Patent Publication Number: US-7909402-B2

Title: Back support for a seat

Description:
CROSS REFERENCE TO RELATED APPLICATION 
     This application claims priority to U.S. Provisional patent application Ser. No. 60/973,212 filed Sep. 18, 2007, the contents of which are incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to seating products such as seats and chairs, more specifically seating products having a back support that is adjustable to conform to the contour of the occupant. 
     2. Description of the Related Art 
     It is not uncommon for people to spend a substantial portion of their daily life sitting. As a result it is important that the seat be both safe and comfortable. One of the most important features of any seat is the manner in which it supports a user&#39;s back. If the seat provides inadequate support or supports the back in an improper position, the user is likely to become uncomfortable leading to an interruption in concentration, contribute to fatigue, poor posture, and even chronic back problems. On the other hand, a seat which provides the proper type of support may avoid, or even help to correct, such problems. 
     People are different in many respects, basic of which are size, shape, and strength. Because each person is unique, it is not uncommon that each person has a unique back support requirement. As a result, the ideal back support will vary from individual to individual. 
     Unfortunately, most seats have a back support designed for “the average individual.” In an effort to produce more comfortable and healthy seating, some seats, particularly those commonly used in the office environment, offer a variety of adjustment features, such as the height and angle of the back support. Other offer front and back adjustment of the seat. Not all seat manufacturers provide a full complement adjustment options so that one seat can fit any user. Many adjustment features do not satisfy the demand requirements of the public to justify their implementation. Other adjustment options are simply too expensive to offer. As a result, such seats cannot provide everyone the proper fit and support. 
     Many attempts have been made to improve the comfort of seating products. For example, the seat described in U.S. Pat. No. 3,990,742 to Glass has a number of individual cam-like members extending laterally across the seat back. These members can be individually rotated to modify the shape of the back support. Although this type of system offers increased adjustability, it sacrifices convenience. Given the number of cam members that must be adjusted for each user, it is impractical for a variety of users to use such a seat. Another seat having a number of individually adjustable back support members is disclosed in U.S. Pat. No. 5,018,786. Again, given the large number of individual adjustments necessary to configure the seat to each user, this type of seat suffers the same disadvantages as that described immediately above. 
     Some seats offer automatic adjustment systems. For example, U.S. Pat. No. 4,944,554 to Gross employs a number of motors to automatically adjust the configuration of a seat to a predetermined spinal profile. However, the complicated electrical and mechanical interfaces required for this type of seat limit its reliability, availability, and practicality in many environments. 
     U.S. Pat. No. 5,328,245 discloses a seat having a seat and an upwardly extending support bar. A number of segments are received along the support bar to define a support surface for supporting the back of the user. The segments are slidable back and forth in a direction perpendicular to the user to allow the support surface to conform to the back of the seated person. A locking mechanism allows the person to lock the segments in the desired position. The disadvantage offered by this invention is that the contour is not truly conforming. Rather the contour is obtained by a series of step-like adjustments resulting in sharp transitions along the contour. 
     Each of the chairs and seats mentioned above has one or more disadvantages. Most of the seats described above provide a complex contouring mechanism for adapting to the user&#39;s back. That is to say that the contouring mechanisms are so time consuming or difficult to configure to the user&#39;s back that most user&#39;s will find them impractical. Others of the seat designs mentioned above offer complex systems for conforming to the back of the occupant resulting in substantially higher costs which translate directly to higher prices for consumers. As a consequence seating products available on the market today appeal to a limited audience and fail to meet the mass market attributes of the day. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING FIGURES 
         FIG. 1  generally illustrates one type of seat having a back support assembly embodying the invention; 
         FIG. 2  is an enlarged elevation view of an upper section of the back support assembly highlighted by circle II shown in  FIG. 1 ; 
         FIG. 3  is an enlarged elevation view of a lower section of the back support assembly contained within circle III shown in  FIG. 1 ; 
         FIG. 4  is an enlarged elevation view of an intermediate section of the back support assembly and generally identified by circle IV shown in  FIG. 1 ; 
         FIG. 5  is a section view of the back support assembly shown in  FIG. 2 ; 
         FIG. 6  is an oblique view of one embodiment of back members contemplated for use in the invention; 
         FIG. 7  is an oblique view of another embodiment of back members contemplated for use in the invention; 
         FIG. 8  is an oblique view of yet another embodiment of back members contemplated for use in the invention; 
         FIG. 9  is an oblique view of a seat employing another embodiment of a back support assembly; 
         FIG. 10  is an oblique view of the seat shown in  FIG. 9  from another angle; 
         FIG. 11  is an oblique view of a back element shown in  FIG. 10 ; and 
         FIG. 12  is an oblique exploded view of another embodiment of a back element contemplated for use in the invention. 
