The present invention relates to the field of electrical outlets, and in particular, to a reorientable electrical outlet.
As the number of electrical appliances in the average household grows, the need for convenient access to numerous electrical outlets grows. Electrical outlets are, of course, well known in the art and typically comprise a face plate, multiple female sockets, and an outlet body.
In a typical residential electrical outlet, the female electrical sockets are fixed in orientation. Such fixed orientation of the socket can reduce the flexibility of the electrical outlet. In some applications, the fixed socket orientation effectively reduces a two-socket outlet to a single-socket outlet.
A variety of techniques have been devised to increase the flexibility of power delivery sockets and plugs. For example, a species of low profile male plugs has been developed that orient the power cord off the axis of the male plug prongs. Rather than extending perpendicularly away from the wall in which the socket is mounted, such power cords extend off to a side or angle and consequently reduce power cord intention into living space or interference with furniture. Such low profile male plugs can, however, reduce the flexibility of the outlet. For example, in polarized socket and plug arrangements, the required directional orientation dictates that the plug be inserted in only one direction. In some cases, particularly in four socket outlets, this can result in power cord interfere with access to other sockets in the same outlet.
There are prior techniques to ensure that the power cord does not overlay other outlet receptacles. Examples of such designs are illustrated in U.S. Pat. No. 4,927,376 to Dickie and U.S. Pat. No. 3,975,075 to Mason. Some of these problems may be resolved by a male plug design in which the cord rotates with respect to the prongs. An example of a rotatable male plug is purportedly shown in U.S. Pat. No. 4,026,618 to Straka. Many of these designs allow free movement between the male plug and power cord around a 360 degree path. The plugs are not, however, designed to be set or held at any particular angular position.
Socket interference can become particularly acute when a transformer for low voltage devices is integrated with a male power socket for direct insertion in a wall outlet. Such box-like transformers may directly block access to other sockets in the outlet face plate.
A conventional electrical outlet ordinarily allows only symmetrical positioning of the multiple female electrical receptacles. Thus, when an integrated male plug-transformer is plugged into one female electrical receptacle of an electrical outlet, an adjacent socket is typically blocked. To mitigate this interference, a multiplug adapter may be inserted into a female electrical receptacle to accommodate multiple male plugs in a given female electrical receptacle of the electrical outlet. Such multiple adapters may present, however, an electrical hazard, in addition to an unsightly mess.
Electrical wiring codes may vary in different parts of a country or from country to country. Some electrical codes require female receptacles in the same electrical outlet box to be positioned horizontally with respect to one another, while other codes require female electrical receptacles in the same electrical outlet box to be positioned vertically with respect to one another. In some instances, electrical appliances can be readily accommodated by an electrical outlet of a certain orientation but may not be suitable for use with electrical outlets oriented at 90 degrees from the given orientation.
Consequently, there is a need for an angularly reorientable electrical socket to accommodate male plugs of a variety of configurations and combinations while remaining substantially fixed at a selected angular orientation.
A reorientable electrical outlet having a housing cavity in a stationary housing and a rotatable electrical female receptacle seated therein is disclosed. Preferably, the rotatable female electrical receptacle includes a set of electrical conductors situated in electrical isolation from one another, arranged one above the other.
In one embodiment, the housing cavity has a set of annular conductive structures formed one above the other to support provide a set of electrically conductive pathways along which slideable contacts rotateably track. Another embodiment places annular conductive structures on the female receptacle. Such structures slideably track on fixed contacts in the housing cavity. The rotatable female electrical receptacle further includes a set of apertures on a exterior top surface aligned with the electrically conductive sleeves for allowing a set of prongs of a male plug to extend through to acquire electrical contact with the electrically conductive pathways via the electrically conductive sleeves.
Two female electrical receptacles 60A and 60B (collectively, “60”) are accommodated in respective receptacle housing cavities 45A and 45B through circular apertures 70A and 70B. Each of female electrical receptacles 60A and 60B exposed surfaces 73A and 73B, respectively.
Circular apertures 70A and 70B having annular conductive contacts 12 (“contacts 12”, “annular contacts 12”) shown in the cutaway view of
Annular contacts 12 may instead be part of receptacles 60A and 60B. In such an embodiment, annular contacts 12 present a rotating surface to fixed contacts on the inner wall or circular apertures 70A and 70B.
Female electrical receptacles 60A and 60B each further include apertures 80, 90, oriented for insertion of a power plug. The depicted apertures 80 and 90 are generally of different size and shape as may be determined by a specific electrical code and/or standard. Each depicted female electrical receptacle 60A and 60B further includes respective ground apertures 100.
In a preferred embodiment, female electrical receptacle 60A with common aperture 80, power aperture 90, and ground aperture 100 forms a female electrical receptacle subassembly. Female electrical receptacle 60A subassembly fits into circular aperture 70A. The diameter of the aperture 70A is slightly larger than the diameter of the female electrical receptacle 60A subassembly.
The female electrical receptacle 60A and 60B subassemblies are preferably constructed in layers held together by axial screws 120. In a preferred embodiment, axial screws 120 are inserted from the bottom of electrical receptacles 60 and terminate under the surface of an insulative cover plate.
In operation, when male plug 95 is plugged into reorientable electrical outlet 20, it can be easily reoriented to a desired angular position by modifying the angular orientation of rotatable female electrical receptacle 60A, thereby allowing an easy deployment of different orientations of a variety of electrical male plugs having varying sizes and configurations.
