Patent Publication Number: US-8991465-B2

Title: System and method for processing a tire-wheel assembly

Description:
FIELD OF THE INVENTION 
     The disclosure relates to tire-wheel assemblies and to a system and method for assembling a tire-wheel assembly. 
     DESCRIPTION OF THE RELATED ART 
     It is known in the art to assemble a tire-wheel assembly in several steps. Usually, conventional methodologies that conduct such steps require a significant capital investment and human oversight. The present invention overcomes drawbacks associated with the prior art by setting forth a simple system and method for assembling a tire-wheel assembly. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The disclosure will now be described, by way of example, with reference to the accompanying drawings, in which: 
         FIG. 1A  is a perspective view of a sub-station for processing a tire and a wheel in accordance with an exemplary embodiment of the invention; 
         FIG. 1B  is a top view of the sub-station of  FIG. 1A ; 
         FIG. 1C  is a perspective view of a portion of the sub-station of  FIG. 1A ; 
         FIGS. 2A-2J  illustrate side, partial cross-sectional views of the sub-station, tire and wheel according to line  2 A- 2 A of  FIG. 1A  in accordance with an exemplary embodiment of the invention; 
         FIG. 3A-3J  illustrate a partial top view of the sub-station, tire and wheel according to lines  3 A- 3 J of  FIGS. 2A-2J  in accordance with an exemplary embodiment of the invention; 
         FIG. 4A  is a perspective view of a sub-station for processing a tire and a wheel in accordance with an exemplary embodiment of the invention; 
         FIG. 4B  is a top view of the sub-station of  FIG. 4A ; 
         FIG. 4C  is a perspective view of a portion of the sub-station of  FIG. 4A ; 
         FIGS. 5A-5J  illustrate side, partial cross-sectional views of the sub-station, tire and wheel according to line  5 A- 5 A of  FIG. 4A  in accordance with an exemplary embodiment of the invention; 
       FIGS.  5 D′ and  5 E′ illustrate side, partial cross-sectional views of the sub-station, tire and wheel according to line  5 A- 5 A of  FIG. 4A  in accordance with an exemplary embodiment of the invention; 
         FIG. 6A-6J  illustrate a partial top view of the sub-station, tire and wheel according to lines  6 A- 6 J of  FIGS. 5A-5J  in accordance with an exemplary embodiment of the invention; 
         FIG. 7A  is a perspective view of a sub-station for processing a tire and a wheel in accordance with an exemplary embodiment of the invention; 
         FIG. 7B  is a top view of the sub-station of  FIG. 7A ; 
         FIG. 7C  is a perspective view of a portion of the sub-station of  FIG. 7A ; 
         FIGS. 8A-8G  illustrate side, partial cross-sectional views of the sub-station, tire and wheel according to line  8 A- 8 A of  FIG. 7A  in accordance with an exemplary embodiment of the invention; 
         FIG. 9A-9G  illustrate a partial top view of the sub-station, tire and wheel according to lines  9 A- 9 G of  FIGS. 8A-8G  in accordance with an exemplary embodiment of the invention; 
         FIG. 10A  is a perspective view of a sub-station for processing a tire and a wheel in accordance with an exemplary embodiment of the invention; 
         FIG. 10B  is a top view of the sub-station of  FIG. 10A ; 
         FIG. 10C  is a perspective view of a portion of the sub-station of  FIG. 10A ; 
         FIGS. 11A-11J  illustrate side, partial cross-sectional views of the sub-station, tire and wheel according to line  11 A- 11 A of  FIG. 10A  in accordance with an exemplary embodiment of the invention; 
         FIG. 12A-12J  illustrate a partial top view of the sub-station, tire and wheel according to lines  12 A- 12 J of  FIGS. 11A-11J  in accordance with an exemplary embodiment of the invention; 
         FIG. 13A  is a perspective view of a sub-station for processing a tire and a wheel in accordance with an exemplary embodiment of the invention; 
         FIG. 13B  is a top view of the sub-station of  FIG. 13A ; 
         FIG. 13C  is a perspective view of a portion of the sub-station of  FIG. 13A ; 
         FIGS. 14A-14J  illustrate side, partial cross-sectional views of the sub-station, tire and wheel according to line  14 A- 14 J of  FIG. 13A  in accordance with an exemplary embodiment of the invention; 
         FIG. 15A-15J  illustrate a partial top view of the sub-station, tire and wheel according to lines  15 A- 15 J of  FIGS. 14A-14J  in accordance with an exemplary embodiment of the invention; 
         FIG. 16A  is a top view of an exemplary tire; 
         FIG. 16B  is a cross-sectional view of the tire according to line  16 B- 16 B of  FIG. 16A ; 
         FIG. 16C  is a side view of the tire of  FIG. 16A ; 
         FIG. 16D  is a bottom view of the tire of  FIG. 16A ; 
         FIG. 17A  is a top view of an exemplary wheel; and 
         FIG. 17B  is a side view of the wheel of  FIG. 17A . 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The Figures illustrate exemplary embodiments of apparatuses and methods for assembling a tire-wheel assembly. Based on the foregoing, it is to be generally understood that the nomenclature used herein is simply for convenience and the terms used to describe the invention should be given the broadest meaning by one of ordinary skill in the art. 
     Prior to describing embodiments of the invention, reference is made to  FIGS. 16A-16D , which illustrate an exemplary tire, T. Further, starting at  FIG. 1A  in the present disclosure, reference may be made to the “upper,” “lower,” “left,” “right” and “side” of the tire, T; although such nomenclature may be utilized to describe a particular portion or aspect of the tire, T, such nomenclature may be adopted due to the orientation of the tire, T, with respect to structure that supports the tire, T. Accordingly, the above nomenclature should not be utilized to limit the scope of the claimed invention and is utilized herein for exemplary purposes in describing an embodiment of the invention. 
     In an embodiment, the tire, T, includes an upper sidewall surface, T SU  (see, e.g.,  FIG. 16A ), a lower sidewall surface, T SL  (see, e.g.,  FIG. 16D ), and a tread surface, T T  (see, e.g.,  FIGS. 16B-16C ), that joins the upper sidewall surface, T SU , to the lower sidewall surface, T SL . Referring to  FIG. 16B , the upper sidewall surface, T SU , may rise away from the tread surface, T T , to a peak and subsequently descend at a slope to terminate at and form a circumferential upper bead, T BU ; similarly, the lower sidewall surface, T SL , may rise away from the tread surface, T T , to a peak and subsequently descend at a slope to terminate at and form a circumferential lower bead, T BL . 
     As seen in  FIG. 16B , when the tire, T, is in a relaxed, unbiased state (see also, e.g.,  FIGS. 3A-3F ,  6 A- 6 G,  9 A- 9 C), the upper bead, T BU , forms a circular, upper tire opening, T OU ; similarly, when the tire, T, is in a relaxed, unbiased state, the lower bead, T BL , forms a circular, lower tire opening, T OL . It will be appreciated that when an external force is applied to the tire, T, the tire, T, may be physically manipulated, and, as a result, one or more of the upper tire opening, T OU , and the lower tire opening, T OL , may be temporality upset such that one or more of the upper tire opening, T OU , and the lower tire opening, T OL , is/are not entirely circular, but, may, for example, be manipulated to include an oval shape (see, e.g.,  FIGS. 3G-3I ,  6 H- 6 I,  9 D- 9 F). 
     Referring to  FIG. 16B , when in the relaxed, unbiased state, each of the upper tire opening, T OU , and the lower tire opening, T OL , form, respectively, an upper tire opening diameter, T OU-D , and a lower tire opening diameter, T OL-D . Further, as seen in  FIGS. 16A-16B , when in the relaxed, unbiased state, the upper sidewall surface, T SU , and the lower sidewall surface, T SL , define the tire, T, to include a tire diameter, T D . 
     Referring to  FIGS. 16A-16B  and  16 D, the tire, T, also includes a passage, T P . Access to the passage, T P , is permitted by either of the upper tire opening, T OU , and the lower tire opening, T OL . Referring to  FIG. 16B , when the tire, T, is in a relaxed, unbiased state, the upper tire opening, T OU , and the lower tire opening, T OL , define the passage, T P , to include a diameter, T P-D . Referring also to  FIG. 16B , the tire, T, includes a circumferential air cavity, T AC , that is in communication with the passage, T P . After joining the tire, T, to a wheel, W, pressurized air is deposited into the circumferential air cavity, T AC , for inflating the tire, T. 
     When the tire, T, is arranged adjacent structure as described in the following disclosure starting at  FIG. 1A , a portion of the lower sidewall surface, T SL , of the tire, T, may be disposed adjacent the structure. In some circumstances, the structure may provide three points of support, and, as such, three portions of the lower sidewall surface, T SL , of the tire, T, may be disposed adjacent the structure. Accordingly, reference is made to  FIG. 16D  in order to identify three exemplary portions of the lower sidewall surface, T SL , of the tire, T, that may be disposed adjacent the structure at reference signs, T SL-1 , T SL-2  and T SL-3 , which may be respectively be referred to as a “first portion of the lower sidewall surface, T SL , of the tire, T,” a “second portion of the lower sidewall surface, T SL , of the tire, T” and a “third portion of the lower sidewall surface, T SL , of the tire, T.” Because the tire, T, may be moved relative to the structure, the three points of support may not necessarily be limited to the illustrated identification at  FIG. 16D , and, as such the three points of support may be located at other regions of the lower sidewall surface, T SL , of the tire, T. 
     Further, when the tire, T, is arranged adjacent structure or a wheel, W (see, e.g.,  FIGS. 17A-17B ), as described in the following disclosure, the written description may reference a “left” portion or a “right” portion of the tire, T. Referring to  FIG. 16C , the tire, T, is shown relative to a support member, S; the support member, S, is provided (and shown in phantom) in order to establish a frame of reference for the “left” portion and the “right” portion of the tire, T. In  FIG. 16C , the tire, T, is arranged in a “non-rolling” orientation such that the tread surface, T T , is not disposed adjacent the phantom support member, S, but, rather the lower sidewall surface, T SL , is disposed adjacent the phantom support member, S. A center diving line, DL, equally divides the “non-rolling” orientation of the tire, T, in half in order to generally indicate a “left” portion of the tire, T, and a “right” portion of the tire, T. 
     As discussed above, reference is made to several diameters, T P-D , T OU-D , T OL-D  of the tire, T. According to geometric theory, a diameter passes through the center of a circle, or, in the present disclosure, the axial center of the tire, T, which may alternatively be referred to as an axis of rotation of the tire, T. Geometric theory also includes the concept of a chord, which is a line segment that whose endpoints both lie on the circumference of a circle; according to geometric theory, a diameter is the longest chord of a circle. 
     In the following description, the tire, T, may be moved relative to structure; accordingly, in some instances, a chord of the tire, T, may be referenced in order to describe an embodiment of the invention. Referring to  FIG. 16A , several chords of the tire, T, are shown generally at T C1 , T C2  (i.e., the tire diameter, T D ) and T C3 . 
     The chord, T C1 , may be referred to as a “left” tire chord. The chord, T C3 , may be referred to as a “right” tire chord. The chord, T C2 , may be equivalent to the tire diameter, T D , and be referred to as a “central” chord. Both of the left and right tire chords, T C1 , T C3 , include a geometry that is less than central chord, T C2 /tire diameter, T D . 
     In order to reference the location of the left chord, T C1 , and the right chord, T C3 , reference is made to a left tire tangent line, T TAN-L , and a right tire tangent line, T TAN-R . The left chord, T C1 , is spaced apart approximately one-fourth (¼) of the tire diameter, T D , from the left tire tangent line, T TAN-L . The right chord, T C3 , is spaced apart approximately one-fourth (¼) of the tire diameter, T D , from the right tire tangent line, T TAN-R . Each of the left and right tire chords, T C1 , T C3 , may be spaced apart about one-fourth (¼) of the tire diameter, T D , from the central chord, T C2 . The above spacings referenced from the tire diameter, T D , are exemplary and should not be meant to limit the scope of the invention to approximately a one-fourth (¼) ratio; accordingly, other ratios may be defined, as desired. 
     Further, as will be described in the following disclosure, the tire, T, may be moved relative to structure. Referring to  FIG. 16C , the movement may be referenced by an arrow, U, to indicate upwardly movement or an arrow, D, to indicate downwardly movement. Further, the movement may be referenced by an arrow, L, to indicate left or rearwardly movement or an arrow, R, to indicate right or forwardly movement. 
     Prior to describing embodiments of the invention, reference is made to  FIGS. 17A-17B , which illustrate an exemplary wheel, W. Further, starting at  FIG. 1A  in the present disclosure, reference may be made to the “upper,” “lower,” “left,” “right” and “side” of the wheel, W; although such nomenclature may be utilized to describe a particular portion or aspect of the wheel, W, such nomenclature may be adopted due to the orientation of the wheel, W, with respect to structure that supports the wheel, W. Accordingly, the above nomenclature should not be utilized to limit the scope of the claimed invention and is utilized herein for exemplary purposes in describing an embodiment of the invention. 
     In an embodiment, the wheel, W, includes an upper rim surface, W RU , a lower rim surface, W RL , and an outer circumferential surface, W C , that joins the upper rim surface, W RU , to the lower rim surface, W RL . Referring to  FIG. 17B , upper rim surface, W RU , forms a wheel diameter, W D . The wheel diameter, W D , may be non-constant about the circumference, W C , from the upper rim surface, W RU , to the lower rim surface, W RL . The wheel diameter, W D , formed by the upper rim surface, W RU , may be largest diameter of the non-constant diameter about the circumference, W C , from the upper rim surface, W RU , to the lower rim surface, W RL . The wheel diameter, W D , is approximately the same as, but slightly greater than the diameter, T P-D , of the passage, T P , of the tire, T; accordingly, once the wheel, W, is disposed within the passage, T P , the tire, T, may flex and be frictionally-secured to the wheel, W, as a result of the wheel diameter, W D , being approximately the same as, but slightly greater than the diameter, T P-D , of the passage, T P , of the tire, T. 
     The outer circumferential surface, W C , of the wheel, W, further includes an upper bead seat, W SU , and a lower bead seat, W SL . The upper bead seat, W SU , forms a circumferential cusp, corner or recess that is located proximate the upper rim surface, W RU . The lower bead seat, W SL , forms a circumferential cusp, corner or recess that is located proximate the lower rim surface, W RL . Upon inflating the tire, T, the pressurized air causes the upper bead, T BU , to be disposed adjacent and “seat” in the upper bead seat, W SU ; similarly, upon inflating the tire, T, the pressurized air causes the lower bead, T BL , to be disposed adjacent and “seat” in the lower bead seat, W SL . 
     The non-constant diameter of the outer circumference, W C , of the wheel, W, further forms a wheel “drop center,” W DC . A wheel drop center, W DC , may include the smallest diameter of the non-constant diameter of the outer circumference, W C , of the wheel, W. Functionally, the wheel drop center, W DC , may assist in the mounting of the tire, T, to the wheel, W. 
     The non-constant diameter of the outer circumference, W C , of the wheel, W, further forms an upper “safety bead,” W SB . In an embodiment, the upper safety bead may be located proximate the upper bead seat, W SU . In the event that pressurized air in the circumferential air cavity, T AC , of the tire, T, escapes to atmosphere, the upper bead, T BU , may “unseat” from the upper bead seat, W SU ; because of the proximity of the safety bead, W SB , the safety bead, W SB , may assist in the mitigation of the “unseating” of the upper bead, T BU , from the upper bead seat, W SU , by assisting in the retaining of the upper bead, T BU , in a substantially seated orientation relative to the upper bead seat, W SU . In some embodiments, the wheel, W, may include a lower safety bead (not shown); however, upper and/or lower safety beads may be included with the wheel, W, as desired, and are not required in order to practice the invention described in the following disclosure. 
     Referring to  FIG. 1A , a processing sub-station  10  for processing a tire-wheel assembly, TW, is shown according to an embodiment. The “processing” conducted by the processing sub-station  10  may include the act of “joining” or “mounting” a tire, T, to a wheel, W, for forming the tire-wheel assembly, TW. The act of “joining” or “mounting” may mean to physically couple, connect or marry the tire, T, and wheel, W, such that the wheel, W, may be referred to as a male portion that is inserted into a passage, T P , of a tire, T, being a female portion. 
     As described and shown in the following Figures, although the desired result of the processing sub-station  10  is the joining or mounting of the tire, T, and wheel, W, to form a tire-wheel assembly, TW, it should be noted that the processing sub-station  10  does not inflate the circumferential air cavity, T AC , of the tire, T, of the tire-wheel assembly, TW, nor does the processing sub-station  10  contribute to an act of “seating” the upper bead, T BU , or the lower bead, T BL , of the tire, T, adjacent the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W (because the act of “seating” typically arises from an inflating step where the tire-wheel assembly, TW, is inflated). Accordingly, upon joining or mounting the tire, T, to the wheel, W, the upper bead, T BU , or the lower bead, T BL , of the tire, T, may be arranged about and/or disposed adjacent the outer circumferential surface, W C , of the wheel, W. 
     In an implementation, the processing sub-station  10  may be included as part of a “single-cell” workstation. A single-cell workstation may include other sub-stations (not shown) that contribute to the processing of a tire-wheel assembly, TW; other sub-stations may include, for example: a soaping sub-station, a stemming sub-station, an inflating sub-station, a match-marking sub-station, a balancing sub-station and the like. The term “single-cell” indicates that the sub-stations contribute to the production of a tire-wheel assembly, TW, without requiring a plurality of successive, discrete workstations that may otherwise be arranged in a conventional assembly line such that a partially-assembled tire-wheel assembly, TW, is “handed-off” along the assembly line (i.e., “handed-off” meaning that an assembly line requires a partially-assembled tire-wheel assembly, TW, to be retained by a first workstation of an assembly line, worked on, and released to a subsequent workstation in the assembly line for further processing). Rather, a single cell workstation provides one workstation having a plurality of sub-stations each performing a specific task in the process of assembling a tire-wheel assembly, TW. This assembling process takes place wherein the tire and/or wheel “handing-off” is either minimized or completely eliminated. As such, a single-cell workstation significantly reduces the cost and investment associated with owning/renting the real estate footprint associated with a conventional tire-wheel assembly line while also having to provide maintenance for each individual workstation defining the assembly line. Thus, capital investment and human oversight is significantly reduced when a single cell workstation is employed in the manufacture of tire-wheel assemblies, TW. 
     Referring to  FIG. 1A , the processing sub-station  10  includes a device  12 . The device  12  may be referred to as a robotic arm. The robotic arm  12  may be located in a substantially central position relative to a plurality of sub-stations (including, e.g., the processing sub-station  10 ) of a single-cell workstation. The robotic arm  12  may be attached to and extend from a base/body portion (not shown) connected to ground, G. 
     The robotic arm  12  may include an end effecter  14 . The end effecter  14  may include a claw, gripper, or other means for removably-securing the wheel, W, to the robotic arm  12 . The end effecter  14  permits the robotic arm  12  to have the ability to retain and not release the wheel, W, throughout the entire procedure performed by the processing sub-station  10  (and, if applied in a single-cell workstation, the ability to retain and not release the wheel, W, throughout the entire assembling procedure of the tire-wheel assembly, TW). Accordingly, the end effecter  14  minimizes or eliminates the need of the robotic arm  12  to “hand-off” the tire-wheel assembly, TW, to (a) subsequent sub-station(s) (not shown). 
     The processing sub-station  10  may perform several functions/duties including that of: (1) a tire repository sub-station and (2) a mounting sub-station. A tire repository sub-station typically includes one or more tires, T, that may be arranged in a “ready” position for subsequent joining to a wheel, W. A mounting sub-station typically includes structure that assists in the joining of a tire, T, to a wheel, W (e.g., the disposing of a wheel, W, within the passage, T P , of the tire, T). 
     Referring to  FIG. 1A , the processing sub-station  10  may be initialized by joining a wheel, W, to the robotic arm  12  at the end effecter  14 . The processing sub-station  10  may also be initialized by positioning the tire, T, upon a support member  16 . The support member  16  may include a first support member  16   a , a second support member  16   b  and a third support member  16   c . Each of the first, second and third support members  16   a ,  16   b ,  16   c  include an upper surface  16 ′ and a lower surface  16 ″. 
