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CROSS-REFERENCE TO RELATED APPLICATIONS 
     The present invention claims the benefit of priority to U.S. Provisional Patent Application No. 60/671,898, filed on Apr. 15, 2005, entitled “Translucent Resin Wall System,” the entire contents of which are incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     1. The Field of the Invention 
     This invention relates to systems and methods for creating and installing resin-based panels that can be used as decorative architectural walls. 
     2. Background and Relevant Art 
     Some recent architectural designs have implemented synthetic, polymeric resins, which can be used as windows, ceiling panels, partitions, walls, etc., in offices and homes. Present polymeric resin-based materials generally used for creating decorative resin-based panels comprise polyvinyl chloride or “PVC” materials; polyacrylate materials such as acrylic, and poly(methylmethacrylate) or “PMMA;” polyester materials such as poly(ethylene terephthalate), or “PET;” poly(ethylene terephthalate modified with a compatible glycol such as 1,4-dimethanol or 2,2-dimethyl-1,3-propanediol) or “PETG” (or “PCTG”); as well as polycarbonate materials. 
     In general, resin-based materials such as these are now popular compared with decorative cast glass or laminated glass materials, since resin-based materials can be manufactured to be more resilient, and to have a similar transparent, translucent, or colored appearance as cast or laminated glass, but with less cost. Decorative resin-based panels can also provide more flexibility, compared with glass, in terms of color, ability to texture, gauge availability, lower material density (implying lower panel weight) and considerably higher impact resistance. Furthermore, decorative resin-based panels have a fairly wide utility since they can be manufactured and fabricated to include a wide variety of artistic colors and images. This stated flexibility applies both in the manufacturing phase, as well as in the post-manufacturing, or ultimate-use, phase. 
     One use-based application of polymeric resins in architectural environments is that of a decorative panel, which can be used to decorate an existing wall, an interior wall or ceiling finish, or as a new wall partition. For example, a 4×8 foot resin-based panel could be used as a partition wall by inserting the resin-based panel inside a wood, plastic or metal frame that has bottom, side, and top grooves for holding the resin-based panel securely. If the resin-based panel is translucent, the resin-based panel might also be formed with embedded decorative materials, which could provide additional creative features to the partition or interior finish. Light transmitted on either side of the wall will provide an aesthetic effect to viewers on the opposing side. 
     In other cases, such as with existing, non-partition walls, a colored, resin-based panel can also be mounted directly against the existing wall (e.g., existing drywall) to provide another kind of aesthetic effect. This is ordinarily done using a combination of adhesives and/or other mounting materials such as two-sided tapes, screws, glues and the like. Unfortunately, the aesthetic effect of this type of resin-based panel material is limited since the resin-based panel&#39;s opacity is important for obscuring the mounting materials (e.g., adhesives, existing dry wall, and so forth). In particular, resin walls used in this type of environment will not ordinarily include decorative objects, and are not constructed to allow light to transmit through the resin-based panel as such translucency can often exhibit a shadowing effect, which is considered undesirable by designers and architects. 
     There are yet additional challenges for mounting these types of resin-based panels directly to an existing wall. For example, the resin-based panels can be fairly heavy relative to the adhesives, and the materials and methods for mounting these materials are often not readily configured for the type of expansion and/or contraction that can effect the resin-based panels over time. Furthermore, existing wall treatment systems designed for polymeric materials also suffer from issues associated with the “creep” of resin-based material over time. Creep occurs when the resin-based material flows over time in the direction of gravity, such that some resin-based panels can gain a slight degree visual distortion in a portion of the panel. Furthermore, creep, in addition to any expansion and contraction of material due to temperature changes, can cause the polymeric-based or resin-based panels to buckle and/or deflect where held in a rigid fashion. For this reason, polymeric materials used in wall panel systems have traditionally been limited to materials that may be more dimensionally stable such as glass, woods, concrete, gypsum, metals and the like, but nevertheless less aesthetically desirable materials due to their lack of translucency. 
