Abstract:
A wall-mounted component can be flush-mounted into a wallboard by first installing a panel with a receiver bracket flush into a wallboard. Once the panel is installed, the component can be inserted into the receiver bracket at which point a locking mechanism automatically or manually engages to lock the component into the wall. The locking mechanism is concealed from view so that a casual observer does not see how the component is affixed to the wall, yet is accessible from the wall&#39;s exterior for routine service and maintenance, as well as reinstallation of updated components.

Description:
This application is a continuation-in-part of non-provisional application Ser. No. 12/202,870 filed Sep. 2, 2008. Ser. No. 12/202,870 is a continuation-in-part of non-provisional application Ser. No. 11/954,667 filed Dec. 12, 2007. Ser. No. 11/954,667 is a continuation-in-part of non-provisional application Ser. No. 11/566,365 filed Dec. 4, 2006, and Ser. No. 11/954,667 also claims priority to (1) provisional application Ser. No. 60/950,237 filed Jul. 17, 2007 and (2) International application Ser. No. PCT/US07/16404 filed Jul. 19, 2007. Ser. No. 11/566,365 claims priority to provisional application Ser. No. 60/825,162 filed Sep. 11, 2006. PCT/US07/16404 claims priority to (1) non-provisional application Ser. No. 11/548,381 filed Oct. 11, 2006, (2) provisional application 60/825,162 filed Sep. 11, 2006, and (3) provisional application 60/950,237 filed Jul. 17, 2007. All prior applications are incorporated by reference in their entirety. 
    
    
     FIELD OF THE INVENTION 
     The field of the invention is locking mechanisms for wall and ceiling receptacles. 
     BACKGROUND 
     Plasma screens, speakers, light switches, electrical outlets, recessed lighting, junction boxes and other components are conventionally mounted to walls or ceilings. Components are generally held in place on a bracket using some sort of attachment mechanism. When those components break down or need to be replaced, however, the attachment mechanism oftentimes needs to be removed in order to service the component. 
     U.S. Pat. No. 5,152,559 to Henrichs teaches a hook and latch mechanism for a wall panel, where the wall panel locks into place as it is installed on a wall bracket, and a large button in the center of the panel releases the latch so that the panel can be removed. Having a visible unlocking device, however, can detract from the aesthetic appeal and elegance of high-end wall mounts, and advertises the mechanism by which the component is affixed to the wallboard. Henrichs and all other extrinsic materials identified herein are incorporated by reference in their entirety. Where a definition or use of a term in an incorporated reference is inconsistent or contrary to the definition of that term provided herein, the definition of that term provided herein applies and the definition of that term in the reference does not apply. 
     US 2007/0051862 to Monti teaches a wall-mounted speaker with protrusions that lock into indentations in a bracket in only one direction. There is no visible unlocking device, as the wall-mounted speaker unlocks by pushing the speaker through the wall to the other side. While the protrusion/indentation mechanism in Monti effectively locks the speaker in place within the bracket without a visible unlocking mechanism, the speaker can only be unlocked by pushing the speaker through to the other side of the wall. Such a configuration is not ideal for many installations where access to the other side of the wall is not available. Additionally, an owner of the speaker may want only authorized persons to detach the speaker from the wall. 
     Thus, there is still a need in the art for locking mechanisms for wall mounts that do not have a visible unlocking mechanism, and can be pulled out from the wallboard. 
     SUMMARY OF THE INVENTION 
     The present invention provides apparatus and methods in which a component is installed into a wallboard receiver by locking the wall component to the receiver using a concealed locking device. Typically, a wallboard is a building board made for surfacing rather than for insulating ceilings and walls. Wallboards are often made into large rigid sheets that are fastened to the frame of a building to provide a surface finish. As used herein, the term “wallboard” should be construed broadly to mean any sort of mechanical barrier for surfacing ceilings or walls. Wallboards can be made of any suitable material, including for example plywood, plaster, wood, wood pulp, or gypsum. 
     The component is locked to the receiver using a locking mechanism that prevents the component from being removed from the receiver, and preferably completely immobilizes the component with respect to the receiver. Suitable locking mechanisms include matching magnets, magnet attractors, indents, detents, compressible material, sliding bolts, recesses, pivoting latches, latch locks, screws and threaded holes. Matching parts of a locking mechanism are two parts that mate with one another to prevent the component from being removed from the receiver. Preferably, the locking mechanism comprises several matching magnets and magnet attractors on the component and the receiver. A magnet attractor is defined herein as any material that has a positive magnetic susceptibility. Contemplated magnet attractors include iron, lodestone, steel, nickel, cobalt, and magnetite. A magnet attractor is attracted to a magnet when placed in close proximity to the magnet, which means that either the magnet is pulled towards the magnet attractor or vice versa. Preferred matching magnets and magnet attractors pull the component into the receiver without any additional forces when the magnets are located within 1, 2, or even 5 inches away from one another. (2.54, 5.08, and 12.7 cm) 
     Whatever the locking mechanism, a cover preferably conceals the locking mechanism from being viewed from a typical viewing angle. This can be accomplished by physically placing or sliding a cover over the locking mechanism, but is typically accomplished by placing the locking mechanism on any side but the front side of the component. A key could be used engage the locking mechanism, however, the locking mechanism preferably automatically engages as the component slides into the receiver so that a user looking at the front of the component does not see how the component is attached to the receiver. 
