Abstract:
A switch actuator device is disclosed. The switch actuator device includes a switch housing, a body having a first and second arm, and a resilient member having a first and second end. The first and second ends of the resilient member are configured to be coupled to the body and switch housing, respectively. The resilient member exerts a first force on the body when the body is at a first position, a second force when the body is at a second position, and a third force when the body is at a threshold position. When the body is rotated about a pivot point from the first to second position, or vice versa, the respective first or second force increases in magnitude and acts on the body to first resist the rotation until the body is in the threshold position, and then assists the rotation.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation application of U.S. patent application Ser. No. 14/474,592 filed on Sep. 2, 2014, now U.S. Pat. No. 9,350,149, which is a continuation application of U.S. patent application Ser. No. 13/917,938 filed on Jun. 14, 2013, now U.S. Pat. No. 8,847,071, which is a continuation of U.S. patent application Ser. No. 12/787,336 filed on May 25, 2010, now U.S. Pat. No. 8,497,424, the disclosures of which are hereby incorporated by reference. 
    
    
     BACKGROUND 
     One embodiment of the invention relates to a universal box system which is configured to work with any type box, in particular FD boxes, which allows for the mounting of multiple different types of electrical devices to the FD box. The universal box system can include multiple different adapters which are configured to be connected to the universal box to allow different types of electrical devices to be connected to the universal box. 
     There are currently multiple types of electrical devices that can be coupled to a FD box, including strap mounted electrical devices, non strap mounted electrical devices, or water resistant devices. Currently there is no known box that is universally adaptable to receive strap based electrical devices, non strap based electrical devices or water resistant electrical devices. 
     In addition, with regard to FD boxes, particularly in the multiple gang type devices, previously, electrical devices would be ganged together with a double gang cover, triple gang cover or other type of multi ganged cover, which would have to be pre-fabricated to fit on a multi ganged box. This is because prior to the present invention, there was no known box and system which would allow for the individual mounting of single gang devices and covers across a multi ganged enclosure. Therefore, there is a need for a universal mounting face as described above, and/or a system which allows for the mounting of multiple single gang devices and individual single gang covers on a multi gang box. 
     SUMMARY 
     At least one embodiment of the invention relates to a universal electrical box such as a FD box, comprising a body having at least one opening for receiving an electrical device. In addition, there is at least one opening for receiving electrical wiring from building wiring. The device can also include at least one mounting bracket coupled to the body, and at least one plate configured to be coupled to the at least one body. In addition, there is at least one duplex electrical frame configured to couple to the at least one plate. The duplex electrical frame is configured to receive a duplex electrical device. In addition, there is at least one sealing gasket configured to be coupled to the body between the at least one frame and the body. This design allows for a universal configuration which allows for multiple different types of electrical devices to be coupled to the enclosure. 
     At least one additional embodiment relates to a system which is configured to allow multiple different single gang devices and associated front covers to be mounted on a multi ganged enclosure or box. One embodiment includes a multi ganged box which is dimensioned such that there are multiple different connection interfaces for receiving multiple different single gang electrical devices. In addition, this multi ganged system includes at least one frame which has sufficient spacing to both cover open sections of the box while still providing sufficient spacing between each connection interface to allow multiple different single gang electrical devices and enclosures to be coupled thereto without interfering with each other. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Other objects and features of the present invention will become apparent from the following detailed description considered in connection with the accompanying drawings. It should be understood, however, that the drawings are designed for the purpose of illustration only and not as a definition of the limits of the invention. 
       In the drawings, wherein similar reference characters denote similar elements throughout the several views: 
         FIG. 1A  is a perspective view of a first embodiment of a single gang box fully assembled; 
         FIG. 1B  is a perspective exploded view of the first embodiment; 
         FIG. 2A  is a perspective view of the unassembled first embodiment of a box; 
         FIG. 2B  is a side cross-sectional view of the universal box shown in  FIG. 2A ; 
         FIG. 2C  is a front view of the universal box shown in  FIGS. 1A, 1B, 2A and 2B ; 
         FIG. 2D  is a side cross sectional view taken down the middle of the universal box of  FIG. 2A ; 
         FIG. 2E  shows a front view showing the connection regions for connecting a duplex electrical device; 
         FIG. 3  is an exploded perspective view of a second embodiment; 
         FIG. 4A  is a front view of the second embodiment; 
         FIG. 4B  is a side cross-sectional view of the embodiment shown in  FIG. 4A ; 
         FIG. 4C  is a top view of a universal box of  FIG. 3 ; 
         FIG. 5A  is a perspective view of the universal box of  FIG. 3 ; 
         FIG. 5B  shows a front view of a double gang enclosure showing connection regions for a duplex electrical device; 
         FIG. 6A  is a front view of a frame for use with the universal box of  FIG. 3 ; 
         FIG. 6B  is a side cross-sectional view of the frame; 
         FIG. 6C  is a side view of the frame; 
         FIG. 6D  is a perspective view of the frame; 
         FIG. 6E  is a back view of the frame; 
         FIG. 6F  shows a side perspective view of a planar board isolator; 
         FIG. 6G  shows an end view of the planar board isolator; 
         FIG. 6H  shows a side view of the planar board isolator; 
         FIG. 6I  shows another end view of the planar board isolator taken from the right side in  FIG. 6F ; 
         FIG. 6J  is a front view of the isolator inserted into a box; 
         FIG. 6K  is a perspective view of the isolator inserted into a box; 
         FIG. 7A  is a front perspective view of the gasket shown in  FIG. 3 ; 
         FIG. 7B  is a front view of the gasket; 
         FIG. 7C  is a back view of the gasket; 
         FIG. 8A  is a perspective view of a triple gang universal box; 
         FIG. 8B  is a front view of the universal box shown in  FIG. 8A ; 
         FIG. 8C  is a top cross-sectional view of the universal box shown in  FIG. 8B ; 
         FIG. 8D  is a top view of the universal box shown in  FIGS. 8A, 8B ; 
         FIG. 8E  shows a top or bottom cross-sectional view of the triple gang box shown in  FIG. 8A ; 
         FIG. 8F  shows a front view of a triple gang box showing connection regions; 
         FIG. 9A  is a perspective view of a triple gang gasket; and 
         FIG. 9B  is a front view of a triple gang gasket. 
