG. 17  is a cross sectional view of the club head depicted in  FIGS. 15 and 16 ; 
         FIGS. 18 and 19  are perspective views of a club head having a main body and a second embodiment of a rear plate and sole plate set attached to the main body; 
         FIG. 20  is a cross sectional view of the club head depicted in  FIGS. 18 and 19 ; 
         FIGS. 21 and 22  are perspective views of a club head having a main body and a third embodiment of a rear plate and sole plate set attached to the main body; 
         FIG. 23  is a cross sectional view of the club head depicted in  FIGS. 21 and 22  taken within a first cross sectional plane to depict the sole plate coupled to the main body; and 
         FIG. 24  is a cross sectional view of the club head depicted in  FIGS. 21 and 22  taken within a second cross sectional plane to depict the rear plate coupled to the main body. 
     
    
    
     Common reference numerals are used throughout the drawings and the detailed description to indicate the same elements. 
     DETAILED DESCRIPTION 
     The detailed description set forth below in connection with the appended drawings is intended as a description of certain embodiments of an adjustable iron-type golf club head, and in particular an adjustable rear and/or sole portion of a wedge-type golf club head, and is not intended to represent the only forms that may be developed or utilized. The description sets forth the various structure and/or functions in connection with the illustrated embodiments, but it is to be understood, however, that the same or equivalent structure and/or functions may be accomplished by different embodiments that are also intended to be encompassed within the scope of the present disclosure. For example, while the present disclosure find particularly utility in relation to wedge type golf clubs, the structural and functional features described below may be applied to other iron-type golf club heads as well. It is further understood that the use of relational terms such as first and second, and the like are used solely to distinguish one entity from another without necessarily requiring or implying any actual such relationship or order between such entities. All recitations of parameter values as “approximate” values are intended to serve as implicit recitations of the precise values of such parameters as optional characteristics of the one or more embodiments to which they pertain. 
     Referring to  FIGS. 1-4  and according to one embodiment, there is depicted a golf club head  10  having a main body  12  adapted to be interchangeably attachable to one of a plurality of different sole components to attain a preferred “feel” for the player using the club head  10  based e.g. on a prescribed alteration in the “bounce” of the club head. In particular, the different sole components each define different structural characteristics, such that each sole component provides a different bounce relative to the other sole components when attached to the main body  12 . As described above, “bounce” as used herein denotes “effective bounce,” which, as described above, may not connote a specific single measureable aspect of a sole, but rather generally pertains to aspects of a golf club sole surface that may contribute to the way the club head feels based on interaction with turf and the way the club may sit when resting on turf in a static position. Classifications of bounce may, in some cases, be based on a single factor, e.g. take-off angle (as described below). However, for practical purposes, “effective bounce” classification conventionally accounts for a number of sole surface aspects that may or may not include take-off angle, sole width, front-to-rear sole camber, and heel-to-toe sole camber. Preferably classifications of effective bounce (and in turn distinctions in one or more interchangeable sole portions having different “bounce” characteristics) include at least differences in “take-off angle” and/or sole width. The user may select a particular sole component based on the user&#39;s swing characteristics, playing environment, or other factors. 
     The golf club head  10  is an iron-type golf club head, and more particularly a wedge, with the main body  12  including a striking face  16  and a rear surface  18  in opposed relation to the striking face  16 . The club head  10  preferably defines a blade portion being an upper portion and (via combination of the main body  12  and the sole component  14 ) a lower muscle portion associated with the blade portion. The blade portion preferably defines a striking wall thickness, “T,” between the striking and rear faces  16 ,  18 . According to various embodiments, the striking wall thickness T is preferably equal to approximately 0.15-0.50 inches, more preferably equal to 0.20-0.30 inches, and most preferably equal to approximately 0.22 inches. The striking face  16  includes a face center  20  and a leading edge  21 , and defines a striking face plane  22 , with the striking face  16  being adapted to repeatedly strike a golf ball during the lifespan of the club head  10 . In this respect, the striking face  16  may include a plurality of grooves to impart spin to the golf ball on impact and/or to displace water or grass from the face  16  to allow for more direct impact between the club head  10  and the golf ball. The main body  12  further includes a heel  24 , a toe  26 , a top line  28 , and an opposing sole  30 . A recess  31  (see e.g.  FIG. 1 ) extends into the main body  12  from the rear surface  18  adjacent the sole  30 , and is adapted to at least partially receive the sole component  14 , as will be described in more detail below. The main body  12  further includes a bore  33  extending into the main body  12  for attaching the sole component  14  to the main body  12 . The bore  33  may be formed within a boss  35  which protrudes from the recess  31  in rearward direction. The main body  12  is fabricated from a metallic material, by forging, casting, or through other manufacturing techniques known in the art. A hosel  32  is coupled to the main body  12 , extending from the heel  24  and defining a hosel axis  34 . The hosel  32  is adapted to engage with a club shaft. The golf club head  10  is said to be in a “reference position” relative to a virtual ground plane, e.g. ground plane  37 , when the hosel axis  34  is coplanar with an imaginary vertical hosel plane  35  that is perpendicular a virtual plane  22  that is perpendicular to the general plane of the striking face  16  and the scorelines extend generally parallel to the ground plane  37 . Unless otherwise indicated, all parameters herein are specified with the golf club head  10  in the reference position. 