     An electronic remote could unlock the locking mechanism, for example a radio frequency transmitter or a passive RFID tag, but the key to unlock the component from the receiver is preferably a low tech solution. For example, a magnet could slide a bolt or latch to the side, or a screwdriver could unscrew a bolt running through the component and the receiver. A user could also simply overpower the locking mechanism by pulling the component from the receiver using a gripping surface, for example a handle, outcropping, or a loop. Where the front surface of the component is without a gripping surface, a vacuum or magnetic force could be used. Vacuum grippers could provide a powerful vacuum force by combining a lever with a suction cup, and electromagnets or lodestones could provide a powerful magnetic force. 
     The bracket is preferably located within a panel that is installed in the wallboard for ease of installation. Preferred panels have compositions and thicknesses that match the wallboard to which they are being finished, in terms of thickness, composition, and so forth. Where there are differences in composition or thickness, it is preferred that the moisture absorption rate and the thermal expansion rate of the panel and the wallboard differ by no more than 30%, 20%, 10% or 5% from one another to prevent cracking and fraying. Contemplated panel materials include polymers, plasters, woods, fiberboards, and gypsum. Since the panel will likely be anchored to a support structure using a screw, nail, or similar attachment mechanism, preferred panels have a plurality of screw hole positions, for example depressions, markings, or screw holes, that indicate potential screw or nail positions. Panels can have factory cut openings that receive the multiple receivers, and in such cases the receivers would likely be glued to the panel material to eliminate any gaps. More advantageously, the panel material can be molded around the receivers so that there is essentially no gap between panel material and receivers. 
     A receiver can be affixed to an opening in the panel, which typically extends from a front side of the panel to the back side of the panel. Receivers can range from a simple rim disposed on the inside of the opening to an extensive bracket and housing extending out the back of the panel. In any event, completed assemblies preferably have little or no discernable gap between the panel and the receiver. This can be accomplished in any suitable manner, including for example, accurately cutting the opening into which the receiver is installed and then gluing the receiver to the panel. Where the panel comprises a formed substance such as drywall, another option is to form the panel around the receiver. 
     In preferred embodiments, a receiver has a spackle shield that covers the opening, which can include useful installation tools, for example a level, installation screws, or installation instructions. In the figures, each receiver also has an optional spackle rim that extends outwardly from the front surface of the panel by a small distance. Preferred distances are less than ½ inch (1.27 cm), more preferably by only ⅛ inch (3.175 mm), and even more preferably 1/16 inch (1.5875 mm). Spackling compounds can then be smoothed over the surface of the wallboard and panel up to the spackle rims to achieve a contiguous visual appearance. While the surface of the wallboard is typically flat, the junction between the wallboard and the panel does not necessarily have to be flat. 
     Panels are typically installed into the wallboard by first approximating the edges of the panel with the edges of the wallboard. “Approximating” is defined herein to mean bringing the edges near or towards one another so that the junction or gap between the edges is less than 10 mm (0.394 in), 5 mm (0.197 in), or even 2 mm (0.079 in). If the junction or gap between the edges is larger, a buffer can be attached to the edge of the panel before installation, or one or more shims can be installed into the junction. The junction can then be concealed using a suitable construction method, for example taping or plastering over the junction. Providing a pre-fabricated panel designed to accept specific components greatly facilitates installation by eliminating the need for on-site precision measurements. 
     All types of components are contemplated for installation, but especially including components having electrical parts. For example, speakers, lights, switches, wall plugs, in-wall controls (audio, video, fan), thermostats (HVAC controllers), fire sprinklers, fire alarms and smoke alarms, mirrors, video screens, kitchen appliances, picture frames, signage, intercoms, air vents, vacuum outlets, security panels, and iPod docks and ports are all contemplated components. 
     The contemplated locking mechanisms allow a user to easily service a component in a wallboard while concealing the locking mechanism from view, facilitating the elegant flush-mounted appearance. As defined herein, “servicing” means installing, uninstalling, or otherwise maintaining the component and/or receiver. 
     Various objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the invention, along with the accompanying drawings in which like numerals represent like components. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING 
         FIG. 1  is a front perspective view of a component and a matching receiver in a wallboard. 