         FIG. 10A  is a perspective view of a frame for use with a triple gang box; 
         FIG. 10B  is a front view of the frame shown in  FIG. 10A ; 
         FIG. 10C  is a back view of the frame shown in  FIG. 10A ; 
         FIG. 10D  is a side view of the frame shown in  FIG. 10A ; 
         FIG. 11A  is a front perspective view of the assembled design of a single gang enclosure; 
         FIG. 11B  is a front perspective view of the assembled design of the double gang enclosure; 
         FIG. 11C  is a front-top perspective view of the assembled triple gang enclosure; 
         FIG. 12A  is a top view of a switch mechanism; 
         FIG. 12B  is a side cross-sectional view of the switch mechanism; 
         FIG. 12C  is a bottom view of the switch mechanism; 
         FIG. 12D  is a perspective view of the switch mechanism; 
         FIG. 12E  is a side view of the switch mechanism; 
         FIG. 12F  is a view of the spring associated with the switch mechanism; 
         FIG. 12G  is a close up view of the switch mechanism taken from  FIG. 12A ; 
         FIG. 13  is a bottom view of the switch mechanism coupled to a spring; 
         FIG. 14A  is a top perspective view of a toggle switch shown in  FIG. 11B , showing the toggle switch in a first position; 
         FIG. 14B  is a top perspective view of the toggle switch shown in  FIG. 13A  in a second position; and 
         FIG. 14C  is a top perspective view of the toggle switch shown in  FIG. 13A  in a third position. 
     
    
    
     DETAILED DESCRIPTION 
     Referring in detail to the drawings,  FIG. 1A-B  is a front perspective view of a first embodiment  5 , which includes a universal electrical box  10 , which can be in the form of a FD box, wherein this box comprises a body  12 , and a back mounting bracket  14 . Box  10  can be made from any known suitable material such as metal, ceramic, composite, polymer, or plastic. In at least one embodiment, the box  10  is made from PVC or polyvinyl chloride. Body  12  is substantially rectangular, and in this embodiment, is a single gang enclosure having five sides and an open front. This box  10  is in the form of a universal box which is configured to be coupled to an outdoor portion of a building such as an office building or a house. 
     Body  12  has a mounting or connection interface  11  formed in a front opening. Body  12  is configured to receive multiple different types of single-gang sized electrical devices such as receptacles, light switches, indicator lights or any other type of suitable single gang device in this mounting or connection interface  11 . For purposes of this application, the term single gang refers to a dimension sufficient to receive a single electrical device such as a standard duplex electrical receptacle. The dimensions of the terms “single gang”, “double gang”, and “triple gang” are generally known in the industry and indicated by NEMA. Therefore, for purposes of this application a double gang dimension is a dimension sufficient to receive at least two electrical devices such as two duplex electrical receptacles in a side by side manner. The term triple gang refers to a dimension sufficient to receive at least three electrical devices such as three duplex electrical receptacles in a side by side manner. 
     Back mounting bracket  14  comprises a first end  14   a , and a second end  14   b . These ends each including holes wherein the first end  14   a  includes holes  15   a  and  15   b  while the second end  14   b  comprises holes  15   c  and  15   d  (See  FIG. 2A ). 
     Body  12  also includes a front rim  16  which expands from the body  12  to accommodate additional adapters such as a front plate, or any other type of appropriate adapter. Front rim  16  also includes an additional guide rim  16   a  (See  FIG. 1B ) which extends out from a front face of front rim  16 . 
     In addition, body  12  includes five walls, including a first side wall  17   a , and a second side wall  17   b  extending perpendicular or substantially perpendicular to the first side wall  17   a . A third side wall  17   c  (See  FIG. 2C ) is perpendicular or substantially perpendicular to the second side wall  17   b  and extends substantially parallel to the first side wall  17   a . A fourth side wall  17   d  is perpendicular or substantially perpendicular to the first side wall  17   a  and the third side wall  17   c  and extends substantially parallel to the second side wall  17   b . In addition, a fifth back wall  17   e  (See  FIG. 2B ) extends substantially perpendicular to the side walls  17   a - d . These walls  17   a - 17   e  are connected together to form an open-faced box, however, other style configurations can be used such as a square box, a rounded box, a circle, hexagon, octagon, pentagon, or any other round shaped device or polygonal shaped device. 
       FIG. 1B  shows a front perspective exploded view of the embodiment shown in  FIG. 1A  wherein in this view, there is a front plate  20 , having a tongue  22  which extends substantially perpendicular to the body of the front plate. This plate  20  includes a plurality of openings  24   a ,  24   b ,  24   c , and  24   d . The plate  20  can be made from any suitable material but in at least one embodiment, it is a metal plate made from a metal such as stainless steel. Body  12  includes a plurality of connection elements which can be comprised of any known connection elements but in this case comprise cylindrically shaped posts  18   a ,  18   b ,  18   c  and  18   d ,  18   e ,  18   f ,  18   g , and  18   h . Posts  18   a  and  18   b  are disposed in a first corner, posts  18   c  and  18   d  are disposed in a second corner, posts  18   e  and  18   f  are disposed in a third corner, and posts  18   g  and  18   h  are disposed in a fourth corner. The first axis  12   i  extends lengthwise across the box  10 . Posts  18   a  and  18   d  are at substantially the same position lengthwise along a first dimension or length (l), posts  18   b  and  18   c  are at substantially the same position lengthwise along this first dimension, posts  18   e  and  18   h  are at substantially the same position lengthwise along the first dimension or length ( 12   i ) while posts  18   f  and  18   g  are at substantially the same position lengthwise along this dimension (l) along axis  12   i . This dimension l is the first dimension, and with a single gang enclosure is the longer dimension or expansion of the box. It also corresponds to the dimension that is parallel to the extension of wiring holes  19   a  and  19   b  (See  FIG. 2A ). 
     The second axis  12   ii  extends widthwise across the box  10 . In addition, posts  18   a  and  18   e  are at substantially the same position width wise along the width dimension along axis  12   ii , posts  18   b  and  18   f  are at substantially the same position width wise along the dimension (w), while posts  18   c  and  18   g  are at substantially the same dimension width wise  12   ii , while posts  18   d  and  18   h  are at substantially the same dimension width wise (w). This post configuration allows for multiple different types of electrical devices, as well as plates to be coupled to the universal box. For example, in this view of  FIG. 1B , the plate  20  has a plurality of eye holes  26   a ,  26   b ,  26   c , and  26   d  wherein these eye holes are configured to line up with or be substantially concentric with corresponding posts  18   b ,  18   c ,  18   f , and  18   g.    