     The lower surface  16 ″ of each of the first, second and third support members  16   a ,  16   b ,  16   c  may be respectively connected to at least one first leg member  18   a , at least one second leg member  18   b  and at least one third leg member  18   c . Each of the at least one first, second and third leg members  18   a ,  18   b ,  18   c  respectively include a length for elevating or spacing each of the first, second and third support members  16   a ,  16   b ,  16   c  from an underlying ground surface, G. Although the robotic arm  12  is not directly connected to the support member  16  (but, rather may be connected to ground, G), the robotic arm  12  may be said to be interfaceable with (as a result of the movements D 1 -D 12  described in the following disclosure) and/or indirectly connected to the support member  16  by way of a common connection to ground, G, due the leg members  18   a - 18   c  connecting the support member  16  to ground, G. 
     The processing sub-station  10  may further include a plurality of tire-engaging devices  20 . The plurality of tire-engaging devices  20  may include a first tire-engaging device  20   a  connected to the upper surface  16 ′ of the first support member  16   a , a second tire-engaging device  20   b  connected to the upper surface  16 ′ of the second support member  16   b  and a third tire-engaging device  20   c  connected to the upper surface  16 ′ of the third support member  16   c.    
     Referring to  FIGS. 1B-1C , the first tire-engaging device  20   a  may include a body  22   a  having a side, tire-tread-engaging surface  22   a ′. Each of the second and third tire-engaging devices  20   b ,  20   c  may include a body  22   b ,  22   c  having an upper, tire-sidewall-engaging surface  22   b ′,  22   c′.    
     The upper sidewall-engaging surfaces  22   b ′,  22   c ′ of the second and third tire-engaging devices  20   b ,  20   c  may be co-planar with one another. The upper sidewall-engaging surfaces  22   b ′,  22   c ′ of the second and third tire-engaging devices  20   b ,  20   c  may be arranged in a spaced-apart relationship with respect to ground, G, that is greater than that of the spaced-apart relationship of the upper surface  16 ′ of the first support member  16   a ; accordingly, the upper sidewall-engaging surfaces  22   b ′,  22   c ′ of the second and third tire-engaging devices  20   b ,  20   c  may be arranged in a non-co-planar relationship with respect to the upper surface  16 ′ of the first support member  16   a.    
     A first tire-tread-engaging post  30   a  may extend from the upper, tire-sidewall-engaging surface  22   b ′ of the second tire-engaging device  20   b . A second tire-tread-engaging post  30   b  may extend from the upper, tire-sidewall-engaging surface  22   c ′ of the third tire-engaging device  20   c.    
     Referring to  FIG. 1B , the second and third support members  16   b ,  16   c  are separated by a gap or first spacing, S 1 . The first tire-tread-engaging post  30   a  is separated from the second tire-tread-engaging post  30   b  by a gap or second spacing, S 2 . The second spacing, S 2 , is greater than the first spacing, S 1 . The first spacing, S 1 , may be approximately equal to, but slightly greater than the diameter, W D , of the wheel, W; further, the tire diameter, T D /central chord, T C2 , may be greater than the first spacing, S 1 . The second spacing, S 2 , may be approximately equal to the left chord, T C1 , and the right chord, T C3 , of the tire, T; further, the tire diameter, T D /central chord, T C2 , may be greater than the second spacing, S 2 . 
     As seen in  FIG. 2A  with reference to  FIG. 3A , prior to joining the tire, T, to the wheel, W, the tire, T, may be said to be arranged in a first relaxed, unbiased orientation such that the upper tire opening, T OU , and the lower tire opening, T OL , define the passage, T P , to include a diameter, T P-D . When the tire, T, is eventually joined to the wheel, W (see, e.g.,  FIG. 2J ), the upper bead, T BU , and the lower bead, T BL , may be arranged proximate but not seated adjacent, respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W; later, upon inflating the tire, T, at, e.g., an inflation sub-station (not shown), the upper bead, T BU , and the lower bead, T BL , may be seated (i.e., disposed adjacent), respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W. Further, when the tire, T, is joined to the wheel, W (see, e.g.,  FIG. 2J ), the tire, T, may be said to be arranged in a second substantially relaxed, but somewhat biased orientation such that the diameter, T P-D , of the passage, T P , is substantially circular and substantially similar to its geometry of the first relaxed, unbiased orientation of the tire, T. 
     Referring to  FIG. 2A , the robotic arm  12  is arranged in a spaced-apart orientation with respect to the support member  16 , which includes the tire, T, arranged in a “ready” position. The “ready” position may include the tread surface, T T , of the tire, T, arranged adjacent the front, tire-tread-engaging surface  22   a ′ of the body  22   a  of the first tire-engaging device  20   a . The “ready” position may further include the tire, T, being arranged in a first angularly-offset orientation, θ 1 , with respect to the upper surface  16 ′ of the first support member  16   a.    
     The first angularly-offset orientation, θ 1 , of the tire, T, may result from the non-co-planar relationship the upper sidewall-engaging surfaces  22   b ′,  22   c ′ of the second and third tire-engaging devices  20   b ,  20   c  with that of the upper surface  16 ′ of the first support member  16   a  such that: (1) the first portion, T SL-1 , of the lower sidewall surface, T SL , being arranged adjacent the upper surface  16 ′ of the first support member  16   a , (2) the second portion, T SL-2 , of the lower sidewall surface, T SL , being arranged adjacent the upper tire-sidewall-engaging surface  22   b ′ of the body  22   b  of the second tire-engaging device  20   b  (noting that, in  FIG. 2A , the second portion, T SL-2 , is not represented due to the line-of-view of the cross-sectional reference line of  FIG. 1A , but, however, is shown in  FIG. 3A ), and (3) a third portion, T SL-3 , of the lower sidewall surface, T SL , being arranged adjacent the upper tire-sidewall-engaging surface  22   c ′ of the body  22   c  of the third tire-engaging device  20   c . Accordingly, the support member  16  may provide a three-point support (which is more clearly shown at  FIG. 1A ) at T SL-1 , T SL-2 , T SL-3  for the lower sidewall surface, T SL , of the tire, T, while remaining portions of the lower sidewall surface, T SL , of the tire, T, are not in direct contact with any other portion of the upper surface surfaces  16 ′,  22   b ′,  22   c ′ of the support member  16  when the tire, T, is arranged in the first angularly-offset orientation, θ 1 . 
     The processing sub-station  10  may execute a mounting procedure by causing a controller, C (see, e.g.,  FIG. 1A ) to send one or more signals to a motor, M (see, e.g.,  FIG. 1A ), that drives movement (according to the direction of the arrows, D 1 -D 12 —see  FIGS. 2A-2J ) of the robotic arm  12 . Alternatively or in addition to automatic operation by the controller, C, according to inputs stored in memory, the movement, D 1 -D 12 , may result from one or more of a manual, operator input, O (e.g., by way of a joystick, depression of a button or the like). 
     As seen in  FIG. 2A , a first, down, D, movement according to the direction of arrow, D 1 , may reduce the spaced-apart orientation of robotic arm  12  with respect to the support member  16 . A second movement according to the direction of arrow, D 2 , may cause the end effecter  14  to rotate the wheel, W, in, for example, a counter-clockwise direction. The movement according to the direction of the arrows, D 1 , D 2 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 2B , the movement according to the direction of the arrows, D 1 , D 2 , may cease upon locating a first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, within the passage, T P , of the tire, T, such that a first (e.g., left) portion of the drop center, W DC , of the wheel, W, is disposed adjacent a first (e.g., left) portion of the upper bead, T BU , of the tire, T. Because a first (e.g., left) portion the tread surface, T T , of the tire, T, is arranged adjacent the front, tire-tread-engaging surface  22   a ′ of the body  22   a  of the first tire-engaging device  20   a , subsequent movements of the wheel, W, resulting from movement of the robotic arm  12  prevents the tire, T, from moving away (e.g., to the left, L) from the second and third support members  16   b ,  16   c.    
     With continued reference to  FIG. 2B , a third movement according to the direction of arrow, D 3 , may cause forwardly (e.g., to the right, R) movement of the wheel, W. A fourth movement according to the direction of arrow, D 4 , may cause the end effecter  14  to rotate the wheel, W, in, for example, a clockwise direction (i.e., rotationally opposite that of the direction of arrow, D 2 ). The movement according to the direction of the arrows, D 3 , D 4 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 2C , the movement according to the direction of the arrows, D 3 , D 4 , may cease upon locating a second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC  of the wheel, W, within the passage, T P , of the tire, T, such that a second (e.g., right) portion of the drop center, W DC , and lower bead seat, W SL , of the wheel, W, are disposed proximate but not adjacent a second (e.g., right) portion of the lower bead, T BL , and away from the second (e.g., right) portion of the upper bead, T BU , of the tire, T. As stated above, because the first (e.g., left) portion the tread surface, T T , of the tire, T, is arranged adjacent the front, tire-tread-engaging surface  22   a ′ of the body  22   a  of the first tire-engaging device  20   a , the movements, D 3 , D 4 , of the wheel, W, resulting from movement of the robotic arm  12  prevents the tire, T, from moving away (e.g., to the left, L), from the second and third support members  16   b ,  16   c.    
     With continued reference to  FIG. 2C , a fifth movement according to the direction of arrow, D 5 , may cause further forwardly (e.g., to the right, R) movement of the wheel, W. A sixth movement according to the direction of arrow, D 6 , may cause the end effecter  14  to rotate the wheel, W, in, for example, a counter-clockwise direction (i.e., rotationally opposite that of the direction of arrow, D 4 ). The movement according to the direction of the arrows, D 5 , D 6 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 2D , the movement according to the direction of the arrows, D 5 , D 6 , may cease upon adjusting an orientation of the wheel, W, relative to the tire, T, as follows: (1) the first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC  of the wheel, W, are orientated within the passage, T P , of the tire, T, but away from and not disposed adjacent the first (e.g., left) portion of the upper bead, T BU , but, rather, proximate but not adjacent to the lower bead, T BL , of the tire, T, and (2) the second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, are orientated within the passage, T P , of the tire, T, but away from and not proximate the second (e.g., right) portion of the lower bead, T BL , but, rather, proximate but not adjacent to the second (e.g., right) portion of the upper bead, T BU , of the tire, T. 
     Further, as seen in  FIG. 2D , the movement according to the direction of the arrows, D 5 , D 6 , may result in the wheel, W, being disposed within the passage, T P , of the tire, T, and partially connected to the tire, T, such that the robotic arm  12  utilizes the wheel, W, to move the tire, T, forwardly (e.g., to the right, R) from the “ready” position to a “partially mounted” position. When the tire, T, is arranged, in the “partially mounted” position with respect to the wheel, W, the front, tire-tread-engaging surface  22   a ′ of the body  22   a  of the first tire-engaging device  20   a  is no longer arranged adjacent the tread surface, T T , of the tire, T, but, rather, one or more of a portion of the tread surface, T T , and the lower sidewall surface, T SL , of the tire, T, are arranged partially adjacent the upper surface  16 ′ of the first support member  16   a.    
     Although no longer arranged in the “ready” position, the support member  16  still provides a three-point support for the lower sidewall surface, T SL , of the tire, T, such that the first portion, T SL-1 , of the lower sidewall surface, T SL , is arranged adjacent the upper surface  16 ′ while the second and third portions, T SL-2 , T SL-3 , of the lower sidewall surface, T SL , of the tire, T, are still arranged adjacent the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c . However, when the orientation of the tire, T, in  FIG. 2D  is compared to the orientation of the tire, T, of  FIGS. 2A-2C , the three points of support are have converged closer together in  FIG. 2D , and, as a result, the tire, T, is arranged at a second angularly-offset orientation, θ 2 , that is greater than the first angularly-offset orientation, θ 1 . 
     With continued reference to  FIG. 2D , a seventh movement according to the direction of arrow, D 7 , may cause one or more of a further forwardly movement and a further downwardly, D, and a further forwardly (e.g., to the right, R) movement of the wheel, W. An eighth movement according to the direction of arrow, D 8 , may cause the end effecter  14  to rotate the wheel, W, in, for example, a further counter-clockwise direction. The movement according to the direction of the arrows, D 7 , D 8 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 2E , the movement according to the direction of the arrows, D 7 , D 8 , may cease upon adjusting an orientation of the wheel, W, relative to the tire, T, as follows: (1) the first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, are orientated out of the passage, T P , of the tire, T, and in a spaced-apart, opposing orientation with the lower sidewall surface, T SL , of the tire, T, and (2) a portion (e.g., a right portion) of a lower, outer rim surface, W RL , of the wheel, W, (proximate the second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W), is disposed within the passage, T P , of the tire, T, and adjacent to the second (e.g., right) portion of the lower bead, T BL , of the tire, T. 
     Per the phantom lines of the body  22   c  of the third tire-engaging device  20   c  (as a result of the orientation of the wheel, W, and tire, T), the movement of the robotic arm  12  according to the direction of the arrows, D 7 , D 8  results in a portion of the wheel, W, being arranged in the gap or first spacing, S 1 , and the right tire chord, T C3  (see, e.g., corresponding top view  FIG. 3E ), being arranged proximate but slightly to the left of the first and second tire-tread-engaging posts  30   a ,  30   b  such that a portion of the tire, T, is arranged in the gap or second spacing, S 2 , but not adjacent the first and second tire-tread-engaging posts  30   a ,  30   b.    
     Because the gap or first spacing, S 1 , may be approximately equal to but greater than a diameter of the wheel, W, the robotic arm  12  is permitted to move the wheel, W, into/through the gap or first spacing, S 1 , and below the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c ; however, because the diameter of the tire, T, is greater than that of the gap or first spacing, S 1 , the movement of robotic arm  12  prohibits movement of the tire, T, through the gap or first spacing, S 1 , with that of the wheel, W. As a result of the wheel, W, being permitted to pass through the gap or first spacing, S 1 , without the tire, T, at least the first (e.g., left) portion of the wheel, W, of the wheel, W, described above (proximate, e.g., the first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W) is permitted to “plunge” through the passage, T P , of the tire, T, such that the first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, is arranged in the spaced-apart, opposing orientation with the lower sidewall surface, T SL , of the tire, T. 
     As a result of the wheel, W, plunging through the passage, T P , of the tire, T, a first (e.g., left) portion of the safety bead, W SB , of the wheel, W, is disposed adjacent the first (e.g., left) portion of the upper bead, T BU , of the tire, T. Further, as a result of the arrangement of the safety bead, W SB , adjacent the first (e.g., left) portion of the upper bead, T BU , of the tire, T, and the arrangement of the portion of the lower, outer rim surface, W RL , of the wheel, W, adjacent the second (e.g., right) portion of the lower bead, T BL , of the tire, T, a substantially downwardly force, DF, is transmitted from the robotic arm  12 , to the wheel, W, and to the contact points of the wheel, W, with the tire, T, described above at the safety bead, W SB , and lower, outer rim surface, W RL , such that the substantially downwardly force, DF, is distributed from the wheel, W, and to the tire, T. The substantially downwardly force, DF, from the wheel, W, to the tire, T, arrives at and is distributed from the first, second and third portions, T SL-1 , T SL-2 , T SL-3 , of the lower sidewall surface, T SL , of the tire, T, to upper surfaces  16 ′,  22   b ′,  22   c ′ of the support member  16 . 
     With continued reference to  FIG. 2E , a ninth movement according to the direction of arrow, D 9 , may cause further forwardly movement (e.g., to the right, R) of the wheel, W. A tenth movement according to the direction of arrow, D 10 , may cause the end effecter  14  to rotate the wheel, W, in, for example, a clockwise direction (i.e., rotationally opposite that of the direction of arrow, D 8 ). The movement according to the direction of the arrows, D 9 , D 10 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIGS. 2F and 3F , the movement according to the direction of the arrows, D 9 , D 10 , may cease upon adjusting an orientation of the wheel, W, relative to the tire, T, as follows: (1) the wheel, W, and tire, T, had previously “hopped over” the first and second tire-tread-engaging posts  30   a ,  30   b  such that the wheel, W, and tire, T, are oriented forwardly (e.g., to the right, R) of the first and second tire-tread-engaging posts  30   a ,  30   b , (2) as a result of the forwardly orientation of the tire, T, and wheel, W, relative to the first and second tire-tread-engaging posts  30   a ,  30   b , approximately three-quarters (¾) of the tire, T, is arranged forwardly of the first and second tire-tread-engaging posts  30   a ,  30   b  (as shown, for example in  FIG. 3F ) such that the left chord, T C1 , of the tire, T, is aligned with the second spacing, S 2 , of the first and second tire-tread-engaging posts  30   a ,  30   b ; as a result of the alignment of the left chord, T C1 , with the second spacing, S 2 , the a first tread surface portion, T T1 , and a second tread surface portion, T T2 , of the tread surface, T T , of the tire, T, are disposed adjacent to and in direct contact with, respectively, the first and second tire-tread-engaging posts  30   a ,  30   b , (3) the lower, outer rim surface, W RL , of the wheel, W, is arranged in a substantially co-planar relationship with the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c , (4) the first (e.g., left) portion of the lower bead, T BL , of the tire, T, is disposed adjacent the first (e.g., left) portion of the drop center, W DC , of the wheel, W, and (5) the portion of the outer rim surface, W RL , of the wheel, W, (proximate the second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W) remains disposed within the passage, T P , of the tire, T, and adjacent to the second (e.g., right) portion of the lower bead, T BL , of the tire, T. 
     Because the lower, outer rim surface, W RL , of the wheel, W, is arranged in a substantially co-planar relationship with the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c , the tire, T, is no longer in direct contact with the first support member  16   a . Further, as explained above, because the diameter, T D , of the tire, T, is greater than that of the gap or first spacing, S 1 , the co-planar orientation of the lower, outer rim surface, W R-L , with the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ results in approximately one-fourth (¼) to one-half (½) of a first (e.g., left) portion of the lower sidewall surface, T SL , of the tire, T, disposed adjacent the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c.    
     With continued reference to  FIG. 2F , an eleventh movement according to the direction of arrow, D 11 , may cause downwardly movement, D, of the wheel, W, such that the lower outer rim surface, W RL , of the wheel, W, (proximate the lower bead seat, W SL , and drop center, W DC , of the wheel, W) is arranged substantially proximate but below the upper tire-sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c . A twelfth movement according to the direction of arrow, D 12 , may cause a rearwardly (e.g., to the left, L) movement of the wheel, W. The movement according to the direction of the arrows, D 11 , D 12 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 2G , as a result of the movement according to the direction of the arrows D 1 -D 12 , the lower bead, T BL , of the tire, T, is arranged in a curved, substantially arcuate orientation over the sidewall-engaging surface  22   b ′,  22   c ′ of the body  22   b ,  22   c  of the second and third tire-engaging devices  20   b ,  20   c . Further, as a result of the initial rearwardly (e.g., to the left, L) movement of the wheel, W, the tire, T, is advanced through the second spacing, S 2  (see, e.g.,  FIG. 3G ), from the left chord, T C1 , to the right chord, T C3 ; as seen in  FIG. 3G , because chords (including, e.g., the central chord, T C2 ) of the tire, T, between the left chord, T C1 , and the right chord, T C3 , are greater than that of the left chord, T C1 , and the right chord, T C3 , the first and second tire-tread-engaging posts  30   a ,  30   b  interfere with movement of the tire, T, through the second spacing, S 2 . 
     As a result of the above-described interference, as seen in  FIG. 3G , the tire, T, temporality deforms such that the diameter, T P-D , of the passage, T P , of the tire, T, is temporality upset to include a substantially oval form rather than a circular form. Accordingly, in a substantially similar fashion, the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , are also temporality upset to include a substantially oval form rather than a circular form. 
     The oval form of the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , reduces a portion of contact (and, as a result, friction) of the lower bead, T BL , and the upper bead, T BU , of the tire, T, with that of the outer circumferential surface, W C , of the wheel, W. Accordingly, referring to  FIGS. 2G-2I  and  3 G- 3 I, as the wheel, W, advances the tire, T, rearwardly (e.g., to the left, L) through the second spacing, S 2 , according to the direction of the arrow, D 12 , the oval deformation of diameters, T P-D , T OU-D , T OL-D  results in the lower bead, T BL , of the tire, T, encountering less resistance or interference with the outer rim surface, W R-L , of the wheel, W, as the lower bead, T BL , is advanced from an orientation opposite that of the outer rim surface, W RL , over the lower bead seat, W SL , and to a final position adjacent the drop center, W DC , of the wheel, W. 
     Referring to  FIGS. 2J and 3J , once the right chord, T C3 , has been advanced through the second spacing, S 2 , from forwardly orientation (e.g., to the right, R) of the first and second tire-tread-engaging posts  30   a ,  30   b  back to the rearwardly orientation (e.g., to the left, L) of the first and second tire-tread-engaging posts  30   a ,  30   b , the entire circumference of the lower bead, T BL , may be said to be advanced to its final “mounted position” adjacent to and about the drop center, W DC . Further, the entire circumference of the upper bead, T BU , may be said to be arranged in its final “mounted position” adjacent to and about the outer circumferential surface, W C , of the wheel, W, proximate the safety bead, W SB . 
