An easily-installed cover plate for hiding the face of sockets by covering an electrical outlet, including the face of the sockets. The cover plate is mounted over the receptacle and has apertures for plug blades. In the preferred embodiment, the cover plate is rectangularly shaped to cover a duplex receptacle, having apertures to receive plug blades, a center hole for receiving a screw which secures the cover plate over the duplex receptacle and a thickness at the apertures for receiving plug blades of not more than 0.075 inches.
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0. 1. A cover plate for an electrical outlet having at least one socket with an insulative socket face having plug blade apertures therethrough, the cover plate comprising:
a one-piece cover plate having at least one front surface configured to cover at least one insulative socket face of an electrical outlet, and a back surface region which contacts the at least one socket face when the cover plate is installed on the electrical outlet;
a plurality of plug blade apertures and at least one securing aperture extending from at least one front surface region to the back surface region of the cover plate;
the at least one front surface region having a thickness between the front surface and the back surface region of not more than about 0.075 inches;
wherein the at least one front surface region at least partially defines a plane substantially parallel with the cover plate through which the cover plate cannot extend beyond.
0. 2. The cover plate of
3. The cover plate of
4. The cover plate of claim 1 3, wherein the thickness is between about 0.035 inches and about 0.045 inches.
5. The cover plate of claim 1 3, wherein the back surface region is substantially flat to seat against the at least one insulative socket face.
6. The cover plate of claim 1 3, further comprising at least one alignment structure configured to align the plurality of plug blade apertures of the cover plate with the plug blade apertures of the at least one insulative socket face.
0. 7. A cover plate for an electrical outlet having at least one socket with an insulative socket face having plug blade apertures therethrough, the cover plate comprising:
a one-piece cover plate configured to cover at least one socket face, having a back surface region that contacts the at least one socket face when the cover plate is installed on the electrical outlet, and a front surface, wherein the back surface region is substantially flat to seat against the at least one insulative socket face when the cover plate is installed;
a plurality of plug blade apertures and at least one securing aperture extending through the one-piece plate; and
a front surface region having a thickness between the front surface and the back surface region of not more than 0.075 inches.
0. 8. The cover plate of
9. The cover plate of
10. The cover plate of claim 7 9, wherein the thickness is between about 0.035 inches and about 0.045 inches.
11. The cover plate of claim 7 9, further comprising a plane through which the front surface cannot extend beyond, the plane defined in part by the front surface region and extending substantially parallel to the cover plate.
12. The cover plate of claim 7 9, further comprising at least one alignment structure configured to align the plurality of plug blade apertures of the cover plate with the plug blade apertures of the at least one insulative socket face.
0. 13. A cover plate for an electrical outlet having at least one socket with an insulative socket face having plug blade apertures therethrough, the cover plate comprising:
a one-piece cover plate configured to cover at least one insulative socket face, the one piece plate having a front surface and a back surface region, wherein the back surface region is substantially flat to seat against the at least one insulative socket face;
a plurality of plug blade apertures and at least one securing aperture extending from a front surface region to the back surface region of the cover plate, the cover plate having a thickness between the front surface region and the back surface region at the plurality of plug blade apertures of not more than 0.075 inches; and
a plane defined in part by the front surface region and extending substantially parallel to the cover plate through which the front surface cannot extend beyond.
0. 14. The cover plate of
15. The cover plate of
16. The cover plate of claim 13 15, wherein the thickness is between about 0.035 inches and about 0.045 inches.
17. The cover plate of claim 13 15, further comprising at least one alignment structure configured to align the plurality of plug blade apertures of the cover plate with the plug blade apertures of the at least one insulative socket face.