     There are a set of connection elements such as inner posts, and connection elements such as outer posts, wherein the inner posts are posts  18   b ,  18   c ,  18   f  and  18   g , while the outer posts are posts  18   a ,  18   d ,  18   e , and  18   h . Inner posts are configured to selectively receive a strap based electrical mounting device while the outer posts are configured to receive a non-strap based electrical device or a front cover such as that shown in  FIGS. 11A-13C . The outer posts are configured in the box based upon an industry standard spacing. 
     In addition, there are rounded corner openings in the plate  20  including openings  24   a ,  24   b ,  24   c , and  24   d , which are configured to be substantially concentric with outer posts  18   a ,  18   d ,  18   e , and  18   h , respectively. This design allows for additional components such as front covers to be connected to the plate  20  while also being connected directly to the body  12  of the universal box  10 . Tongue  22  serves as a guide which guides plate  20  inside box  10 . Furthermore, the inner connection elements formed as posts  18   b ,  18   c ,  18   f  and  18   g  are formed as recessed posts which are formed recessed relative to the outer posts  18   a ,  18   d ,  18   e  and  18   h  thereby allowing plate  20  to be inserted therein and forming a single flush mounting face for all of the posts. 
     The first and second wiring holes  19   a  and  19   b  are configured to receive building wire, which provides electrical power to the universal box  10 . The first wiring hole  19   a  is configured to be adjacent to back mounting bracket  14 , including first end  14   a  and second end  14   b . Therefore, there is a first cut out  19   c  in first end  14   a  of back mounting bracket  14 , and a second cut out  19   d  in the second end  14   b  of back mounting bracket  14 . This allows a pipe fitting to be fit inside of wiring holes  19   a  and  19   b.    
       FIG. 2A  is a perspective view of the universal box  10 . In this view, a second wiring hole  19   b  is shown which is substantially concentric with first wiring hole  19   a . First and second wiring holes  19   a ,  19   b  allow building wiring to pass into the box. This view shows recesses or cut outs  23   a ,  23   b ,  23   c , and  23   d  formed in the connection elements such as posts  18   b ,  18   c ,  18   f , and  18   g , which provide additional connection space for a device to be inserted into that region. Cut outs or recesses  23   a  and  23   c  are also shown in  FIG. 2D  as well. 
       FIG. 2B  is a side cross-sectional view of the universal box  10 , wherein in this view, posts  18   a ,  18   b ,  18   e  and  18   f  are shown extending frusto-conically into box  10  to show posts that are tapered in size. These posts  18   a ,  18   b ,  18   e ,  18   f  are shown extending substantially parallel to each other inside of body  12 . 
       FIG. 2C  is a front view of the universal box  10  which shows posts  18   a ,  18   b ,  18   c ,  18   d ,  18   e ,  18   f ,  18   g  and  18   h  extending as described above. Each of these posts has a corresponding connector  21   a ,  21   b ,  21   c ,  21   d ,  21   e ,  21   f ,  21   g , and  21   h  for respective coupling the post to an adjacent side wall. 
     As shown in this view, body  12  comprises a first pair of substantially parallel spaced side walls, including first side wall  17   a , and third side wall  17   c  extending substantially parallel to a first axis  12   i ; and a second pair of substantially parallel spaced side walls, including second side wall  17   b  and fourth side wall  17   d  extending substantially parallel to a second axis  12   ii . Body  12  further comprises a plurality of posts  18   a - 18   h  as described above, comprising a first set of posts comprising posts  18   a ,  18   d ,  18   e  and  18   h  coupled to the first pair of substantially parallel spaced first and third sidewalls  17   a ,  17   c , and a second set of posts comprising posts  18   b ,  18   c ,  18   f , and  18   g  being coupled to the first set of posts  18   a ,  18   d ,  18   e ,  18   h  respectively, and being spaced apart from the first set of substantially parallel spaced first and third side walls  17   a ,  17   c . These different sets of posts provide for multiple different connection surfaces to allow for multiple different types of plates as well as different types of electrical devices and covers to be coupled to the universal box. 
       FIG. 2D  is a side cross sectional view taken down the middle of box  10 , wherein this view shows first and second wiring holes  19   a  and  19   b  extending concentrically into box  10 . This view also shows recesses  23   a  and  23   c  formed in box  10 . 
       FIG. 2E  shows a front view of the single gang box  10 , which shows a standard width dimension  29   w  and a standard length dimension  291 . In addition, because of recesses  23   a - d  ( FIG. 2A ), there are formed two separate connection or mounting regions  29   a  and  29   b  which are configured to receive a duplex wiring device which can have in at least one instance a circular or rounded dimension. These recesses  23   a - d  allow for additional devices, such as duplex electrical receptacles, to be installed therein. As shown, these recesses  23   a - d  are formed as angled, flat shaped cut-outs formed in rounded posts. These recesses  23   a - d  allow for curved or rounded receptacle elements to slide therein. 
       FIG. 3  is an exploded perspective view of a second embodiment which shows a double gang universal box  30 , which essentially comprises two sets of boxes  10  (See  FIG. 2A ) without intervening walls. Box  30  comprises an expansive front rim  36 , and first side wall  37   a , second side wall  37   b , third side wall  37   c , fourth side wall  37   d  and a fifth back wall  37   e  wherein these walls are coupled together to form an open box. Front rim  36  further comprises a front edge rim  36   a  which is configured to index with plates, covers, gaskets, and frames which can be coupled to this front rim. Front rim  36  extends around a front opening forming a connection interface  31  ( FIG. 4A ). Essentially the connection interface  31  is formed by the opening in the box and the surrounding connection elements. 
     The term index or indexing essentially relates to aligning components together in a complementary manner such that they fit in their desired manner. Grooves, protrusions, keys, male-female connections can be used to index two components together. 
     Double gang universal box  30  comprises a plurality of different connection elements such as posts  38   a ,  38   b ,  38   c ,  38   d ,  38   e ,  38   f ,  38   g ,  38   h ,  38   i ,  38   j ,  38   k ,  38   l ,  38   m ,  38   n ,  38   o ,  38   p . A first group of posts  38   a - 38   h  correspond in dimension and spacing to posts  18   a - 18   h , while a second group of posts  38   i - 38   p  correspond in dimension and spacing to posts  18   a - 18   h  as well. Therefore, these two groups of connection posts  38   a - h ,  38   i - p  form a connection interface having two different types of connections in a double gang enclosure. 