     There are other ways in which decorative walls can be fastened to an existing wall to create decorative effects, which can avoid some of the disadvantages of using primarily opaque materials. For example, some builders will mount a translucent glass panel to an existing wall using one or more “standoffs” that are designed to mount into a specifically designed frame for the existing wall, or, in other configurations, to mount directly to metal or wood studs in the wall, or some other concrete or steel substrate. This type of mounting allows light to pass from the gap—created by the standoffs—between the frame that was mounted to the existing wall and the translucent glass panel, and to the other side of the panel to thereby create an aesthetic effect. 
     Unfortunately, glass is a heavier, often more expensive, and typically more fragile material than polymeric resin-based panels. In particular, the weight of glass makes it fairly difficult, if not impossible, to mount a glass panel to common drywall or wood wall substrates. Furthermore, the frame systems used to mount the glass panels in a standoff position from an existing wall tend to be quite complicated, tend to need precise measurements of the existing wall, and also tend to involve a significant amount of labor to install. Still further, glass panels cannot be easily modified to incorporate decorative materials, and so are limited in the type of aesthetic effect they can provide, even after taking the time to create and install them in a specific environment. Yet still further, glass systems that use standoffs attached directly to the wall must be pre-fabricated to accommodate the natural expansion and contraction that could otherwise be field-fabricated with resin-based panels. 
     Another of the problems with existing panel systems is that many attachment points are typically needed in order to counter the tendency of the attached material to deflect under its own weight. This is partially because systems generally rely on supporting the panel from the bottom portion of the panel. In addition, existing panel or wall systems are configured to hold the given panels in their existing shape, which tend to be either flat or curved, with little additional variation thereof. Unfortunately, to achieve a curved wall surface, the wall system frame (or relevant attachment objects) will ordinarily need to be constructed to match the curves of the material, which can result in significant expense, complexity, and still other aesthetic limitations. 
     BRIEF SUMMARY OF THE INVENTION 
     The present invention solves one or more problems in the art with systems, methods, and apparatus configured to provide existing walls with decorative, translucent resin-based panels in a simple, cost-effective, and aesthetically pleasing manner. In particular, systems and methods in accordance with implementations of the present invention relate to mounting polymeric resin-based panels, which can be modified to provide a wide range of aesthetic effects, such as having a light source shine through from behind the resin-based walls compared to an existing wall constructed with other materials. 
     For example, a translucent wall assembly in accordance with at least one implementation of the present invention includes a frame having one or more vertical members and one or more horizontal members. The frame is configured to be vertically positioned adjacent an existing wall. The frame also has one or more standoffs connected thereto, which are ultimately used to fasten one or more polymeric resin-based panels to the frame in an at least adjacent fashion. The translucent wall assembly also includes a polymeric resin-based panel connected to the frame via at least a portion of one or more standoffs. The distance provided by the standoffs relative to the frame allows light to pass from a front side that opposes the frame to a back side that faces the frame, and from the back side that faces the frame to the front side that opposes the frame. 
     Alternately, a frame assembly for mounting one or more resin-based panels to an existing wall at an extended position includes, for example, a plurality of horizontal members having a groove formed therein, as well as a plurality of vertical members also having a groove formed therein. The frame assembly further includes a plurality of standoffs slidingly-coupled to the groove of one of the plurality of horizontal members or to the groove of one of the plurality of vertical members. The plurality of standoffs are also coupled on an opposing end to either one or more resin-based panels, or to a secondary frame to which the one or more resin-based panels are mounted. 
     Accordingly, implementations of the present invention provide a number of advantages to builders and/or architects looking to enhance existing walls, such that the existing walls can take on the aesthetic properties of the resin-based panels, including incorporating lighting from behind. These aesthetic properties can be many and varied, and can include variations in color, texture, inclusion of different types of decorative objects, as well as differing shapes. Furthermore, wall and/or frame systems in accordance with the present invention can be readily adjusted in the relevant attachment positions over time to account for any potential creep and/or expansion/contraction of the given polymeric panels. Still further, the panels and systems described herein can also be made to include fire resistance properties, such as may be needed in certain types of manufacturing or building environments as sometimes required by building officials or local building codes. 