     
    
    
     DETAILED DESCRIPTION OF THE VARIOUS EMBODIMENTS 
     For purposed of the following description, the terms “upper”, “lower”, “right”, “left”, “rear”, “front”, “vertical”, “horizontal” and derivatives thereof shall relate to the invention as oriented in  FIG. 1 . However, the invention may assume various alternative orientations except where expressly specified to the contrary. It is also to be understood that the specific devices and processes illustrated in the attached drawings, and described in the following specification, are simply exemplary embodiments of the inventive concepts defined in the specification and any appended claims. Specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered limiting unless the claims expressly state otherwise. 
     The term ‘seat’ as used herein refers to something that may be sat on. The definition includes any place in which a person may sit. Such structures include, but are not limited to items of furniture for the home or office such as a chair, a stool, a sofa, a bench, and a lounge, and other forms used in other applications including seating for vehicles such as automobiles, water craft, aircraft and the like. The terms “seat back,” “back support,” and “back rest” as used herein refer to, but are not limited to, structures associated with the seat upon which a person may lean against while seated. 
       FIG. 1  generally illustrates a seat  20  comprising in general terms a base assembly  22  supporting a seat assembly  24 . Attached to one of the base assembly  22  or the seat assembly  24  and extending upwardly there from is a back support assembly  26 . The back support assembly  26  may be attached to one of the base assembly  22  or the seat assembly  24  in a manner that permits the user to adjust the tilt angle of the back support assembly  26  relative to the seat assembly  24 . Other common place adjustments include the ability to adjust the tilt angle of the seat assembly  24  relative to the base assembly  22 , the front and back position of the seat assembly  24  relative to the base assembly  22  and the back assembly  26 , and of course the height of the seat assembly  24  above the floor  27 . 
       FIGS. 1-4 , it is anticipated that the back support assembly  26  can be easily and readily adjusted to conform to the contour of the user&#39;s back. The back support assembly  26  includes a frame assembly  28  comprising a frame member  30  manufactured from metal or other material offering substantial structural rigidity to keep the back support assembly  26  in an upright orientation. It is contemplated that plate or tubular steel or aluminum and alloys thereof may be used to build the frame member  30 . Other suitable materials may also include wood and wood composites. In a preferred embodiment of the invention, the frame member  30  is generally J-shaped wherein the laterally extending bottom leg  32  may be coupled to one of the base assembly  22  or the seat assembly  24 . Extending upwardly from one end of the lower leg  32  is a vertical leg  34  extending substantially the length of the back support assembly  26 . The upper end  38  of leg  34  includes at least one and preferably two laterally extending flanges  40 . Should two flanges  40  be used, it is preferred they be aligned with one another and extend from opposite sides of the vertical member  34  to form a yoke-like structure for reasons that will become readily apparent below. Should a single flange be preferred, it is desired that the flange extend laterally outward from a central portion of the vertical member  34 . Regardless of the number of flanges  40 , it is preferred that the distal end furthest from the upright  34  include a transverse hole  44  for receiving a bolt or other fastener. A similar yoke-like structure is also preferred to be formed toward the opposite and lower end of the vertical member  34 , proximate the seat assembly  24 . Shown in  FIG. 4 , two laterally extending flanges  42  extend from opposite sides of the vertical member  34 . However, just as with the yoke-like structure described immediately above, it may be desired to use a single flange such as  42  extending laterally from a central portion of the one side of the vertical member  34 . 