     With continued reference to  FIG. 2J , a thirteenth movement according to the direction of arrow, D 13 , may cause upwardly movement, U, of the wheel, W, and tire, T, away from the support member  16 . The robotic arm  12  may move the tire-wheel assembly, TW, to, for example, a subsequent sub-station (not shown), such as, for example, an inflation sub-station in order to inflate the tire-wheel assembly, TW, which may cause the upper bead, T BU , to be seated adjacent the upper bead seat, W SU , and the lower bead, T BL , to be seated adjacent the lower bead seat, W SL . 
     Referring to  FIG. 4A , a processing sub-station  100  for processing a tire-wheel assembly, TW, is shown according to an embodiment. The “processing” conducted by the processing sub-station  100  may include the act of “joining” or “mounting” a tire, T, to a wheel, W, for forming the tire-wheel assembly, TW. The act of “joining” or “mounting” may mean to physically couple, connect or marry the tire, T, and wheel, W, such that the wheel, W, may be referred to as a male portion that is inserted into a passage, T P , of a tire, T, being a female portion. 
     As described and shown in the following Figures, although the desired result of the processing sub-station  100  is the joining or mounting of the tire, T, and wheel, W, to form a tire-wheel assembly, TW, it should be noted that the processing sub-station  100  does not inflate the circumferential air cavity, T AC , of the tire, T, of the tire-wheel assembly, TW, nor does the processing sub-station  100  contribute to an act of “seating” the upper bead, T BU , or the lower bead, T BL , of the tire, T, adjacent the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W (because the act of “seating” typically arises from an inflating step where the tire-wheel assembly, TW, is inflated). Accordingly, upon joining or mounting the tire, T, to the wheel, W, the upper bead, T BU , or the lower bead, T BL , of the tire, T, may be arranged about and/or disposed adjacent the outer circumferential surface, W C , of the wheel, W. 
     In an implementation, the processing sub-station  100  may be included as part of a “single-cell” workstation. A single-cell workstation may include other sub-stations (not shown) that contribute to the processing of a tire-wheel assembly, TW; other sub-stations may include, for example: a soaping sub-station, a stemming sub-station, an inflating sub-station, a match-marking sub-station, a balancing sub-station and the like. The term “single-cell” indicates that the sub-stations contribute to the production of a tire-wheel assembly, TW, without requiring a plurality of successive, discrete workstations that may otherwise be arranged in a conventional assembly line such that a partially-assembled tire-wheel assembly, TW, is “handed-off” along the assembly line (i.e., “handed-off” meaning that an assembly line requires a partially-assembled tire-wheel assembly, TW, to be retained by a first workstation of an assembly line, worked on, and released to a subsequent workstation in the assembly line for further processing). Rather, a single cell workstation provides one workstation having a plurality of sub-stations each performing a specific task in the process of assembling a tire-wheel assembly, TW. This assembling process takes place wherein the tire and/or wheel “handing-off” is either minimized or completely eliminated. As such, a single-cell workstation significantly reduces the cost and investment associated with owning/renting the real estate footprint associated with a conventional tire-wheel assembly line while also having to provide maintenance for each individual workstation defining the assembly line. Thus, capital investment and human oversight is significantly reduced when a single cell workstation is employed in the manufacture of tire-wheel assemblies, TW. 
     Referring to  FIG. 4A , the processing sub-station  100  includes a device  112 . The device  112  may be referred to as a robotic arm. The robotic arm  112  may be located in a substantially central position relative to a plurality of sub-stations (including, e.g., the processing sub-station  100 ) of a single-cell workstation. The robotic arm  112  may be attached to and extend from a base/body portion (not shown) connected to ground, G. 
     The robotic arm  112  may include an end effecter  114 . The end effecter  114  may include a claw, gripper, or other means for removably-securing the wheel, W, to the robotic arm  112 . The end effecter  114  permits the robotic arm  112  to have the ability to retain and not release the wheel, W, throughout the entire procedure performed by the processing sub-station  100  (and, if applied in a single-cell workstation, the ability to retain and not release the wheel, W, throughout the entire assembling procedure of the tire-wheel assembly, TW). Accordingly, the end effecter  114  minimizes or eliminates the need of the robotic arm  112  to “hand-off” the tire-wheel assembly, TW, to (a) subsequent sub-station(s) (not shown). 
     The processing sub-station  100  may perform several functions/duties including that of: (1) a tire repository sub-station and (2) a mounting sub-station. A tire repository sub-station typically includes one or more tires, T, that may be arranged in a “ready” position for subsequent joining to a wheel, W. A mounting sub-station typically includes structure that assists in the joining of a tire, T, to a wheel, W (e.g., the disposing of a wheel, W, within the passage, T P , of the tire, T). 
     Referring to  FIG. 4A , the processing sub-station  100  may be initialized by joining a wheel, W, to the robotic arm  112  at the end effecter  114 . The processing sub-station  100  may also be initialized by positioning the tire, T, upon a support member  116 . The support member  116  may include a first support member  116   a , a second support member  116   b  and a third support member  116   c . Each of the first, second and third support members  116   a ,  116   b ,  116   c  include an upper surface  116 ′ and a lower surface  116 ″. 
     The lower surface  116 ″ of each of the first, second and third support members  116   a ,  116   b ,  116   c  may be respectively connected to at least one first leg member  118   a , at least one second leg member  118   b  and at least one third leg member  118   c . Each of the at least one first, second and third leg members  118   a ,  118   b ,  118   c  respectively include a length for elevating or spacing each of the first, second and third support members  116   a ,  116   b ,  116   c  from an underlying ground surface, G. Although the robotic arm  112  is not directly connected to the support member  116  (but, rather may be connected to ground, G), the robotic arm  112  may be said to be interfaceable with (as a result of the movements D 1 -D 8  described in the following disclosure) and/or indirectly connected to the support member  116  by way of a common connection to ground, G, due the leg members  118   a - 118   c  connecting the support member  116  to ground, G. 
     The processing sub-station  100  may further include a plurality of tire-engaging devices  120 . The plurality of tire-engaging devices  120  may include a first tire-engaging device  120   a  connected to the upper surface  116 ′ of the first support member  116   a , a second tire-engaging device  120   b  connected to the upper surface  116 ′ of the second support member  116   b  and a third tire-engaging device  120   c  connected to the upper surface  116 ′ of the third support member  116   c.    
     In reference to the processing sub-station  10  of  FIGS. 1A-3J , the plurality of tire-engaging devices  20  may be said to be in a fixed orientation with respect to the upper surface  16 ′ of each of the first, second and third support members  16   a ,  16   b ,  16   c . However, as will be described in the following disclosure, the plurality of tire-engaging devices  120  of the processing sub-station  100  may be said to be in a non-fixed, moveable orientation with respect to the upper surface  116 ′ of each of the first, second and third support members  116   a ,  116   b ,  116   c.    
     Referring to  FIGS. 4B-4C , the first tire-engaging device  120   a  may include a body  122   a  having a front (right) side, tire-tread-engaging surface  122   a ′, a rear (left) side surface  122   a ″, an upper surface  122   a ′ and a lower surface  122   a ″″ (see, e.g.,  FIG. 4C ). Each of the second and third tire-engaging devices  120   b ,  120   c  may include a body  122   b ,  122   c  having an upper tire-sidewall-engaging surface  122   b ′,  122   c ′ a rear side surface  122   b ″,  122   c ″ and a lower surface  122   b ′″,  122   c ′″ (see, e.g.,  FIG. 4C ). 
     The upper sidewall-engaging surfaces  122   b ′,  122   c ′ of the second and third tire-engaging devices  120   b ,  120   c  may be co-planar with one another. The upper sidewall-engaging surfaces  122   b ′,  122   c ′ of the second and third tire-engaging devices  120   b ,  120   c  may be arranged in a spaced-apart relationship with respect to ground, G, that is greater than that of the spaced-apart relationship of the upper surface  116 ′ of the first support member  116   a ; accordingly, the upper sidewall-engaging surfaces  122   b ′,  122   c ′ of the second and third tire-engaging devices  120   b ,  120   c  may be arranged in a non-co-planar relationship with respect to the upper surface  116 ′ of the first support member  116   a.    
     The rear side surface  122   a ″ of the body  122   a  of the first tire-engaging device  120   a  may be connected to a first rod  124   a . The first rod  124   a  may be connected to a first actuator, A 1  (see, e.g.,  FIG. 4B ). The lower surface  122   a ″″ of the body  122   a  of the first tire-engaging device  120   a  may include at least one female recess  126   a  (see, e.g.,  FIG. 4C ). The at least one female recess  126   a  receives at least one male guide member  128   a  connected to the upper surface  116 ′ of the first support member  116   a.    
     The rear side surface  122   b ″ of the body  122   b  of the second tire-engaging device  120   b  may be connected to a second rod  124   b . The second rod  124   b  may be connected to a second actuator, A 2  (see, e.g.,  FIG. 4B ). The lower surface  122   b ′″ of the body  122   b  of the second tire-engaging device  120   b  may include at least one female recess  126   b  (see, e.g.,  FIG. 4C ). The at least one female recess  126   b  receives at least one male guide member  128   b  connected to the upper surface  116 ′ of the second support member  116   b.    
     The rear side surface  122   c ″ of the body  122   c  of the second tire-engaging device  120   c  may be connected to a third rod  124   c . The third rod  124   c  may be connected to a third actuator, A 3  (see, e.g.,  FIG. 4B ). The lower surface  122   c ′ of the body  122   c  of the third tire-engaging device  120   c  may include at least one female recess  126   c  (see, e.g.,  FIG. 4C ). The at least one female recess  126   c  receives at least one male guide member  128   c  connected to the upper surface  116 ′ of the third support member  116   c.    
     The rods  124   a - 124   c , female recesses  126   a - 126   c  and male guide members  128   a - 128   c  may assist in or contribute to the movement of the plurality of tire-engaging devices  120  relative the upper surface  116 ′ of each of the first, second and third support members  116   a ,  116   b ,  116   c . For example, each of the first, second and third rods  124   a ,  124   b ,  124   c  may providing a driving force and/or a reactive force (e.g., by way of a spring) to, respectively, the first, second and third tire-engaging devices  120   a ,  120   b ,  120   c , in order to respectively cause or react to forward or backward movement of the first, second and third tire-engaging devices  120   a ,  120   b ,  120   c . If a spring is included as or with one or more of the actuators A 1 -A 3 , the spring may bias one or more of the first, second and third rods  124   a ,  124   b ,  124   c  to a particular orientation; accordingly, if an object, such as, for example, one or more of the tire, T, and wheel, W, pushes or exerts a force upon one or more of the first, second and third tire-engaging devices  120   a ,  120   b ,  120   c , the reactive/biasing force of the spring may act upon one or more of the first, second and third tire-engaging devices  120   a ,  120   b ,  120   c  in order to regulate movement of one or more of the first, second and third tire-engaging devices  120   a ,  120   b ,  120   c  relative to the upper surface  116 ′ of one or more of the first, second and third support members  116   a ,  116   b ,  116   c . The female recesses  126   a - 126   c  and male guide members  128   a - 128   c  may assist in providing linear movement of the first, second and third tire-engaging devices  120   a ,  120   b ,  120   c  relative to the upper surface  116 ′ of the first, second and third support members  116   a ,  116   b ,  116   c.    
     With continued reference to  FIGS. 4B-4C , a first tire-tread-engaging post  130   a  may extend from the upper tire-sidewall-engaging surface  122   b ′ of the second tire-engaging device  120   b . A second tire-tread-engaging post  130   b  may extend from the upper tire-sidewall-engaging surface  122   c ′ of the third tire-engaging device  120   c . Each of the first and second tire-tread-engaging posts  130   a ,  130   b  include an upper tire-sidewall-engaging surface  132   a ,  132   b.    
     Referring to  FIG. 4B , the second and third support members  116   b ,  116   c  are separated by a gap or first spacing, S 1 . The first tire-tread-engaging post  130   a  is separated from the second tire-tread-engaging post  130   b  by a gap or second spacing, S 2 ′. The second spacing, S 2 ′, may be greater than the first spacing, S 1 . The first spacing, S 1 , may be approximately equal to, but slightly greater than the diameter, W D , of the wheel, W; further, the tire diameter, T D /central chord, T C2 , may be greater than the first spacing, S 1 . The second spacing, S 2 ′, may be approximately equal to the left chord, T C1 , and the right chord, T C3 , of the tire, T; further, the tire diameter, T D /central chord, T C2 , may be greater than the second spacing, S 2 ′. 
     The first spacing, S 1 , of the processing sub-station  100  is substantially similar to the first spacing, S 1 , of the processing sub-station  10 . The second spacing, S 2 ′, of the processing sub-station  100  is substantially similar to the second spacing, S 2 , of the processing sub-station  10 ; however, the second spacing, S 2 ′, of the processing sub-station  100  is different than that of the second spacing, S 2 , of the processing sub-station  10  due to the movement of the second and third tire-engaging devices  120   b ,  120   c  of the processing sub-station  100 . Accordingly, the second spacing, S 2 ′, of the processing sub-station  100  may be referred to as a “variable” or “adjustable” second spacing, S 2 ′. 
     In reference to the processing sub-station  10  of  FIGS. 1A-3J , the first, second and third support members  16   a ,  16   b ,  16   c  may be said to be individual units arranged in a spaced-apart relationship. In reference to the processing sub-station  100  of  FIGS. 4A-4C , the plurality the first, second and third support members  116   a ,  116   b ,  116   c  may also be said to be individual units; however, as seen, for example, in  FIG. 4B , a forward (e.g., right) end  116   a   ER  of the first support member  116   a  may be arranged in an abutting or adjacent relationship with respect to a rearward (e.g., left) end  116   b   EL  of the second support member  116   b  and a rearward (e.g., left) end  116   c   EL  of the third support member  116   c . Further, as seen in  FIG. 4B , the at least one male guide member  128   a  connected to the upper surface  116 ′ of the first support member  116   a  may extend all the way to and terminate at the forward (e.g., right) end  116   a   ER  of the first support member  116   a.    
     As seen in  FIG. 4A  with reference to  FIGS. 5A and 6A , prior to joining the tire, T, to the wheel, W, the tire, T, may be said to be arranged in a first relaxed, unbiased orientation such that the upper tire opening, T OU , and the lower tire opening, T OL , define the passage, T P , to include a diameter, T P-D . When the tire, T, is joined to the wheel, W (see, e.g.,  FIGS. 5J and 6J ), the upper bead, T BU , and the lower bead, T BL , may be arranged proximate but not seated adjacent, respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W; later, upon inflating the tire, T, at, e.g., an inflation sub-station (not shown), the upper bead, T BU , and the lower bead, T BL , may be seated (i.e., disposed adjacent), respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W. Further, when the tire, T, is joined to the wheel, W (see, e.g.,  FIGS. 5J and 6J ), the tire, T, may be said to be arranged in a second substantially relaxed, but somewhat biased orientation such that the diameter, T P-D , of the passage, T P , is substantially circular and substantially similar to its geometry of the first relaxed, unbiased orientation of the tire, T. 
     Referring to  FIG. 5A , the robotic arm  112  is arranged in a spaced-apart orientation with respect to the support member  116 , which includes the tire, T, arranged in a “ready” position. As seen in  FIGS. 5A and 6A , the “ready” position may include the tread surface, T T , of the tire, T, arranged adjacent the front, tire-tread-engaging surface  122   a ′ of the body  122   a  of the first tire-engaging device  120   a , and, further, the “ready” position may further include the tire, T, being arranged in a first angularly-offset orientation, θ 1  (see, e.g.,  FIG. 5A ), with respect to the upper surface  116 ′ of the first support member  116   a.    
     Referring to  FIG. 5A , the first angularly-offset orientation, θ 1 , of the tire, T, may result from the non-co-planar relationship the upper sidewall-engaging surfaces  122   b ′,  122   c ′ of the second and third tire-engaging devices  120   b ,  120   c  with that of the upper surface  116 ′ of the first support member  116   a  such that: (1) the first portion, T SL-1 , of the lower sidewall surface, T SL , being arranged adjacent the upper surface  116 ′ of the first support member  116   a , (2) as seen in  FIGS. 5A and 6A , the second portion, T SL-2 , of the lower sidewall surface, T SL , being arranged adjacent a portion of the upper tire-sidewall-engaging surface  132   a  of the first tire-tread-engaging post  130   a  of the second tire-engaging device  120   b  (noting that the second portion, T SL-2 , is not represented in  FIG. 5A  due to the cross-sectional reference line of  FIG. 4A ), and (3) a third portion, T SL-3 , of the lower sidewall surface, T SL , being arranged adjacent a portion of the upper tire-sidewall-engaging surface  132   b  of the second tire-tread-engaging post  130   b  of the third tire-engaging device  120   c . Accordingly, the support member  116  may provide a three-point support (which is more clearly shown at  FIG. 4A ) at T SL-1 , T SL-2 , T SL-3  for the lower sidewall surface, T SL , of the tire, T, while remaining portions of the lower sidewall surface, T SL , of the tire, T, are not in direct contact with any other portion of the upper surface surfaces  116 ′,  132   a ,  132   b  of the support member  116  when the tire, T, is arranged in the first angularly-offset orientation, θ 1 . 
     The processing sub-station  100  may execute a mounting procedure by causing a controller, C (see, e.g.,  FIG. 4A ) to send one or more signals to a motor, M (see, e.g.,  FIG. 4A ), that drives movement (according to the direction of the arrows, D 1 -D 9 —see  FIGS. 5A-5J ) of the robotic arm  112 . Alternatively or in addition to automatic operation by the controller, C, according to inputs stored in memory, the movement, D 1 -D 9 , may result from one or more of a manual, operator input, O (e.g., by way of a joystick, depression of a button or the like). 
     As seen in  FIG. 5A , a first, down, D, movement according to the direction of arrow, D 1 , may reduce the spaced-apart orientation of robotic arm  112  with respect to the support member  116 . A second movement according to the direction of arrow, D 2 , may cause the end effecter  114  to rotate the wheel, W, in, for example, a counter-clockwise direction. The movement according to the direction of the arrows, D 1 , D 2 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 5B , the movement according to the direction of the arrows, D 1 , D 2 , may cease upon locating a first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, within the passage, T P , of the tire, T, such that a first (e.g., left) portion of the drop center, W DC , of the wheel, W, is disposed adjacent a first (e.g., left) portion of the upper bead, T BU , of the tire, T. Because a first (e.g., left) portion the tread surface, T T , of the tire, T, is arranged adjacent the front, tire-tread-engaging surface  122   a ′ of the body  122   a  of the first tire-engaging device  120   a , subsequent movements of the wheel, W, resulting from movement of the robotic arm  112  prevents the tire, T, from moving away (e.g., to the left, L) from the second and third support members  116   b ,  116   c.    
     With continued reference to  FIG. 5B , a third movement according to the direction of arrow, D 3 , may cause forwardly (e.g., to the right, R) movement of the wheel, W. A fourth movement according to the direction of arrow, D 4 , may cause the end effecter  114  to rotate the wheel, W, in, for example, a clockwise direction (i.e., rotationally opposite that of the direction of arrow, D 2 ). The movement according to the direction of the arrows, D 3 , D 4 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 5C , the movement according to the direction of the arrows, D 3 , D 4 , may cease upon locating a second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC  of the wheel, W, within the passage, T P , of the tire, T, such that a second (e.g., right) portion of the drop center, W DC , and lower bead seat, W SL , of the wheel, W, are disposed proximate but not adjacent a second (e.g., right) portion of the lower bead, T BL , and away from the second (e.g., right) portion of the upper bead, T BU , of the tire, T. As stated above, because the first (e.g., left) portion the tread surface, T T , of the tire, T, is arranged adjacent the front, tire-tread-engaging surface  122   a ′ of the body  122   a  of the first tire-engaging device  120   a , the movements, D 3 , D 4 , of the wheel, W, resulting from movement of the robotic arm  112  prevents the tire, T, from moving rearwardly away (e.g., to the left, L), from the second and third support members  116   b ,  116   c.    