     Additional features and advantages of exemplary implementations of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of such exemplary implementations. The features and advantages of such implementations may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features will become more fully apparent from the following description and appended claims, or may be learned by the practice of such exemplary implementations as set forth hereinafter. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In order to describe the manner in which the above-recited and other advantages and features of the invention can be obtained, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered to be limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which: 
         FIG. 1A  illustrates a resin-based wall panel mounted to an existing wall at a standoff position in accordance with an implementation of the present invention; 
         FIG. 1B  illustrates a close up perspective view of at least one standoff assembly used to mount the resin-based wall panel illustrated in  FIG. 1A ; 
         FIG. 1C  illustrates an exploded perspective view of the standoff assembly illustrated in  FIG. 1B  when used to mount a top portion of the resin-based wall panel; 
         FIG. 1D  illustrates an exploded perspective view of the standoff assembly illustrated in  FIG. 1B  when used to mount a lower portion of the resin-based wall panel; 
         FIG. 2A  illustrates another implementation of a resin-based wall panel in accordance with the present invention in which one or more resin-based wall panels are modified for a curved effect; 
         FIG. 2B  illustrates a back perspective view of the resin-based wall panel illustrated in  FIG. 2A ; 
         FIG. 2C  illustrates a facing diagrammatic view of a panel and a frame configured to create the wave effect illustrated in  FIG. 2A ; 
         FIG. 3A  illustrates still another implementation of a resin-based wall panel in accordance with the present invention in which one or more resin-based wall panels are mounted within a grid system; 
         FIG. 3B  illustrates a close up perspective view of a grid intersection of the resin-based wall panel illustrated in  FIG. 3A ; 
         FIG. 3C  illustrates an exploded perspective view of an intersection assembly of the frame used in creating the grid intersection illustrated in  FIG. 3B ; 
         FIG. 4A  illustrates a top perspective view of another implementation of a resin-based wall panel system, wherein one or more resin-based wall panels are positioned between ridged frame members to create a curved effect; 
         FIG. 4B  illustrates an exploded view of resin-based wall panels and frame members of the resin-based wall system shown in  FIG. 4A . 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The present invention extends to systems, methods, and apparatus configured to provide existing walls with decorative, translucent resin-based panels in a simple, cost-effective, and aesthetically pleasing manner. In particular, systems and methods in accordance with implementations of the present invention relate to mounting polymeric resin-based panels, which can be modified to provide a wide range of aesthetic effects, such as having a light source shine through from behind the resin-based walls compared to an existing wall constructed with other materials. 
     In particular, and as will be understood more fully from the following specification and claims, one aspect of the invention includes positioning one or more translucent resin walls at a standoff position from an existing wall. Another aspect of the invention includes providing an existing walls with resin-based panels that have been enhanced in one or more ways for color, degree of translucence, fire-resistance, and/or to include one or more decorative objects. Still another aspect of the present systems includes mounting the one or more resin-based panels to an existing wall using any number of techniques in order to provide a wide variety of formational effects such as straight, grid-like, or curved effects. A further aspect of the invention includes providing ease of installation, as well as greater durability of the resin wall by accounting for material creep, and/or allowing for natural expansion and contraction. 
     For example,  FIG. 1A  illustrates a resin wall that has been mounted to a frame, and that can further be mounted to an existing wall. As shown, the resin wall  100   a  includes resin-based panels  105   a - b  that are mounted at a standoff position with respect to the frame  103  in accordance with an implementation of the present invention. Due to the resin wall&#39;s translucent properties, light can be transmitted from the frame  103  side of the resin wall  100   a  to an opposing side, since the resin wall  100   a  is translucent. The composition of the resin wall  100   a , as well as resin walls  100   b  and  100   c  (as in the subsequent Figures), can be any suitable polymeric resin for creating a sufficiently solid vertical panel. 
     Examples of suitable polymeric resins include any copolyesters such as PET, PETG, PCTG, and the like; any acrylics such as PMMA; any polycarbonate material; and any combinations thereof. Panels made from these polymeric resins can be of varying color, translucence, and texture, and can also be made to include decorative objects. Panels made from these polymeric resins can also be made to have fire-resistance properties without sacrificing translucence, and so can be helpful when used in building applications, such as interior finishes, that carry additional flammability performance requirements as regulated by local or national building codes (e.g., flame spread and smoke tests characterized American Society for Testing and Materials E84—“ASTM E84”). 