     Another portion of the back support assembly  26  is supported by the frame assembly  28 . Referring to  FIGS. 2-4 , a back assembly  50  of predetermined length is attached to the frame assembly  28 . An upper end  52  of the back assembly  50  is attached between the upper yoke-like flanges  40  and an opposite end  54  is likewise attached between the lower yoke-like flanges  42 . In a preferred embodiment, the length of the back assembly  50  is greater than the distance between the upper and lower yoke structures  40 ,  42  to cause the back assembly  50  to bow or arch away a predetermined distance from the upright member  34 . 
     The back assembly  50  is preferably formed from a plurality of back members generally identified by the reference numeral  56 . In one embodiment, back members  56  include an upper anchor member  58  defined by a generally body portion  60  and an adjoining coupling block  62  which in the preferred embodiment is received between the upper yoke flanges  40 . The coupling block  62  preferably includes a longitudinal hole or passage  64  adapted to align with the holes  44  in the flanges  40 . In a similar fashion the back assembly  50  includes a lower anchor member  66  also having a generally solid body  68  attached to a lower coupling block or body  70 . The lower coupling body  70  is similarly received between the lower yoke flanges  42  and includes a longitudinal passage  72  adapted to be aligned with the holes  44  in the flanges  42  to receive a bolt or other type of fastener (not shown). The coupling arrangement between the respective upper and lower coupling bodies or blocks  62  and  70  with the flanges  40  and  42  permit the back assembly  50  to pivot at each end to allow the back assembly to conform to the contour of an occupant as will become more readily apparent below. 
     Intermediate the upper and lower anchor members  58  and  66  are a plurality of back elements or members  74 , each juxtaposed one another vertically. See  FIG. 4 . Each of the back elements  74  is able to articulate within a predetermined range of angular arc relative to an adjacent back element  74  so that the back assembly  50  may conform to a substantially any serpentine shape.  FIGS. 4 and 5  illustrate one embodiment of the back elements  74  in greater detail. 
     In a first embodiment, back elements or members  74  may include a first member  80  and a second member  82 . As illustrated, each first member  80  may be in the form of a generally polygonal or semi-cylindrical form of predetermined dimension and my have generally parallel surfaces  84  and  86 , and opposing ends  88  and  90 . Upper and lower surfaces or ends  92  and  94  may include opposing longitudinally concave surfaces of predetermined radius generally complimentary to that of the juxtaposed second member  82 . The second member  82  may also be in the form of a polygon or cylindrical solid of predetermined dimension generally similar in terms of width and length as that of each first member  80 . The shape or form of the curved surface of the second member  82  is preferably similar to the shape of the concave surfaces formed in the ends  92  and  94  of the first members  80 , but need not be exact with the intention to create as much friction as possible between the first and second members at certain times while in use. A few ways for creating such interference will be described in greater detail below. 
     Although the first and second members  80  and  82  have been described above, it is anticipated that other shapes and forms may be used including various oblate and prolate ovals, spheroids, and polygons so long as there is sufficient surface area between the two components to provide an interference or frictional surface for reasons that will be become more readily apparent below. It is also anticipated that different materials may be implemented to form the different members  80 ,  82  to increase the interference or frictional interaction and locking function in a first configuration while at the same time permitting relatively easy movement between the support members in a second configuration. A variety of modifications described in greater detail below are designed to help achieve that function. 