     Referring to  FIG. 5C , although the movement according to the direction of the arrows, D 3 , D 4 , does not result in the tire, T, moving rearward with respect to the second and third support members  116   b ,  116   c , the portions of the lower sidewall surface, T SL , of the tire, T, may no longer be arranged adjacent to the upper tire-sidewall-engaging surfaces  132   a ,  132   b  of the first and second tire-tread-engaging posts  130   a ,  130   b ; this may result from the wheel, W, pressing upon and pivoting the tire, T (about the point of support, T SL-1 , adjacent the upper surface  116 ′), in a counter-clockwise direction. Accordingly, the tire, T, may no longer be arranged adjacent the support member  116  at three points of support; rather, the tire, T, only contact the support member  116  at one point of support, T SL-1 , being the upper surface  116 ′ of the first support member  116   a.    
     Further, as a result the orientation of the tire, T, being supported at one point of support, T SL-1 , the tire, T, is no longer arranged at the first angularly-offset orientation, θ 1 , with respect to the upper surface  116 ′ of the first support member  116   a . Rather, as seen in  FIG. 5C , the tire, T, is arranged at a second angularly-offset orientation, θ 2 , with respect to the lower sidewall surface, T SL , and the upper surface  116 ′ of the first support member  116   a ; the second angularly-offset orientation, θ 2 , may be greater than that of the first angularly-offset orientation, θ 1 . 
     With continued reference to  FIG. 5C , a fifth movement according to the direction of arrow, D 5 , may cause one or more of a further forwardly (e.g., to the right, R) and downwardly (e.g., down, D) movement of the wheel, W. A sixth movement according to the direction of arrow, D 6 , may cause the end effecter  114  to rotate the wheel, W, in, for example, a further clockwise direction. The movement according to the direction of the arrows, D 5 , D 6 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 5D , the movement according to the direction of the arrows, D 5 , D 6 , may cease upon adjusting an orientation of the wheel, W, relative to the tire, T, as follows: (1) the entire lower bead seat, W SL , is located within the passage, T P , of the tire, T, and (2) the entire upper bead, T BU , is disposed about and adjacent the drop center, W DC , of the wheel, W 
     Further, as seen in  FIG. 5D , the movement according to the direction of the arrows, D 5 , D 6 , may result in the wheel, W, being disposed within the passage, T P , of the tire, T, and partially connected to the tire, T, such that the robotic arm  112  may utilize the wheel, W, to lift and carry the tire, T, by way of the temporary connection of the entire upper bead, T BU , being disposed about and adjacent the drop center, W DC , of the wheel, W. Further, the wheel, W, and the tire, T, may be said to be arranged in a “partially mounted” orientation. 
     Once arranged in the “partially mounted” orientation, the robotic arm  112  may move the wheel, W, and tire, T, forwardly (e.g., to the right, R) such that the front, tire-tread-engaging surface  122   a ′ of the body  122   a  of the first tire-engaging device  120   a  is no longer arranged adjacent the tread surface, T T , of the tire, T. Further, the movement according to the direction of the arrows, D 5 , D 6 , may result in the wheel, W, carrying the tire, T, up or over the first and second tire-tread-engaging posts  130   a ,  130   b  such that the tire, T, and wheel, W, are arranged substantially forwardly of (e.g., to the right, R) of the first and second tire-engaging posts  130   a ,  130   b . Yet even further, the movement according to the direction of the arrows, D 5 . D 6 . may result in the lower, outer rim surface, W RL , of the wheel, W, and the lower sidewall surface, T SL , of the tire, T, being arranged proximate, but in a substantially parallel, but spaced-apart relationship with respect to the upper tire-sidewall-engaging surface  122   b ′,  122   c ′ of the body  122   b ,  122   c  of the second and third tire-engaging devices  120   b ,  120   c.    
     With reference to  FIG. 6D , which is a top view of  FIG. 5D , the tread surface, T T , of the tire, T, is arranged proximate, but in a spaced-apart relationship with respect to the first and second tire-tread-engaging posts  130   a ,  130   b . Further, as seen in  FIG. 5D , because the tread surface, T T , of the tire, T, no longer contacts the front, tire-tread-engaging surface  122   a ′ of the body  122   a  of the first tire-engaging device  120   a , the first tire-engaging device  120   a  may be moved rearwardly (e.g., to the left, L) and away from the second and third tire-engaging devices  120   b ,  120   c . With continued reference to  FIG. 5D , a seventh movement according to the direction of arrow, D 7 , may cause a downwardly, D, movement of the wheel, W. 
     Referring to  FIG. 5E , the movement according to the direction of the arrow, D 7 , results in the wheel, W, “plunging” through the passage, T P , of the tire, T, such that: (1) the first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, are orientated out of the passage, T P , of the tire, T, and in a spaced-apart, opposing orientation with the lower sidewall surface, T SL , of the tire, T, and (2) a portion (e.g., a right portion) of a lower, outer rim surface, W RL , of the wheel, W, (proximate the second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W), is disposed within the passage, T P , of the tire, T, and adjacent to the second (e.g., right) portion of the lower bead, T BL , of the tire, T. 
     Per the phantom lines of the body  122   c  of the third tire-engaging device  120   c  (as a result of the orientation of the wheel, W, and tire, T), the movement of the robotic arm  112  according to the direction of the arrow, D 7 , results in a portion of the wheel, W, being arranged in the gap or first spacing, S 1 , and the left tire chord, T C1  (see, e.g., corresponding top view  FIG. 6E ), being arranged proximate but slightly to the right of the first and second tire-tread-engaging posts  130   a ,  130   b  such that a portion of the tire, T, is arranged in the gap or second spacing, S 2 ′, but not adjacent the first and second tire-tread-engaging posts  130   a ,  130   b.    
     Because the gap or first spacing, S 1 , is approximately equal to but greater than a diameter, W D , of the wheel, W, the robotic arm  112  is permitted to move the wheel, W, into/through the gap or first spacing, S 1 , and below the upper tire-sidewall-engaging surface  122   b ′,  122   c ′ of the body  122   b ,  122   c  of the second and third tire-engaging devices  120   b ,  120   c ; however, because the diameter, T D , of the tire, T, is greater than that of the gap or first spacing, S 1 , the movement of robotic arm  112  prohibits movement of the tire, T, through the gap or first spacing, S 1 , with that of the wheel, W. As a result of the wheel, W, being permitted to pass through the gap or first spacing, S 1 , without the tire, T, the lower bead seat, W SL , and drop center, W DC , of the wheel, W, are permitted to “plunge” through (as seen in  FIG. 5E ) the passage, T P , of the tire, T. 
     As a result of the wheel, W, plunging through the passage, T P , of the tire, T, a first (e.g., left) portion of the safety bead, W SB , of the wheel, W, may be disposed substantially adjacent the first (e.g., left) portion of the upper bead, T BU , of the tire, T. Further, as a result of the arrangement of the safety bead, W SB , substantially adjacent the first (e.g., left) portion of the upper bead, T BU , of the tire, T, and the arrangement of the portion of the lower, outer rim surface, W RL , of the wheel, W, adjacent the second (e.g., right) portion of the lower bead, T BL , of the tire, T, a substantially downwardly force, DF, is transmitted from the robotic arm  112 , to the wheel, W, and to the contact points of the wheel, W, with the tire, T, described above at the safety bead, W SB , and lower, outer rim surface, W RL . The substantially downwardly force, DF, further causes a portion of the lower sidewall surface, T SL , of the tire, T, to no longer be spaced-apart, but, adjacent with respect to and in direct contact with the upper surfaces  122   b ′,  122   c ′ of the second and third support members  116   b ,  116   c ; accordingly, the downwardly force, DF, is distributed from the wheel, W, and to the tire, T, and ultimately arrives at and is distributed to the upper surfaces  122   b ′,  122   c ′ of the second and third support members  116   b ,  116   c.    
     With continued reference to  FIG. 5E , an eighth movement according to the direction of arrow, D 8 , may cause a rearwardly (e.g., to the left, L) movement of the wheel, W. Referring to  FIG. 5F , as a result of the movement according to the direction of the arrows D 1 -D 8 , the lower bead, T BL , of the tire, T, is arranged in a curved, substantially arcuate orientation over the sidewall-engaging surface  122   b ′,  122   c ′ of the body  122   b ,  122   c  of the second and third tire-engaging devices  120   b ,  120   c . Further, as a result of the initial rearwardly (e.g., to the left, L) movement of the wheel, W, the tire, T, is advanced through the second spacing, S 2 ′, from the left chord, T C1 , to the right chord, T C3 ; as seen in  FIG. 6F-6J , because chords (including, e.g., the central chord, T C2 ) of the tire, T, between the left chord, T C1 , to the right chord, T C3 , are greater than that of the left chord, T C1 , and the right chord, T C3 , the first and second tire-tread-engaging posts  130   a ,  130   b  interfere with movement of the tire, T, through the second spacing, S 2 ′. The interference of the first and second tire-tread-engaging posts  130   a ,  130   b  with the tire, T, includes the contacting of a first tread surface portion, T T1  (see, e.g.,  FIG. 6F ) and a second tread surface portion, T T2  (see, e.g.,  FIG. 6F ) of the tread surface, T T , of the tire, T, with that of the tire-tread-engaging posts  130   a ,  130   b.    
     Referring back to  FIG. 5D , the “plunging” action described above may result in, for example, the wheel, W, pushing upon the tire, T, such that the lower sidewall surface, T SL , of the tire, T, contact the upper surfaces  122   b ′,  122   c ′ of the second and third support members  116   b ,  116   c . Further, because the diameter, W D , of the wheel, W, is larger than the diameter, T D , of the tire, T, a portion of the lower bead, T BL , of the tire, T (see, e.g., phantom portion of the lower bead, T BL ′), may be deformed or deflected in order to pass the wheel, W, through the passage, T P , of the tire, T. Although such deformation/deflection permits the tire-wheel assembly, TW, to be processed, in some circumstances, the deformation/deflection may not be desirable (e.g., the integrity of the lower bead, T BL , of the tire, T, may be unintentionally compromised). 
     In order to obviate the exemplary deformation, T BL ′, of the tire, T, described above, the direction of the arrows, D 5 , D 6  (from  FIG. 5C ), may include a directional component that results in the wheel, W, being arranged at an offset angle with respect to the tire, T. As seen in FIG.  5 D′, the lower sidewall surface, T SL , of the tire, T, is arranged in a substantially parallel relationship with respect to the upper surfaces  122   b ′,  122   c ′ of the second and third support members  116   b ,  116   c ; the wheel, W, however, is not arranged in parallel with respect to the upper surfaces  122   b ′,  122   c ′ of the second and third support members  116   b ,  116   c , and, as such, is arranged in a canted or angularly-offset relationship with respect to the tire, T. Referring to FIG.  5 E′, as a result of the arrangement of the wheel, W, with respect to the tire, T, when the wheel, W, is plunged through the passage, T P , of the tire, T, the portion of the lower bead, T BL , of the tire, T, may be less likely to interfere with the movement of the wheel, W, and, as a result, the tire, T, is less likely to be deformed or deflected (as shown at T BL ′ in  FIG. 5D ) as the wheel, W, passes through the passage, T P , of the tire, T. 
     Referring to  FIG. 6E , in an embodiment, the second and third actuators, A 2 , A 3  may include, for example, motors that may retract the second and third tire-engaging devices  120   b ,  120   c  in a manner to arrange the first and second tire-tread-engaging posts  130   a ,  130   b  in order to provide the (variable) second spacing, S 2 ′. Prior to the initial rearwardly (e.g., to the left, L) movement, of the wheel, W, and tire, T, the actuators, A 2 , A 3 , may cause an initial, partial retraction of the second and third tire-engaging devices  120   b ,  120   c  in a manner to arrange the first and second tire-tread-engaging posts  130   a ,  130   b  according to the direction of arrows, O 1 , O 2 . 
     Referring to  FIGS. 6F-6I , upon the initial rearwardly (e.g., to the left, L) movement of the wheel, W, the tire, T, is advanced through the second spacing, S 2 ′, without further actuation of the motors, A 2 , A 3 ; accordingly the first and second tire-tread-engaging posts  130   a ,  130   b  remain in a fixed orientation and interfere with the tire, T, and press the tire, T, radially inwardly in a manner such that the tire, T, is temporality deformed such that the diameter, T P-D , of the passage, T P , of the tire, T, is temporality upset to include a substantially oval form rather than a circular form. Accordingly, in a substantially similar fashion, the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , are also temporality upset to include a substantially oval form rather than a circular form. 
     The oval form of the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , reduces a portion of contact (and, as a result, friction) of the lower bead, T BL , and the upper bead, T BU , of the tire, T, with that of the outer circumferential surface, W C , of the wheel, W. Accordingly, referring to  FIGS. 5G-5I  and  6 G- 6 I, as the wheel, W, advances the tire, T, through the second spacing, S 2 ′, the oval deformation of diameters, T P-D , T OU-D , T OL-D  results in the lower bead, T BL , of the tire, T, encountering less resistance or interference with the outer rim surface, W R-L , of the wheel, W, as the lower bead, T BL , is advanced from being orientated opposite the outer rim surface, W RL , to being arranged over the lower bead seat, W SL , and to a final position adjacent the drop center, W DC , of the wheel, W, as the tire, T, is advanced from the forwardly orientation (e.g., to the right, R) of the first and second tire-tread-engaging posts  130   a ,  130   b  back to the rearwardly orientation (e.g., to the left, L) of the first and second tire-tread-engaging posts  130   a ,  130   b.    
     Referring to  FIGS. 5I-5J  and  6 I- 6 J, once the central chord, T C2 , or the right chord, T C3 , has been advanced through the second spacing, S 2 ′, the motors, A 2 , A 3 , may be actuated in order to further retract the first and second tire-tread-engaging posts  130   a ,  130   b  outwardly according to the direction of the arrows, O 1 , O 2 . Accordingly, as seen in  FIG. 6J , the first and second tire-tread-engaging posts  130   a ,  130   b  may no longer contact the tread surface, T T , of the tire, T. Further, as a result of the movement of the wheel, W, and tire, T, through the spacing, S 2 ′, the entire circumference of the lower bead, T BL , is advanced to its final “mounted position” adjacent to and about the drop center, W DC ; further, the entire circumference of the upper bead, T BU , is arranged in its final “mounted position” adjacent to and about the outer circumferential surface, W C , of the wheel, W, proximate the safety bead, W SB . 
     In addition to the result of the movement according to the direction of the arrow, D 8 , and the actuation of the actuators, A 2 , A 3 , referring to  FIG. 5F , the first actuator, A 1 , may be actuated in order to move the body  122   a  of the first tire-engaging device  120   a  in a forwardly (e.g., right, R) direction along the at least one male guide member  128   a  toward the forward end  116   a   ER  of the first support member  116   a ; the movement of the first tire-engaging device  120   a  by way of the actuator, A 1 , in the forwardly direction may be conducted just prior to, or, in conjunction with the rearwardly, (to the left, L) movement initiated by the robotic arm  112  according to the direction of the arrow, D 8 . 
     Referring to  FIG. 5G , when driven to the forward end  116   a   ER  of the first support member  116   a , the upper surface  122   a ′″ of the body  122   a  of the first tire-engaging device  120   a  may be substantially coplanar with the upper tire-sidewall-engaging surface  122   b ′,  122   c ′ of the body  122   b ,  122   c  of the second and third tire-engaging devices  120   b ,  120   c . Accordingly, the upper surface  122   a ′″ of the body  122   a  of the first tire-engaging device  120   a  may serve as an “extension surface” of the upper tire-sidewall-engaging surface  122   b ′,  122   c ′ of the body  122   b ,  122   c  of the second and third tire-engaging devices  120   b ,  120   c . Referring to  FIGS. 5H-5I , as the tire, T, through the second spacing, S 2 ′, rearwardly (e.g., to the left, L), the first actuator, A 1 , may be actuated in order to move the body  122   a  of the first tire-engaging device  120   a  in a correspondingly, rearwardly (e.g., left, L) direction along the at least one male guide member  128   a  away from the forward end  116   a   ER  of the first support member  116   a.    
     With reference to  FIG. 5I , after mounting the tire, T, to the wheel, W, a ninth movement of the robotic arm  112  according to the direction of arrow, D 9 , may cause upwardly movement, U, of the wheel, W, and tire, T, away from the support member  116 . The robotic arm  112  may move the tire-wheel assembly, TW, to, for example, a subsequent sub-station (not shown), such as, for example, an inflation sub-station in order to inflate the tire-wheel assembly, TW, which may cause the upper bead, T BU , to be seated adjacent the upper bead seat, W SU , and the lower bead, T BL , to be seated adjacent the lower bead seat, W SL . 
     Referring to  FIG. 7A , a processing sub-station  200  for processing a tire-wheel assembly, TW, is shown according to an embodiment. The “processing” conducted by the processing sub-station  200  may include the act of “joining” or “mounting” a tire, T, to a wheel, W, for forming the tire-wheel assembly, TW. The act of “joining” or “mounting” may mean to physically couple, connect or marry the tire, T, and wheel, W, such that the wheel, W, may be referred to as a male portion that is inserted into a passage, T P , of a tire, T, being a female portion. 
     As described and shown in the following Figures, although the desired result of the processing sub-station  200  is the joining or mounting of the tire, T, and wheel, W, to form a tire-wheel assembly, TW, it should be noted that the processing sub-station  200  does not inflate the circumferential air cavity, T AC , of the tire, T, of the tire-wheel assembly, TW, nor does the processing sub-station  200  contribute to an act of “seating” the upper bead, T BU , or the lower bead, T BL , of the tire, T, adjacent the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W (because the act of “seating” typically arises from an inflating step where the tire-wheel assembly, TW, is inflated). Accordingly, upon joining or mounting the tire, T, to the wheel, W, the upper bead, T BU , or the lower bead, T BL , of the tire, T, may be arranged about and/or disposed adjacent the outer circumferential surface, W C , of the wheel, W. 
     In an implementation, the processing sub-station  200  may be included as part of a “single-cell” workstation. A single-cell workstation may include other sub-stations (not shown) that contribute to the processing of a tire-wheel assembly, TW; other sub-stations may include, for example: a soaping sub-station, a stemming sub-station, an inflating sub-station, a match-marking sub-station, a balancing sub-station and the like. The term “single-cell” indicates that the sub-stations contribute to the production of a tire-wheel assembly, TW, without requiring a plurality of successive, discrete workstations that may otherwise be arranged in a conventional assembly line such that a partially-assembled tire-wheel assembly, TW, is “handed-off” along the assembly line (i.e., “handed-off” meaning that an assembly line requires a partially-assembled tire-wheel assembly, TW, to be retained by a first workstation of an assembly line, worked on, and released to a subsequent workstation in the assembly line for further processing). Rather, a single cell workstation provides one workstation having a plurality of sub-stations each performing a specific task in the process of assembling a tire-wheel assembly, TW. This assembling process takes place wherein the tire and/or wheel “handing-off” is either minimized or completely eliminated. As such, a single-cell workstation significantly reduces the cost and investment associated with owning/renting the real estate footprint associated with a conventional tire-wheel assembly line while also having to provide maintenance for each individual workstation defining the assembly line. Thus, capital investment and human oversight is significantly reduced when a single cell workstation is employed in the manufacture of tire-wheel assemblies, TW. 
     Referring to  FIG. 7A , the processing sub-station  200  includes a device  212 . The device  212  may be referred to as a robotic arm. The robotic arm  212  may be located in a substantially central position relative to a plurality of sub-stations (including, e.g., the processing sub-station  200 ) of a single-cell workstation. The robotic arm  212  may be attached to and extend from a base/body portion (not shown) connected to ground, G. 
     The robotic arm  212  may include an end effecter  214 . The end effecter  214  may include a claw, gripper, or other means for removably-securing the wheel, W, to the robotic arm  212 . The end effecter  214  permits the robotic arm  212  to have the ability to retain and not release the wheel, W, throughout the entire procedure performed by the processing sub-station  200  (and, if applied in a single-cell workstation, the ability to retain and not release the wheel, W, throughout the entire assembling procedure of the tire-wheel assembly, TW). Accordingly, the end effecter  214  minimizes or eliminates the need of the robotic arm  212  to “hand-off” the tire-wheel assembly, TW, to (a) subsequent sub-station(s) (not shown). 
     The processing sub-station  200  may perform several functions/duties including that of: (1) a tire repository sub-station and (2) a mounting sub-station. A tire repository sub-station typically includes one or more tires, T, that may be arranged in a “ready” position for subsequent joining to a wheel, W. A mounting sub-station typically includes structure that assists in the joining of a tire, T, to a wheel, W (e.g., the disposing of a wheel, W, within the passage, T P , of the tire, T). 