     Examples of adding color or decorative objects to a resin-based panel are found in commonly-assigned U.S. patent application Ser. No. 10/465,465, filed on Jun. 18, 2003, entitled “Laminate Structure with Polycarbonate Sheets and Method Of Making,” which is a continuation-in-part of commonly-assigned U.S. patent application Ser. No. 10/086,269, filed on Mar. 1, 2002, entitled “Laminated Article and Method of Making Same,” which claims the benefit of priority to U.S. Provisional application Ser. No. 60/273,076, filed on Mar. 5, 2001, entitled “Lamination of Dissimilar Materials and Method for Making Same.” Examples of forming a polymeric resin-based panel with decorative objects are found in commonly-assigned U.S. patent application Ser. No. 10/821,307, filed on Apr. 9, 2004, entitled “Architectural Laminate Panel with Embedded Compressible Objects and Methods for Making the Same.” 
     In addition, examples of adding fire-resistant properties to translucent polymeric resin-based materials, which are suited for use in interior finish applications, are found in commonly-assigned U.S. patent application Ser. No. 11/103,829, filed on Apr. 12, 2005, entitled “Fire-Resistant Architectural Resin-based materials,” which claims the benefit of priority to U.S. Provisional Patent Application No. 60/579,004, filed on Jun. 11, 2004, entitled “Fire-Resistant Architectural Resin-based materials.” The entire content of each of the aforementioned U.S. patent applications is incorporated by reference herein. 
     Referring again to the figures, frame  103  is configured to be easily assembled into a cross section that can be adjusted to the size and width of virtually any existing wall. For example, the frame  103  includes two or more horizontal frame members, such as horizontal frame members  110   a  and  110   b , and two or more vertical frame members, such as vertical frame members  120   a - b . The horizontal and vertical frame members in turn can be expanded or shortened, and reduced or multiplied in number as appropriate. Furthermore, the frame members  110  and  120  comprise multiple grooves, oz perforations, and/or tracks for adjustably receiving one or more mounting components or fasteners, such that the frame  103  can be adjusted and mounted to virtually any size or shape of existing wall. 
     As shown in the close up perspective view of  FIG. 1B , the frame  103  can also be configured to receive any other support members, such as support member  112 . For example, support member  112  is inserted in corresponding “Z-grooves” of the frame  103  on the side ultimately proximate to an existing wall, and can be used to stabilize the frame  103  in any of an X or Y orientation. In one implementation, the support member  112  is mounted inside an existing wall; while in other implementations, the support member  112  is mounted directly to an existing wall, and the vertical members  120  (e.g.,  120   a - d ) mounted to the support member  112  essentially hang from the support member  112 . The hanging effect of the support member  112  can be helpful for providing side-to-side adjustability of the overall frame  103 . 
     The one or more support members  112  can be anchored to the frame  103  against the existing wall using any number of fasteners or anchor apparatus (not shown). As such, the one or more support members  112  also comprise any suitable grooves, perforations, and/or tracks, which can be used to help mount the frame to the existing wall (not shown). The horizontal members  110 , vertical members  120 , and/or support structure(s)  112  can be made of any suitably strong metal, alloy, polymeric material, and/or combinations thereof. (In one implementation, the frame members are selected for their aesthetic properties since they will be seen through the translucent resin-based materials.) 
     The grooves, perforations, and/or tracks of horizontal frame members  110   a - b  and vertical frame members  120   a - c  can also be configured to receive one or more securing members, such as standoffs  115 , at one or more X/Y positions. As shown, standoffs  115  are configured in turn to receive a corresponding resin-based panel  105   a  on one end, and secure the given panel (e.g.,  105   a - b ) at an extended position relative to the frame  103 . 