     As seen best in  FIG. 5 , first members  80  and second members  82  may be substantially solid but for several passages extending transversely there through. Although we have shown them as being substantially solid, they need not be, and could be formed from a networks of bulkheads and other interior framework to provide rigidity. But with respect to what is shown, each back support member  56  includes a central passage  100  that passes entirely through each member  56  and configured to substantially align with a similar passage  100  formed in an adjacent member  56 . In this embodiment it is also envisioned that two outboard passages  102  and  104  also extend through each member  56  outboard of and parallel to central passage  100 . The upper and lower throats of each passage within each member  56  are preferably larger in terms of lateral dimension that in the center of each member  56  for reasons provided below but it is also anticipated that the dimensions may be constant throughout. The wider throats toward each end of each passage  100 ,  102  and  104  provides greater leeway in aligning the passages in the adjacent support member when one rotates relative to one another. 
     No direct linking or coupling is required to keep adjacent back members together. Rather the plurality of back members  56  may be threaded on a clamping or tensioning member  110  such as, but not restricted to, a cable, strap, or rod extending through each back member  56 . The uppermost end of the clamping or tensioning member  110  is anchored in one of the anchoring members  58 ,  66  described above. The opposite end of the clamping or tensioning member  110  is preferably coupled to a tensioning apparatus or device  112  ( FIG. 1 ) attached to a fixed structure such as one of the frame assembly  28 , the seat assembly  24  or the base assembly  22 . Together, the clamping or tensioning member  110  and the tensioning apparatus or device  112  comprises the clamping assembly. In a preferred embodiment, the tensioning device  112  may be fixed to the frame assembly such that any tension applied to the member  110  places the back support members in compression in a first configuration, creating substantial loads between the pluralities of back members  56  along the mating surface areas described above. In a second configuration of the tensioning device, tension on the member  110  is relieved, allowing the back members  56  to disengage from one another, and rebound through pivoting or relative movement to one another. The tensioning member  110  may be adjusted to place any desired degree of tension on the back member  56  to suit the user&#39;s preference as to stiffness. That is to say the tensioning member  110  may be adjusted anywhere between no tension and full tension to provide the desired stiffness in the back member  56 . Any one of a number of different forms of tensioning devices  112  may be utilized to adjust the amount of tension applied to member  110 . Examples of such devices include threaded wheels, ratcheting drums, over center levers and linkages, cam tensioning devices, as well as a host of others. 
     Extending through each of the respective outboard passages  102  and  104  is a resilient biasing assembly  114  having a predetermined spring constant. The biasing assembly  114  may formed from one or more resilient members or springs  116  to provide lateral or rotational rigidity to the back support assembly  26 , yet also absorb and provide flexibility in some measured degree to the contour of the back. In the embodiment depicted in the drawing figures, two resilient members or springs  116  are depicted on opposite sides of the tensioning member  110 . However it is envisioned that a single resilient member or spring such as  116  may be used. In that scenario it is contemplated that the tensioning member  110  may be located slightly off-center along with the one resilient member or spring  116  to provide as much of the forces toward a centerline of the back member  56 . It is also envisioned that if more than one resilient member or spring is being used, it may be desired to place the springs  116  as far outboard as possible, depending upon the chair design. Regardless of the location of the springs or resilient members  116 , it is desired that the members  116  apply a biasing force to the back. This way, the user is able to sit in the seat and apply sufficient force to allow the back assembly  50  to conform to the occupant&#39;s back contour. This also provides the user the option to fix the contour should it be desired by increasing the tension on the tensioning member  110 , placing each of the plurality of back members  56  into compression and a locked position. In one form of the invention it is envisioned that the resilient members  116  may be in the form of rods, blades, tubes or coils of metallic or polymeric material providing sufficient spring constant to apply a biasing force to each of the back support members displaced from its original position. Other forms, shapes, and materials for the resilient members  116  may be used to apply the desired biasing forces to the back. 