     The main body  12  defines a loft angle, Φ, as the angle between the hosel plane  35  and the striking face plane  22 , as shown in  FIG. 4 . According to various embodiments, the loft angle Φ is preferably no less than 38°, even more preferably greater than 40°, still more preferably between 45° and 70°, and even more preferably between 55° and 60° and most preferably equal to approximately 56°. Golf club heads, e.g., iron-type club heads, of lofts within these ranges are particularly apt for sole contour adjustment provided an increased tendency to “dig” into the ground. 
     As noted above, the main body  12  is specifically adapted for interchangeable use with a plurality of differently configured sole components  14 , particular examples of which will be described in more detail below with reference to  FIGS. 12-14 . In this respect, the golfer may select which one of the plurality of sole components  14  to attach to the main body  12  to define the golf club head  10 , with each sole component  14  providing unique bounce and hence “feel” attributes when attached to the main body  12 . For instance, the different sole components  14  may have different dimensions and define different contours, which may create a distinctive feel of the club head  10 . It is also contemplated that the sole components  14  may have different weights, densities, materials or other structural distinctions aimed at creating distinctive attributes to the club head  10 , and notably the bounce characteristic described above. 
     In general, each sole component  14  includes an inner surface  36 , a top surface  38 , a bottom surface  40 , and a rear surface  42 , with the sole component  14  defining a heel portion and a toe portion. A counter-bore  48  is formed through the sole component  14  and defines a counter-bore axis  50 , which passes through the rear surface  42  and the inner surface  36 . 
     According to one embodiment, the sole component  14  may be attached to the main body  12  by positioning the sole component  14  within the recess  31 , with the inner surface  36  of the sole component  14  facing the main body  12 . The boss  35  may assist in properly locating the sole component  14  relative to the main body  12 , such that the counter-bore  48  is coaxially aligned with the bore  33  formed on the main body  12 . A mechanical fastener, such as a screw  52 , may be used to secure the sole component  14  to the main body  12 . The sole component  14  and main body  12  are preferably configured such that the sole component  14  abuts both an inner surface  36  of the recess  31 , a recess upper sidewall  31   a  and a recess lower sidewall  31   b . By configuring the sole component  14  to abut these respective recess sidewalls  31   a  and  31   b , the sole component  14  and main body  12  combination may be more likely to behave as a solid component upon an impact of the club head  10  with a golf ball during typical play. For example, slight movement (which may result in clicking) of the sole component may be further minimized due to the abutment of plural surfaces that are angled relative to each other (as opposed to abutment generally about a surface in a single plane). In this regard, feel is improved, enabling such an adjustable club head to be more likely accepted as a replacement for a similar non-adjustable type club head (which may likely actually be formed of a single unitary component). As a corollary, by providing a more solid feel, such an adjustable club head, if used as a fitting tool, is more likely to feel like a conventional purchasable non-adjustable club head to which such adjustable club head may have been intended to correspond. In this case, a golfer undergoing a bounce fitting is less likely to be disappointed that an actual purchased club does not feel like a test club intended to represent the purchased club (or at a minimum feel that the fitting operation was of little value). In some embodiments, at least one of (and in some cases both of) the sidewalls  31   a  and  31   b  of the recess  31  is tapered in complementary manner to a tapered portion of the upper surface  38  and lower surface  40  of the sole component  14 . In this manner, the association between the main body  12  and the sole component  14  may be made more snug and/or accommodate manufacturing tolerances. By solidly securing the sole portion  14  to the main body  12 , generating relatively thin regions in the sole component  12  (e.g. to blend into the blade portion of the club head) may be avoided. Such thin portions may be associated with propagating unwanted vibrations upon impact of the striking face  16  with a golf ball in typical use. 
     Referring now to  FIG. 5 , there is depicted a rear view of the club head  10  having one prescribed sole component  14  attached to main body  12 .  FIG. 6  is a side sectional view of the club head  10  shown in a transverse plane located adjacent the toe of the club head  10 , while  FIG. 7  is a side sectional view of the club head  10  shown in the transverse plane located adjacent the heel of the club head  10 . As is apparent, the size of the sole component  14  may vary in a heel to toe direction, with the sole component  14  having a larger cross sectional area proximate the heel than proximate the toe (and distal the heel). 
     The sole component  14  and main body  12 , when attached to each other, collectively define a sole surface  54  having a sole contour including a parting line  56  at the intersection of the main body  12  and sole component  14 . In view of the sole component  14  defining a portion of the sole surface  54 , the contour of the sole surface  54  may be varied by interchanging one sole component  14  for another. Along these lines, a set of at least three sole components  14   a ,  14   b  and  14   c  are shown in  FIGS. 12-14 . The at least three sole components  14   a ,  14   b , and  14   c  are interchangeably attachable to a main body  12  to vary contour of the sole surface formed between the main body  12  and the sole component (of the set of sole component  14   a ,  14   b , and  14   b ) that is secured to the main body  12 . When, for example, the first sole component  14   a  ( FIG. 12 ) is attached to the main body  12 , the first sole component  14   a  and main body  12  collectively form a first club head  10   a  including a first sole surface defining a first sole contour having a first parting line formed between the first sole component  14   a  and the main body  12 . If the first sole component  14   a  is removed and replaced with, for example a second sole component  14   b  ( FIG. 13 ), the main body  12  and the second sole component  14   b  collectively form a second club head  10   b , which differs from the first club head  10   a , and includes a second sole surface defining a second sole contour having a second parting line formed between the second sole component and the main body  12 . 