         FIG. 2  is a front perspective view of the component mounted in the matching receiver of  FIG. 1 . 
         FIGS. 3A-3B  are simplified horizontal cross-sections of the component and receiver of  FIG. 2 , taken along line  3 - 3 . 
         FIGS. 4A-4B  are horizontal cross sections of a component that is pulled out of a receiver by applying a magnetic gripper to the front of the component. 
         FIGS. 5A-5B  are horizontal cross sections of a component that is pulled out of a receiver by applying a vacuum gripper to the front of the component. 
         FIG. 6  is a horizontal cross section of a component and receiver that lock using matching indents and detents. 
         FIG. 7  is a horizontal cross section of a component and receiver that lock using compressible material lining the receiver 
         FIG. 8A-8B  is a horizontal cross section of a component and receiver that lock using matching sliding bolts and recesses. 
         FIG. 9A-9D  is a horizontal cross section of a component and receiver that lock using matching pivoting latches and protrusions. 
         FIG. 10A  is a horizontal cross section of a component and receiver that lock using matching threaded bolts and threaded holes. 
         FIG. 10B-10C  are front plan views of the component of  FIG. 10A . 
         FIG. 10D-10F  are horizontal cross section views of a shortened component and receiver of  FIG. 10A , with a magnetic faceplate attached. 
         FIG. 11  is a plan view of a panel having an opening, and a receiver disposed in the opening. 
         FIG. 12  is a front perspective view of the receiver in  FIG. 11 . 
         FIG. 13A  is a simplified vertical cross-section of the panel of  FIG. 11 , taken along line  13 - 13 , installed in a wallboard with an attached component. 
         FIG. 13B  is a blown up view of the circled portion of  FIG. 13 , taken along line  14 - 14 . 
         FIG. 14  is a front perspective view of the receiver of  FIG. 12  positioned to couple with a bracket backing. 
         FIG. 15  is a blown up view of the circled portion of  FIG. 13 , taken along  14 - 14 , with the bracket and bracket backing of  FIG. 15 . 
         FIG. 16A  is a front perspective view of a panel being affixed to two studs in a wall, the panel having a spackle shield covering the openings. 
         FIG. 16B  is a front perspective view of the panel of  FIG. 17A , around which drywall has been installed. 
         FIG. 16C  is a front perspective view of the panel and drywall of  FIG. 17B , showing mesh tape. 
         FIG. 16D  is a front perspective view of the panel and drywall of  FIG. 17C , where the mesh tape has been covered by spackle. 
         FIG. 16E  is a front perspective view of the panel and drywall of  FIG. 17C , where the spackle shields have been removed to show the openings. 
         FIG. 17A  is a perspective view of two structures in a building (e.g. walls or wall and ceiling), in which an opening has been cut to receive a panel assembly. 
         FIG. 17B  is a perspective view of the two structures of  FIG. 18A , in which the panel assembly has been placed within the opening. 
         FIG. 17C  is a perspective view of the two structures of  FIG. 18B , in which the approximated edges of the panel assembly and the wall have been finished to provide a superficially continuous junction. 
         FIG. 18  is a perspective view of a panel assembly being formed by pouring a panel material into a mold. 
     
    
    
     DETAILED DESCRIPTION 
     In  FIG. 1 , a component mounting system  100  generally includes a wallboard  110 , a receiver  120 , and a component  130 . It should be appreciated that while component  130  is a speaker, any suitable component mounted to a wall could be used, for example plasma screens, in wall art panels, in wall cabinets, windows, wall outlets, security systems, fuse boxes, light switches, lighting, sprinkler systems, smoke detectors, and so forth. While the receiver is generally shaped and sized to fit particular electronic devices, for example a rectangle for a light switch or a circle for a ceiling light, the universal receiver may be used that can accommodate a variety of electronic devices. To fit the component to a universal receiver, the component could consist of an outer casing that fits around the electronic device and couples to the universal receiver. 
     As shown in  FIG. 2 , component  130  can be inserted into receiver  120  to create a flush-mounted appearance within wallboard  110 . Flush-mounting means to make a surface of the component substantially flush with the surface of the wallboard. Although the portions of the wallboard  110  depicted in the  FIG. 2  is substantially flat, those skilled in the art will appreciate that the structure could be curved, slanted, or have curved/slanted portions in any direction. Preferably, a locking mechanism (not shown) locks component  130  to receiver  120  to prevent the component from being removed from the receiver. In an exemplary embodiment, the locking mechanism completely immobilizes component  130  within receiver  120  until the locking mechanism is disengaged. The locking mechanism is hidden from view once the component is installed in the receiver so as not to disturb the elegant flush-mounted Contemplated locking mechanisms are disclosed in  FIGS. 3-10 , and are discussed in detail below. 