     Posts  38   b ,  38   c ,  38   f , and  38   g  correspond to inner posts, along with posts  38   j ,  38   k ,  38   n , and  38   o  also forming inner posts. Consequently, posts  38   a ,  38   d ,  38   e , and  38   h , along with posts  38   i ,  38   l ,  38   m , and  38   p  form outer posts. Therefore, these posts provide a universal or nearly universally adaptable face for receiving fasteners for coupling to brackets, plates, gaskets, or for coupling directly with different electrical devices with the inner posts being configured to receive strap based electrical devices while the outer posts are configured to receive front covers shown in  FIGS. 11A-13C . In addition, posts  38   d  and  38   h  are spaced apart from posts  38   i  and  38   m  such that a sufficient distance is created to allow two different individual single gang electrical devices to be mounted to the box with corresponding different single gang covers being mounted over these electrical boxes as well. This distance can be for example at least two inches. 
     Box  30  is configured as a double gang box which is configured to be mounted on an exterior portion of a wall and designed to receive two different single gang electrical devices or a single integrated double gang electrical device. 
     This view also shows a back mounting bracket including first end  34   a  and second end  34   b  as well as holes  35   a ,  35   b ,  35   c ,  35   d ,  35   e , and  35   f  for mounting the universal box to another surface. In addition, there are different wiring holes  39   a ,  39   b ,  39   c , and  39   d  wherein wiring holes  39   a  and  39   c  are concentric with each other and wiring holes  39   b  and  39   d  are concentric with each other. 
     Furthermore, there is also shown a gasket  50  which can be comprised of any suitable type of sealing element such as plastic, metal or rubber, wherein, in at least one embodiment there is a thermoplastic rubber. In at least one embodiment, the gasket  50  is at least partially made of rubber such that it is configured to seal the interior of the box from any exterior elements when a bracket such as an adapter or frame  60  is coupled to the box. Gasket  50  is discussed in greater detail in  FIGS. 7A-7C . 
     Frame  60  comprises first and second openings  61   a  and  61   b , (See  FIG. 6 a   ) as well as a central face  62 . In addition, a support extension  64  is coupled to central face  62  and extends therein away from central face  62 . Frame  60  is discussed in greater detail in  FIGS. 6A-6E . Central face  62  is spaced a sufficient distance to allow two different single gang electrical devices to be mounted to the two individual connection interfaces with two different single gang adapter covers being mounted over these electrical devices. In at least one embodiment the width of central face  62  could be 1 inch, approximately 1 inch or at least one inch, in at least one additional embodiment the width of central face  62  could be 1.25 inches, while in at least one further embodiment the width of central face  62  could be at least 1.5 inches. 
     In addition, a plurality of plates  20  having grounding wiring  20   a  can be set inside of the first and second openings  61   a ,  61   b  of the frame  60  to create a universally adaptable face for mounting electrical devices. 
       FIG. 4A  is a front view of the second embodiment of the box  30  which also shows a connection interface  31  having a plurality of connection elements formed by sliding posts. These connection elements comprise a plurality of sliding posts  33   a ,  33   b ,  33   c  and  33   d , wherein sliding posts  33   a  and  33   b  form a first set of parallel spaced sliding posts, while sliding posts  33   c  and  33   d  form a second set of sliding posts. These posts are configured to support a frame  60  when it is inserted into the box. 
       FIG. 4B  is a side, cross-sectional view of the embodiment shown in  FIG. 4A  taken along the Axis  30   i . Since the box is symmetrical, this view can either be a top cross-sectional view looking down at the bottom half of the box or a bottom cross sectional view looking up at the top of the box. In this view, there is shown wiring holes  39   c  and  39   d  which are concentric with wiring holes  39   a  and  39   b  shown in  FIG. 3 . 
     As shown, there are recesses  43   a ,  43   b ,  43   e , and  43   f  shown based upon a bottom view looking up at the device. In addition, there is also shown a top down view, wherein recesses  43   g ,  43   h ,  43   c  and  43   d  are shown. 
       FIG. 4C  shows a top view which shows posts such as posts  38   a ,  38   b ,  38   c ,  38   d ,  38   i ,  38   j ,  38   k  and  38   l  extending outside of the box. This additional extension allows for the sealing gasket and the frame to be placed on the box and still provide a post that can be used to allow an electrical device such as a strap mounted electrical device or a non strap mounted electrical device to be coupled to the box  30 . 
       FIG. 5A  is a perspective view of the embodiment shown in  FIG. 4A  which shows posts  38   a - 38   p  with their respective configurations as shown in  FIG. 4A . In addition this view also shows wiring holes  39   c  and  39   d . This view also shows a connection interface  31  for at least two different ganged electrical devices. In this connection interface are recesses  43   a ,  43   b ,  43   e  and  43   f  shown in greater detail in  FIG. 4B . 
     Essentially, a connection interface  31  is formed on the front end of the box and can comprise any one of posts or other types of connection elements such as first group of posts  38   a - 38   h , forming a first connection interface along with the respective side walls formed by rims  36  and  36   a . If a frame  60  is added or a plate  20  is added these connection elements can also be used to form the connection interface. 
       FIG. 5B  shows a front view of the double gang box showing connection or mounting regions  45   a ,  45   b ,  45   c , and  45   d , which represent substantially rounded openings such as circular shaped or oval shaped openings, formed in the connection interface  31  and which are configured to receive circular shaped electrical devices such as a duplex receptacle. With this design, because the box  30  is a double gang box, the box  30  is configured to receive two different electrical devices such as two different single gang duplex receptacles installed side by side in the box (See for example  FIG. 11B ). 
       FIG. 6A  is a front view of a frame  60  for use with the universal box of  FIG. 3 . Frame  60  includes first and second openings  61   a  and  61   b , as discussed above. First opening  61   a  includes outer rim  62   a , tabs  63   a  and  63   b , inner rim  65   a  as well as cut outs  65   b ,  65   c ,  65   d  and  65   e . In addition, second opening  61   b  includes outer rim  62   b  and also includes tabs  67   a  and  67   b  as well as an inner rim  66   a  as well as cut outs  66   b ,  66   c ,  66   d ,  66   e . Central face  62  is configured to divide these first and second openings  61   a  and  61   b , and as disclosed above is configured to space two different single gang devices and their respective covers apart. 
     In addition, support extension  64  (See  FIG. 6B-6F ) is coupled to central face  62  and extends therein away from central face  62 . Support extension  64  is configured to line up with sliding posts  33   a ,  33   b ,  33   c , and  33   d  (See  FIG. 4A ) such that support extension  64  slides on top of these sliding posts to be supported on these sliding posts to be easily supported on an associated box.  FIG. 6C  shows the side view of this bracket which shows a semi-circular cut out  64   a  of this support extension  64 . Cut-outs  64   a  is formed to allow a user to extend his or her hand through from one area to another inside of box  30 . 