       FIG. 1C  illustrates a close up exploded perspective view of a standoff assembly  115  positioned between a resin-based panel  105   a  and a vertical member. In particular,  FIG. 1C  shows that standoff  115  comprises a body  113  configured with a threaded recess for receiving a threaded stem  119  that extends from a cap  117 . The standoff body  113  in turn receives a threaded connector  111 , which secures the standoff body  113  to the resin-based panel (e.g.,  105   a ) on one side. The standoff body  113  also attaches to a slidable brace  107  on an opposing side. The brace  107  is further configured to slide within a groove  127  of the vertical member  120   a . Thus, the body  113 , connector  111 , and brace  107  can slide in concert along groove  127  until the body  113  is tightened to a certain point with respect to the brace  107  and member  120   a . The standoff  115 , including cap  117 , threaded member  119 , body  113 , connector  111  and brace  107  can be made of any appropriate metal, alloy, or polymeric materials, or combinations thereof, for holding a weight of a resin-based panel by itself, and/or with one or more other standoffs  115 . 
     As also shown, the cap  117  secures the resin-based panel  105   a  to the standoff by inserting the threaded member  119  through a specifically sized eyelet  123   a . In particular,  FIG. 1C  shows that threaded member  119  is inserted through eyelet  123   a  before being inserted and screwed into body  113 . As shown, the eyelet  123   a  is about the same size (or slightly larger) in diameter as the threaded member  119 , since what is shown is the upper portion of the panel  105   a . This relatively precise size or diameter of eyelet  123   a  ensures that the resin-based panel  105   a  is secured where the relevant standoff body  113  is secured to the frame  103 , and thus allows for little variation or modifiability of the same. In general, however, a manufacturer may desire to implement greater variability in this or other eyelets of the relevant panel. 
     For example,  FIG. 1D  shows a wider eyelet  123   b  that has been implemented in the lower portion of the panel  105   a . In particular,  FIG. 1D  shows that the wider eyelet  123   b  provides at least a greater ±Y variability for positioning the panel  105   a  with respect to the standoff  115  (and hence to the relevant vertical or horizontal frame member). This variability in the lower eyelets (e.g.,  123   b ) can help the resin-based panel  105   a  maintain appearances in spite of any natural degradation that might be associated with age. In particular, this type of ±Y variability in the lower portion can be helpful for resin-based panels made of materials that may be prone to some material redistribution. In one implementation, for example, these larger, oversized eyelets  123   b  are configured to account for expansion/contraction, while, in conjunction with standoff  113  (i.e., due to the ability to adjust the position of the standoff point support by sliding it up and down in the given vertical frame member) are duly configured to accommodate material creep. Accordingly, a manufacturer may find a wide variety of advantages by creating differently sized eyelets for different portions of each of the resin-based panels, as desired. That is, exact or differently sized eyelets  123   a - b  can provide flexibility to the assembler as well as durability in aesthetic appearance. 
       FIGS. 1A through 1D  therefore show how the frame  103  and corresponding parts can be configured so that thread receptors can be readily positioned and matched with corresponding eyelets of the primarily flat, translucent resin-based panels. By contrast,  FIG. 2A  illustrates another implementation of a resin wall, or resin wall  100   b  in accordance with the present invention where one or more resin-based panels  130   a ,  130   b , and  130   c  are configured to provide alternating, curved aesthetic effects. 
     For example,  FIG. 2A  shows a facing perspective view of resin wall  100   b , in which horizontally lain, vertically stacked panels  130   a - c  are formed with alternating and opposing curvatures. In particular, from left to right, panel  130   a  is convex (extending away from frame  103 ) between members  120   a  to  120   b , and concave (extending toward frame  103 ) between vertical members  120   b  and  120   c . By contrast, panel  130   b  is concave between vertical members  120   a  to  120   b , but convex between vertical members  120   b  to  120   c , and so forth. Panel  130   c , in turn has a similar convex/concave pattern as panel  130   a , or is another sequence of curvatures, as desired. 