     In  FIGS. 3A and 3B , a magnet locking mechanism  300  generally comprises magnet attractors  310  and magnets  320 . Magnets  320  pull component  130  into receiver  120  so that the front portion of component  130  is flush with the front of wallboard  110 . While magnets  320  do not have to be particularly strong, magnets  320  are preferably strong enough to pull component  130  into the locked position when magnets  320  are less than 5 inches (12.7 cm), 2 inches (5.08 cm), or 1 inch (2.54 cm) from magnet attractors  310 . It should be appreciated that magnet attractors  310  could be switched with magnets  320 , or could be magnets themselves. In a preferred embodiment, magnet attractors  310  are magnets, and magnets  320  are electromagnets. A remote control (not shown) could then reverse the polarity of magnets  320  to “eject” the component from the receiver when maintenance needs to be performed. Alternatively, a wire (not shown) could run to the front of component  130  and surround magnet attractors  310  so that when a current is applied to the wire, the magnet attractors  310  reverse polarity to “eject” the component from the receiver. 
     Component  130  has electrical male connectors  330  are banana jacks that are sized, spaced, and oriented to mate with electrical female connectors  340  as component  130  is being mounted in receiver  120 . Banana couplings are preferred because they provide a particularly robust connection, and it is relatively easy to orient the plug to the jack. Of course, one could use a single plug and jack provided that a proper electrical pathway is established, for example, an RF connector. All other suitable types of connectors are also contemplated, including for example inductive connections (not shown), simple bent wire or other bump connectors (not shown), loudspeaker connectors (not shown), D-sub connectors (not shown), and combinations thereof. It should be appreciated that male connectors  330  and female connectors  340  could be switched with one another without departing from the scope of the invention. 
     Regardless of the type of connectors and manner of providing the electrical connections, it is preferred that the electrical connection is a substantially automatic. As the component is mounted in the receiver, the female electrical connectors  340  should mate with the male electrical connectors  330  without a separate act. In  FIG. 3A and 3B , as component  130  is placed within receiver  120 , the magnetic force of magnets  320  upon magnet attractors  310  pulls male electrical connectors  330  into female electrical connectors  340 . Forcing the user to manually mate the connectors in a separate act, whether with a WIRE-NUT™ or otherwise, is thought to be much less preferable. 
     It should be appreciated that electrical connectors may not need to be installed at all, particularly where the component does not require an electrical connection, for example in the case of a picture frame or a wireless doorbell. 
     In  FIGS. 4A and 4B , instead of using an electromagnet of reversed polarities to eject the component from the receiver, a magnet gripper  410  could be used with a magnet attractor  420  to overpower the magnetic force between magnet attractor  310  and magnet  320 . It should be appreciated that the magnetic force between magnet gripper  410  and magnet attractor  420  should be much stronger than the magnetic force between magnet attractor  310  and magnet  320 . It should also be appreciated that if component  130  is an electronic device, that magnet attractors  310  and  420  should be located well aware of any electrical machinery that would be negatively affected by a strong magnetic force. An additional magnet gripper (not shown), or a single magnet gripper with an additional handle, could be used for a user to pull the component out of the receiver with two hands instead of one. 
     In  FIGS. 5A and 5B , a vacuum gripper  510  is used instead of a magnet gripper to overpower the magnetic force between magnet attractor  310  and magnet  320 . Vacuum gripper has a lever  512  that is attached to suction cup  514  such that when lever  512  is activated, air is removed from suction cup  514 . When lever  512  is pulled while suction cup  514  abuts the flat surface of component  130 , the absence of air in suction cup  514  provides a vacuum force that locks vacuum gripper  510  to the front of component  130 . From that point, a user can simply pull on vacuum gripper  510  to remove component  130  from receiver  120 . 
     In  FIG. 6 , an indent/detent locking mechanism  600  generally comprises indents  610  and detents  620 . Indents  610  are sized, spaced, and oriented to mate with detents  620  as component  130  is being inserted into receiver  120 . Preferably, detents snap into place around indents  610  without locking into place, so that component  130  can be pulled out of receiver  120  without damaging the indent/detent mating. Detent  620  could also be a push-push latch, so that component  130  could be disengaged merely by pressing on the front of component  130 . In a preferred embodiment, indents  610  are male banana jacks and detents  620  are female banana jacks that provide an electrical communication between component  130  and receiver  120  and a locking mechanism between component  130  and receiver  120 . 
     In  FIG. 7 , a compressible locking mechanism  700  generally comprises a compressible material  710  that fits in the gap between the rear portion of component  130  and the receiver  120 . Compressible material  710  is preferably an elastic polymer or fabric that has a tendency to return to its own shape. The combined elastic forces of compressible material  710  and the vacuum force of pushing air out of receiver  120  holds component  720  in place within receiver  120 . In this particular example, the outside face plate  720  is larger than the rear portion of component  130 . 