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This application is continuation-in-part of patent application by Shotey, et al. entitled “RECEPTACLE-MOUNTED COVER PLATE TO HIDE ELECTRICAL SOCKET FACE,” Ser. No. 10/853,925, filed on May 25, 2004, which is a continuation of patent application by Shotey, et al. entitled “RECEPTACLE-MOUNTED COVER PLATE TO HIDE ELECTRICAL SOCKET FACE”, Ser. No. 10/283,586, filed Oct. 29, 2002 and issued on Jul. 13, 2004 as U.S. Pat. No. 6,761,582, which is a continuation of patent application by Shotey et al. entitled “RECEPTACLE-MOUNTED COVER PLATE TO HIDE ELECTRICAL SOCKET FACE”, Ser. No. 09/351,761, filed Jul. 12, 1999 and issued on Jan. 28, 2003 as U.S. Pat. No. 6,511,343, which is a continuation of patent application by Shotey, et al. entitled “RECEPTACLE-MOUNTED COVER PLATE TO HIDE ELECTRICAL SOCKET FACE,” Ser. No. 08/775,382, filed Dec. 30, 1996 and issued on Oct. 12, 1999 as U.S. Pat. No. 5,965,846, the disclosures of which are hereby incorporated herein by reference.
1. Technical Field
This invention relates generally to cover plates for electrical outlets and more particularly to a simplified means to cover the face of unattractive electrical sockets and thereby make the outlet more aesthetically pleasing while maintaining proper functionality.
2. Background Art
Conventional electrical outlets are made of several components, including a wall box and a receptacle, which is typically composed of pairs of sockets and a yoke. The receptacle is typically attached to the wall box that is typically attached to a framing member inside the wall, and is accessible through a hole cut in the wall. A cover plate having apertures to allow the sockets to protrude is installed over these components, typically with one or two screws. Electrical devices are plugged in by inserting the plug blades through aligned apertures in the cover plate and socket.
A cover plate is installed after construction. It is common practice to remove the cover plate during remodeling or redecorating so that it does not become damaged or defaced with paint drips and splatters, wallpaper paste, or other decorating materials. The conventional cover plate is easily removed by unscrewing the screw or screws that attach it directly to the receptacle. However, the receptacle is not usually removed during remodeling or redecorating because it is hard-wired into the building's electrical system. Consequently, the receptacle and sockets are left exposed and the face of the sockets become covered with paint splatters and the like. If not cleaned immediately, the face becomes permanently defaced, thereby making the electrical outlet more unsightly and conspicuous. Repeated paintings only make the problem worse. Reinstalling the cover plate then emphasize the paint-splattered surface of the outlet, as the defaced socket surface is compared to the pristine surface of the cover plate.
Cover plates are available in a variety of colors, decorator textures and even covered with wallpaper to match the wall. However, the underlying receptacles and cover plates are made in standard colors, usually beige and dark brown, and unfortunately do not match many decorative cover plates. Because most cover plates allow the face of the sockets to be exposed, such mismatched sockets and cover plates cause the outlets to be more conspicuous. It is desirable, then, to provide a cover plate that can be installed over existing receptacles that covers not only the wall box assembly, but the face of the sockets, too, in order to make the outlet less conspicuous and more attractive.
Decorative cover plates known in the art attempt to make outlets more attractive by attaching a new cover plate to existing cover plates. For example, in U.S. Pat. No. 1,784,277 Darlington describes an ornamental cover for a light switch manufacturable in many colors. The cover is a multilayer pad of adhesively-backed sheets which is adhesively attached to the existing cover plate. When desired, a decorative sheet may be removed, exposing a new sheet. In U.S. Pat. No. 4,312,458, Stewart describes a fabric slipcover for an existing cover plate. In U.S. Pat. No. 3,840,692 Wells describes an outsized cover plate that is screwed over an existing cover plate. Because these decorative cover plates overlay the existing cover plate, these inventions result in a cover that projects farther from the wall than the original cover plate, thereby making the outlet even more noticeable.
More complex devices have been invented to achieve an aesthetically pleasing electrical outlet. For example, U.S. Pat. No. 5,180,886 issued to Dierenbach describes an entire wall box assembly to provide an attractive designer-style appearance. The decorative appearance is achieved with the use of a multi-component cover plate requiring a plurality of attachment means to secure the components in place.