       FIG. 2B  shows a back perspective view of the resin wall  100   b . As shown each standoff  115  is substantially the same length between a given frame member (e.g.,  120   a - e ) and the resin-based panel  130   a - c , and hence provides the same length of distance between the relevant resin-based material and the existing wall at the given attachment point (e.g.,  117  attached at an eyelet  123 ,  FIG. 2C ). One will appreciate, however, that the length of the given standoff  115  can be varied by a manufacturer to enhance this curved effect as desired, or to create other types of shapes using curvature. For example, in one implementation, the manufacturer implements progressively longer standoffs (not shown) from vertical member  120   a  through  120   e , thereby creating a waved effect that progressively extends toward the viewer. In sum, there are a wide variety of ways in which a manufacturer can create and/or enhance a curved aesthetic effect. 
     In any event, in order to create the curved effect in the first instance,  FIG. 2C  illustrates one way in which this can be accomplished. In particular,  FIG. 2C  shows each of the vertical members  120   a ,  120   b , and  120   c  of an eventual frame  103  are separated an equal distance of “x” from the next vertical member. By contrast, an exemplary panel  130  has a first position of eyelets  125   a  and a second set eyelets  125   b  that are separated a distance of “x+n” (i.e., where “n” is greater than 0). Panel  130  further has a third set eyelets  125   c , which are positioned a distance “x” from the second position of eyelets  125   b.    
     The first position of eyelets  125   a  are configured to receive a threaded member  119 , which fastens into a corresponding standoff bodies  113  that has been previously secured to vertical member  120   a . The second position of eyelets  125   b  are similarly configured to receive a threaded member  119  that will also be fastened into the standoff bodies  113 , albeit one positioned in vertical member  120   b . Similarly, the third position of eyelets  125   c  are configured to align with the standoff bodies  113  positioned in vertical member  120   c . Since there is a greater amount of distance (i.e., “x+n”) in the between the first position of eyelets  125   a  and the second position of eyelets  125   b  than the spacing between vertical members  120   a  and  120   b , the resin-based panel  2 C will bow outwardly or inwardly as desired, based on the flexibility or thickness of the chosen material. For example, in one implementation, the manufacturer uses a thicker, lower-modulus resin-based material that is subject to bending. In another implementation, the manufacturer uses a more rigid material that is made flexible due to its relative thickness (e.g., quarter inch or thinner). 
     By contrast, where the distance “x” between the second position of eyelets  125   b  and third position of eyelets  125   c  of caps  117  is equal to the spacing between vertical members  120   b  and  120   c , the resin-based panel  130  will simply be held in a flat conformation. This spacing, therefore, is merely exemplary, and contrasts with  FIGS. 2A and 2B , which show either concave or convex bowing between vertical members  120   a - e . Accordingly,  FIGS. 2A through 2C  show that a manufacturer can adjust the spacing or positioning of eyelets in a given polymeric resin-based panel to achieve a wide range of aesthetic effects, such as that provides each given panel with a desired shape or lay with respect to the frame  103 . 
       FIG. 3A  illustrates still another implementation of a resin wall, or resin wall  100   c , in accordance with the present invention, wherein one or more resin-based panels  140  are mounted to a frame assembly in a grid-like fashion. In contrast with the preceding Figures, however, none of the panels  140  include eyelets through which a threaded member  119  of a cap  117  is inserted to join with a standoff body  113 . Rather, as further shown in  FIG. 3B , resin wall  100   c  comprises two frames, such as frame  103  and secondary frame  160 , set apart by standoffs  115 . The resin-based panels  140  are then held in place by overlapping caps  117 , which overlap and secure the peripheral edges of each panel  140 . For example, in  FIG. 3B , secondary frame  160  is held at an extended position from frame  103  via standoffs  115 , while each of resin-based panels  140  are held in place by overlapping caps  117 . 
       FIG. 3C  illustrates an exploded perspective view of one implementation of the grid intersection illustrated in  FIG. 3B . In particular, a grid intersection of secondary frame  160  can be created using a mitered intersection connector  167 , which includes vertical arms for receiving vertical members  150   a  and  150   b , as well as perpendicular, horizontal arms for receiving horizontal members  155   a  and  155   b . Each of horizontal members  155   a - b  and vertical members  150   a - b  include a groove  163 , through which an assembler inserts brace  107 . The vertical members  150   a  and  150   b , and horizontal members  155   a - b  may be the same vertical members as any of  120   a - c  and/or the same as any of horizontal members  110   a - c  shown previously, or may be different vertical or horizontal members, or some other modified portions thereof. 