       FIG. 6  illustrates another embodiment of the back members  120  that may be used to form the back assembly  50 . Each back member  120  may be in the general form of a cylinder of predetermined radius. It is envisioned that each back member  120  may also be tubular or solid in form so long as each provides sufficient surface area to interact with the juxtaposed back member  120  when placed in compression. The length of each back member  120  is predetermined as well and just like the previous embodiment, includes a central passage  122  and outboard passages  124  and  126  of predetermined dimension. As in the previous embodiment, the dimensions of the passages may be constant throughout although it is also anticipated that the throats at each end may be greater than the lateral dimensions of the passage intermediate the ends. 
     To increase the frictional locking force between the back members  120 , the surface area around the circumference  128  may be increased by providing topography or interference structures. In one embodiment the interference structures may be in the form of a plurality of circumferential or annular ridges  130  spaced at predetermined intervals along the length of each member  120 . The profile of each interference member  130  may vary depending upon the desires of the manufacturer, but in a preferred embodiment, each may have a triangular cross-sectional profile of predetermined pitch and height. The corresponding and mating member  132  shown in  FIG. 7  may also include a corresponding mating interference profile defined in the upper and lower ends  134 ,  136 , respectively. As shown in  FIG. 7 , the upper end  134  includes a longitudinal concave profile in which are defined a like number of transverse interference structures such as grooves or channels  138 . The pitch profile of each structure  138  may be slightly different from that of a mating structure  130  so that when placed in compression relative to one another, each structure or member  130  is wedged into a receiving or corresponding structure  138 , providing a good frictional lock between the two components. It has been found that the addition of the plurality of annular structures  130  and their interaction with the structure or member  138  provides additional rotational rigidity than the use of purely cylindrical frictional interfaces. 
     Based upon the suggested description made above with respect to  FIG. 6 , other surface area modifications or adaptations can be made between the interacting back members  56  to increase the frictional interference characteristics as well as reduce torsional motion or movement. For example as shown in  FIG. 7 , one such alteration may include providing longitudinal splines  140  about the circumferential surface  142  of a cylindrical member such as  144 . Like longitudinal mating splines, grooves or the like  146  may be formed in the longitudinal trough or concave end  148  of a mating first member such as  150 . Other modifications are contemplated as well, including providing a plurality of mating facets or surfaces on the back support members that act to index the degree of angular arc each back support member may travel relative to an adjacent back support member. The faceted faces may also serve to increase the frictional surface area as well as resist torsional or rotational movement of the back support members relative to one another. Other topical treatments or relief may be used on the interacting surfaces of the juxtaposed back support members, including, but not limited to, a plurality of interacting detents, dimples and pimples, cams and cam followers, ridges and grooves, among others, to provide increased surface area as well as structural interlocking. 
     It is anticipated that rather than having two dissimilar back support members such as described above, a plurality of like back members such as generally identified by reference numeral  160  may be used to achieve substantially the same function in substantially the same way to achieve substantially the same result without seriously departing from scope and objects of the invention. Referring to the drawing figure, it is anticipated that each back member  160  may include a body  162  having a width (w), a height (h), and a depth (d). The body  162  may be generally rectangular having generally parallel front and back surfaces  164 ,  166 , generally parallel opposing end surfaces  168 ,  170 , and roughly parallel top and bottom surfaces  172 ,  174 , respectively, although just as described above, other forms may also be adopted without departing substantially from the objects of the invention. In the embodiment depicted, the top surface  172  may be convex. The bottom surface  174  may be concave in a shape substantially complimentary to the convex shape of surface  172  of a lower back support member  160 . 
     It is further contemplated that in one embodiment, it may be preferred that every back member  160  be substantially identical to the one above and/or below in order to reduce the number of different components needed to carry out the invention. However, depending upon the desired profile or contour to be adopted by the back support assembly it may be desired to alter the dimensions in terms of height (h), width (w), or depth (d) of one or more back members  160  in order to alter the profile of the back. 