     Referring now specifically to  FIGS. 8 and 9 , there is depicted cross sectional views of the club head  10  taken within a cross sectional vertical plane which passes through the face center  20  and is perpendicular to the striking face plane  22 , with  FIG. 8  depicting an exploded view and  FIG. 9  depicting an assembled view. As can be seen, the sole component  14  is attached to the main body  12  via the screw member  52  having a screw head  58  and an externally threaded screw shaft  60  that defines a screw shaft axis  62 . According to one embodiment, there are preferably no less than three threads on the screw shaft  60 , and more preferably from 3-5 threads on the screw shaft  60 . Of course, other embodiments may include more than 5 threads on the screw shaft  60  without departing from the spirit and scope of the present disclosure. 
     The screw member  52  is configured to secure the sole component  14  to the main body  12  to form the club head  10  such that, when the club head  10  is oriented in the reference position, the screw shaft axis  62  intersects a virtual vertical hosel plane  64  that contains the hosel axis at a screw shaft angle, Θ, of between about 75° and about 110°, more preferably between 80°-100°, and more preferably equal to about 90°. Along these lines, the bore  33  is internally threaded and configured to engage with the external threads on the screw shaft  60 , with the bore  33  being disposed about a bore axis  66 , which is equal to the screw shaft angle Θ. The bore  33  extends into the main body  12  deep enough to allow for a sufficient number of thread turns. The counter-bore  48  formed in the sole component  14  includes a first section that is of a first diameter larger than the diameter of the screw shaft  60  and smaller than the diameter of the screw head  58 , and a second section that is of a second diameter larger than the diameter of the screw head  58 , such that when the screw is completely advanced into the bore  33 , the screw head  58  is received within the second section of the counter-bore  48 , as shown in  FIG. 9 . According to one embodiment, the screw head  58  is a socket-style screw head, which matches the tool socket for adjustable/removable shaft securing screws, although it is understood that the screw head  58  may be a Phillips-head-style screw head, flat-head-style screw head, or a socket adapted to operably engage with a wrench, allen wrench, allen key, torx wrench, a wrench having a polygonal cross-section, a wrench having a proprietary cross-sectional shape, or other types of screw heads known in the art. In some embodiments a set of sole components may be offered in combination with the main  12  and/or a corresponding fastening tool to appropriately secure any of the sole components  14   a ,  14   b  and  14   c  to the main body  12 . Such a tool may comprise a conventional screw driver, wrench, allen wrench, allen key, torx wrench, a wrench having a polygonal cross-section, a wrench having a proprietary cross-sectional shape, or the like. In one or more embodiments, the fastening tool includes a torque-sensing device and, optionally, an indicator for indicating, to the user, the current torque being applied to the fastener and/or when a threshold torque has been reached or exceeded. Furthermore, the main body  12  and sole component  14  are adapted to enable to the sole component  14  to be attached to the main body  12  via a single screw member  52 , which provides simplicity and ease of use, and allows for quick and easy interchangeability of the sole component  14  to the main body  12 . The configuration of the bore  33 , counter-bore  48  and the screw member  52  may also reduce “clicking” during use by virtue of plural points of contact therebetween. This configuration, particularly the case in which the screw bore  33  extends from the rear surface of the sole component  14  at an angle within the ranges of angles described above, ensures that the screw enters the main body  12  in a location and in a direction aligned with a relative thick portion of the club head  12 . This allows diminished presence of thin walls and/or unnecessary “hollowing” of the main body  12 , which may promote beneficial feel. Also, orienting the screw bore  33  in this manner ensures that a relative lengthy portion of screw material is secured to the main body  12 , further enabling a solid association of the sole component  14  and the main body  12 , promoting beneficial feel and ensuring the structural integrity of the multi-component club head system. 
     It is also contemplated that an optional tape layer or other adhesives may be used in addition to the screw member  52  to couple the sole component  14  to the main body  12 . The tape layer may improve the feel and further reduce “clicking,” although in most instances, the use of the screw member  52  without an additional tape layer may be considered sufficient. 
     According to another embodiment, a captive screw may be used to secure the sole component  14  to the main body  12 . The use of a captive screw may permit unthreading to remove the sole component  14  while keeping the screw retained in the main body  12 . 
     It is further contemplated that the sole component  14  and main body  12  may be coupled using any fastening element or technique known in the art. For instance, the sole component  14  may be coupled to the main body  12  using one or more magnets, or a screw having a spring to enable quick release or quick-turn options in reducing the time associated with interchanging sole components. 
       FIGS. 10 and 11  are reproductions of the club head  10  shown in  FIG. 9 , for purposes of illustrating various dimensions and parameters associated with the club head  10 . With reference specifically to  FIG. 10 , the sole component  14  includes a forward-most point defining a sole component forward plane  68  parallel to the striking face plane  22  and a rearward-most point  70  defining a sole component rearward plane  72  parallel to the striking face plane  22 . The club head  10  further includes a plane  74  passing through the parting line  56  and parallel to the striking face plane  22 . The distance between the striking face plane  22  and the plane  74  passing through the parting line  56  defines a distance D1. The distance between the striking face plane  22  and the sole component rearward plane  72  defines a distance D2, and a maximum depth. The distance between the sole component forward plane  68  and the plane passing through the parting line  56  defines a distance D3. The distance between the sole component forward plane  68  and the sole component rearward plane  72  defines a distance D4. 
     According to one embodiment, the distance D1 is preferably greater than or equal to approximately 0.25 inches, and more preferably greater than or equal to approximately 0.35 inches, even more preferably between approximately 0.40 inches and 0.60 inches, still even more preferably between approximately 0.42 inches and 0.50 inches, and most preferably equal to approximately 0.47 inches. 