The prior art also describes removable paint shields to protect the sockets and cover plates during painting. In U.S. Pat. No. 5,003,128 Grondin describes a cover that removably adheres to an existing cover plate of an electrical outlet so that the electrical elements are protected during painting. The device completely covers the receptacles such that a plug may not be inserted. Gilchrist describes a paint shield in U.S. Pat. No. 5,285,014 that also covers all exposed surfaces of an electrical outlet. The shield is temporarily attached using suction of adhesives, or with prongs that fit snugly in the socket apertures. While these devices do protect the outlets if installed before painting, they do not remedy the situation where the sockets are already defaced. Similarly, these covers do not provide a means for making the outlets more attractive.
Other patents describe inventions that replace existing cover plates to improve safety of the outlet. In U.S. Pat. No. 5,165,042 Klinger describes a decorative safety cover plate that replaces the existing plate. This invention comprises a base plate and a decorative face plate that slides between a closed position where the sockets are occluded, and an open position where the sockets are exposed. Barla describes a safety cover plate in U.S. Pat. No. 5,240,426 that replaces the existing cover plate. The plate has manually positionable shutters to occlude the entire socket so that plugs may not be inserted. While improving safety, these devices are multi-component parts that are relatively expensive, more difficult to install than a conventional cover plate, and prone to breaking. They also suffer the same problem as the known decorative cover plates: they project farther from the wall than the original cover plate, thereby making the outlet even more noticeable.
In U.S. Pat. No. 5,965,846 to Shotey et al., from which this patent is a continuation-in-part, a cover plate is disclosed having a thickness of 0.080 inches or greater. Cover plates according to this invention with thicknesses of 0.080 inches or greater have been sold. However, it does not teach the use of a cover plate with a thickness less than 0.080 inches.
Accordingly what is needed is a cover plate to cover the socket face of unattractive electrical receptacles and thereby make the receptacle less noticeable while maintaining proper functionality of electrical devices plugged into the covered socket.
This invention provides a simple, easily-installed cover plate that hides the face of sockets by covering an electrical outlet, including the face of the sockets. In particular embodiments, the cover plate may comprise a plurality of plug blade apertures, a front surface, one or more thinned regions on the front surface, and a back surface region that contacts the socket face.
The back surface region may be substantially flat to seat against the insulative socket face. In particular embodiments, the cover plate also comprises an alignment structure to align the plurality of plug blade apertures on the cover plate with the plug blade apertures on the socket face. The alignment is particularly useful in obtaining proper seating of the back surface region against the insulative socket face.
In other embodiments of the present invention, the thinned areas may be of various shapes, including, but not limited to a duplex shape and a decora shape and may be formed using protrusions from the front surface or grooves in the front surface.
The foregoing and other features and advantages of the present invention will be apparent from the following more detailed description of the particular embodiments of the invention, as illustrated in the accompanying drawings.
Referring to
In embodiments of the present invention, the cover plate is specifically designed to cover the socket faces of the receptacle so there are no socket face apertures in the cover plate. For example and referring to
While the shape of the recessed, thinned areas need not coincide with the shape of the socket, the recessed, thinned areas can be manufactured to match the shape of the socket face. The cover plate is stronger and more durable with smaller thinned areas, however. With the more durable embodiment of the cover plate, the cover plate can also protect the receptacle from damage due to rough handling. For example, if a plug inserted into an outlet with a conventional cover plate is yanked out of the wall sideways, that is, substantially parallel to the wall, the forces applied to the sockets can cause the receptacle to be jarred loose or to crack. A cover plate of the present invention can help protect the receptacle because as the plug is pulled sideways from an outlet having the present cover plate, the applied forces in part act on the cover plate, reducing or eliminating the forces on the receptacle. Additionally, as areas of the cover plate are thinned, there is a visible slight variation in the cover plate at the thinned areas. Separating the thinned area by use of grooves or protrusions separates the visible distinction of the thinned area from the rest of the cover plate, rendering the differentiation more inconspicuous.