     In addition  FIGS. 6F-6I  show different views for an isolator  70 , which can comprise a planar board. This isolator  70  then completely divides two different ganged enclosures so that low voltage wiring can be fed into each now separate box without any interference from the wiring of the other box. This isolator  70  can be configured from any suitable material such as plastic, PVC, or any other type material. 
     Isolator  70  comprises a central section  71 , first and second ends  73  and  75  wherein first end  73  comprises a central rounded hub  73   a , and two wings  73   b  and  73   c . In addition, second end  75  comprises a central rounded hub  75   a  and two wings  75   b  and  75   c . When isolator  70  is inserted into the slot formed by sliding posts  33   a ,  33   b ,  33   c , or  33   e , or sliding posts  83   a ,  83   b ,  83   e  and  83   f  ( FIG. 6J ) or into a region formed by sliding posts  83   c ,  83   d ,  83   g  and  83   h , isolator  70  would then divide the box into different compartments. With this design, first and second ends  73  and  75  would slide into this region. In addition, region  71   a  formed from section  71  would then extend out from this region. A frame  60  or  100  could then slide in over this region  71   b , thereby sealing off with this region inserting into semi-circular cut out  64   a  of support extension  64 . 
     For example,  FIG. 6G  shows how wings  75   b  and  75   c  would slide into a region formed by sliding posts  83   a  and  83   b . Wings  75   b  and  75   c  would extend over sliding posts  83   a  and  83   b  so that these posts would lock this isolator  70  into place. 
       FIG. 6J  is a front view of triple gang box  80  with multiple isolators  70  inserted into the triple gang box  80 . In this view there are sliding posts  83   a ,  83   b    83   e , and  83   f  surrounding ends  75  and  73  respectively of isolator  70 . In addition, there are sliding posts  83   c ,  83   d , surrounding end  75 , and sliding posts  83   g  and  83   h  surrounding end  73  thereby securing isolator  70  within box  80 . 
       FIG. 6K  shows a perspective view of box  80  which shows multiple isolators  70  inserted therein. This view shows how end  71   a  of isolator  70  extends out towards the front side of box  80 . This end  71   a  allows support extension such as support extension  64  or  104   a  or  104   b  to fit over this end  71   a . Thus, this isolator  70  is configured to isolate each gang of a box, while still allowing a frame such as frame  60  or frame  100  to fit onto a front end of the box. Another benefit of the isolator  70  in combination with a triple gang box  80  is that a triple gang box  80  when divided up by isolator  70  creates three separate single gang boxes which have a larger interior volume for fitting additional wires or components therein. For example, the volume of an individual box such as box  10  could be approximately 26 cubic inches while the volume for a divided single gang compartment of a triple gang box  80  or a double gang box  30  would be approximately 31 cubic inches. The larger volume would therefore allow for more wires to fit inside of the box. This benefit along with the benefit of fitting low voltage wiring inside of each divided compartment provides additional benefit for isolating each single gang compartment of a multiple gang box. 
       FIG. 7A  is a perspective view of the gasket  50  which includes a corresponding gap or post  52   a ,  52   b  configured to receive support extension  64 . Gasket  50  includes an outer rim  51 , and an inner lip or rim  53 . Posts  52   a  and  52   b  are cut out from inner lip or rim  53 . In addition, there are a plurality of cut outs  55   a ,  55   b ,  55   c ,  55   d ,  55   e ,  55   f ,  55   g  and  55   h  which are configured to line up with respective posts  38   b ,  38   c ,  38   j ,  38   k ,  38   f ,  38   g ,  38   n  and  38   o .  FIG. 7B  shows a front view of this gasket  50  and  FIG. 7C  shows a back view of gasket  50 . 
     Gasket  50  also includes at least one, but in this embodiment two grooves, one groove  58   a  on a first or front side and another groove  58   b  on a back or opposite side. Gasket  50  is configured to index with rim  36   a  on box  30 , and rim  62   b  on the back end of frame  60 . 
       FIG. 8A  is a perspective view of a triple gang universal box  80  with  FIG. 8B  being the front view.  FIG. 8C  shows a cross-sectional view taken along the line  80   i  while  FIG. 8D  shows a top or bottom view with both views being identical or substantially identical. This box  80  includes first side wall  87   a , second side wall  87   b , third side wall  87   c  and fourth side wall  87   d , wherein first and third side walls  87   a  and  87   c  are parallel or substantially parallel to each other; while second and fourth side walls  87   b  and  87   d  are parallel or substantially parallel to each other, and substantially perpendicular to first and third side walls  87   a  and  87   c . Box  80  also includes a rim  86  which forms a wider opening area, and wherein there is a front edge rim  86   a  which extends out from rim  86 . Front edge rim  86   a  is configured to index with an associated groove on a gasket such as gasket  90  shown in  FIGS. 9A and 9B . 
     Rim  86  surrounds an opening in box  80  which provides a connection interface  79 . Connection interface  79  comprises this opening along with the different connection elements such as connection elements or posts  88   a - 88   x  spaced around this opening. 
     There is also first and second mounting brackets  84   a  and  84   b  extending out from the box wherein first mounting bracket  84   a  has screw holes  85   a ,  85   b ,  85   c  and  85   d . Second mounting bracket  84   b  has screw holes  85   e ,  85   f ,  85   g , and  85   h  wherein these screw holes are configured to allow screws or other mounting elements to mount the box on a wall. 
     In addition, there are sliding posts  83   a ,  83   b ,  83   c ,  83   d ,  83   e ,  83   f ,  83   g , and  83   h . These sliding posts create a slot for allowing an isolator to be inserted therein. 
     Furthermore, the box  80  includes at least one but even up to three different connection interfaces each comprising a plurality of different connection elements comprising a plurality of different posts  88   a - 88   x , with the first group of posts  88   a - 88   h  forming a first group for a single gang electrical enclosure, a second group of posts  88   i - 88   p  forming a second group of posts configured in a substantially identical respective manner to the posts  88   a - 88   h , and posts  88   q - 88   x  forming the third respective substantially identical group. In addition, wiring holes  89   a ,  89   b ,  89   c ,  89   d ,  89   e  and  89   f  are set into the box, wherein wiring holes  89   a  and  89   d  are concentric with each other, wiring holes  89   b  and  89   e  are concentric with each other, and wiring holes  89   c  and  89   f  are concentric with each other. 