     Each back member  160  may further include at least one, and preferably a plurality of through passages such as  176 ,  178  and  180 . Passage  176 ,  178  and  180  are intended to extend from the upper surface  172  downwardly parallel to the height axis of the body  162  and out the bottom surface  174 . In a first form, each passage  178  passes along a central axis through each member, while the outboard passages  176  and  180  parallel the central passage, but a predetermined distance laterally offset from the central passage  178 . In one form of the invention the diameter or dimension of the passages  176 ,  178  and  180  may be constant throughout their length. The passages  176 ,  178  and  180  may have an hour-glass or other vertical profile such that proximate the top and bottom surfaces  168 ,  170 . the dimensions are greater than the dimension of the passages near the center of the body  162  to provide an easier transition to the same passage in an adjoining or juxtaposed back support member. 
     Similar to that described above, passage  178  of each back support member is intended to receive a clamping or tensioning member such as  110  therein that extends a predetermined length of the back support assembly. In one form, the tensioning member may include substantially any structure that can be placed under a tensile load such that the opposite force places the respective back support members under compression. Acceptable tensioning member structures include metal or polymeric twist or braided cable, polymeric braided cable or ropes, metal and polymeric solid rods and straps, or substantially any other type of material capable of being placed under tension. The biasing passage(s) may receive any one of a number of members capable of providing a restoring force to the back support. Such restoring forces may be provided by biasing members in the form of cables, rods, straps, blades, and coiled springs. Other structures may also be used to provide the restoring or biasing force without departing substantially from the scope and objects of this invention. 
     In operation, it is envisioned that to adjust the back assembly  26  to fit the contour of the occupant, the tensioning device  112  is placed in a release configuration removing any axial compressive forces upon the juxtaposed back support members. The degree of release may be adjusted to range from where the return springs just overcome the compressive force so that the biasing force of the springs just overcomes the compressive force on a limited number of back support members, to a point where all compression is removed, allowing the springs to move all of the back support members to an initial bowed or arched position relative to the frame assembly. In a preferred embodiment, it is anticipated that the invention will be tuned at the time of manufacture so that when the tensioning device is released, the occupant may lean against the back assembly  50  and have the back members articulate or pivot about axes of rotation contained in an adjacent back support member to allow the back assembly to bend and shape to the serpentine contour of the user&#39;s back without a complete collapse. Moreover, it is anticipated that the spring constant of the return springs will also provide a substantial amount of resistive force to keep the occupant from feeling like he/she is falling back in the seat. The resistive force applied by the spring will also aid in redistributing the forces to cause the back support assembly conform to the shape of the user. Once the desired profile has been established by the user in the seat, the occupant simply move the tensioning device  112  to a second or locking position. Actuation of the tensioning or locking device  112  places the cable or tensioning rod  110  in tension. This action places an equal and opposite reaction upon the plurality of back support member, causing them to compress against one another along the line of the profile adopted from the occupant. As the back support elements compress, the frictional surfaces produced by the mating concave and convex surfaces provide ample force to keep the back assembly at the established profile. It is also envisioned that structure be added behind the back assembly to keep the assembly from oil canning in the opposite direction. Such a structure may include a limiter on the degree of movement of the back assembly in a direction toward the frame. The tensioning device may be adjusted to place any desired degree of tension on the back member to suit the user&#39;s preference as to stiffness as more fully described below. 
       FIGS. 9 and 10  illustrate another embodiment of a seat  200  including a base assembly  202 , a seat assembly  204 , and a back support assembly  206  offering the same novel features, advantages and benefits of the previously described embodiments, offering lateral support for the back of the user. Similar to the prior embodiments, the back support assembly  206  includes a frame assembly  208  formed from a frame member  210  which is dependent from one of the base assembly  202  or the seat assembly  204 , and extends upwardly therefrom. Mounted intermediate an upper and lower end of the frame assembly  210  is a back assembly  212  assembled from a plurality of back members  214  disposed in serial arrangement one adjacent another. Each back member  214  may generally be in the form of a cylinder and disposed relative to an adjacent member  214  such that the cylindrical sides may be tangentially in contact with one another. 