     Referring to  FIG. 7A , the processing sub-station  200  may be initialized by joining a wheel, W, to the robotic arm  212  at the end effecter  214 . The processing sub-station  200  may also be initialized by positioning the tire, T, upon a support member  216 . The support member  216  may include a first support member  216   a , a second support member  216   b  and a third support member  216   c . Each of the first, second and third support members  216   a ,  216   b ,  216   c  include an upper surface  216 ′ and a lower surface  216 ″. 
     The lower surface  216 ″ of each of the first, second and third support members  216   a ,  216   b ,  216   c  may be respectively connected to at least one first leg member  218   a , at least one second leg member  218   b  and at least one third leg member  218   c . Each of the at least one first, second and third leg members  218   a ,  218   b ,  218   c  respectively include a length for elevating or spacing each of the first, second and third support members  216   a ,  216   b ,  216   c  from an underlying ground surface, G. Although the robotic arm  212  is not directly connected to the support member  216  (but, rather may be connected to ground, G), the robotic arm  212  may be said to be interfaceable with (as a result of the movements D 1 -D 6  described in the following disclosure) and/or indirectly connected to the support member  216  by way of a common connection to ground, G, due the leg members  218   a - 218   c  connecting the support member  216  to ground, G. 
     The processing sub-station  200  may further include a plurality of tire-engaging devices  220 . The plurality of tire-engaging devices  220  may include a first tire-engaging device  220   b  connected to the upper surface  216 ′ of the second support member  216   b  and a second tire-engaging device  220   c  connected to the upper surface  216 ′ of the third support member  216   c.    
     In reference to the processing sub-station  10  of  FIGS. 1A-3J , the plurality of tire-engaging devices  20  may be said to be in a fixed orientation with respect to the upper surface  16 ′ of each of the first, second and third support members  16   a ,  16   b ,  16   c . However, as will be described in the following disclosure, the plurality of tire-engaging devices  220  of the processing sub-station  200  may be said to be in a non-fixed, moveable orientation with respect to the upper surface  216 ′ of each of the second and third support members  216   b ,  216   c . Further, in comparison the processing sub-station  10 , the processing sub-station  200  does not include a tire-engaging device connected to the first support member  216   a ; accordingly the processing sub-station  200  includes the first and second tire-engaging device  220   b ,  220   c  connected to the second and third support members  216   b ,  216   c.    
     Referring to  FIGS. 7B-7C , each of the first and second tire-engaging devices  220   b ,  220   c  may include a body  222   b ,  222   c  having an upper tire-sidewall-engaging surface  222   b ′,  222   c ′ a rear side surface  222   b ″,  222   c ″ (see, e.g.,  FIG. 7B ), a lower surface  222   b ′″,  222   c ′″ (see, e.g.,  FIG. 7C ) and a side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″. The geometry of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ defines the upper tire-sidewall-engaging surface  222   b ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c  to include a substantially “L shape” or “J shape.” For example, as seen in  FIGS. 7B and 7C , each of the side, wheel-circumference-engaging surfaces  222   b ″″,  222   c ″″ include a first, substantially linear segment, J 1 , and a second, substantially linear segment, J 2 , that are connected by a third, substantially arcuate segment, J 3 . 
     The upper sidewall-engaging surfaces  222   b ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c  may be co-planar with one another. The upper sidewall-engaging surfaces  222   b ′,  222   c ′ of the second and third tire-engaging devices  220   b ,  220   c  may be arranged in a spaced-apart relationship with respect to ground, G, that is greater than that of the spaced-apart relationship of the upper surface  216 ′ of the first support member  216   a ; accordingly, the upper sidewall-engaging surfaces  222   b ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c  may be arranged in a non-co-planar relationship with respect to the upper surface  216 ′ of the first support member  216   a.    
     The rear side surface  222   b ″ of the body  222   b  of the first tire-engaging device  220   b  may be connected to a first rod  224   b . The first rod  224   b  may be connected to a first actuator, A 2 . The lower surface  222   b ′″ of the body  222   b  of the first tire-engaging device  220   b  may include at least one female recess  226   b . The at least one female recess  226   b  receives at least one male guide member  228   b  connected to the upper surface  216 ′ of the second support member  116   b.    
     The rear side surface  222   c ″ of the body  222   c  of the second tire-engaging device  220   c  may be connected to a second rod  224   c . The second rod  224   c  may be connected to a second actuator, A 3 . The lower surface  222   c ′″ of the body  222   c  of the second tire-engaging device  220   c  may include at least one female recess  226   c . The at least one female recess  226   c  receives at least one male guide member  228   c  connected to the upper surface  216 ′ of the third support member  216   c.    
     The rods  224   b - 224   c , female recesses  226   b - 226   c  and male guide members  228   b - 228   c  may assist in or contribute to the movement of the plurality of tire-engaging devices  220  relative the upper surface  216 ′ of each of the second and third support members  216   b ,  216   c . For example, each of the first and second rods  224   b ,  224   c  may providing a driving force and/or a reactive force (e.g., by way of a spring) to, respectively, the first, and second tire-engaging devices  220   b ,  220   c , in order to respectively cause or react to forward or backward movement of the first and second tire-engaging devices  220   b ,  220   c . If a spring is part of or included with one or more of the actuators A 2 , A 3 , the spring may bias one or more of the first and second rods  224   b ,  224   c  to a particular orientation; accordingly, if an object, such as, for example, one or more of the tire, T, and wheel, W, pushes or exerts a force upon one or more of the first and second tire-engaging devices  220   b ,  220   c , the reactive/biasing force may act upon one or more of the first and second tire-engaging devices  220   b ,  220   c  in order to regulate movement relative to the upper surface  216 ′ of one or more of the second and third support members  216   b ,  216   c . The female recesses  226   b - 226   c  and male guide members  228   b - 228   c  may assist in providing linear movement of the first and second tire-engaging devices  220   b ,  220   c  relative to the upper surface  216 ′ of the second and third support members  216   b ,  216   c.    
     With continued reference to  FIGS. 7B-7C , a first tire-tread-engaging post  230   a  may extend from the upper tire-sidewall-engaging surface  222   b ′ of the first tire-engaging device  220   b . A second tire-tread-engaging post  230   b  may extend from the upper tire-sidewall-engaging surface  222   c ′ of the second tire-engaging device  220   c . Each of the first and second tire-tread-engaging posts  230   a ,  230   b  include an upper tire-sidewall-engaging surface  232   a ,  232   b.    
     Referring to  FIG. 7B , the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c  are separated by a gap or first spacing, S 1 ′. The first tire-tread-engaging post  230   a  is separated from the second tire-tread-engaging post  230   b  by a gap or second spacing, S 2 ′. The second spacing, S 2 ′, may be greater than the first spacing, S 1 ′. The first spacing, S 1 ′, may be approximately equal to, but slightly less than the diameter, W D , of the wheel, W; further, the tire diameter, T D /central chord, T C2 , may be greater than the first spacing, S 1 ′. The second spacing, S 2 ′, may be approximately equal to the left chord, T C1 , and the right chord, T C3 , of the tire, T; further, the tire diameter, T D /central chord, T C2 , may be greater than the second spacing, S 2 ′. 
     Because the first spacing, S 1 ′, of the processing sub-station  200  is referenced from the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″, the first spacing, S 1 ′, is different than that of the first spacing, S 1 , of the processing sub-stations  10 ,  100 . Further, the first spacing, S 1 ′, of the processing sub-station is differentiated from the first spacing, S 1 , of the processing sub-stations  10 ,  100  due to the fact that the first spacing, S 1 ′, is associated with the moveable first and second tire-engaging devices  220   b ,  220   c ; accordingly, the first spacing, S 1 ′, may be referred to as a “variable” or “adjustable” first spacing, S 1 ′. 
     The second spacing, S 2 ′, of the processing sub-station  200  is substantially similar to the second spacing, S 2 ′, of the processing sub-station  100  due to the fact that the first and second tire-engaging devices  220   b ,  220   c  are movable (as compared to the second and third tire-engaging devices  120   b ,  120   c  of the processing sub-station  100 ). Accordingly, the second spacing, S 2 ′, of the processing sub-station  200  may be referred to as a “variable” or “adjustable” second spacing, S 2 ′. 
     As seen in  FIG. 7A  with reference to  FIGS. 8A and 9A , prior to joining the tire, T, to the wheel, W, the tire, T, may be said to be arranged in a first relaxed, unbiased orientation such that the upper tire opening, T OU , and the lower tire opening, T OL , define the passage, T P , to include a diameter, T P-D . When the tire, T, is joined to the wheel, W (see, e.g.,  FIGS. 8G and 9G ), the upper bead, T BU , and the lower bead, T BL , may be arranged proximate but not seated adjacent, respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W; later, upon inflating the tire, T, at, e.g., an inflation sub-station (not shown), the upper bead, T BU , and the lower bead, T BL , may be seated (i.e., disposed adjacent), respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W. Further, when the tire, T, is joined to the wheel, W (see, e.g.,  FIGS. 8G and 9G ), the tire, T, may be said to be arranged in a second substantially relaxed, but somewhat biased orientation such that the diameter, T P-D , of the passage, T P , is substantially circular and substantially similar to its geometry of the first relaxed, unbiased orientation of the tire, T. 
     Referring to  FIG. 8A , the robotic arm  212  is arranged in a spaced-apart orientation with respect to the support member  216 , which includes the tire, T, arranged in a “ready” position. The “ready” position may include a portion of one or more of the lower sidewall surface, T SL , and the tread surface, T T , of the tire, T, arranged adjacent the upper surface  216 ′ of the first support member  216   a . Referring to  FIG. 8A , the “ready” position may further include the tire, T, being arranged in a first angularly-offset orientation, θ 1 , with respect to the upper surface  116 ′ of the first support member  116   a.    
     The first angularly-offset orientation, θ 1 , of the tire, T, may result from the non-co-planar relationship the upper sidewall-engaging surfaces  222   b ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c  with that of the upper surface  216 ′ of the first support member  216   a  such that: (1) the first portion, T SL-1 , of the lower sidewall surface, T SL , being arranged adjacent the upper surface  216 ′ of the first support member  216   a , (2) the second portion, T SL-2 , of the lower sidewall surface, T SL , being arranged adjacent a portion of the upper tire-sidewall-engaging surface  232   a  of the first tire-tread-engaging post  230   a  of the first tire-engaging device  220   b  (noting that the second portion, T SL-2 , is not represented in  FIG. 8A  due to the cross-sectional reference line of  FIG. 7A ), and (3) a third portion, T SL-3 , of the lower sidewall surface, T SL , being arranged adjacent a portion of the upper tire-sidewall-engaging surface  232   b  of the second tire-tread-engaging post  230   b  of the second tire-engaging device  220   c . Accordingly, the support member  216  may provide a three-point support (which is more clearly shown at  FIG. 7A ) at T SL-1 , T SL-2 , T SL-3  for the lower sidewall surface, T SL , of the tire, T, while remaining portions of the lower sidewall surface, T SL , of the tire, T, are not in direct contact with any other portion of the upper surface surfaces  216 ′,  232   a ,  232   b  of the support member  216  when the tire, T, is arranged in the first angularly-offset orientation, θ 1 . 
     The processing sub-station  200  may execute a mounting procedure by causing a controller, C (see, e.g.,  FIG. 7A ) to send one or more signals to a motor, M (see, e.g.,  FIG. 7A ), that drives movement (according to the direction of the arrows, D 1 -D 6 —see  FIGS. 8A-8G ) of the robotic arm  212 . Alternatively or in addition to automatic operation by the controller, C, according to inputs stored in memory, the movement, D 1 -D 6 , may result from one or more of a manual, operator input, O (e.g., by way of a joystick, depression of a button or the like). 
     As seen in  FIG. 8A , a first, down, D, movement according to the direction of arrow, D 1 , may reduce the spaced-apart orientation of robotic arm  212  with respect to the support member  216 . A second movement according to the direction of arrow, D 2 , may cause the end effecter  214  to move the wheel, W, rearwardly (e.g., to the left, L) toward the tire, T. The movement according to the direction of the arrows, D 1 , D 2 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 8B , the movement according to the direction of the arrows, D 1 , D 2 , may cease upon locating a first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, within the passage, T P , of the tire, T. With continued reference to  FIG. 8B , a third movement according to the direction of arrow, D 3 , may cause further downwardly, D, movement of the wheel, W. A fourth movement according to the direction of arrow, D 4 , may cause further rearwardly (e.g., to the left, L) movement of the wheel, W. The movement according to the direction of the arrows, D 3 , D 4 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 8C , the movement according to the direction of the arrows, D 3 , D 4 , may cause the tire, T, to rotate (e.g., in a counter-clockwise direction) as a result of the wheel, W, pushing or exerting a downwardly, D, force upon the tire, T. Accordingly, the portion (e.g., T SL-1 ) of the lower sidewall surface, T SL , of the tire, T, is no longer arranged adjacent the upper surface  216 ′ of the first support member  216   a . Further, as a result of the downwardly, D, force upon the tire, T, the lower sidewall surface, T SL , of the tire, T, no longer is arranged adjacent the upper tire-sidewall-engaging surface  232   a ,  232   b  of the first and second tire-tread-engaging posts  230   a ,  230   b . Thus, the tire, T, may no longer be arranged adjacent the support member  216  at three points of support; rather, the second and third portions (e.g., T SL-2 , T SL-3 ) that were formerly disposed adjacent the upper tire-sidewall-engaging surface  232   a ,  232   b  of the first and second tire-tread-engaging posts  230   a ,  230   b  are displaced downwardly, D, and contact the upper tire-sidewall-engaging surface  222   b ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c  to thereby provide two points of support for the lower sidewall surface, T SL , of the tire, T. As a result the orientation of the tire, T, being supported upon the upper tire-sidewall-engaging surface  222   b ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c , the tire, T, is no longer arranged at the first angularly-offset orientation, θ 1 , with respect to the support member  216 . 
     Further, as seen in  FIG. 8C , the movement according to the direction of the arrows, D 3 , D 4 , may result in the wheel, W, being disposed within the passage, T P , of the tire, T, and partially connected to the tire, T, such that the robotic arm  212  utilizes the wheel, W, to move rearwardly (e.g., to the left, L) such that the tire, T, is moved from the “ready” position to a “partially mounted” position. With reference to  FIG. 9C , which is a top view of  FIG. 8C , the tread surface, T T , of the tire, T, is arranged proximate, but in a space-apart relationship with respect to the first and second tire-tread-engaging posts  230   a ,  230   b.    
     Referring to  FIG. 8C , the movement according to the direction of the arrow, D 3 , D 4  results in the wheel, W, “plunging” through the passage, T P , of the tire, T, such that: (1) the first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, are orientated out of the passage, T P , of the tire, T, and in a spaced-apart, opposing orientation with the lower sidewall surface, T SL , of the tire, T, and (2) a portion (e.g., a right portion) of a lower, outer rim surface, W RL , of the wheel, W, (proximate the second (e.g., right) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W), is disposed within the passage, T P , of the tire, T, and adjacent to the second (e.g., right) portion of the lower bead, T BL , of the tire, T. Because the gap or first spacing, S 1 ′, is approximately equal to but less than the diameter, T D , of the tire, T, the tire, T, is not permitted to move into/through the gap or first spacing, S 1 ′, and below the upper tire-sidewall-engaging surface  222   b ′,  222   c ′ of the body  222   b ,  222   c  of the first and second tire-engaging devices  220   b ,  220   c.    
     Further, as seen in  FIGS. 8C and 9C , the movement of the robotic arm  212  according to the direction of the arrows, D 3 , D 4  results in a portion of the wheel, W, being arranged between the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c  such that a first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, respectively engages the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c ; further, the wheel, W, may be said to be arranged in the gap or first spacing, S 1 ′. Further, the movement of the robotic arm  212  results in the left tire chord, T C1 , being arranged proximate but slightly to the right of the first and second tire-tread-engaging posts  230   a ,  230   b  such that a portion of the tire, T, may be said to be arranged in the gap or second spacing, S 2 ′, but not adjacent the first and second tire-tread-engaging posts  230   a ,  230   b.    
     As a result of the wheel, W, plunging through the passage, T P , of the tire, T, a first (e.g., left) portion of the safety bead, W SB , of the wheel, W, is disposed adjacent the first (e.g., left) portion of the upper bead, T BU , of the tire, T. Further, as a result of the arrangement of the safety bead, W SB , adjacent the first (e.g., left) portion of the upper bead, T BU , of the tire, T, and the arrangement of the portion of the lower, outer rim surface, W R-L , of the wheel, W, adjacent the second (e.g., right) portion of the lower bead, T BL , of the tire, T, a substantially downwardly force, DF, is transmitted from the robotic arm  212 , to the wheel, W, and to the contact points of the wheel, W, with the tire, T, described above at the safety bead, W SB , and lower, outer rim surface, W RL . The substantially downwardly force, DF, further causes a portion of the lower sidewall surface, T SL , of the tire, T, to no longer be spaced-apart, but, adjacent with respect to and in direct contact with the upper surfaces  222 ′,  222   c ′ of the first and second tire-engaging devices  220   b ,  220   c ; accordingly, the downwardly force, DF, is distributed from the wheel, W, and to the tire, T, and ultimately arrives at and is distributed to the upper surfaces  222   b ′,  222   c ′ of the first and second tire-engaging members  220   b ,  220   c.    
     With continued reference to  FIG. 8C , a fifth movement according to the direction of arrow, D 5 , may cause a rearwardly (e.g., to the left, L) movement of the wheel, W. Referring to  FIG. 5D , as a result of the movement according to the direction of the arrows D 1 -D 5 , the lower bead, T BL , of the tire, T, is arranged in a curved, substantially arcuate orientation over the sidewall-engaging surface  222   b ′,  222   c ′ of the body  222   b ,  222   c  of the first and second tire-engaging devices  220   b ,  220   c.    
     As a result of the initial rearwardly (e.g., to the left, L) movement of the wheel, W, the wheel, W, is advanced through the first spacing, S 1 ′, as the tire, T, is advanced through the second spacing, S 2 ′, from the left chord, T C1 , to the right chord, T C3 . As seen in  FIG. 9D-9F , because chords (including, e.g., the central chord, T C2 ) of the tire, T, between the left chord, T C1 , to the right chord, T C3 , are greater than that of the left chord, T C1 , and the right chord, T C3 , the first and second tire-tread-engaging posts  230   a ,  230   b  interfere with movement of the tire, T, through the second spacing, S 2 ′. The interference of the first and second tire-tread-engaging posts  230   a ,  230   b  with the tire, T, includes the contacting of a first tread surface portion, T T1 , and a second tread surface portion, T T2 , of the tread surface, T T , of the tire, T, with that of the tire-tread-engaging posts  230   a ,  230   b.    
     Further, as a result of the initial rearwardly (e.g., to the left, L) movement of the wheel, W, as seen in  FIG. 9D-9F , because the diameter, W D , of the wheel, W, is greater than that of the first spacing, S 1 ′, the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c  interfere with movement of the wheel, W, through the first spacing, S 1 ′. The interference of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c  with the wheel, W, includes the contacting of the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, with that of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c.    
     In an embodiment, first and second actuators, A 2 , A 3  may include, for example, motors that may retract/deploy the first and second tire-engaging devices  220   b ,  220   c  in a manner to provide the (variable) first and second spacings, S 1 ′, S 2 ′. Referring to  FIGS. 9C-9D , upon the initial rearwardly (e.g., to the left, L) movement of the wheel, W, the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, directly contact the first, substantially linear segment, J 1 , of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c ; as a result, the first and second actuators, A 2 , A 3 , cause the first and second tire-engaging devices  220   b ,  200   c  to retract and move outwardly (i.e., away from one another) according to the direction of the arrows, O 1 , O 2 . 
     Referring to  FIG. 9D , as the wheel, W, is moved rearwardly (e.g., to the left, L), just as the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, cease direct contact of the first, substantially linear segment, J 1 , of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  220   c , the first and second actuators, A 2 , A 3 , cause the first and second tire-engaging devices  220   b ,  200   c  to deploy and move inwardly (i.e., toward one another) according to the direction of the arrows, O 1 ′, O 2 ′, which is opposite the direction of the arrows, O 1 , O 2 . Referring to  FIG. 9E , as a result of further rearwardly (e.g., to the left, L) movement of the wheel, W, and, as a result of the deployment, according to the direction of the arrows, O 1 ′, O 2 ′, of the first and second tire-engaging devices  220   b ,  200   c , the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, directly contact the second, substantially linear segment, J 2 , of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c.    