       FIG. 8E  is a cross-sectional view of box  80  taken along line A-A and this view shows that it can be either a bottom cross sectional view looking up to a top or first side, relative to  FIGS. 8A and 8B , or an opposite top down view looking at the bottom side. In this view, from the bottom up view, there are recesses  81   a ,  81   b ,  81   e ,  81   f ,  81   i , and  81   j  formed respectively in posts  88   b ,  88   c ,  88   j ,  88   k ,  88   r , and  88   s . From the opposite, top down view looking at the bottom, there are shown recesses  81   k ,  811 ,  81   g ,  81   h ,  81   c  and  81   d , formed respectively in posts  88   w ,  88   v ,  88   o ,  88   n ,  88   u , and  88   f  (see  FIG. 8C ).  FIG. 8F  shows the result of these recesses, which result in substantially enlarged, and substantially round or even circular connection regions such as regions  82   a ,  82   b ,  82   c ,  82   d ,  82   e , and  82   f  formed in this box. This design would allow for the installation of a plurality of different front covers to be mounted side by side inside of this box. For example, standard duplex electrical receptacles such as those shown with covers  120   a  and  120   b  in  FIGS. 11A-11C  can then be installed into this box. 
       FIG. 9A  is a perspective view of a triple gang gasket  90 , and  FIG. 9B  is a front view of the gasket  90 . Gasket  90  includes a plurality of gaps  92   a  and  92   b ,  92   c  and  92   d  configured to receive a support extension from an associated frame. Gasket  90  includes an outer rim  91 , and an inner lip or rim  93 . In addition, there are a plurality of cut outs  95   a ,  95   b ,  95   c ,  95   d    95   e ,  95   f ,  95   g ,  95   h ,  95   i ,  95   j ,  95   k , and  95   l  which are configured to line up with respective posts  88   b ,  88   c ,  88   j ,  88   k ,  88   r ,  88   s ,  88   f ,  88   g ,  88   h ,  88   o ,  88   v , and  88   w . Furthermore, a groove  98  is configured to align with front edge rim  86   a  on box  80  (See  FIG. 8D ). In addition, a groove (not shown) is on an opposite face and is configured to align with an extending rim  107   b  on a back side of frame  100 . 
       FIG. 10A  is a front perspective view of a triple gang frame  100  which has a body section  100   a  and includes two support extensions  104   a  and  104   b  as well as two spacing faces  102   a  and  102   b . These two spacing faces provide sufficient spacing such as spacings  102   i  and  102   ii  to allow multiple individual single gang electrical devices, as well as their individual single gang front covers to be mounted to the box over their respective devices. For example, as described above, this spacing of this front face could be at least 1 inch, or at least 1.25 inches or at least 1.5 inches. 
     In addition, there are three openings  101   a ,  101   b , and  101   c  bounded by outer rims  103   a ,  103   b , and  103   c , as well as inner rims  105   a ,  105   b , and  105   c . This design also includes tabs  106   a ,  106   b ,  106   c ,  106   d ,  106   e  and  106   f  disposed in their respective openings. Each of the two support extensions  104   a , and  104   b  includes a semi-circular cut out  109   a ,  109   b  which allows for additional room inside of an associated universal box  80 . There are also cut outs in inner rims  105   a ,  105   b , and  105   c  wherein these cut outs allow for access to associated inner posts. For example, there are cut outs  108   a ,  108   b ,  108   c , and  108   d  which allow access to posts  88   b ,  88   c ,  88   f , and  88   g , while cut outs  108   e ,  108   f ,  108   g ,  108   h  allow access to posts  88   j ,  88   k ,  88   n ,  88   o , while cut outs  108   i ,  108   j ,  108   k , and  108   l  allow access to posts  88   r ,  88   s ,  88   v , and  88   w  thereby allowing an additional front plate to be mounted thereon. These cut outs  108   a - 108   l  are configured to receive or are configured to be allowed to receive screws or other types of fasteners configured to fasten an electrical device and also correspondingly the frame to a triple gang box. 
     This embodiment also includes extending rims  107   a  which extend out from a front side, while an extending rim  107   b  extends out from a back side. These extending rims allow the device to be indexed with other elements such as gasket  90  wherein extending rim  107   b  would fit inside of a complementary groove  97  (not shown) on gasket  90 . 
     This triple gang box  80  is configured to be able to receive front plates that can be in the form of a single triple gang front plate  20  so that strap based devices can be mounted, non strap based devices can also be mounted or front covers can also be mounted to any one or all of the connection interfaces. 
       FIG. 10C  is a back view of the frame  100  shown in  FIG. 10A , in this view there is shown support extensions  104   a  and  104   b  wherein these support extensions include semi-circular cut outs  109   a  and  109   b  shown in greater detail in  FIG. 10D , wherein these cut outs are configured to allow a user to move his fingers inside of the triple gang box. 
     These designs with the body or housing such as boxes  10 ,  30 , and  80  in the form of respective single gang, double gang or triple gang enclosures provide for a universally adaptable box which is configured to receive multiple different style electrical devices therein. In addition because frames are also available, along with corresponding gaskets, this allows for a universally adaptable interface for universal boxes which thereby allows a person using this box to have a wide variety of means for connecting these devices. 
       FIG. 11A  shows a front perspective view of the completed box which includes the body  12 , a front rim  16 , along with sealing adapter covers  120   a  and  120   b  disposed on a two part frame comprising frames  119   a  and  119   b . As stated above, because of a plate, a strap mounted electrical device can be mounted to an electrical box, with an additional unincorporated single gang cover being mounted independently and separately over the strap mounted device. Once the two components are mounted on the single gang box, they can remain coupled to the box simultaneously due to the universal mounting face. 
       FIG. 11B  is a perspective view of a double gang box which includes a box  30 , along with adapter covers  120   a , and  120   b . In addition, there is a toggle switch  130  which includes a handle  131 . Covers  120   a ,  120   b , and toggle switch  130  are all coupled to box  30  with gasket  50 , and frame  60  being positioned in between. As described above, gasket  50  provides a water resistant seal, while frame  60  provides individually mountable sections for two different single gang electrical devices, which can be mounted via a strap style mounting by using an additional plate such as plate  20 . As described above, with this design, frame  60  includes a central face  62  which provides a sufficient spacing distance to allow for a hinge overhang such as via hinge  121   a , wherein this hinge overhang would not interfere with a separately mounted single gang device such as a toggle switch  130 . 