     As best seen in  FIG. 10 , extending from opposite ends of each back member  24  is a lateral support  216 , each of which may vary in terms of length, width, and thickness, depending in large part upon the vertical location along the back assembly  212 , as well as the extent and amount of support desired. For example, lateral supports  216  that are thicker, wider and longer provide support over a greater area than supports  216  that are shorter, thinner, and narrower. The arrangement of the lateral supports  216  along the back support assembly  206  may vary depending upon the desired support characteristics one wishes to achieve. In a preferred embodiment, each lateral support generally includes a blade section  218  of predetermined length and width extending from a root section  220  designed to transition with an end of a back member  214 . Transitioning outwardly from the root section  220 , the blade section widens to a predetermined width forming a front surface  222  and a back surface  224 . The thickness of the blade section may vary, but it is envisioned, depending upon the type of material used in the manufacture, that each blade section may run between one-eighth and one-quarter of an inch thick. The flexibility of each blade section may also be controlled by a flexor or rib member  226  extending along the back surface parallel to the length of the blade, beginning at the root section and extending a predetermined distance along its length. In a preferred embodiment the flexor or rib member  226  is formed integrally with the blade section. The width or thickness of the flexor member may vary along the length of each blade to provide the desired amount of flexion in each support. 
     As seen in  FIGS. 9 and 10 , not every back member  214  need have lateral supports extending from each end. Indeed, if lateral supports offering wide support in the vertical direction are used, fewer lateral supports may be desired to reduce interference with one another. On the other if support to a greater degree is desired, the manufacturer may reduce the vertical extent of each lateral support, narrowing them so that a greater number may be used. The lateral supports may be formed separately from each of the back members and attached to the ends of the members using one or more of a host of connection methods. These include male/female connections, mechanical fastening, and adhesives. Alternatively it may be desired to manufacture each back member and lateral support as a single integral unit reducing the time for manufacture and removing any inherent weakness in the transition. 
     Although the above description describes the lateral supports  216  as being formed integrally with select ones of the back members, it is envisioned that the back members may have couplers formed at opposite ends for having select lateral supports attached thereto to form a custom back support. For example as shown in  FIG. 12 , a back member  230  may have a recess  232  formed in opposite ends thereof which are configured to receive a male member  234  extending from an end  236  of each lateral support  238 . The male member  234  extending from the lateral support  238  may be one of any number of designs or shapes to provide a secure coupling yet offering the desired orientation relative to the back member. It should be immediately recognized that the respective coupling members may be reversed to obtain substantially the same result. Other types of coupling arrangements may be selected to allow custom positioning of the lateral supports on the back members, yet ensuring that the attachment of each lateral support to a respective back member is secure and able to remain attached to the back member during use. 
     It may be desired to cover or conceal all or portions of the back support assembly with a mesh, a fabric, and leather or vinyl skin. Depending upon the actual shape and design of the frame assembly, the cover may enclose the frame assembly, or leave it exposed, depending upon the style or design intended by the manufacturer. In one particular embodiment, it is envisioned that the cover enclose just the back assembly and those portions of the frame assembly where the back assembly is connected, leaving the framework for the frame assembly exposed as part of the design. Depending upon the specific configuration of the back support assembly and its spatial relationship with the seat assembly, other covers and concealments may be designed that provide an aesthetic appearance or particular design characteristic. 
     It is currently envisioned that the individual back support member described above and the variants described above may be manufactured from a variety of materials, including resin and other polymeric materials, metals and their alloys, as well as wooden based products. However it is preferred that the back support members be made using injection molding techniques from resins and other polymers to achieve the preferred durometer hardness for maximizing the frictional locking forces when in the compressed state. Injection molding also provides the user the most efficient mechanism for obtaining the varieties of profiles and structures described above. 
     In the foregoing description, it will be readily appreciated by those skilled in the art that modifications may be made to the invention without departing from the concept disclosed herein. Such modifications are to be considered as included in the following claims, unless these claims by their language expressly state otherwise.