     According to another embodiment, the distance D2 is preferably greater than or equal to approximately 0.50 inches, more preferably between approximately 0.60 inches and 0.75 inches, and most preferably equal to approximately 0.63 inches. 
     According to still another embodiment, the distance D3 is preferably greater than or equal to approximately 0.25 inches, more preferably between approximately 0.30 inches and 0.40 inches, and most preferably equal to approximately 0.35. 
     According to yet another embodiment, the distance D4 is preferably greater than approximately 0.35 inches, more preferably between approximately 0.45 inches and 0.60 inches, and most preferably equal to approximately 0.51 inches. 
     In addition to the foregoing dimensions, there are several preferred ratios associated with the club head  10 . According to one embodiment, the ratio of D1/D2 is preferably greater than or equal to approximately 0.40, more preferably greater than or equal to approximately 0.50, even more preferably greater than or equal to approximately 0.70, and most preferably equal to approximately 0.74. The ratio of D3/D4 is preferably greater than or equal to approximately 0.30, more preferably greater than or equal to approximately 0.50, even more preferably greater than or equal to 0.60, yet more preferably greater than or equal to approximately 0.65, and most preferably equal to approximately 0.68. By configuring the adjustable club head  10  in this regard, the parting line proximate the sole surface  54  is relatively rearward with respective to the club head  10 . This minimizes the possibly-detrimental effect of the parting line on feel as it is located at or near a point of primary turf interaction. Accordingly, the above described configurations enable such an adjustable club head to be more likely accepted as a replacement for such a typical non-adjustable club head. As a corollary, by providing a more similar feel, such an adjustable club head  10 , if used as a fitting tool, is more likely to feel like a conventional purchasable non-adjustable club head to which such adjustable club head  10  may have been intended to correspond. In this case, a golfer undergoing, e.g., a bounce fitting is less likely to be disappointed that an actual purchased club does not feel like a test club intended to represent the purchased club (or at a minimum feel that the fitting operation was of little value). 
     Referring now to  FIG. 11 , the club head  10  formed by the combined main body  12  and sole component  14  defines a center of gravity  76  which is spaced perpendicularly from the striking face plane  22  by a distance CG 1  and is elevated above the ground plane  37  by a distance CG 2 . According to one embodiment, CG 1  is preferably equal to approximately 1-5 mm, more preferably equal to approximately 2-4 mm, and still more preferably equal to approximately 2.2 mm, while CG 2  is preferably equal to approximately 10-25 mm, more preferably equal to approximately 15-20 mm, and still more preferably approximately 17.5 mm. Configuring the adjustable club head  10  in this regard enables such adjustable club head to be more likely accepted as a replacement for such a typical non-adjustable club head. As a corollary, by providing a more similar feel, such an adjustable club head  10 , if used as a fitting tool, is more likely to feel like a conventional purchasable non-adjustable club head to which such adjustable club head  10  may have been intended to correspond. In this case, a golfer undergoing, e.g., a bounce fitting is less likely to be disappointed that an actual purchased club does not feel like a test club intended to represent the purchased club (or at a minimum feel that the fitting operation was of little value). 
     Furthermore,  FIG. 11  illustrates that in the virtual central vertical plane, the parting line  56  is spaced rearwardly from the leading edge  80  of the striking face by a horizontal distance, D5, and the sole surface comprises a sole surface horizontal length, D6. The distance D5 is preferably greater than or equal to approximately 0.35 inches, more preferably between approximately 0.40-0.70 inches, and most preferably equal to about 0.51 inches. The sole surface horizontal length D6 is preferably greater than or equal to approximately 0.50 inches, more preferably between approximately 0.70-1.00 inches, and most preferably equal to approximately 0.815 inches. According to one embodiment, the ratio of D5/D6 is greater than or equal to approximately 0.50, more preferably between approximately 0.55-0.70, even more preferably between approximately 0.60-0.65, and most preferably equal to approximately 0.63. 
       FIG. 11  further depicts a “take-off” angle, β, which is defined (in the virtual central vertical plane perpendicular to the striking face plan and passing through a ground contact point  82 ) as the angle between a line  78  (passing through the leading edge  80  and the ground contact point  82 ) and the ground plane  37 . According to one embodiment, the take-off angle β is preferably equal to approximately 40-60°, more preferably equal to approximately 45-55°, and most preferably equal to approximately 51°. 
     The club head  10  preferably is of a head mass that is greater than or equal to approximately 200 g, more preferably between 240-300 g, even more preferably between 250-290 g, and most preferably equal to approximately 276 g. Furthermore, according to one embodiment, the moment of inertia through the center of gravity  76  about a vertical axis when the club head  10  is in the reference position is no less than approximately 3000 g*cm 2 , more preferably no less than approximately 3400 g*cm 2 , even more preferably between approximately 3500-3800 g*cm 2 , and most preferably equal to approximately 3600 g*cm 2 . By configuring the adjustable club head  10  in this regard, the feel of the club head may be more similar to a typical non-adjustable unitary club head, enabling such an adjustable club head to be more likely accepted as a replacement for such a typical non-adjustable club head. As a corollary, by providing a more similar feel, such an adjustable club head  10 , if used as a fitting tool, is more likely to feel like a conventional purchasable non-adjustable club head to which such adjustable club head  10  may have been intended to correspond. In this case, a golfer undergoing, e.g., a bounce fitting is less likely to be disappointed that an actual purchased club does not feel like a test club intended to represent the purchased club (or at a minimum feel that the fitting operation was of little value). 