       FIG. 11C  is a front-top perspective view of the triple gang enclosure, wherein in this view there is a triple gang box  80  which has a front cover  140  which includes a cover section  140   a  along with a hinge  141 . This cover  140  is configured to cover and seal this section of the triple gang box. In addition, there are shown adapter covers  120   a  and  120   b  along with hinges  121   a  and  121   b.    
     This view also shows box  80  which is a triple gang box, and which has associated with it gasket  90  and frame  100 . As described above, gasket  90  along with frame  100  creates a water resistant seal with box  80 , wherein frame  100  allows three different individual single gang devices to be mounted to the box  80 . In addition, in each of the single gang openings formed by frame  100 , plate  20  can be used to allow strap based electrical devices to be mounted on the front face. However, because this box design  80  includes both inner and outer sets of posts for each of the single gang enclosures, additional front covers such as adapter covers  120   a  and  120   b , toggle switch  130  and cover  140 . 
     As described above, because frame  100  includes spacing faces  102   a  and  102   b  (See  FIG. 10B ), these spacing faces provide sufficient spacing so that three individually mounted single gang devices with their individually mounted single gang covers can be mounted side by side on a multi ganged box such as on triple gang box  80 . Thus, there is no need to form a single integrated multi-ganged cover for covering all three devices because the spacing provided by spacing faces  102   a  and  102   b  allows for the individual mounting of the electrical devices and their associated individual covers. 
     Furthermore, there are shown both reducers  150  configured to be received inside of holes such as wiring holes  19   a , and  19   b  (See  FIG. 1A ). In addition, caps  160  are shown for plugging these wiring holes. Multiple different sized reducers or caps can be used to either reduce the diameter for receiving a feed pipe or for plugging a hole. 
     All of these elements including any one of box  10 , box  30  or box  80 , gasket  50 , frame  60 , gasket  90  and frame  100  can each be sold as a kit along with other optional parts such as caps  160  and reducers  150  which fit inside of holes such as wiring holes  19   a  and  19   b.    
     As stated above, these type boxes with both the inner and outer sets of mounting posts, allow both strap mounted devices and non strap mounted devices to be simultaneously or separately mounted on a box such as a FD box, with the FD cover or front cover being mounted on top. With the designs of  FIGS. 11A-11C , a strap based electrical device such as a switch is mounted first on the FD box, and then the front cover  136  (see  FIG. 14A ) is mounted on the box such as box  10 . The front cover  136  covers the switch and keeps it from becoming impinged or corroded by elements. In addition, because covers such as cover  136  can be mounted on the box over a strap mounted device, additional devices such as toggle switch  130  can be placed over the switch to create a switch having a threshold tripping mechanism which biases the switch in either an “on” position or an “off” position wherein these positions relate to whether power is passed to a downstream load associated with the switch. 
       FIG. 12A  is a top view of a switch mechanism or actuator  170  which includes a body section  170   a , and arms  171  and  172  forming a fork.  FIG. 12B  is a side cross-sectional view of the switch mechanism  170  which includes body section  170   a , a post section  173 , and a central hole  174  extending into post section  173 . Central hole  174  is for receiving a screw or bolt for securing this switch mechanism to an adjacent housing. There are also holes or relief  176  and  177  with hole  176  configured radially out from a center region while hole  177  is configured to be in a central region of body section  170   a.    
       FIG. 12C  is a bottom view of the switch mechanism  170  which shows radial hole  175  along with arms  171  and  172  coupled to body section  170   a . Radial hole  175  is configured to receive an end of spring  180  shown in  FIG. 12F . 
       FIG. 12D  is a perspective view of the switch mechanism  170  having arms  171  and  172 , as well as holes  179   a  and  179   b  in arms  171  and  172  respectively. There are also shown protrusions  171   a  and  171   b  (See  FIG. 12G ) which are configured as protrusions to control the mounting orientation and which prevents the installation of the actuator in a wrong orientation or position. 
       FIG. 12E  is a side view of the switch mechanism  170  which shows post section  173 . 
       FIG. 12F  is a view of spring  180  which has a first end  181  and a second end  182 . There is also an intermediate curved section  183  which is configured to act as a spring, selectively compressing and expanding based upon movement of toggle switch  130 . 
     Spring  180  is coupled to switch mechanism  170  such that the first end  181  is coupled to radial hole  175  while the second end  182  is coupled to the housing for housing the device of the switch mechanism.  FIG. 12G  is a close up view of the switch mechanism  170  taken from  FIG. 12A  wherein in this view, there is shown post section  173 , center hole  174 , arms  171  and  172 , holes  179   a , and  179   b  as well. This switch mechanism  170  is coupled to spring  180  and is coupled inside of a housing  139  such as that shown in  FIG. 14A . 
       FIG. 13  is an enlarged view of the switch mechanism  170  coupled to spring  180  with a first end  181  being inserted into radial hole  175  and a second end  182  being coupled to a stationary portion or post of a housing  139 . When the switch mechanism  170  is rotated, from either an on or an off position, as shown by the arrow crossing over arms  171  and  172  of the fork, this causes a temporary compression of spring  180  in region  183 . Once the rotation reaches a threshold tripping point or position, the compression of the spring forces the movement forward so that the spring expands so that the switch mechanism  170  completes its rotational motion. This motion results in the arms  171  and  172  then resting either on stop  139   a  or stop  139   b  which represent either an on or an off position for an associated switch. Thus, during the initial rotational movement, the spring  180  is compressed further, however, after hitting or passing the threshold point, the spring  180  is pushed into a position where it can expand such that it forces continued rotational movement on to the second position. Thus, the switch mechanism  170  in combination with spring  180  turns an unbiased switch into a rotationally biased lever for actuating a switch. 
       FIG. 14A  is a top perspective view of a body  12  having a first cover  136 , and a second cover  137  wherein these covers along with third cover  139  are coupled to toggle switch  130  shown in  FIG. 11A . Toggle switch  130  is in a first position, however, this shows a correspondingly small switch  189 . 
       FIG. 14B  is a top perspective view of the toggle switch  130  shown in  FIG. 14A  in the first position, however the switch  190  is in physical communication with switch mechanism  170 . Switch  190  is configured to be moved by the rotation of toggle switch  130  which acts on arms  171  and  172 . When toggle switch  130  is rotated such as in the direction of the arrow ( FIG. 13 ), this rotation of the lever rotates arms  171  and  172  such that these arms act upon switch  190 . In addition, this switch mechanism  170  in conjunction with spring  180  is configured to be biased in either a first position or a second position, but to generally resist being stuck in a middle position between the first position and the second position. 