     In  FIG. 8 , a sliding bolt locking mechanism  800  generally comprises sliding bolts  810  in component  130  and recesses  820  in receiver  120 . Sliding bolt  810  is a magnet attractor that is pulled into place by drawing magnet  830  across the surface of component  130 . In this particular example, component  130  has a handle  840  that extends from a front surface of component  130  to allow a user to pull component  130  away from receiver  120  once the sliding bolt mechanism is unlocked. 
     In  FIGS. 9A-9D , a pivoting latch locking mechanism  900  generally comprises pivoting latches  910  in component  130 , latch lock  920  in receiver  120 , and magnet attractor  930  in component  130 . As component  130  is inserted into receiver  120 , pivoting latches  910  pivot into a recess (not shown) in component  130  and then snap into latch locks  920 , preventing component  130  from being pulled out of receiver  120 . Latch lock  920  is shown as a beveled recess, but could be a protrusion or any other suitable latch lock that prevents component  130  from being pulled out of receiver  120 . Here, pivoting latches  910  are also made of a magnet attracting material. When magnet gripper  410  is applied to magnet attractor  930 , magnet attractor  930  acts as a magnet, pulling latches  910  out of latch locks  920 , so that component  130  can then be pulled out of receiver  120 . 
     In  FIGS. 10A-10C , a screw locking mechanism  1000  generally comprises screws  1010 , screw holes  1020  in receiver  120 , and a cover  1030 . Screws  1010  are threaded and run through the entirety of component  130  and into screw holes  1020  to hold component  130  against receiver  120 . It should be appreciated that screws  1010  could also be angled towards a closer wall of receiver  120 , or could be fully threaded along the entire length of the screw. As seen in  FIG. 10B , the heads of screws  1010  are visible from the front of component  130 . Thus, after installation, cover  1030  is positioned in the recess, and magnetically, mechanically or otherwise held in place to provide an even front surface to component  130 . 
     In  FIGS. 10D-10E , the screw locking mechanism  1000  also has a magnetic faceplate  1030  with magnet attractor  1040  and magnets  1050 . Magnets  1050  hold the faceplate against component  130  by coupling to the heads of screws  1010 . It should be appreciated that component  130  could comprise other magnet attractors that help couple the magnetic faceplate to the component. Faceplate  1030  could be removed with either a magnet gripper  410  or another suitable gripping device, for example a vacuum gripper. 
     As shown in  FIG. 10F , faceplate  1030  could also be held in place and removed using matching indents  1060  and spring detents  1070  to form a push-push mechanical coupling. While the faceplate coupling also preferably conceals the locking mechanism, all other suitable couplings are contemplated. 
     In all of the embodiments, the receiver is preferably preinstalled in a panel that is then installed in a wallboard to provide better support for the component. In  FIG. 11 , a component mounting apparatus  1100  generally includes a panel  1110  with an opening  1120 , and a receiver  1140  disposed in the opening  1120 , and attachment wings  1170 A- 1170 D. It should be appreciated that while each receiver is sized and dimensioned to hold a specific component, the receivers could be identical to one another to create a “universal bracketing system” that can hold components of various sizes. 
     Panel  1110  is a piece of gypsum board, wood, plastic, or other material (or combination of materials) sufficiently strong to support a speaker or other desired component between two studs of a wall, or joists or other supports in a ceiling. Where plywood is used as the panel material, for example, the panel might be as thin as ¼″ (6.35 mm), but would more preferably measure at least ½″ (12.7 mm) or ⅜″ (19.05 mm). Preferred materials include wallboard, Medium Density Fiberboard (MDF), High Density Fiberboard (MDF), Acrylonitrile Butadiene Styrene (ABS), and other materials that closely match various characteristics of drywall. Multiple materials could be used, for example mixed in with one another, alternating, layered on top of one another, or a combination. Preferably, the material has equal moisture absorption and coefficient of thermal expansion as the surrounding wallboard, while having greater durability and strength for attaching heavy components directly to the panel. For example QuietRock® 525 could be a paneling material used where the wallboard comprises drywall. 
     Panel  1110  is generally about twenty inches (about 50 cm) to twenty-four inches (about 60 cm) wide, but panel  1110  can have any other suitable dimensions, even for example, up to the size to replace an entire sheet of wallboard. Narrower panels are also contemplated, although they would likely not have a sufficient width to extend between wall studs or ceiling joists. It is preferable for the panel  1110  to have a width of at least six inches (15.24 cm) or twelve inches (30.48 cm) greater than the spacing between studs, which allows the installer considerably greater flexibility in positioning the panel on the wall. Lateral wings (not shown) could be attached to the perimeter of panel  1110  to extend the width for installations where the studs are spread apart at a greater distance from each other than normal. While panel  1110  is shown as a substantially planar apparatus, panel  1110  can be concave, convex, or any other shape to either match the shape of the wallboard, or to introduce a non-planar surface to the wallboard. 