     In one method of assembly, an assembler mounts the various horizontal frame members  110  (e.g.,  110   a - c ) and vertical frame members  120  (e.g.,  120   a - d ) with any necessary support members  112  against an existing wall (not shown). The assembler then creates the secondary frame  160  by inserting each of the horizontal frame members  155   a - b  and vertical frame members  150   a - b  (or portions of members  110  and/or  120 ) into an intersection connector  167 . The assembler also secures a standoff body  113  to a position of a vertical frame member (e.g.,  120   b ), and inserts any appropriate braces  107  within grooves  163  of the vertical frame members  150   a - b  and horizontal frame members  155   a - b  of the secondary frame  160 . The intersection connector  167  is then secured to the standoff body  113 , and the assembler then aligns each panel  140  in the appropriate grid position. The assembler then secures each panel  140  by screwing any appropriate number of caps  117  into the braces  107  of the secondary frame  160 . When all panels  140  and frames  103  (or also  160 ) are assembled together, the resulting structure resembles the structure shown in  FIGS. 3A and 3B . 
       FIG. 4A  illustrates a top perspective view of another implementation of a resin wall system, wherein one or more resin-based panels are positioned between ridged frame members to create a curved effect. In particular, a resin-based panel  205   a  can be placed inside another form of a securing member, or elongate groove  210   a , which is mounted on one frame member  220   a , and inside another securing member, or elongate groove (not shown), of a next/adjacent frame member (not shown). For example,  FIG. 4A  shows that panel  205   b  is placed in the opposite elongate groove  210   b  of the frame member  220   a . If the frame members (e.g.,  220   a , and other frame members not shown) are placed sufficiently close together, the resin-based panel will bow in one of a concave or convex direction, as desired. Alternatively, the manufacturer or assembly might opt to straighten the panels by separating the relevant frame members  220 . 
       FIG. 4B  illustrates a dissembled view of resin-based panels and frame members of the resin wall system shown in  FIG. 4A . In particular,  FIG. 4B  shows that a frame member  220   a  comprises an elongate attachment  230 , which is inserted over a protruding neck portion  225 . The elongate attachment  230  comprises corresponding elongate grooves  210   a - b  (or securing members) formed on opposing sides. There are, of course, other ways of providing grooves into which a resin-based panel can be inserted, and ultimately made to curve. For example, the elongate groove  210   a - b  can be formed directly in the frame member itself, rather than in a separate attachment. Alternatively, the grooves  210   a - b  may be less elongate, and more sporadically spaced, or may be evident as a combination of multiple clips providing similar function. As such, one will appreciate that the apparatus and systems shown in  FIG. 4B  are merely exemplary. 
     Accordingly, the present invention provides a wide variety of systems and apparatus for mounting translucent resin walls to existing walls, and for adding a decorative, aesthetically pleasing appearance to existing walls. Furthermore, implementations of the present invention allow for existing walls to take on a pleasing appearance without significant hassle, at least in part since the frame systems can be easily modified to accommodate virtually any existing wall. Still further, implementations of the present invention provide for one or more frames that can be easily assembled with pre-cut, pre-drilled components that are configured for any number of conformations or designs, and that are configured to hold their designs in a pleasing manner even after some natural changes occur to the resin-based materials. Thus, implementations of the present invention provide a number of important advantages over conventional glass or resin wall systems. 
     The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Summary:
A translucent wall in accordance with the present invention is configured to provide aesthetic qualities to existing walls using resin-based panels. In one implementation, one or more resin-based panels are mounted to an existing wall using one or more easily assembled frames and one or more standoffs. The panels, frames, and standoffs are configured to mount the resin-based panels away from the wall by a specific distance, thereby allowing light to be transmitted through the resin-based panels. This light transmittance in turn provides a number of decorative advantages in terms of coloring, texturing, and in terms of exhibiting decorative objects embedded in the resin-based panels. The one or more frames used in accordance with the present invention can be easily adapted to any interior or exterior space or finish, such that the disclosed systems can benefit from mass-production techniques.