     Referring now to  FIGS. 12-14 , there is depicted enlarged, partial, cross sectional views of three club heads  10   a - 10   c  formed with respective ones of three different, exemplary sole components  14   a - 14   c . Referring first to  FIG. 12 , the first sole component  14   a  is coupled to the main body  12  to define the first club head  10   a . The first sole component  14   a  defines a first ground contact point  82   a  where the first sole component  14   a  intersects with the ground plane  37   a , which defines a first take-off angle, β 1 , between the ground plane  37   a  and an axis passing through the first ground contact point  82   a  and the leading edge  80 . The first ground contact point  82   a  and the leading edge  80  define a first leading edge height, H 1 . The first sole component  14   a  further defines a first grind  84   a , which extends rearwardly from the first ground contact point  82   a  and terminates at a first rearward-most point  70   a , which is elevated above the ground plane  37   a  by a first grind height, G 1 . 
     Referring now to  FIG. 13 , the second sole component  14   b  is coupled to the main body  12  to define the second club head  10   b . The second sole component  14   b  defines a second ground contact point  82   b  where the second sole component  14   b  intersects with the ground plane  37   b , which defines a second take-off angle, β 2 , between the ground plane  37   b  and an axis passing through the second ground contact point  82   b  and the leading edge  80 . The second ground contact point  82   b  and the leading edge  80  define a second leading edge height, H 2 . The second sole component  14   b  further defines a second grind  84   b , which extends rearwardly from the second ground contact point  82   b  and terminates at a second rearward-most point  70   b , which is elevated above the ground plane  37   b  by a second grind height, G 2 . 
     Referring now to  FIG. 14 , a third sole component  14   c  is coupled to the main body  12  to define a third club head  10   c . The third sole component  14   c  defines a third ground contact point  82   c  where the third sole component  14   c  intersects with the ground plane  37   c , which defines a third take-off angle, β 3 , between the ground plane  37   c  and an axis passing through the third ground contact point  82   c  and the leading edge  80 . The third ground contact point  82   c  and the leading edge  80  define a third leading edge height, H 3 . The third sole component  14   c  further defines a third grind  84   c , which extends rearwardly from the third ground contact point  82   c  and terminates at a third rearward-most point  70   c , which is elevated above the ground plane  37   c  by a third grind height, G 3 . 
     The first, second, and third sole components  14   a - c  each define respective contours, which modify the overall structural characteristics of the first, second, and third club heads  10   a - c , with the aim being to provide different bounce characteristics for each club head  10   a - c . In some cases, as shown a rear portion of the sole is ground to varying degrees. By increase the degree of grinding, the location of sole contact may vary, resulting in changes to take-off angle β and leading edge height H. More specifically, for instance, according to one embodiment, the location of the first ground contact point  82   a  relative to the main body  12  differs from the location of the second and third ground contact points  82   b ,  82   c , with the location of the first ground contact point  82   a  being located closer to the leading edge  80  than the location of the second and third ground contact points  82   b ,  82   c . Furthermore, the leading edge height may vary from one club head to the next. For instance, the first leading edge height H 1  may be smaller than the second and third leading edge heights H 2  and H 3 . According to various embodiments, the first leading edge height H 1  varies from the second and/or third leading edge heights H 2 , H 3  by an amount Δ, which is approximately equal to 0.15-0.40 mm, more preferably equal to approximately 0.20-0.25 mm, and most equal to approximately 0.218 mm. According to one embodiment, the first leading edge height H 1  is less than the second and/or third leading edge heights H 2 , H 3  by the amount Δ. Moreover, the grind heights, G 1-3 , may vary between the sole components  14   a - c , such that in one implementation, the first grind height G 1  is greater than the second grind height G 2  and the third grind height G 3 . By configuring the adjustable club head  10  in this regard, the feel of the club head may be more similar to a typical non-adjustable unitary club head, enabling such an adjustable club head to be more likely accepted as a replacement for such a typical non-adjustable club head. As a corollary, by providing a more similar feel, such an adjustable club head  10 , if used as a fitting tool, is more likely to feel like a conventional purchasable non-adjustable club head to which such adjustable club head  10  may have been intended to correspond. In this case, a golfer undergoing, e.g., a bounce fitting is less likely to be disappointed that an actual purchased club does not feel like a test club intended to represent the purchased club (or at a minimum feel that the fitting operation was of little value). 
     The various sole components  14   a - c  may provide certain benefits in different playing environments and/or for players having different swing characteristics. For instance, the first sole component  14   a  may be preferable when playing from firm conditions and tight lies. The first sole component  14   a  may also be more suitable for players with shallow attack angles. The second sole component  14   b  may be most accommodating for the largest variety of sand, turf and swing types. The third sole component  14   c  may be preferred when used on softer turf conditions and bunkers, or for use with players having a steep attack angle. 
     The ability to interchange the sole components  14   a - c  enables a user to easily test different feels, and thus, the sole components  14   a - c  effectively provide three club heads in one. A user may quickly move between different bounces with a single club by swapping one sole component  14  (e.g., sole components  14   a ,  14   b ,  14   c ) for another. Furthermore, it is easier to carry around several sole components  14  than it is to carry several different clubs, particularly around the course or on tour. The sole components  14  are also easier to manufacture at a lesser cost than entirely separate club heads. In addition, some golfers become accustomed to a particular striking face, which has been “worked” over a period of time, and thus, the golfer may be able to use different sole components  14  with the same striking face to achieve different bounce characteristics, rather than switching to an entirely different club. 