     Hole primers  1112  are spaced approximately 1 inch (2.5 cm) from center, a diameter of 0.375 in (9.525 mm), and are approximately ¼ in (6.35 mm) deep, but can be shaped and configured in other suitable ways. A “hole primer” is a concave hole deepest in the center that helps an installer drill a screw or hammer a nail in a designated place without slipping. The diameter of the hole primer is preferably larger than the diameter of the screw head or nail head used so as to prevent the head of the screw or nail from leaving an unsightly bump on the surface of the wallboard after spackling. Other suitable receivers are contemplated, for example visual marks or pre-drilled and threaded screw holes. 
     Opening  1120  can also be of any suitable shape and size. Preferred openings are rectangular to accommodate common rectangular components, for example light switches, wall outlets, speaker volume controls, and home security systems. However, the openings could also be oval or circular or any other desired shape. The area of the opening is generally dependent on the size of the component, and can range up to 80 in 2  or larger. Especially preferred openings have an area of at least 20 in 2 , 40 in 2 , 60 in 2 , and even 80 in 2 . Nevertheless, for stability, it is contemplated that the panel have openings with a length that is no more than half or one third the length of the panel. 
     In some cases it may be desirable to include multiple openings for multiple components. Openings with varying height could be aligned along their top or bottom edges, aligned along a centerline, or could be arranged in a staircase fashion with a top edge aligned to a bottom edge. Openings could be cut at a job site or elsewhere by an installer, but are more conveniently precut (or molded to include the opening) at the manufacturer. It is possible for a panel to have punch out openings or perhaps cutout lines to facilitate selection of the position of the opening at the job site, but those options are currently disfavored relative to a manufactured pre-cut or molded opening and a relatively large panel. 
     The top, bottom, and side wings  1170 A- 1170 D, respectively, preferably extend from the corresponding edges of the panel  1110  by at least about one inch (2.54 cm), which is deemed to be sufficient space to conveniently drive a nail or screw into a stud. It is also contemplated, however, that at least one of the wings  1170 A- 170 D can extend much longer, perhaps 24 to 30 inches (about 60-75 cm) or more. Such long wings can accommodate odd installations where the studs are spread apart at a greater distance from each other than normal. Wings  1170 A- 1170 D are preferably made of a metal mesh, but can include of any suitable material or materials so long as the material(s) provide(s) sufficient shear strength to support the panel  1110  and the component (not shown). Metal mesh is also desirable because the wings are advantageously relatively thin, so as not to push out the overlying wallboard, and metals can provide considerable strength with thickness of less than 100 mils. It should also be appreciated that although wings  1170 A- 1170 D are described herein by separate numerals, they may well be one continuous piece of material. 
     Receiver  1140  is preferably sized and dimensioned to fit snugly into opening  1120 , but in any event is screwed, glued, clamped, or are otherwise securely attached to the panel  1110 . The secure attachment is important since in at least some embodiments, the component housing will be attached to the receiver rather than being directly attached to the panel  1110 . The receiver is preferably molded from polyethylene or other sufficiently strong and durable thermoset plastic. A front of receiver  1140  is shown in greater detail in  FIG. 12 , and includes holes  1142  for screws (not shown), a recess  1144  into which a component cover (not shown) can be removably secured via a holding mechanism, and a rim  1140 A, and optional magnets  1146  or an optional press fit (not shown). 
     A spackle shield (not shown) preferably covers the opening of the receiver to prevent mud or drywall from splashing to the other side of the panel, and can be removed after spackling. This is particularly helpful for when an electronic component is pre-installed behind the panel before spackling. The spackle shield (not shown) can have optional level (not shown) to help ensure that the panel is being installed horizontally. Other devices that assist in installation can be provided in the spackle shield, for example a laser leveler to help align several panels with one another or a compartment that stores extra screws and magnets. 
       FIG. 13A-B  shows a side view of panel  1110  and receiver  1140 . The rim  1140 A is sized and dimensioned to extend outwardly beyond a front of the panel  1110  by a very small distance  1141 , which provides a lip that can readily be used as a stop against which to spread a spackling compound, for example plaster or drywall. Preferred such distances  1141  are less than ⅛ inch, and preferably about 1/16 inch, or in metric terms about 1-3 mm. Preferably, the panel has a thickness of at least ¼ inch (6.35 mm). Also shown in  FIG. 13B  is an attachment member  1148  that helps secure receiver  1140  to panel  1110 . A screw hole (not shown) can be provided in attachment member  1148  to help affix receiver  1140  to panel  1110 . 
     It should be appreciated that the rim could be separable from the panel. Thus, for example, the rim could be a separately molded piece of plastic, metal or composite that is installed into the opening by the installer, or at a factory. 