     Referring to  FIG. 9F , as the wheel, W, is moved rearwardly (e.g., to the left, L), just as the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, cease direct contact of the second, substantially linear segment, J 2 , of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  220   c , the first and second actuators, A 2 , A 3 , cause the first and second tire-engaging devices  220   b ,  200   c  to retract and move outwardly (i.e., in opposite directions) according to the direction of the arrows, O 1 , O 2 , which is opposite the direction of the arrows, O 1 ′, O 2 ′. Referring to  FIG. 9G , as a result of further rearwardly (e.g., to the left, L) movement of the wheel, W, and, as a result of the retraction, according to the direction of the arrows, O 1 , O 2 , of the first and second tire-engaging devices  220   b ,  220   c , the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, no longer contact the second, substantially linear segment, J 2 , of the side, wheel-circumference-engaging surface  222   b ″″,  222   c″″.    
     During the contact of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  200   c  with the wheel, W, as described above, the tire, T, is concurrently advanced through the second spacing, S 2 ′. Although each of the first and second tire-tread-engaging posts  230   a ,  230   b  is concurrently moved with its corresponding side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″, the second spacing S 2 ′, includes a geometry that results in interference with the tire, T, in order to cause the first and second tire-tread-engaging posts  230   a ,  230   b  to press the tire, T, radially inwardly in a manner such that the tire, T, is temporality deformed. As a result of the tire, T, being deformed, the diameter, T P-D , of the passage, T P , of the tire, T, is temporality upset to include a substantially oval form rather than a circular form. Accordingly, in a substantially similar fashion, the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , are also temporality upset to include a substantially oval form rather than a circular form. 
     The oval form of the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , reduces a portion of contact (and, as a result, friction) of the lower bead, T BL , and the upper bead, T BU , of the tire, T, with that of the outer circumferential surface, W C , of the wheel, W. Accordingly, referring to  FIGS. 8D-8F  and  9 D- 9 F, as the wheel, W, advances the tire, T, through the second spacing, S 2 ′, the oval deformation of diameters, T P-D , T OU-D , T OL-D  results in the lower bead, T BL , of the tire, T, encountering less resistance or interference with the outer rim surface, W RL , of the wheel, W, as the lower bead, T BL , is advanced from the outer rim surface, W RL , over the lower bead seat, W SL , and to a final position adjacent the drop center, W DC , of the wheel, W, as the tire, T, is advanced from the forwardly orientation (e.g., to the right, R) of the first and second tire-tread-engaging posts  230   a ,  230   b  to a rearwardly orientation (e.g., to the left, L) of the first and second tire-tread-engaging posts  230   a ,  230   b.    
     Referring to  FIGS. 8F and 9F , once the central chord, T C2 , or the right chord, T C3 , has been advanced through the second spacing, S 2 ′ (and, just as the first and second portion, W C1 , W C2 , of the circumference, W C , of the wheel, W, cease direct contact of the second, substantially linear segment, J 2 , of the side, wheel-circumference-engaging surface  222   b ″″,  222   c ″″ of the first and second tire-engaging devices  220   b ,  220   c ), the motors, A 2 , A 3 , may be actuated in order to retract the first and second tire-engaging devices  220   b ,  220   c  such that the first and second tire-tread-engaging posts  230   a ,  230   b  are correspondingly moved outwardly according to the direction of the arrows, O 1 , O 2 . Accordingly, as seen in  FIG. 9G , the first and second tire-tread-engaging posts  230   a ,  230   b  may no longer contact the tread surface, T T , of the tire, T. Further, as seen in  FIG. 8G , as a result of the movement of the wheel, W, and tire, T, through the spacing, S 2 ′, the entire circumference of the lower bead, T BL , is advanced to its final “mounted position” adjacent to and about the drop center, W DC ; further, the entire circumference of the upper bead, T BU , is arranged in its final “mounted position” adjacent to and about the outer circumferential surface, W C , of the wheel, W, proximate the safety bead, W SB . 
     With reference to  FIGS. 8F-8G , a sixth movement according to the direction of arrow, D 6 , may cause upwardly movement, U, of the wheel, W, and tire, T, away from the support member  216 . The robotic arm  212  may move the tire-wheel assembly, TW, to, for example, a subsequent sub-station (not shown), such as, for example, an inflation sub-station in order to inflate the tire-wheel assembly, TW, which may cause the upper bead, T BU , to be seated adjacent the upper bead seat, W SU , and the lower bead, T BL , to be seated adjacent the lower bead seat, W SL . 
     Referring to  FIG. 10A , a processing sub-station  300  for processing a tire-wheel assembly, TW, is shown according to an embodiment. The “processing” conducted by the processing sub-station  300  may include the act of “joining” or “mounting” a tire, T, to a wheel, W, for forming the tire-wheel assembly, TW. The act of “joining” or “mounting” may mean to physically couple, connect or marry the tire, T, and wheel, W, such that the wheel, W, may be referred to as a male portion that is inserted into a passage, T P , of a tire, T, being a female portion. 
     As described and shown in the following Figures, although the desired result of the processing sub-station  300  is the joining or mounting of the tire, T, and wheel, W, to form a tire-wheel assembly, TW, it should be noted that the processing sub-station  300  does not inflate the circumferential air cavity, T AC , of the tire, T, of the tire-wheel assembly, TW, nor does the processing sub-station  300  contribute to an act of “seating” the upper bead, T BU , or the lower bead, T BL , of the tire, T, adjacent the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W (because the act of “seating” typically arises from an inflating step where the tire-wheel assembly, TW, is inflated). Accordingly, upon joining or mounting the tire, T, to the wheel, W, the upper bead, T BU , or the lower bead, T BL , of the tire, T, may be arranged about and/or disposed adjacent the outer circumferential surface, W C , of the wheel, W. 
     In an implementation, the processing sub-station  300  may be included as part of a “single-cell” workstation. A single-cell workstation may include other sub-stations (not shown) that contribute to the processing of a tire-wheel assembly, TW; other sub-stations may include, for example: a soaping sub-station, a stemming sub-station, an inflating sub-station, a match-marking sub-station, a balancing sub-station and the like. The term “single-cell” indicates that the sub-stations contribute to the production of a tire-wheel assembly, TW, without requiring a plurality of successive, discrete workstations that may otherwise be arranged in a conventional assembly line such that a partially-assembled tire-wheel assembly, TW, is “handed-off” along the assembly line (i.e., “handed-off” meaning that an assembly line requires a partially-assembled tire-wheel assembly, TW, to be retained by a first workstation of an assembly line, worked on, and released to a subsequent workstation in the assembly line for further processing). Rather, a single cell workstation provides one workstation having a plurality of sub-stations each performing a specific task in the process of assembling a tire-wheel assembly, TW. This assembling process takes place wherein the tire and/or wheel “handing-off” is either minimized or completely eliminated. As such, a single-cell workstation significantly reduces the cost and investment associated with owning/renting the real estate footprint associated with a conventional tire-wheel assembly line while also having to provide maintenance for each individual workstation defining the assembly line. Thus, capital investment and human oversight is significantly reduced when a single cell workstation is employed in the manufacture of tire-wheel assemblies, TW. 
     Referring to  FIG. 10A , the processing sub-station  300  includes a device  312 . The device  312  may be referred to as a robotic arm. The robotic arm  312  may be located in a substantially central position relative to a plurality of sub-stations (including, e.g., the processing sub-station  300 ) of a single-cell workstation. The robotic arm  312  may be attached to and extend from a base/body portion (not shown) connected to ground, G. 
     The robotic arm  312  may include an end effecter  314 . The end effecter  314  may include a claw, gripper, or other means for removably-securing the wheel, W, to the robotic arm  312 . The end effecter  314  permits the robotic arm  312  to have the ability to retain and not release the wheel, W, throughout the entire procedure performed by the processing sub-station  300  (and, if applied in a single-cell workstation, the ability to retain and not release the wheel, W, throughout the entire assembling procedure of the tire-wheel assembly, TW). Accordingly, the end effecter  314  minimizes or eliminates the need of the robotic arm  312  to “hand-off” the tire-wheel assembly, TW, to (a) subsequent sub-station(s) (not shown). 
     The processing sub-station  300  may perform several functions/duties including that of: (1) a tire repository sub-station and (2) a mounting sub-station. A tire repository sub-station typically includes one or more tires, T, that may be arranged in a “ready” position for subsequent joining to a wheel, W. A mounting sub-station typically includes structure that assists in the joining of a tire, T, to a wheel, W (e.g., the disposing of a wheel, W, within the passage, T P , of the tire, T). 
     Referring to  FIG. 10A , the processing sub-station  300  may be initialized by joining a wheel, W, to the robotic arm  312  at the end effecter  314 . The processing sub-station  300  may also be initialized by positioning the tire, T, upon a support member  316 . The support member  316  may include a first support member  316   a , a second support member  316   b , a third support member  316   c  and fourth support member  316   d . Each of the first, second, third and fourth support members  316   a ,  316   b ,  316   c ,  316   d  include an upper surface  316 ′ and a lower surface  316 ″. In the illustrated embodiment of  FIG. 10A , the tire, T, may be arranged upon the first support member  316   a.    
     The lower surface  316 ″ of each of the first, second, third and fourth support members  316   a ,  316   b ,  316   c ,  316   d  may be respectively connected to at least one first leg member  318   a , at least one second leg member  318   b , at least one third leg member  318   c  and at least one fourth leg member  318   d . Each of the at least one first, second, third and fourth leg members  318   a ,  318   b ,  318   c ,  318   d  respectively include a length for elevating or spacing each of the first, second, third and fourth support members  316   a ,  316   b ,  316   c ,  316   d  from an underlying ground surface, G. Although the robotic arm  312  is not directly connected to the support member  316  (but, rather may be connected to ground, G), the robotic arm  312  may be said to be interfaceable with (as a result of the movements D 1 -D 3  described in the following disclosure) and/or indirectly connected to the support member  316  by way of a common connection to ground, G, due the leg members  318   a - 318   d  connecting the support member  316  to ground, G. 
     The processing sub-station  300  may further include a plurality of tire-engaging devices  320 . The plurality of tire-engaging devices  320  may include a first tire-engaging device  320   a  connected to the upper surface  316 ′ of the first support member  316   a , a second tire-engaging device  320   b  connected to the upper surface  316 ′ of the second support member  316   b , a third tire-engaging device  320   c  connected to the upper surface  316 ′ of the third support member  316   c , a fourth tire-engaging device  320   d  connected to the upper surface  316 ′ of the second support member  316   b , a fifth tire-engaging device  320   e  connected to the upper surface  316 ′ of the third support member  316   c  and a sixth tire-engaging device  320   f  connected to the upper surface  316 ′ of the fourth support member  316   d.    
     In reference to the processing sub-station  10  of  FIGS. 1A-3J , the plurality of tire-engaging devices  20  may be said to be in a fixed orientation with respect to the upper surface  16 ′ of each of the first, second and third support members  16   a ,  16   b ,  16   c . However, as will be described in the following disclosure, one or more of the plurality of tire-engaging devices  320  of the processing sub-station  300  may be said to be in a non-fixed, moveable orientation with respect to the upper surface  316 ′ of one or more of the first, second, third and fourth support members  316   a - 316   d.    
     Referring to  FIGS. 10B-10C , the first tire-engaging device  320   a  includes a substantially cylindrical body  322   a ′ that is supported by one or more brackets  322   a ″. The one or more brackets  322   a ″ may support the substantially cylindrical body  322   a ′ at a distance away from the upper surface  316 ′ of the first support member  316   a . The one or more brackets  322   a ″ may include a pair of brackets. The substantially cylindrical body  322   a ′ may be a tubular body having an axial passage. 
     A central pin  322   a ′ may be disposed within the axial passage. The central pin  322   a ′″ may be connected and fixed to the pair of brackets  322   a ″; accordingly, the substantially tubular, cylindrical body  322   a ′ may be movably-disposed about the central pin  322   a ′″ such that the substantially tubular, cylindrical body  322   a ′ is permitted to move in a rotating/rolling motion relative to a fixed orientation of the central pin  322   a ′″. Alternatively, the substantially cylindrical body  322   a ′ may not include an axial passage and may rotatably-connected-to or non-movably-fixed-to the pair of brackets  322   a″.    
     Referring to  FIGS. 10B-10C , each of the second and third tire-engaging devices  320   b ,  320   c  may include a tire tread engaging post/body  322   b ′,  322   c ′ having a lower surface  322   b ″,  322   c ″ including at least one female recess  326   b ,  326   c . The at least one female recess  326   c ,  326   c  receives at least one male guide member  328   b ,  328   c  connected to the upper surface  316 ′ of each of the second and third support members  316   b ,  316   c . Accordingly, as will be explained in the following disclosure, upon one or more of the tire, T, and the wheel, W, contacting the second and third tire-engaging devices  320   b ,  320   c , the tire tread engaging post/body  322   b ′,  322   c ′ may be slidably-moved relative to the upper surface  316 ′ and along the male guide member  328   b ,  328   c  in a repeatable, controlled fashion. 
     The tire tread engaging post/body  322   b ′,  322   c ′ may further include an upper, tire-sidewall-engaging surface  322   b ′″,  322   c ′″ and a laterally-extending wheel-engaging portion  322   b ″″,  322   c ″″. The upper tire-sidewall-engaging surface  322   b ′″,  322   c ′″ may include a substantially conical geometry and may be rotatably-disposed relative to a non-rotatable, but slidable orientation with respect to the tire tread engaging post/body  322   b ′,  322   c ′. The laterally-extending wheel-engaging portion  322   b ″″,  322   c ″″ may include a substantially L-shaped member that is fixed to a lateral side surface of the tire tread engaging post/body  322   b ′,  322   c ′. The laterally-extending wheel-engaging portions  322   b ″″,  322   c ″″ may be arranged directly facing one another in an opposing, spaced-apart relationship; further, as seen in  FIGS. 10B-10C , each tire tread engaging post/body  322   b ′,  322   c ′ may be arranged in a default orientation near an end of each male guide member  328   b ,  328   c  such that the laterally-extending wheel-engaging portions  322   b ″″,  322   c ″″ are spaced apart at a distance that is less than the diameter, W D , of the wheel, W. 
     Referring to  FIGS. 10B-10C , each of the fourth and fifth tire-engaging devices  320   d ,  320   e  may include a body  322   d ′,  322   e ′ having a side surface  322   d ″,  322   e ″ connected, respectively, to a first rod  324   a  and a second rod  324   b . The first rod  324   a  may be connected to a first actuator, A 1  (see, e.g.,  FIGS. 12A-12I ), and, the second rod  324   b  may be connected to a second actuator, A 2  (see, e.g.,  FIGS. 12A-12I ). As will be explained in the following disclosure, the actuators A 1 , A 2 , may push or pull the body  322   d ′,  322   e ′ such that the body  322   d ′,  322   e ′ is movably-disposed relative to the upper surface  316 ′ of each of the second and third support members  316   b ,  316   c  in a repeatable, controlled fashion. 
     The body  322   d ′,  322   e ′ may further include a tire-tread-surface-engaging member  322   d ′″,  322   e ′″. The tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may be movably-connected to an upper surface of the body  322   d ′,  322   e ′ such that the tire-tread-surface-engaging member  322   d ′″,  322   e ′″ is permitted to rotate or swivel relative to the body  322   d ′,  322   e′.    
     The tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may include a first linear segment  322   d ″″,  322   e ″″ and a second linear segment  322   d ′″″,  322   e ′″″ that are arranged to form an obtuse angle. Although the tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may include a first linear segment  322   d ″″,  322   e ″″ and a second linear segment  322   d ′″″,  322   e ′″″ forming an obtuse angle, the tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may include one curved segment having an arc shape (i.e., the tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may be alternatively referred to as an arcuate segment). 
     Each tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may include an array of tire-tread-engaging posts  330   d ,  330   e . In an embodiment, each tire-tread-surface-engaging member  322   d ′″,  322   e ′″ may include four tire-tread-engaging posts  330   d ,  330   e  comprising a first pair of posts  330   d ,  330   e  arranged upon the first linear segment  322   d ″″,  322   e ″″ and a second pair of posts arranged upon the second linear segment  322   d ′″″,  322   e ′″″. One or more of each of the tire-tread engaging posts  330   d ,  330   e  may rotate relative to the first/second linear segment  322   d ″″,  322   e ″″/ 322   d ′″″,  322   e ′″″; rotation of one or more of the tire-tread engaging posts  330   d ,  330   e  relative to the first/second linear segment  322   d ″″,  322   e ″″/ 322   d ′″″,  322   e ′″″ may occur upon contact of the tread surface, T T , of the tire, T, with the one or more of the tire-tread engaging posts  330   d ,  330   e.    
     Referring to  FIGS. 10B-10C , the sixth tire-engaging device  320   f  may include a body  322   f ′ having a side surface  322   f ′″ connected to a third rod  324   c . The third rod  324   c  may be connected to a third actuator, A 3  (see, e.g.,  FIGS. 12A-12I ). As will be explained in the following disclosure, the actuator, A 3 , may push or pull the body  322   f ′ such that the body  322   f ′ is movably-disposed relative to the upper surface  316 ′ of the fourth support member  316   d  in a repeatable, controlled fashion. 
     The body  322   f ′ may further include a tire-tread-surface-engaging member  322   f ′″. The tire-tread-surface-engaging member  322   f ′″ may be fixed to an upper surface of the body  322   f ′ in a non-rotatable fashion. 
     The tire-tread-surface-engaging member  322   f ′″ may form a cradle  322   f ″″ formed by first, second and third linear segments. Although the cradle  322   f ″″ may include first, second and third linear segments, the cradle  322   f ″″ may include one curved segment having an arc shape (i.e., the cradle  322   f ″″ may be alternatively referred to as an arcuate or C-shaped cradle). 
     Referring to  FIG. 10B , the actuators, A 1 -A 3  (not shown), and rods  324   a - 324   c  may assist in or contribute to the movement of the fourth, fifth and sixth tire-engaging devices  320   d - 320   f  relative the upper surface  316 ′ of each of the second, third and fourth support members  316   b - 316   d  by way of a push or pull driving force, F/F′, whereas movement of the second and third tire-engaging devices  320   b ,  320   c  may be regulated/biased with a reactive force, R (by way of, e.g., a spring, not shown). Accordingly, if an object, such as, for example, one or more of the tire, T, and wheel, W, pushes or exerts a force upon one or more of the second and third tire-engaging devices  320   b - 320   c , the reactive/biasing force, R, may permit, but resist, movement (in a direction according to arrow, R′, that is opposite the direction of the reactive force, R) relative to the upper surface  316 ′ of the second and third support members  316   b - 316   c . Although one or more of an actuator and a rod is/are not shown connected to the second and third tire-engaging devices  320   b ,  320   c , an actuator and/or rod may be coupled to the second and third tire-engaging devices  320   b ,  320   c  to permit a similar movement as described above with respect to the fourth, fifth and sixth tire-engaging devices  320   d - 320   f.    
     Referring to  FIG. 10B , the laterally-extending wheel-engaging portion  322   b ″″,  322   c ″″ of the second and third tire-engaging devices  320   b ,  320   c  are separated by a gap or first spacing, S 1 ′. Additionally, the substantially conical upper tire-sidewall-engaging surfaces  322   b ′″,  322   c ′″ are separated by a gap or second spacing, S 2 ′. The first spacing, S 1 ′, may be approximately equal to, but slightly less than the diameter, W D , of the wheel, W; the second spacing, S 2 ′, may be approximately equal to, but slightly less than the diameter, T D , of the tire, T. The first and second spacings, S 1 ′/S 2 ′, of the processing sub-station  300  is substantially similar to the first/second spacing, S 1 ′/&#39;S 2 ′, of the processing sub-station  200  due to the fact that the first/second spacings, S 1 ′/S 2 ′ are associated with the moveable tire-engaging devices; accordingly, the first and second spacing, S 1 ′, S 2 ′, of the processing sub-station  300  may be similarly referred to as a “variable” or “adjustable” first and second spacing, S 1 ′, S 2 ′. 
     Referring to  FIGS. 10A ,  11 A and  12 A, prior to joining the tire, T, to the wheel, W, the tire, T, may be said to be arranged in a first relaxed, unbiased orientation such that the upper tire opening, T OU , and the lower tire opening, T OL , define the passage, T P , to include a diameter, T P-D . When the tire, T, is joined to the wheel, W (see, e.g.,  FIGS. 11J and 12J ), the upper bead, T BU , and the lower bead, T BL , may be arranged proximate but not seated adjacent, respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W; later, upon inflating the tire, T, at, e.g., an inflation sub-station (not shown), the upper bead, T BU , and the lower bead, T BL , may be seated (i.e., disposed adjacent), respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W. Further, when the tire, T, is joined to the wheel, W (see, e.g.,  FIGS. 11J and 12J ), the tire, T, may be said to be arranged in a second substantially relaxed, but somewhat biased orientation such that the diameter, T P-D , of the passage, T P , is substantially circular and substantially similar to its geometry of the first relaxed, unbiased orientation of the tire, T. 