     It is contemplated that the various components described herein may be sold as a kit, wherein the main body  12  is sold with a plurality of sole components  14 . The main body  12  may be sold in conjunction with a club shaft, or separate from a club shaft. It is further contemplated that the main body  12  and sole components  14  may be sold separate from each other. 
     Referring now to  FIGS. 15-24 , there is depicted another aspect of the present disclosure which provides further adaptability and customization of an iron-type golf club head  110 . While the embodiments depicted in  FIGS. 1-14  are primarily directed at varying the bounce of the club head through the use of interchangeable sole components  14 , with one sole component  14  being attached to the club head at any given time, the club heads  110  depicted in  FIG. 15-24  enable attachment of at least two plates or inserts  114 ,  116  to a club head main body  112  at any given time. Such adaptability may allow for additional customization (e.g., varying center of gravity location, creating desired weight distribution, etc.) to further accommodate the particular swing characteristics and preferences of the user. The plates  114 ,  116  may also allow a user to customize the look of the club head  110 , as the plates  114 ,  116  may be formed from different colors, or have specific logos or indicia emblazoned thereon. 
     The club heads  110  shown in  FIGS. 15-24  each generally include main body  112 , a rear plate  114 , and a sole plate  116 , with both plates  114 ,  116  being selectively attachable to the main body  112 . The main body  112  in each club head  110  shown in  FIGS. 15-24  is identical, while the configuration of the rear plates  114  and sole plates  116  vary, as will be described in more detail below. The main body  112  of each club head  110  includes a topline  118  and a sole  120  in generally opposed relation to the topline  118 , with at least a portion of the sole  120  resting on the ground plane  122  when the club head  110  is in the reference position. A striking face  124  extends between the topline  118  and the sole  120 , and a rear face  126  is in generally opposed relation to the striking face  124 . 
     The main body  112  cooperates with the rear plate  114  and the sole plate  116  via a rear cavity  128  and a sole cavity  130 , respectively, which are separated from each other by a partition  132  extending across the rear of the club head  110  between the heel  134  and toe  136 . According to one embodiment, when the club head  110  is in the reference position relative to the ground plane  122 , the partition  132  extends between the heel  134  and the toe  136  in a generally horizontal direction. 
     The rear cavity  128  extends in a first direction into the main body  112  from the rear face  126  toward the striking face  124  and terminates at a rear recessed surface  138  to define a rear cavity depth. The rear cavity  128  also extends in a second direction from the partition  132  toward the topline  118 , with the upper periphery  128   a  of the rear cavity  128  being similar in shape to, e.g. parallel with, the topline  118 . In this regard, the periphery of the rear cavity  128  adjacent the partition  132  (i.e. the lower periphery portion  128   b ) follows a generally linear path. In this manner, the lower periphery portion  128   b  of the rear cavity  128  generally follows, e.g. is parallel with, the junction between the blade portion of the club head and the muscle portion of the club head  110 . In the particular embodiment shown in  FIG. 15 , such junction is generally linear. However, in other embodiments, the junction between a club head blade portion and a muscle portion may be arcuate, having e.g. upward concavity or upward convexity. In such cases, the lower periphery  128   b  of the rear cavity  128  preferably follows the path of such junction. For example, in embodiments where the junction follows an upwardly concave path, the lower periphery  128   b  of the rear cavity  128  also preferably follows an upwardly concave path. In embodiments in which such junction follows an upwardly convex path, the lower periphery  128   b  of the rear cavity  128  also follows an upwardly convex path. These configurations ensure that maximum space is dedicated to removable mass, providing for a greater range of customizability. Of course, in alternative embodiments, the path of the lower periphery  128   b  of the rear cavity  128  does not follow the path of the junction between the blade portion and muscle portion of the club head  110  and may, for example, follow a mirror-image path. Similarly, in alternative embodiments, the path of the upper periphery portion  128   a  of the rear cavity  128  does not generally follow the path of the top line  118 , and may, for example, follow a mirror-image path. One or more threaded cavities or recesses may further extend into the main body  112  from the rear recessed surface  138  to facilitate attachment of the rear plate  114  to the main body  112  through the use of a mechanical fastener, as will be described in more detail below. 
     The sole cavity  130  extends into the sole  120  in a first direction from a sole rear surface  140  and terminates at a sole recessed surface  142  and in a second direction from the partition  132  toward a sole bottom surface  144 . In this regard, the periphery  130   a  of the sole cavity  130  adjacent the partition  132  (i.e. the upper periphery portion  130   a ) follows a generally linear path. In this manner, the upper periphery portion  130   a  of the sole cavity  130  generally follows, e.g. is parallel with, the junction between the blade portion of the club head and the muscle portion of the club head  110 . In the particular embodiment shown in  FIG. 15 , such junction is generally linear. However, in other embodiments, the junction between a club head blade portion and a muscle portion may be arcuate, having e.g. upward concavity or upward convexity. In such cases, the upper periphery  130   a  of the sole cavity  130  preferably follows the path of such junction. For example, in embodiments where the junction follows an upwardly concave path, the upper periphery  130   a  of the sole cavity  130  also preferably follows an upwardly concave path. In embodiments in which such junction follows an upwardly convex path, the upper periphery  130   a  of the sole cavity  130  also follows an upwardly convex path. These configurations ensure that maximum space is dedicated to removable mass, providing for a greater range of customizability. Of course, in alternative embodiments, the path of the upper periphery  130   a  of the sole cavity  130  does not follow the path of the junction between the blade portion and muscle portion of the club head  110  and may, for example, follow a mirror-image path. Similarly, in alternative embodiments, the path of the lower periphery portion  130   b  of the sole cavity  130  does not generally follow the path of the junction line between the sole portion  120  and the rear surface  140 , and may, for example, follow a mirror-image path. One or more threaded cavities or recesses may further extend into the main body  112  from the sole recessed surface  142  to facilitate attachment and detachment of the sole plate  116  to the main body  112  through the use of a mechanical fastener. 