     As seen in  FIGS. 14 and 15 , a receiver backing  1180  with screw holes  1182  could be used to clamp receiver  1140  to panel  1110 . In this embodiment, attachment member  1148  fits within recess  1114  on the front of panel  1110  and receiver backing  1180  fits within recess  1116  on the back of panel  1110 . Screw  1184  threads through screw holes  1142  and  1182 , and finally through nut  1186  to provide a clamping force around panel  1110 . Clamping receiver  1140  to panel  1110  provides a secure connection without the need for expensive glues or adhesives. 
     In  FIG. 16A , the panel  1110  is affixed to two studs  1210 A,  1210 B in a wall, and screws  1215  are inserted through hole primers  1112  and the panel  1110  on the right side, and through attached flange  1170 . Panel  1110  shows opening  1120  with a spackle shield covering the receiver. Of course, the positioning and orientation of the panel could be varied in any suitable manner with respect to the studs,  1210 A,  1210 B, including moving the panel  1110  higher or lower, left or right, or even tilting the panel clockwise or counterclockwise. Similarly, the studs should also be interpreted herein as emblematic of any support structures of a wall, whether or not such structures are technically considered to be studs. In addition, a greater or lesser number of screws could be used, or inserted in some other arrangement than that shown to provide greater or lesser support. The screws could also be replaced or supplemented by some other attachment means such as an adhesive. 
     Those skilled in the art will appreciate that the combination of panel and receiver could be provided in several different ways. The panel and receiver could, for example, be joined together at a job site, and indeed the panel could even be “manufactured” at the job site by cutting or punching out the opening. More preferably, however, the panel and receiver are provided as an item of manufacture to the installer by a supplier or manufacturer. The rim of the panel can be pre-installed to the panel. Thus, in various embodiments a kit could contain one or more of a panel, a receiver (or at least a rim around the edges of an opening in the panel), a speaker housing, a spackle shield, and installation screws. The installer would then provide whatever labor is appropriate for the installation, including optionally installing the receiver and/or rim, optionally installing the spackle shield, and optionally mounting the speaker into the speaker housing to the back side of the panel. It is also contemplated that the speaker can be pre-installed into the panel before installation. Alternatively the combination of the panel and receiver can be mounted before installing a rim on the opening. 
     In  FIG. 16B  drywall  1220  or other wallboard has been installed on all four sides around the panel  1110 , and coupled to the wings using screws  1215 . Where wings are present, as in the embodiment depicted, the drywall  1220  overlays the wings, but the wings are sufficiently thin so that the drywall is not noticeable raised. Those skilled in the art will appreciate that although  FIG. 16B  shows the drywall  1220  surrounding the panel  1110  as a single piece; it is entirely possible that the drywall could comprise multiple pieces (not shown). It is also contemplated that installation of the drywall  1220  might be delegated to drywaller or other tradesman distinct from the panel installer. Nevertheless, the process of installing the panel on one or more wall supports is deemed to include the step of positioning the panel so that it can be approximated in an end-to-end fashion by a piece of wallboard or other wall section. 
     In  FIG. 16C  mesh tape  1230  is applied along the juxtapositions or other approximations between edges of the panel  1110  and edges of the drywall  1220 . Here again, this step is usually delegated to a professional drywaller, but could be accomplished by the installer of the panel, regardless of which person actually does the work. 
     In  FIG. 16D  the mesh tape is covered by a spackling compound, and is ready for painting, wallpapering, or other surface coating. Preferably, the spackling compound is smoothed over the entire front surface of the panel to the lips of opening  1120 . As used herein, the terms “spackle” and “spackling” should be interpreted as broadly as possible, to include for example plaster and plastering of any type. One objective is to provide a smoothed out surface that completely or substantially hides the joints between edges of the panel and edges of the drywall 
     In  FIG. 16E , the spackle shield is removed from opening  1120  and a component can be installed in the new uniform wallboard  1220 . 
     In  FIG. 17A  an installation  1700  generally includes wallboards  1710 ,  1720 , an opening  1714  on structure  1710 , and a panel assembly  1730  that will installed into the space  1714 , as shown by arrow  1740 . 
     As used herein, the term “assembly” means an object that has multiple components or functional portions. Thus, the term comprises: (a) multiple pieces that are coupled together in some manner, either temporarily or permanently; and also (b) a single molded object with multiple functional components. By way of example, panel assembly  1810  in  FIG. 18  is a panel assembly molded as a single piece. 