     Referring to  FIG. 11A , the robotic arm  312  is arranged in a spaced-apart orientation with respect to the first support member  316   a , which includes the tire, T, arranged in a “ready” position. The “ready” position may include a portion (i.e., T SL-1 , T SL-2  and T SL-3 ) of one or more of the lower sidewall surface, T SL , and the tread surface, T T , of the tire, T, arranged adjacent the upper surface  316 ′ of the first support member  316   a . Referring to  FIG. 11A , the “ready” position may further include the tire, T, being arranged in a first angularly-offset orientation, θ 1 , with respect to the upper surface  316 ′ of the first support member  316   a.    
     The first angularly-offset orientation, θ 1 , of the tire, T, results from the non-co-planar relationship of the substantially cylindrical body  322   a ′ of the first tire-engaging device  320   a  that engages the lower sidewall surface, T SL , of the tire, T (at T SL-2  and T SL-3 ), with that of a portion of the upper surface  316 ′ of the first support member  316   a  (at T SL-1 ) such that: (1) the first portion, T SL-1 , of the lower sidewall surface, T SL , of the tire, T, is arranged adjacent the upper surface  316 ′ of the first support member  316   a , (2) the second portion, T SL-2 , of the lower sidewall surface, T SL , of the tire, T, is arranged adjacent a portion of the substantially cylindrical body  322   a ′ of the first tire-engaging device  320   a  (noting that the second portion, T SL-2 , is not represented in  FIG. 11A  due to the cross-sectional reference line of  FIG. 10A ), and (3) a third portion, T SL-3 , of the lower sidewall surface, T SL , of the tire, T, is arranged adjacent a portion of the substantially cylindrical body  322   a ′ of the first tire-engaging device  320   a . Accordingly, the support member  316  may provide a three-point support (which is more clearly shown at  FIG. 10A ) at T SL-1 , T SL-2 , T SL-3  for the lower sidewall surface, T SL , of the tire, T, while remaining portions of the lower sidewall surface, T SL , of the tire, T, are not in direct contact with any other portion of the support member  316  when the tire, T, is arranged in the first angularly-offset orientation, θ 1 . 
     The processing sub-station  300  may execute a mounting procedure by causing a controller, C (see, e.g.,  FIG. 10A ) to send one or more signals to a motor, M (see, e.g.,  FIG. 10A ), that drives movement (according to the direction of the arrows, D 1 -D 3 —see  FIGS. 11A-11I ) of the robotic arm  312 . Alternatively or in addition to automatic operation by the controller, C, according to inputs stored in memory, the movement, D 1 -D 3 , may result from one or more of a manual, operator input, O (e.g., by way of a joystick, depression of a button or the like). 
     As seen in  FIG. 11A , the wheel, W, may be arranged above and be substantially aligned-with the passage, T P , of the tire, T. A first, down, D, movement according to the direction of arrow, D 1 , may reduce the spaced-apart orientation of robotic arm  312  with respect to the support member  316  such that the wheel, W, may also be moved closer with respect to the tire, T, that is positioned upon the support member  316 . 
     Referring to  FIG. 11B , the robotic arm  312  may continue movement according to the direction of the arrow, D 1 , upon locating a first (e.g., left) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, within the passage, T P , of the tire, T. The robotic arm  312  may then conduct a second movement according to the direction of arrow, D 2 , to cause the robotic arm  312  to directly move the wheel, W (and, as a result of the orientation of the wheel, W, within the passage, T P , of the tire, T, indirectly move the tire, T), rearwardly (e.g., to the left, L). 
     Referring to  FIG. 11C , the movement according to the direction of the arrow, D 1 , may continue such that the wheel, W, pushes or exerts a downwardly, D, force upon the tire, T, such that a portion of the lower, outer rim surface, W RL , of the wheel, W, is partially disposed within the passage, T P , while a portion of the lower, outer rim surface, W RL , of the wheel, W, is disposed adjacent and pushes down upon the upper sidewall surface, T SU , of the tire, T; accordingly, the tire, T, may be leveraged about the substantially cylindrical body  322   a ′ such that a portion (e.g., T SL-1 ) of the lower sidewall surface, T SL , of the tire, T, is no longer arranged adjacent the upper surface  316 ′ of the first support member  316   a . Thus, the tire, T, may no longer be arranged adjacent the support member  316  at three points of support; rather, the second and third portions (e.g., T SL-2 , T SL-3 ) are still arranged adjacent the substantially cylindrical body  322   a ′ of the first tire-engaging device  320   a  to thereby provide two points of support for the lower sidewall surface, T SL , of the tire, T. As a result the orientation of the tire, T, being supported upon the substantially cylindrical body  322   a ′ of the first tire-engaging device  320   a , the tire, T, is no longer arranged at the first angularly-offset orientation, θ 1 , with respect to the support member  316 . 
     Referring to  FIG. 11C , downward movement according to the direction of the arrow, D 1 , may cease when, for example, the lower, outer rim surface, W RL , of the wheel, W, is arranged in a space-apart relationship with respect to the substantially cylindrical body  322   a ′ at a distance, d. During the downward movement according to the direction of the arrow, D 1  (in the view according to  FIG. 11B ), or, in an alternative embodiment, just after ceasing the downward movement according to the direction of the arrow, D 1 , the robotic arm  312  may cause rearwardly movement (e.g., to the left) of the wheel, W, and the tire, T, according to the direction of the arrow, D 2 . 
     Referring to  FIGS. 11D-11E , the movement according to the direction of the arrow, D 2 , results in the lower sidewall surface, T SL , of the tire, T, to being “dragged over” the substantially cylindrical body  322   a ′ of the first tire-engaging device  320   a  due to the rearwardly (e.g., to the left, L) movement in conjunction with the lower, outer rim surface, W RL , of the wheel, W, being disposed adjacent and pushing down upon the upper sidewall surface, T SU , of the tire, T. Accordingly, as the wheel, W, drags the lower sidewall surface, T SL , of the tire, T, over the substantially cylindrical body  322   a ′, the upper and lower beads, T BU , T BL , of the tire, T, are arranged closer in proximity to one anther. As the wheel, W, is advanced rearwardly (e.g., to the left, L) past the substantially cylindrical body  322   a ′, the upper bead, T BU , of the tire, T, is urged or flexed over one or both of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, such that the lower, outer rim surface, W RL , of the wheel, W, is no longer disposed adjacent the upper sidewall surface, T SU , of the tire, T. Accordingly, as seen in  FIG. 11D , the tire, T, is arranged relative to the wheel, W, such that the upper bead, T BU , of the tire, T, circumscribes the wheel, W, and is arranged proximate the drop center, W DC , while the lower, outer rim surface, W RL , the lower bead seat, W SL , and the drop center, W DC , of the wheel, W, are arranged within the passage, T P , of the tire, T; accordingly, the robotic arm  312  utilizes the wheel, W, to move rearwardly (e.g., to the left, L) such that the tire, T, is moved from the “ready” position (of  FIGS. 11A-11C ) to a “partially mounted” position (of  FIG. 11D ) upon the wheel, W. 
     Referring to  FIG. 11E , once the tire, T, is arranged relative to the wheel, W, as described above, the second movement according to the direction of arrow, D 2 , continues while the robotic arm  312  may slightly lower the wheel, W, and the tire, T, according to a second downwardly direction according to the direction of the arrow, D 3 . The movement according to the direction of the arrows, D 2 , D 3 , may be conducted separately or simultaneously, as desired. 
     Referring to  FIG. 11F , the third movement according to the direction of the arrow, D 3 , may result in the robotic arm  312  arranging at least a portion of the tire, T, in alignment with the substantially conical upper tire-sidewall-engaging surface  322   b ′″,  322   c ′″ and at least a portion of the wheel, W, in alignment with the laterally-extending wheel-engaging portion  322   b ″″,  322   c ″″ of the second and third tire-engaging devices  320   b ,  320   c . Further, the third movement according to the direction of the arrows, D 2 , D 3 , eventually results in, the tire, T, being arranged in an orientation of contact with the second and third tire-engaging devices  320   b ,  320   c , and, then eventually results in the wheel, W, being arranged in an orientation of contact with the second and third tire-engaging devices  320   b ,  320   c.    
     As described above, the first spacing, S 1 ′, may be approximately equal to, but slightly less than the diameter, W D , of the wheel, W, and, the second spacing, S 2 ′, may be approximately equal to, but slightly less than the diameter, T D , of the tire, T. Accordingly, as the robotic arm  312  advances the tire, T, and the wheel, W, rearwardly (e.g., to the left, L) according to the direction of the arrow, D 2 , past/through the spacing, S 1 ′, S 2 ′ as seen in  FIGS. 12E-12I , one or more of the tread surface, T T , tire, T, and the lower rim surface, W RL , of the wheel, W, engages and pushes, R′ (see  FIGS. 12F-12G ) the second and third tire-engaging devices  320   b ,  320   c  outward. 
     The second and third tire-engaging devices  320   b ,  320   c  may at least partially resist, R, as seen in  FIG. 10B ) the movement imparted to the tire, T (i.e., the second and third tire-engaging devices  320   b ,  320   c  may provide a countering, “push-back” force according to the direction of the arrow, R), such that the tire, T, is permitted to flex relative to a fixed orientation of the wheel, W, that is joined to the robotic arm  312 . As described above, the push-back force, R, may arise from any desirable structure, such as, for example, a spring (not shown) that is connected to the second and third tire-engaging devices  320   b ,  320   c . Referring to  FIGS. 12F-12I , the push-back force, R, results in the laterally-extending wheel-engaging portion  322   b ″″,  322   c ″″ of the second and third tire-engaging devices  320   b ,  320   c  ‘tracing’/following a portion of the lower rim surface, W RL , of the wheel, W, while the substantially conical upper tire-sidewall-engaging surface  322   b ′″,  322   c ′″ “traces”/follows a portion of the tread surface, T T , of the tire, T. 
     As seen in  FIGS. 11F-11I , the countering push-back force, R, provided by the second and third tire-engaging members  320   b ,  320   c  may result in the substantially conical upper tire-sidewall-engaging surface  322   b ′″,  322   c ′″ interfering with movement of the tire, T, through the spacing, S 2 ′, according to the direction of the arrow, D 2 ; as a result of the interference, the tire, T, physically deforms relative to the wheel, W, in a manner that results in the lower bead, T BL , of the tire, T, being permitted to flex or wrap-over the lower rim surface, W RL , of the wheel, W, as seen in  FIGS. 11F-11I . Continued movement according to the direction of the arrow, D 2 , results in the lower bead, T BL , of the tire, T, circumscribing the wheel, W, about the drop center, W DC  (see  FIG. 11I ), once the tire, T, and the wheel, W, is passed through the spacing, S 1 ′, S 2 ′. 
     In addition to the push-back force, R, provided by the second and third tire-engaging devices  320   b ,  320   c , additional push-back force RR and RRR may be provided by the fourth, fifth and sixth tire-engaging devices  320   d ,  320   e ,  320   f . Referring to  FIGS. 11G and 12G , continued movement of the robotic arm  312  according to the direction of the arrow, D 2 , results in a leading-end, T T-LE  (see  FIG. 12G ), of the tread surface, T T , of the tire, T, coming into contact with the cradle  322   f ″″ of the sixth tire-engaging device  320   f ; as seen, comparatively in  FIGS. 11F-12F  and  11 G- 12 G, the actuator, A 1 , may retract (according to the direction of the arrow, D 2 ) the cradle  322   f ″″ as the robotic arm  312  advances the wheel, W, and the tire, T. The speed of retraction of the sixth tire-engaging device  320   f  according to the direction of the arrow, D 2 , may be slower than the speed of advancement of the tire, T, and the wheel, W, according to the direction of the arrow, D 2 , such that the sixth tire-engaging device may interfere with movement of (and, as a result, “push-back,” RR, upon) the tire, T, as the tire, T, is moved through the spacing, S 2 ′, in order to contribute to the physical manipulation of the orientation of the tire, T, relative to the wheel, W, described above. 
     In an alternative embodiment, upon the leading-end, T T-LE , of the tread surface, T T , of the tire, T, coming into contact with the cradle  322   f ″″, the sixth tire-engaging device  320   f  may move in concert with the robotic arm  312  according to the direction of the arrow, D 2 ; accordingly the cradle  322   f ″″ may provide a support surface for the tire, T, that may serve as a leverage surface to assist in the manipulation of the tire, T, and not necessarily contribute to an interference of the tire, T, as the tire, T, is moved through the spacing, S 2 ′. In another embodiment, the sixth tire-engaging device  320   f  may remain in a static, fixed orientation after the leading-end, T T-LE , of the tread surface, T T , of the tire, T, comes into contact with the cradle  322   f ″″ and, then, subsequently, move in concert with the robotic arm  312  according to the direction of the arrow, D 2 . In another embodiment, the speed of retraction of the sixth tire-engaging device  320   f  according to the direction of the arrow, D 2 , may be faster than the speed of advancement of the tire, T, and the wheel, W, according to the direction of the arrow, D 2  (e.g., after, as described above, remaining in a static orientation). Accordingly, the first actuator, A 1 , may control the timing and/or speed of movement of the sixth tire-engaging device  320   f  according to the direction of the arrow, D 2 , in any desirable manner in order to control a particular physical manipulation of an orientation of the tire, T, relative the wheel, W. 
     Referring to  FIGS. 11   h  and  12 H, the second and third actuators, A 2 , A 3 , may be actuated for driving the fourth and fifth tire-engaging devices  320   d ,  320   e  toward the tread surface, T T , of the tire, T, such that the array of tire-tread-engaging posts  330   d ,  330   e  come into contact with and engage portions of the tread surface, T T , of the tire, T. The actuators, A 2 , A 3 , may drive the array of tire-tread-engaging posts  330   d ,  330   e  into contact with and engage portions of the tread surface, T T , of the tire, T, before, during or after the leading-end, T T-LE , of the tread surface, T T , of the tire, T, comes into contact with the cradle  322   f ″″ of the sixth tire-engaging device  320   f ; in the illustrated embodiment, the leading-end, T T-LE , of the tread surface, T T , of the tire, T, comes into contact with the cradle  322   f ″″ first (see  FIGS. 11G and 12G ) and then secondly, the array of tire-tread-engaging posts  330   d ,  330   e  into contact with and engage portions of the tread surface, T T , of the tire, T (see  FIGS. 11H and 12H ). 
     In a substantially similar manner as described above, the second and third actuators, A 2 , A 3 , may drive or retract the array of tire-tread-engaging posts  330   d ,  330   e  into a dis/engaged orientation with respect to the tread surface, T T , of the tire, T. If driven to an engaged orientation with the tread surface, T T , of the tire, T, the array of tire-tread-engaging posts  330   d ,  330   e  may “push-back,” RRR, upon the tire, T, as the tire, T, is moved through the spacing, S 2 ′, by the robotic arm  312  in order to contribute to the manipulation of the orientation of the tire, T, relative to the wheel, W. Alternatively, as similarly described above, the array of tire-tread-engaging posts  330   d ,  330   e  may provide a support surface for the tire, T, that may serve as a leverage surface to assist in the manipulation of the tire, T, and not necessarily contribute to an interference of the tire, T, as the tire, T, is moved through the spacing, S 2 ′. 
     Referring to  FIGS. 12H-12I , the push-back force, RRR, may also results in the array of tire-tread-engaging posts  330   d ,  330   e  ‘tracing’/following a portion of the tread surface, T T , of the tire, T, in a substantially similar fashion as that of the substantially conical upper tire-sidewall-engaging surface  322   b ′″,  322   c ′″. The tracing conducted by the array of tire-tread-engaging posts  330   d ,  330   e  is permitted by the swiveling-connection of the tire-tread-surface-engaging member  322   d ′″,  322   e ′″ and the body  322   d ′,  322   e ′ of each of the fourth and fifth tire-engaging devices  320   d ,  320   e.    
     Referring to  FIG. 12I , once the robotic arm  312  has moved the tire, T, through the spacing, S 2 ′, the movement according to the direction of the arrow, D 2 , may cease; additionally, the second and third actuators, A 2 , A 3 , may retract the fourth and fifth tire-engaging devices  320   d ,  320   e  to a “ready orientation” according to the direction of the arrow, RRR′, which is opposite that of the direction of the arrow, RRR, that is substantially similar to what is shown in  FIG. 12A . Additionally, as seen in  FIG. 12I , the second and third tire-engaging devices  320   b ,  320   c  may be returned to a “ready orientation” that is substantially similar to what is shown in  FIG. 12A  as a result of, for example, a spring (not shown) that provides the “push-back” force, R, being fully expanded. Referring to  FIG. 11J , as a result of the tire, T, now being mounted to the wheel, W, by the processing sub-station  300 , the robotic arm  312  may move upwardly according to the direction of the arrow, D 1 ′, which is substantially opposite the direction of the arrow, D 1 , to carry the tire-wheel assembly, TW, to another processing sub-station, such as, for example, an inflation sub-station (not shown) for inflating the tire-wheel assembly, TW, which may cause the upper bead, T BU , to be seated adjacent the upper bead seat, W SU , and the lower bead, T BL , to be seated adjacent the lower bead seat, W SL . 
     Referring to  FIG. 13A , a processing sub-station  400  for processing a tire-wheel assembly, TW, is shown according to an embodiment. The “processing” conducted by the processing sub-station  400  may include the act of “joining” or “mounting” a tire, T, to a wheel, W, for forming the tire-wheel assembly, TW. The act of “joining” or “mounting” may mean to physically couple, connect or marry the tire, T, and wheel, W, such that the wheel, W, may be referred to as a male portion that is inserted into a passage, T P , of a tire, T, being a female portion. 
     As described and shown in the following Figures, although the desired result of the processing sub-station  400  is the joining or mounting of the tire, T, and wheel, W, to form a tire-wheel assembly, TW, it should be noted that the processing sub-station  400  does not inflate the circumferential air cavity, T AC , of the tire, T, of the tire-wheel assembly, TW, nor does the processing sub-station  400  contribute to an act of “seating” the upper bead, T BU , or the lower bead, T BL , of the tire, T, adjacent the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W (because the act of “seating” typically arises from an inflating step where the tire-wheel assembly, TW, is inflated). Accordingly, upon joining or mounting the tire, T, to the wheel, W, the upper bead, T BU , or the lower bead, T BL , of the tire, T, may be arranged about and/or disposed adjacent the outer circumferential surface, W C , of the wheel, W. 
     In an implementation, the processing sub-station  400  may be included as part of a “single-cell” workstation. A single-cell workstation may include other sub-stations (not shown) that contribute to the processing of a tire-wheel assembly, TW; other sub-stations may include, for example: a soaping sub-station, a stemming sub-station, an inflating sub-station, a match-marking sub-station, a balancing sub-station and the like. The term “single-cell” indicates that the sub-stations contribute to the production of a tire-wheel assembly, TW, without requiring a plurality of successive, discrete workstations that may otherwise be arranged in a conventional assembly line such that a partially-assembled tire-wheel assembly, TW, is “handed-off” along the assembly line (i.e., “handed-off” meaning that an assembly line requires a partially-assembled tire-wheel assembly, TW, to be retained by a first workstation of an assembly line, worked on, and released to a subsequent workstation in the assembly line for further processing). Rather, a single cell workstation provides one workstation having a plurality of sub-stations each performing a specific task in the process of assembling a tire-wheel assembly, TW. This assembling process takes place wherein the tire and/or wheel “handing-off” is either minimized or completely eliminated. As such, a single-cell workstation significantly reduces the cost and investment associated with owning/renting the real estate footprint associated with a conventional tire-wheel assembly line while also having to provide maintenance for each individual workstation defining the assembly line. Thus, capital investment and human oversight is significantly reduced when a single cell workstation is employed in the manufacture of tire-wheel assemblies, TW. 
     Referring to  FIG. 13A , the processing sub-station  400  includes a device  412 . The device  412  may be referred to as a robotic arm. The robotic arm  412  may be located in a substantially central position relative to a plurality of sub-stations (including, e.g., the processing sub-station  400 ) of a single-cell workstation. The robotic arm  412  may be attached to and extend from a base/body portion (not shown) connected to ground, G. 