     The configuration of the main body  112  described above can be used with any of the rear plates  114  or sole plates  116  shown in  FIGS. 15-24  and described in more detail below. 
     Referring first to  FIGS. 15-17 , there is shown a club head  110   a  as a species of the club head  110  and outfitted with a rear plate  114   a  as a species of the rear plate  114  and a sole plate  116   a  as a species of the sole plate  116 . In the club head  110   a , the rear plate  114   a  and sole plate  116   a  have a substantially constant thickness throughout. The rear plate  114   a  is complementary in shape to the rear cavity  128  and includes a first face  148  and an opposing second face  150  to define a rear plate thickness therebetween. In the embodiment depicted in  FIGS. 15-17 , the distance between the first face  148  and the second face  150  remains generally constant across the entirety of the rear plate  114   a . In this regard, the distance remains the same in a topline-to-sole direction, as well as in a heel-to-toe direction. The rear plate  114   a  includes a generally linear edge which is positioned adjacent the partition  132  and an arcuate or curved edge which is placed adjacent the topline  118 . 
     The rear plate  114   a  is configured to be removably secured within the rear cavity  128 . In some embodiments, the rear plate  114   a  includes a throughbore for receiving a fastener  154  therethrough. The fastener  154  preferably include a threaded screw defining a shaft axis coincident with a rear cavity axis  152 . The rear plate  114  may include a pair of openings or such throughbores, which are aligned with corresponding recesses formed on the main body  112  to enable a pair of rear plate fasteners  154 , such as a screw or other mechanical fastener to be received therein for securing the rear plate  114   a  to the main body  112 . In cases in which the fasteners include plural threaded screws, each define screw axes that are parallel to each other. It is also contemplated that tape, magnets or other fasteners known in the art may be used to secure the rear plate  114   a  to the main body  112 . 
     The sole plate  116   a  is complementary in shape to the sole cavity  130  and includes a first face  156  and an opposing second face  158  to define a sole plate thickness therebetween. In the embodiment depicted in  FIGS. 15-17 , the distance between the first face  156  and the second face  158  remains generally constant across the entirety of the sole plate  116   a . In this regard, the distance remains the same in a topline-to-sole direction, as well as in a heel-to-toe direction. The sole plate  116   a  includes a generally linear edge which is positioned adjacent the partition  132  and an arcuate or curved edge which is placed adjacent the sole bottom surface  144 . 
     The sole plate  116   a  is configured to be removably secured within the sole cavity  130 . In some embodiments, the sole plate  116   a  includes a throughbore for receiving a fastener  162  therethrough. The fastener  162  preferably includes a threaded screw defining a shaft axis coincident with a sole cavity axis  160 , which is angularly offset from the rear cavity axis  152 . It is also contemplated that tape, magnets or other fasteners known in the art may be used to secure the sole plate  116   a  to the main body  112 . In cases in which the fasteners include plural threaded screws, each define screw axes that are parallel to each other. 
     The rear and sole plates  114   a ,  116   a  may be configured to have respective thicknesses which fill the corresponding rear and sole cavities  128 ,  130 , exceed the rear and sole cavities  128 ,  130 , or alternatively, only partially fill the rear and sole cavities  128 ,  130 . Preferably, the rear and sole plates  114 ,  116  fill the rear sole cavities  128 ,  130 , respectively, such that their exterior surfaces are substantially flush (e.g. allowing for tolerances in manufacturing) with respective adjacent surrounding exterior surfaces of the club head  110 . Such provides for retention of the tradition appearance of the club head, promoting confidence, and minimizes sharp contours which may collect debris. 
     Referring now to  FIGS. 18-20 , there is shown a club head  110   b  as another species of the club head  110  and outfitted with a rear plate  114   b  as another species of the rear plate  114  and a sole plate  116   a  as another species of the sole plate  116 . In the club head  110   b , the rear plate  114   b  and sole plate  116   b  are each of a variable (e.g., non-uniform) thickness. Along these lines, the rear plate  114   b  includes a first surface  166  and an opposing second surface  168 , wherein the distance between the first and second surfaces  166 ,  168  varies, with the distance being the smallest adjacent the partition  132 , and the distance being the largest along the topline  118 . In this regard, the rear plate  114   b  is considered to have a “vertical slant,” as the thickness of the rear plate  114   b  varies in a generally vertical direction when the plate  114   b  is coupled to the main body  112  and the club head  110   b  is in the reference position. The vertical slant of the rear plate  114   b  results in more mass being positioned adjacent the topline  118  when the rear plate  114   b  is attached to the main body  112  so as to elevate the center of gravity of the club head  110   b.    