       FIG. 14C  shows the switch mechanism in contact with another type of switch  191  which is essentially a smaller version of switch  190  shown in  FIG. 14B . 
     The rotation of toggle switch  130  allows for the easier switching and a mechanical advantage to moving switch  190  than if that switch was already available. In addition, because switch mechanism  170  also includes a spring  180 , this allows for a singular on/off movement which allows the toggle switch to be thrown from a first position to a second position, or back again without remaining in a middle position or preventing the actuator from remaining in a middle position between the first position and the second position. The first position can be either an “on” position or an “off” position while the second position can be either an “on” position or an “off” position. 
     Ultimately the above design(s) provide for an electrical box such as box  10 ,  30 , or  80  comprising a body having at least one opening forming a connection interface  11 ,  31 , or  79  for receiving an electrical device, and at least one opening for receiving electrical wiring such as wiring holes  19   a ,  19   b ,  39   a ,  39   b ,  39   c ,  39   d ,  89   a ,  89   b ,  89   c ,  89   d ,  89   e ,  89   f  from building wiring. There can also be a connection interface  11 ,  31 ,  79  disposed in the opening of the respective box  10 ,  30 ,  80 , wherein the connection interface  11  for box  10  comprises a first set of connection elements or posts  18   a ,  18   d ,  18   e , and  18   h , and a second set of connection elements or posts  18   b ,  18   c ,  18   g ,  18   f . Box  30  comprises a first set of connection elements or posts  38   a ,  38   d ,  38   i ,  38   l ,  38   e ,  38   h ,  38   m , and  38   p  or a second set of connection elements or posts  38   b ,  38   c ,  38   j ,  38   k ,  38   f ,  38   g ,  38   n , and  38   o . Box  80  comprises a first set of connection elements or posts  88   a ,  88   d ,  88   e ,  88   h ,  88   i ,  88   l ,  88   m ,  88   p ,  88   q ,  88   t ,  88   u ,  88   x , and a second set of connection elements or posts  88   b ,  88   c ,  88   f ,  88   g ,  88   j ,  88   k ,  88   n ,  88   o ,  88   r ,  88   s ,  88   v ,  88   w.    
     The first set of connection elements are configured to couple to a first type of mounting device, and the second set of connection elements are configured to couple to a second type of mounting device. In addition, at least one of the connection elements comprises a recess such as recesses  23   a ,  23   b ,  23   c , and  23   d  in box  10 , recesses  43   a ,  43   b ,  43   c ,  43   d ,  43   e ,  43   f ,  43   g , and  43   h  in box  30 , and recesses  81   a - 81   l  on box  80 . 
     These recesses are configured to create a substantially round shaped mounting region such as mounting regions  29   a ,  29   b , in box  10 , mounting regions  45   a ,  45   b ,  45   c , and  45   d  in box  30 , and mounting regions  82   a ,  82   b ,  82   c ,  82   d ,  82   e , and  82   f  on box  80  at the connection interface. 
     This design can also result in a method for providing a mounting interface. This method can include presenting at least one connection interface such as connection interfaces  11 ,  31 , and  79 , and then presenting a plurality of connection elements or posts  18   a - h ,  38   a - p ,  88   a - x  on the connection interface. 
     Next, the plurality of connection elements or posts  18   a - 18   h ,  38   a - 38   p , and  88   a - 88   x  can be spaced around the respective connection interface  11 ,  31  and  79 . 
     Next, each respective box can provide at least one recess such as recesses  23   a - 23   d ,  43   a - 43   h , and  81   a - 81   l  in at least one of the connection elements or posts. The at least one recess is configured to receive an electrical device when the electrical device is mounted to the connection interface  11 ,  31 ,  79 . 
     From this design, there can also be a method for providing a mounting interface comprising presenting at least one multiple gang enclosure having an open front face, such as connection interface  11 ,  31 , and  79 . Next, a frame such as frame  60  or frame  100  can be coupled to the at least one multiple gang box  30  or  80 , over the open front face of connection interface  31  or  79 . Frame such as frame  60  or  100  comprises a central face  62 , or spacing faces  102   a  or  102   b  having a spacing such as spacing  102   i  and  102   ii  sufficient to space at least two different single gang front covers apart from each other on the multiple gang enclosure. 
     Thus, this configuration creates a universal box for mounting multiple different front covers on a single box design. 
     While the boxes can have any particular suitable dimensions taken along the length or the width such as length  291  or width  29   w , or length  45   l , or width  45   w , or length  82   l  and width  82   w , examples of the box dimensions are explained below. These dimensions are only examples of one embodiment and the claims are not limited to these dimensions unless these dimensions are included in the claims. 
     For example a single gang box can have a width from outer edge to outer edge  29   w  of approximately 3.125 inches while a length  291  from outer edge to outer edge of approximately 4.625 inches. Box  30  can have a width  45   w  from outer edge to outer edge of approximately 7 inches, and a length  45   l  from outer edge to outer edge of approximately 4.625 inches. Box  80  can have a width  82   w  from outer edge to outer edge of approximately 10.825 inches and a length  82   l  from outer edge to outer edge of approximately 4.625 inches. 
     In addition posts, such as posts  18   a , and  18   d  can be spaced apart from each other along a width dimension by approximately 1.875 inches from a center region on each post, while posts such as posts  18   b  and  18   c  can be spaced apart from each other along a width dimension by approximately 1.125 inches from a center region on each post. In addition, posts  18   a , and  18   e  can be spaced apart from each other by approximately 3.25 inches in a length dimension from a center region on each post, while posts  18   b  and  18   f  can be spaced apart from each other along a length dimension by approximately 3.624 inches from a center region on each post. 
     Recesses such as recesses  23   a ,  23   b ,  23   c , and  23   d  can extend in at least 0.7 inches such as approximately 0.718 inches from a front edge of the box. The box depth such as box  10  can be approximately 3.5 inches from a front edge to a back surface. Recesses  23   c  and  23   d  are configured such that they have recess surfaces that are angled such that if these surfaces were extended they would intersect at a 110 degree or approximately 110 degree angle. 
     While the above embodiments are shown as examples, the claims are not limited to the above dimensions provided unless the claims are written to include particular dimensions. 
     Accordingly, while a few embodiments of the present invention have been shown and described, it is to be understood that many changes and modifications may be made thereunto without departing from the spirit and scope of the invention as defined in the appended claims.