Referring now to
Also shown in
Exemplary embodiments of the present invention have the thickness 88 within the range of not more than 0.075 inches. It has been found that the conventional thickness of 0.080 inches and larger causes concern among some that sufficient contact will not be made by the plug prongs into the socket. Reduction of the thickness 88 to less than 0.075 inches, and more particularly to a range of 0.020-0.075 inches, permits the plug prongs to extend more fully into the socket, relieving many of those concerns. In particular embodiments of the present invention, a thickness of 0.020 inches may be achieved by use of particular materials, such as, but not limited to, polypropylene and polyethylene. In other particular embodiments, the thickness of 0.020 inches may also be accomplished by use of a vacuum used during the material flow process. As the vacuum evacuates the air within a mold used to form a cover plate, the material forming the cover plate may more easily be drawn into all cavities of the mold. To maximize the strength of the covering surface while minimizing the thickness 88, it has been found that a thickness between 0.030 inches and 0.055 inches reduces the likelihood of structural failure while maintaining the ability to achieve sufficient contact of the plug prongs within the socket. To maximize the contact made by the plug prongs into the socket, it has been found that a thickness within the range of 0.035-0.045 inches provides a substantially maximum contact between the plug prongs and the socket for a covered socket face while providing adequate strength of the covering surface. It will be understood by those of ordinary skill in the art that the ranges of thickness disclosed are for the exemplary purposes of this disclosure and that the present invention is not limited to these ranges.
In particular embodiments of the present invention, the thickness 88 may be accomplished by recessing or reducing the thickness from the back surface of the cover plate. This enables the front surface of the cover plate to not extend beyond the plane defined in part by the one or more thinned regions of the front surface that extends parallel to the cover plate. This vertical plane sets the boundary for which portions of the cover plate should not extend past, allowing for unobstructed insertion of plug blades into the receptacle through the cover plate. While portions of the front face may not extend beyond the vertical plane, they may extend backward. For example, a protrusion may extend from the back surface of the cover plate at the plug blade apertures corresponding to particular recesses on the socket face. This protrusion thereby provides proper alignment of the apertures, allowing the back surface of the cover plate to seat properly against the socket face, while maintaining the vertical plane boundary at the thinned front surface regions of the cover plate. Protrusions extending from the back surface may be used so long as the thickness 88 remains less than 0.075 inches from the front surface of the cover plate to the foremost portion of the socket face seated against the back surface of the cover plate at the plug blade apertures of the cover plate.
Referring to
Cover plates of the present invention may be installed in various manners. Conventional outlets have a threaded receiving aperture centered between the sockets for receiving a screw while other outlets have a pair of receiving apertures placed at opposite ends of the receptacle in the yoke. The present invention may be made to accommodate any underlying receptacle. If necessary to strengthen the cover plate's securing aperture, a protrusion such as the flange 26, shown surrounding the securing aperture 24 in
The number of apertures in the cover plate for receiving plug blades is dependent on the number of blades on the plug. Typically, the number and position of apertures on the cover plate will match the number and position of apertures on the receptacles, although fewer apertures may be used on the cover plate to exclude particular apertures in the socket faces, if desired. Conventional dual receptacle outlets have two sets of apertures, one set for each socket face. In addition to outlets having different numbers of apertures, outlets may have varying numbers of socket faces. For example, conventional outlets have two socket faces and are known as single-gang outlets. Double-gang outlets are also common. The cover plate of the present invention can be made with corresponding number and placement of apertures to match and align with the number of underlying socket faces. Alternatively, cover plates comprising selected aspects of the present invention may be manufactured to include one or more openings for switches or other electrical devices, without limitation, in addition to including one or more thinned front surface regions for hiding socket faces.
The cover plates of the present invention typically have outside dimensions that substantially match a conventional or existing cover plate, but the cover plates herein described may be designed in any desired size and shape to enhance the appearance of the electrical outlet.
The embodiments and examples set forth herein were presented in order to best explain the present invention and its practical application and to thereby enable those of ordinary skill in the art to make and use the invention. However, those of ordinary skill in the art will recognize that the foregoing description and examples have been presented for the purposes of illustration and example only. The description as set forth is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the teachings above without departing from the spirit and scope of the forthcoming claims.
Shotey, Marcus J., Maltby, Edgar W.
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