Although the depicted preferred embodiments of the invention employ two grounded female electrical receptacles, the invention is usable for a variety of female electrical receptacles including those that employ a single receptacle. It should also be recognized that the apertures 80, 90, and 100 in female electrical receptacles 60 can be replaced by any type of similar female socket that allows proper insertion and contact with a mating male-type conductive prongs of a male plug. Moreover, the invention is not limited to use with 110–220 V AC-type or DC-type appliances.
In this embodiment, sleeves 205 and 210 have conductive contacts paths 206 and 211, respectively. Conductive contacts paths 206 and 211 (“contacts”), which each form a conductive path away from the center C of female receptacle 60. Conductive contact paths 206 preferably traverse or extend across at least a small distance radially, away from the center of receptacle 60 toward the annular contacts 12 which are, in this embodiment, disposed around the outer sides of receptacle 60. Other embodiments may have annular conductive contacts disposed toward the center of receptacle 60, with receptacle 60 rotating about such contacts. The outside is preferred. Contact 206 slideably contacts, or leans on, annular contact 12C. The two portions of the depiction labeled 12C are opposing portions of the same annular contact 12. In this embodiment, contact 206 extends across a distance radially from conductive sleeve 205 to annular contact 12C. Such extension may or may not point in a straight radial direction. Contact 206 is disposed at least partially at the vertical level of annular contact 12C.
Sleeve 210 has conductive contact path 211 traversing, or extending, radially from conductive sleeve 210 to annular contact 12 B. Such a path may or may not point in a direct radial direction. Conductive contact path 211 is disposed at least partially at the vertical level of annular contact 12B in a manner devised to avoid mechanical interference with other conductive contact paths or annular rings when female receptacle 60 is rotated about its center C. Preferably, there is no limit to such rotation and receptacle 60 may be rotated a full 360 degrees. Preferably, sleeves 205 and 210 are formed together with conductive contact paths 206 and 211 by bending their constituent metal pieces.
Referring to
One alternative embodiment has no floors 506, and thereby allows connection of a conductive member to a lower portion of annular conductive contact 12.
In this embodiment, portion 502 has slot 504 formed in its upper side for insertion of conductive member 902 (
Referring to
Referring to the preceding Figures, one preferred sequence of assembling a socket 20 according to the present invention is as follows. A bottom portion 502 is provided with annular conductive contacts 12C which are connected to a conductive member 902 placed in slot 504. A first portion 702 is placed atop the bottom portion 502 and provided with annular conductive contacts 12B. A conductive member 902 is placed in the slot 704, in electrical connection with the annular conductive contacts 12B. A second portion 702 is placed atop the first portion 702 and provided with annular conductive contacts 12A. A conductive member 1002 is paced in slot 704 of the second portion 702, and electrically connected to annular conductive contacts 12A. Such connection forms a housing with openings 45A and 45B of each of portions 502 and 702 aligning to form housing cavities.
A first and a second female electrical receptacle assembly 60 are placed in the housing cavities 45A and 45B respectively. Respective electrical connections are made between contacts on assembly 60 and the annular conductive rings as depicted in
The various conductive components employed in the depicted embodiment of the present invention are preferably of brass. However, as persons skilled in the art will recognize, any suitable conductive material can be employed for this purpose. For example, use of brass, copper, steel alloys, and other alloys is prevalent. The employed nonconductive components of the depicted embodiment of the present invention can be of any suitable nonconductive or insulative material including plastic and polyvinyl chloride (PVC). Again, those skilled in the art will appreciate that any suitable nonconductive or insulative material may be employed. For clarity of the present exposition, a simple exemplary reorientable electrical outlet 20 is illustrated, although those skilled in the art will appreciate, reorientable electrical outlet 20 described here is adaptable to a variety of models, configurations and may be devised to include many other types of female electrical receptacles and adapters. For example, the present invention may be embodied in an adapter devised to convert a fixed socket to a reorientable facility.
It should also be understood that, the number, form, and structure of female electrical receptacles are merely examples and not to be construed as design limitations required for employment in the present invention. For example, female electrical receptacles 60A and 60B could range from typical residential receptacles, both grounded and non-grounded, all the way up through power strip, 220V receptacles, and up through 480V receptacles including 2, 3, 4, or more prong-receptive designs. These devices can allow for prongs of a variety of male plugs to be inserted into the female electrical receptacles and rotated to any desired positions, so as to allow for non-interfering positioning with regards to other male plugs or other types of restrictions which could preclude the use of any given male plug into an adjacent female electrical receptacle.
In an alternate embodiment of the present invention, female electrical receptacles may be devised to include only oppositely disposed apertures oriented for insertion of conventional power and common prongs of an exemplary non-polarized male plug. Such a two-prong male plug-receptive design of the female electrical receptacles requires no outer concentric annular conductor supporting structure component for the absent ground prong, which is present in the case of the three-prong male plug-receptive preferred embodiment.
In this embodiment, central support portion 1202 is assembled with conductive sleeves 205, 210, and 215 inserted into the depicted slots, and annular conductive contacts 12 abutting ledge 1208. Lower portion 1204 fits onto central support portion 1202 to lock the lower depicted contact 12 into place. Similarly, slotted cap 1206 fits onto central support portion 1202 to lock the upper depicted contact 12 into place. In this embodiment, sleeve 215 has lower contact portion 1210 for electrically connecting to conductor 1304 (
Although the embodiments herein have been described in detail, it will be apparent to those skilled in the art that many embodiments taking a variety of specific forms and reflecting changes, substitutions and alterations can be made without departing from the spirit and scope of the invention. The described embodiments illustrate the scope of the claims but do not restrict the scope of the claims.
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Number | Date | Country | |
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20060110946 A1 | May 2006 | US |