     In typical installations, the wallboards  1710 ,  1720  would be adjacent vertical walls, or a vertical wall and a ceiling, and  FIG. 17A  should be interpreted to include all such embodiments. Thus, for example, where wallboards  1710 ,  1720  are interpreted to be vertical walls, members  1712 ,  1722  could be studs. Where wallboard  1710  is interpreted as a ceiling, members  1712  could be joists, and members  1722  could be horizontal struts. Although the portions of the wallboards  1710  and  1720  are depicted in the figure as substantially flat, those skilled in the art will appreciate that the structures could be curved, or have curved portions. In addition, those skilled in the art will appreciate that wallboard  1710  could exist independently of wallboard  1720 . 
     Wallboards  1710 ,  1720  would typically comprise drywall, which term is used herein generically to include all manner of wallboard, fiberboard, gypsum board, GWB, plasterboard, Sheetrock® and Gyproc®, and so forth. Additionally or alternatively, wallboards  1710 ,  1720  could comprise other materials, including for example polymers, masonry, ceramics, and acoustic ceiling tile materials or other composites. 
     Wallboards  1710 ,  1720  can have any suitable dimensions, from only a few square feet or less, to hundreds of square feet or more. Wallboards  1710 ,  1720  will usually, however, have relatively small thicknesses of between ¼″ and 1″ in thickness. 
     Panel assembly  1730  can be produced at a job site, for example, by cutting a hole out of a piece of drywall. The piece being used in such instances can be cut out from an existing vertical wall or ceiling, and or can be completely new to the job site. Either of those methods could work adequately for drywall, acoustic ceiling tile and other materials that are fairly easy to cut, but for difficult to cut materials, including for example polymers, masonry, and ceramics, the panel assembly can be most conveniently produced in a factory where the panel is dried or cured around a form (see  FIG. 18 ) to define the opening. 
     As discussed above with respect to  FIGS. 11-16 , the opening  1734  of  FIG. 17A  can be any suitable size, shape, or number. As currently contemplated, it is desirable that the total front facing area consumed by the opening be relatively small with respect to that of the panel  1732 . That ratio is preferably at least 3, more preferably at least five. Viewed from another perspective, it is preferred that the panel  1732  extend in at least one direction at least 3 inches (7.62 cm) from the closest edge of the opening  1734  for light or other simple switches, electrical outlets and so forth, and at least 5 inches (12.7 cm) for lights, more complicated switches and other controllers, speakers and so forth. Where the component has a front-facing surface area of at least 25 in 2  (about 160 cm 2 ), the panel  1732  extends in at least one direction at least 12, 117, or even 24 inches (about 30, 45, or 60 cm) from the closest edge of the opening  1734 . 
     In  FIG. 17B  the panel assembly  1730  has been placed within the space  1714 . There will almost always be some gap between the edges of the panel assembly  1730  and those of the surrounding structural component  1710 , ranging in typical installations from zero (where the panel assembly  1730  is abutted against the structural component  1710 ), and perhaps 1/17″ (3.175 mm) to ¼″ (6.35 mm). Indeed, there will almost always be multiple different gaps around the edge of the panel assembly. Where the workmanship is sloppy, or the project is especially difficult, the gap in some sections can be larger. In addition, it is contemplated that an intermediate member (not shown), as for example a paper, shim, or even a frame can be installed in the gap between the panel assembly  1730  and the structural component  1710 . As long as the edges of the assembly and the wallboard are somewhat near each other, and the gap can be finished and concealed such that an at least superficially continuous junction is established between them, the edges are considered to be approximated. 
     In  FIG. 17C  the approximated edges of the panel assembly and the wallboard have been finished to provide an at least superficially continuous junction. As used herein the term “at least superficially continuous junction” refers to a junction that appears to casual observation to be seamless. By way of example, a good workman-like job in taping and plastering adjacent sections of wall board is considered herein to produce an at least superficially continuous junction, especially where subsequent painting or wallpapering eliminates any seam apparent to casual observation. 
       FIG. 18  is a perspective view of a panel assembly  1810  being formed by pouring a panel material from container  1840  into a mold  1820 . This process brings the poured material right up against the frame portion that defines the opening  1830 , regardless of any irregularity or other difficulties with the shape of the opening. All manner of panel materials are contemplated, including for example curable plastics, and masonry composites. 
     Thus, specific embodiments and applications of concealed locking components for wallboard mounts have been disclosed. It should be apparent to those skilled in the art that many more modifications besides those already described are possible without departing from the inventive concepts herein. The inventive subject matter, therefore, is not to be restricted except in the spirit of the appended claims. Moreover, in interpreting both the specification and the claims, all terms should be interpreted in the broadest possible manner consistent with the context. In particular, the terms “comprises” and “comprising” should be interpreted as referring to elements, components, or steps in a non-exclusive manner, indicating that the referenced elements, components, or steps may be present, or utilized, or combined with other elements, components, or steps that are not expressly referenced. Where the specification claims refers to at least one of something selected from the group consisting of A, B, C . . . and N, the text should be interpreted as requiring only one element from the group, not A plus N, or B plus N, etc.