     The sole plate  116   b  also includes a “vertical slant,” which is defined by a first surface  170  and an opposing second surface  172 , wherein the distance between the first and second surfaces  170 ,  172  varies, with the distance being the smallest adjacent the sole bottom surface  144 , and the distance being the largest adjacent the partition  132 . The vertical slant of the sole plate  116   b  results in more mass being positioned adjacent the partition  132  when the sole plate  116   b  is attached to the main body  112 , so as to elevate the center of gravity of the club head  110   b.    
     Although the embodiment shown in  FIGS. 18-20  includes rear and sole plates  114   b ,  116   b  each having a thickness which increases in a generally upward direction (e.g., the portion of the plates  114   b ,  116   b  extending away from the sole  120  is the thickest), it is also contemplated that they may have the reverse configuration, with the thickness decreasing in a generally upward direction (e.g., the portion of the plates  114   b ,  116   b  extending toward the sole  120  is the thickest). 
     Referring now to  FIGS. 21-24 , there is shown a club head  110   c  as yet another species of the club head  110  and outfitted with a rear plate  114   c  as yet another species of the rear plate  114  and a sole plate  116   c  as yet another species of the sole plate  116 . In the club head  110   c , the rear plate  114   c  and sole plate  116   c  are each of a variable (e.g., non-uniform) thickness in a generally heel-to-toe direction. Along these lines, the rear plate  114   c  includes a first surface  176  and an opposing second surface  178 , wherein the distance between the first and second surfaces  176 ,  178  varies, with the distance being the smallest adjacent the heel  134 , and the distance being the largest adjacent the toe  136 . Thus, when the rear plate  114   c  is attached to the main body  112 , more mass is located adjacent the toe  136 , which results in the center of gravity of the club head  110   c  being moved closer to the toe  136 . By providing gradual thickness variation in the plate  114   c , the location of the center of gravity may be shifted to the appropriate degree in a manner that does not detract from the traditional appearance of the club head or require plural components of varying density, which may raise the cost of manufacturing. 
     The sole plate  116   c  also includes a first surface  180  and an opposing second surface  182 , wherein the distance between the first and second surfaces  180 ,  182  varies, with the distance being the least adjacent the heel  134 , and the distance being the greatest adjacent the toe  136 . Therefore, when the sole plate  116   c  is attached to the main body  112 , more mass is located adjacent the toe  136 , which results in the center of gravity of the club head  110   c  being moved closer to the toe  136 . 
     Although  FIGS. 21-24  show the rear and sole plates  114   c ,  116   c  as being thickest adjacent the toe  136 , it is contemplated that they may be provided in the reverse configuration, with the plates  114   c ,  116   c  being thickest adjacent the heel  134 . 
     The use of the rear and sole plates  114 ,  116  as shown in  FIGS. 15-24  allows a user to adjust the weight and center of gravity of the club head  110 . According to one embodiment, the center of gravity is spaced from a reference point by approximately 20.00-22.50 mm along the X-axis (i.e., to the right from the perspective shown in  FIG. 17 ), 6.00-7.00 mm along the Y-axis (i.e., toward the heel), and 13.50-16.00 mm along the Z-axis (i.e., toward the topline). The variability of each dimension is dependent upon the configuration of the main body  112 , as well as the material used for each insert. For instance, the plates  114 ,  116  may be formed from aluminum, tungsten, stainless steel, a material with anodized surfaces, tungsten impregnated with rubbers/polymers, or other materials known in the art. In this respect, the plates  114 ,  116  may be associated with different densities. 
     Although  FIGS. 15-24  show the various rear plates  114  used in combination with the sole plates  116 , it is also contemplated that the rear plate  114  may be used in combination with sole components  14  described above and shown in  FIGS. 1-14  so as to enable further variation of bounce characteristics, as well as center of gravity or weight variation opposite the striking face. For example, the location of the center of gravity of a club head may be considered to affect the orientation in which the club head is permitted to rest when placed in its natural soled position. Also, the center of gravity of the club head affects the manner in which the club head dynamically responds to impact with a golf ball and/or with turf during a typical golf swing. For at least these reasons, the location of the center of gravity, in some embodiments, is preferably a factor in determining and assigning an effective bounce angle to a club head, such manner described above in further detail. Furthermore, when used in combination with the sole components  14  discussed above, the same tool may be used to attach/detach the rear plates  114  and sole components  14  to and from the main body  112 , as well as for any removable shaft component if also incorporated into one or more embodiments. Along these lines, the plates  114 ,  116 , sole component(s)  14 , and/or adjustment tool may be packaged and sold collectively as a kit. 
     In addition, although the club head  110  shown in  FIGS. 15-24  includes a single rear cavity  128  adapted to receive only one rear plate  114  at a time, and a single sole cavity  130  adapted to receive one sole plate  116  at a time, it is contemplated that other embodiments of the club head  110  include a main body  112  having a plurality of rear cavities, and a plurality of sole cavities, wherein each of the rear cavities is adapted to receive a respective rear plate, and each sole cavity is adapted to receive a plurality of sole plates. Thus, in a given club head  110 , there may be a plurality of rear plates and a plurality of sole plates coupled to the main body  112 . 
     The particulars shown herein are by way of example only for purposes of illustrative discussion, and are not presented in the cause of providing what is believed to be most useful and readily understood description of the principles and conceptual aspects of the various embodiments of the present disclosure. In this regard, no attempt is made to show any more detail than is necessary for a fundamental understanding of the different features of the various embodiments, the description taken with the drawings making apparent to those skilled in the art how these may be implemented in practice.