     The robotic arm  412  may include an end effecter  414 . The end effecter  414  may include a claw, gripper, or other means for removably-securing the wheel, W, to the robotic arm  412 . The end effecter  414  permits the robotic arm  412  to have the ability to retain and not release the wheel, W, throughout the entire procedure performed by the processing sub-station  400  (and, if applied in a single-cell workstation, the ability to retain and not release the wheel, W, throughout the entire assembling procedure of the tire-wheel assembly, TW). Accordingly, the end effecter  414  minimizes or eliminates the need of the robotic arm  412  to “hand-off” the tire-wheel assembly, TW, to (a) subsequent sub-station(s) (not shown). 
     The processing sub-station  400  may perform several functions/duties including that of: (1) a tire repository sub-station and (2) a mounting sub-station. A tire repository sub-station typically includes one or more tires, T, that may be arranged in a “ready” position for subsequent joining to a wheel, W. A mounting sub-station typically includes structure that assists in the joining of a tire, T, to a wheel, W (e.g., the disposing of a wheel, W, within the passage, T P , of the tire, T). 
     Referring to  FIG. 13A , the processing sub-station  400  may be initialized by joining a wheel, W, to the robotic arm  412  at the end effecter  414 . The processing sub-station  400  may also be initialized by positioning the tire, T, upon a support member  416 . The support member  416  may include a first support member  416   a , a second support member  416   b , a third support member  416   c  and a fourth support member  416   d . Each of the first, second, third and fourth support members  416   a ,  416   b ,  416   c ,  416   d  include an upper surface  416 ′ and a lower surface  416 ″. 
     The lower surface  416 ″ of each of the first, second, third and fourth support members  416   a ,  416   b ,  416   c ,  416   d  may be respectively connected to at least one first leg member  418   a , at least one second leg member  418   b , at least one third leg member  418   c  and at least one fourth leg member  418   d . Each of the at least one first, second, third and fourth leg members  418   a ,  418   b ,  418   c ,  418   d  respectively include a length for elevating or spacing each of the first, second, third and fourth support members  416   a ,  416   b ,  416   c ,  416   d  from an underlying ground surface, G. Although the robotic arm  412  is not directly connected to the support member  416  (but, rather may be connected to ground, G), the robotic arm  412  may be said to be interfaceable with (as a result of the movements D 1 -D 5  described in the following disclosure) and/or indirectly connected to the support member  416  by way of a common connection to ground, G, due the leg members  418   a - 418   d  connecting the support member  416  to ground, G. 
     The processing sub-station  400  may further include a plurality of tire-engaging devices  420 . The plurality of tire-engaging devices  420  may include a first tire-engaging device  420   a  connected to the upper surface  416 ′ of the first support member  416   a , a second tire-engaging device  420   b  connected to the upper surface  416 ′ of the second support member  416   b  and a third tire-engaging device  420   c  connected to the upper surface  416 ′ of the third support member  416   c.    
     Referring to  FIGS. 13B-13C , the first tire-engaging device  420   a  includes a substantially cylindrical body  422   a ′ that is supported by one or more brackets  422   a ″. The one or more brackets  422   a ″ may support the substantially cylindrical body  422   a ′ at a distance away from the upper surface  416 ′ of the first support member  416   a . The one or more brackets  422   a ″ may include a pair of brackets. The substantially cylindrical body  422   a ′ may be a tubular body having an axial passage (nor shown). A central pin (not shown) may be disposed within the axial passage. The central pin may be connected and fixed to the pair of brackets  422   a ″; accordingly, the substantially tubular, cylindrical body  422   a ′ may be movably-disposed about the central pin such that the substantially tubular, cylindrical body  422   a ′ is permitted to move in a rotating/rolling motion relative to a fixed orientation of the central pin. Alternatively, the substantially cylindrical body  422   a ′ may not include an axial passage and may rotatably-connected-to or non-movably-fixed-to the pair of brackets  422   a″.    
     Referring to  FIG. 13A , the second tire-engaging device  420   b  includes a first tire-tread-engaging post  430   a  that may extend from the upper surface  416 ′ of the second support member  416   b . The third tire-engaging device  420   c  includes a second tire-tread-engaging post  430   b  that may extend from the upper surface  416 ′ of the third support member  416   c.    
     Referring to  FIG. 13B , the second and third support members  416   b ,  416   c  are separated by a gap or first spacing, S 1 . The first tire-tread-engaging post  430   a  is separated from the second tire-tread-engaging post  430   b  by a gap or second spacing, S 2 . The fourth support member  416   d  is separated from the second and third support members  416   b ,  416   c  by a third gap or spacing, S 3 . 
     The second spacing, S 2 , is greater than the first spacing, S 1 . The first spacing, S 1 , may be approximately equal to, but slightly greater than the diameter, W D , of the wheel, W; further, the tire diameter, T D /central chord, T C2 , may be greater than the first spacing, S 1 . The second spacing, S 2 , may be approximately equal to the left chord, T C1 , and the right chord, T C3 , of the tire, T; further, the tire diameter, T D /central chord, T C2 , may be greater than the second spacing, S 2 . The third spacing, S 3 , may be approximately equal to, but slightly greater than the diameter, W D , of the wheel, W, and less than the diameter, T D , of the tire, T. 
     As seen in  FIG. 14A  and with reference to  FIG. 15A , prior to joining the tire, T, to the wheel, W, the tire, T, may be said to be arranged in a first relaxed, unbiased orientation such that the upper tire opening, T OU , and the lower tire opening, T OL , define the passage, T P , to include a diameter, T P-D . When the tire, T, is eventually joined to the wheel, W (see, e.g.,  FIG. 14J ), the upper bead, T BU , and the lower bead, T BL , may be arranged proximate but not seated adjacent, respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W; later, upon inflating the tire, T, at, e.g., an inflation sub-station (not shown), the upper bead, T BU , and the lower bead, T BL , may be seated (i.e., disposed adjacent), respectively, the upper bead seat, W SU , and the lower bead seat, W SL , of the wheel, W. Further, when the tire, T, is joined to the wheel, W (see, e.g.,  FIG. 14J ), the tire, T, may be said to be arranged in a second substantially relaxed, but somewhat biased orientation such that the diameter, T P-D , of the passage, T P , is substantially circular and substantially similar to its geometry of the first relaxed, unbiased orientation of the tire, T. 
     Referring to  FIG. 14A , the robotic arm  412  is arranged in a spaced-apart orientation with respect to the support member  416 , which includes the tire, T, arranged in a “ready” position. The “ready” position may include a portion of the lower sidewall surface, T SL , of the tire, T, arranged adjacent the substantially cylindrical body  422   a ′ of the first tire-engaging device  420   a . The “ready” position may further include the tire, T, being arranged in a first angularly-offset orientation, θ 1 , with respect to the upper surface  416 ′ of the first support member  416   a.    
     The first angularly-offset orientation, θ 1 , of the tire, T, may result from the non-co-planar relationship the substantially cylindrical body  422   a ′ of the first tire-engaging device  420   a  with that of the upper surface  416 ′ of the first support member  416   a  such that: (1) the first portion, T SL-1 , of the lower sidewall surface, T SL , is arranged adjacent the upper surface  416 ′ of the first support member  416   a , (2) the second portion, T SL-2 , of the lower sidewall surface, T SL , is arranged adjacent the substantially cylindrical body  422   a ′ of the first tire-engaging device  420   a  (noting that, in  FIG. 14A , the second portion, T SL-2 , is not represented due to the line-of-view of the cross-sectional reference line of  FIG. 13A , but, however, is shown in  FIG. 15A ), and (3) a third portion, T SL-3 , of the lower sidewall surface, T SL , is arranged adjacent the substantially cylindrical body  422   a ′ of the first tire-engaging device  420   a . Accordingly, the support member  416  may provide a three-point support (which is more clearly shown at  FIG. 13A ) at T SL-1 , T SL-2 , T SL-3  for the lower sidewall surface, T SL , of the tire, T, while remaining portions of the lower sidewall surface, T SL , of the tire, T, are not in direct contact with any other portion of the upper surface surfaces  416 ′,  422   b ′,  422   c ′ of the support member  416  when the tire, T, is arranged in the first angularly-offset orientation, θ 1 . 
     The processing sub-station  400  may execute a mounting procedure by causing a controller, C (see, e.g.,  FIG. 13A ) to send one or more signals to a motor, M (see, e.g.,  FIG. 13A ), that drives movement (according to the direction of the arrows, D 1 -D 5 —see  FIGS. 14A-14J ) of the robotic arm  412 . Alternatively or in addition to automatic operation by the controller, C, according to inputs stored in memory, the movement, D 1 -D 5 , may result from one or more of a manual, operator input, O (e.g., by way of a joystick, depression of a button or the like). 
     As seen in  FIG. 14A , a first, down, D, movement according to the direction of arrow, D 1 , may reduce the spaced-apart orientation of robotic arm  412  with respect to the support member  416 . Referring to  FIG. 14B , the movement according to the direction of the arrow, D 1 , may cease upon locating: (1) a first (e.g., left) portion of the lower rim surface, W RL , of the wheel, W, adjacent a first (e.g., left) portion of the upper sidewall surface, T SU , of the tire, T, and (2) a second (e.g. right) portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, within the passage, T P , of the tire, T, such that a portion of the drop center, W DC , of the wheel, W, is disposed in a spaced-apart relationship with respect to a first (e.g., right) portion of the upper bead, T BU , of the tire, T. 
     With continued reference to  FIG. 14B , a second movement according to the direction of arrow, D 2 , may cause forwardly (e.g., to the right, R) movement of the wheel, W. Referring to  FIG. 14C , the movement according to the direction of the arrow, D 2 , results in the spaced-apart relationship of the drop center, W DC , of the wheel, W, and the first (e.g., right) portion of the upper bead, T BU , of the tire, T, being reduced such that the drop center, W DC , of the wheel, W, and the first (e.g., right) portion of the upper bead, T BU , of the tire, T, are eventually in direct contact with one another. With corresponding reference to  FIG. 15C , the tread surface, T T , of the tire, T, is arranged in a spaced-apart relationship with respect to the first tire-tread-engaging post  430   a  and the second tire-tread-engaging post  430   b.    
     In addition to the drop center, W DC , of the wheel, W, and the first (e.g., right) portion of the upper bead, T BU , of the tire, T, eventually being in direct contact with one another, movement according to the direction of the arrow, D 2 , also results in a change in orientation of the lower rim surface, W RL , of the wheel, W, with respect to the first (e.g., left) portion of the upper sidewall surface, T SU , of the tire, T. For example, as seen in  FIG. 14C , movement according to the direction of the arrow, D 2 , results in the lower rim surface, W RL , of the wheel, W, being arranged in an opposing relationship with a lesser amount of a portion of the first (e.g., left) portion of the upper sidewall surface, T SU , of the tire, T but more so in a substantially opposing relationship with a left portion of the upper bead, T BU , of the tire, T. 
     Referring to  FIGS. 14C-14D , after the drop center, W DC , of the wheel, W, and the first (e.g., right) portion of the upper bead, T BU , of the tire, T, are eventually in direct contact with one another, further movement according to the direction of the arrow, D 2 , results in the lower sidewall surface, T SL , of the tire, T, being dragged across the substantially cylindrical body  422   a ′ of the first tire-engaging device  420   a  from left-to-right as the tread surface, T T , of the tire, T, is moved closer to the first tire-tread-engaging post  430   a  and the second tire-tread-engaging post  430   b  such that, as seen in  FIGS. 14D and 15D , the tread surface, T T , is ultimately arranged in direct contact with both of the first tire-tread-engaging post  430   a  and the second tire-tread-engaging post  430   b.    
     Referring to  FIGS. 14D-14F , as a result of the forwardly (e.g., to the right, R) movement of the wheel, W, according to the direction of the arrow, D 2 , the tire, T, is advanced through the second spacing, S 2 , formed by the first and second tire-tread-engaging pasts  430   a ,  430   b  from the right chord, T C3 , to the left chord, T C1 ; because chords (including, e.g., the central chord, T C2 ) of the tire, T, between the left chord, T C1 , and the right chord, T C3 , are greater than that of the left chord, T C1 , and the right chord, T C3 , the first and second tire-tread-engaging posts  430   a ,  430   b  interfere with movement of the tire, T, through the second spacing, S 2 . 
     As a result of the above-described interference, the tire, T, temporality deforms such that the diameter, T P-D , of the passage, T P , of the tire, T, is temporality upset to include a substantially oval form rather than a circular form. Accordingly, in a substantially similar fashion, the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , are also temporality upset to include a substantially oval form rather than a circular form. 
     The oval form of the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , reduces a portion of contact (and, as a result, friction) of the upper bead, T BU , of the tire, T, with that of the outer circumferential surface, W C , of the wheel, W, and, as such permits at least a partial mounting of the tire, T, to the wheel, W, to occur. Accordingly, as seen in  FIGS. 14D-14F  and  15 D- 15 F, as the wheel, W, advances the tire, T, forwardly (e.g., to the right, R) through the second spacing, S 2 , according to the direction of the arrow, D 2 , the oval deformation of at least the diameter, T OU-D , results in an oval deformation of the upper bead, T BU , of the tire, T, such that the first (e.g., left) portion of the lower rim surface, W RL , of the wheel, W, encounters less resistance or interference with the upper bead, T BU , of the tire, T, as the left portion of the upper bead, T BU , of the tire, T, is moved from the substantially opposing relationship with a left portion of the upper bead, T BU , of the tire, T, as seen in  FIG. 14E  to a different orientation substantially adjacent one or more of the outer circumferential surface, W C , and drop center, W DC , of the wheel, W. 
     Referring to  FIGS. 14F and 15F , once the left chord, T C1 , has been advanced through the second spacing, S 2 , from a rearwardly orientation (e.g., to the left, L) of the first and second tire-tread-engaging posts  430   a ,  430   b  to a forwardly orientation (e.g., to the right, R) of the first and second tire-tread-engaging posts  430   a ,  430   b , the entire circumference of the upper bead, T BU , of the tire, T, may be said to be arranged in a preliminary “mounted position” adjacent/about one or more of the outer circumferential surface, W C , and the drop center, W DC , of the wheel, W. As illustrated, however, the entire circumference of the lower bead, T BL , of the tire, T, may be said to be arranged in “un-mounted position” due to the lower bead, T BL , of the tire, T, being arranged in a non-adjacent orientation with respect to any portion of the wheel, W. 
     As seen in  FIG. 14F , the movement according to the direction of the arrow, D 2 , may cease upon arranging the wheel, W, above the third spacing, S 3 . Then, as seen in  FIG. 14F , a second, down, D, movement according to the direction of arrow, D 3 , may occur in order to move the wheel, W, toward the support member  416 . Referring to  FIG. 14G , the movement according to the direction of the arrow, D 3 , may cease upon locating: (1) the left portion of the lower sidewall surface, T SL , of the tire, T, adjacent the upper surface  416 ′ of each of the second support member  416   b  and the third support member  416   c , (2) the right portion of the lower sidewall surface, T SL , of the tire, T, adjacent the upper surface  416 ′ of the fourth support member  416   d , and (3) the lower bead seat, W SL , of the wheel, W, substantially coplanar with both of the second support member  416   b  and the third support member  416   c . Additionally, as shown in  FIGS. 14F-14G , the upper surface  416 ′ of the second and third support members  416   b ,  416   c  are not co-planar with but arranged at a higher orientation when compared to the orientation of the upper surface  416 ′ of the fourth support member  416   d.    
     As seen in  FIG. 14G , a result of the movement according to the direction of the arrow, D 3 , the wheel, W, is permitted to plunge through the passage, T P , of the tire, T, in order to arrange the tire, T, relative to the wheel, W, in a “further mounted” orientation. As seen in  FIG. 14G , movement according to the direction of the arrow, D 3 , results in: (1) the left portion of the lower bead seat, W SL , and drop center, W DC , of the wheel, W, being orientated out of the passage, T P , of the tire, T, and in a spaced-apart, opposing orientation with the left portion of the lower bead, T BL , of the tire, T, and (2) a right portion of a lower, outer rim surface, W RL , of the wheel, W, proximate the right portion of the lower bead seat, W SL , such that a right portion of the lower sidewall surface T SL  of the tire, T, is disposed adjacent the upper surface  416 ′ of the fourth support member  416   d , and (3) the drop center, W c , of the wheel, W, being disposed within the passage, T P , of the tire, T, and adjacent to the right portion of the lower bead, T BL , of the tire, T, while (4) the upper bead, T BU , of the tire, T, substantially circumscribes the circumferential surface, W C , of the wheel, W. 
     Referring to  FIG. 14G , after the movement according to the direction of the arrow, D 3 , has ceased, an upward movement, U, according to the direction of arrow, D 4 , may occur in order to move the wheel, W, away from the support member  416  and then, subsequently, a rearwardly movement to the left, L, according to the direction of arrow, D 5 , may occur. The upward movement, U, according to the direction of the arrow, D 4 , results in the lower bead seat, W SL , of the wheel, W, being no longer substantially coplanar with both of the second support member  416   b  and the third support member  416   c , but, rather, the lower bead seat, W SL , and lower, outer rim surface, W RL , of the wheel, W, are arranged at least above the upper surface  416 ′ of both of the second support member  416   b  and the third support member  416   c.    
     Referring to  FIG. 14H , as a result of the rearwardly (e.g., to the left, L) movement of the wheel, W, according to the direction of the arrow, D 5 , the tire, T, is advanced toward the first and second tire-tread-engaging posts  430   a ,  430   b  and through the second spacing, S 2 , formed by the first and second tire-tread-engaging pasts  430   a ,  430   b  from the left chord, T C1 , to the right chord, T C3 ; as similarly explained above, because chords (including, e.g., the central chord, T C2 ) of the tire, T, between the left chord, T C1 , and the right chord, T C3 , are greater than that of the left chord, T C1 , and the right chord, T C3 , the first and second tire-tread-engaging posts  430   a ,  430   b  interfere with movement of the tire, T, through the second spacing, S 2 . 
     As a result of the above-described interference, the tire, T, in a similar manner as explained above, temporality deforms such that the diameter, T P-D , of the passage, T P , of the tire, T, is temporality upset to include a substantially oval form rather than a circular form. Accordingly, in a substantially similar fashion, the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , are also temporality upset to include a substantially oval form rather than a circular form. 
     The oval form of the upper tire opening diameter, T OU-D , and the lower tire opening diameter, T OL-D , reduces a portion of contact (and, as a result, friction) of the lower bead, T BL , of the tire, T, with that of the outer circumferential surface, W C , of the wheel, W, and, as such permits a further mounting of the tire, T, to the wheel, W, to occur such that the partial mounting of the tire, T, with the wheel, W, transitions to a “full mounting” of the tire, T, with the wheel, W. Accordingly, as seen in  FIGS. 14H-14I  and  15 H- 15 I, as the wheel, W, advances the tire, T, rearwardly (e.g., to the left, L) through the second spacing, S 2 , according to the direction of the arrow, D 5 , the oval deformation of at least the diameter, T OL-D , results in an oval deformation of the lower bead, T BL , of the tire, T, such that the right portion of the lower rim surface, W RL , of the wheel, W, encounters less resistance or interference with the lower bead, T BL , of the tire, T, as the right portion of the lower bead, T BL , of the tire, T, is moved from an un-mounted orientation with respect to the drop center, W DC , of the wheel, W, to a mounted orientation (see, e.g.,  FIG. 14J ) with respect to the drop center, W DC , of the wheel, W. Referring to  FIG. 14I , as the tire, T, is moved through the second spacing, S 2 , the lower sidewall surface, T SL , of the tire, T, may contact and be biased by the substantially cylindrical body  422   a ′ in order to assist movement of the lower bead, T BL , of the tire, T, from the un-mounted orientation with respect to the drop center, W DC , of the wheel, W, to the mounted orientation. Referring to  FIG. 14J , once the tire, T, has been completely moved through the second spacing, S 2 , according to the direction of the arrow, D 5 , the tire, T, may be said to be mounted to the wheel, W, such that the upper bead, T BU , of the tire, T, circumscribes the outer circumferential surface, W C , and as the lower bead, T BL , of the tire, T, circumscribes and is disposed adjacent the drop center, W DC , of the wheel, W. 
     The present invention has been described with reference to certain exemplary embodiments thereof. However, it will be readily apparent to those skilled in the art that it is possible to embody the invention in specific forms other than those of the exemplary embodiments described above. This may be done without departing from the spirit of the invention. For example most embodiments shown herein depict engaging a wheel (by way of a robotic arm) and manipulating the wheel to mount a tire thereon. However, nothing herein shall be construed to limit the scope of the present invention to only manipulating a wheel to mount a tire thereon. The exemplary embodiments are merely illustrative and should not be considered restrictive in any way. The scope of the invention is defined by the appended claims and their equivalents, rather than by the preceding description.