The present disclosure relates to an electrical receptacle having an antenna configured to at least receive radio frequency (RF) signals for controlling (e.g., powering on/off, etc.) an electrical outlet or socket of the electrical receptacle, and an antenna therefor.
Electrical receptacles may include an antenna that allows for the wireless control of at least one electrical socket of the electrical receptacle. Such antennas are typically provided in the form of a wire. However, electrical receptacles with such antennas do not provide protective features to prevent foreign objects from being inserted into the openings of the receptacle. Such receptacles do not protect against insertion of objects such as paper clips, screwdriver blades, etc. into the receptacle contact openings. Also, it has been found that wire antennas used within electrical receptacles may be susceptible to becoming de-tuned when a cord (e.g., an extension cable, etc.) having considerable length is plugged into the electrical socket.
One embodiment of the invention relates to an electrical receptacle including a housing and at least one socket at least partially disposed within the housing and having at least a pair of entry ports. The at least one socket is controllable by a radio frequency signal. The electrical receptacle also includes an antenna at least partially disposed within the housing configured to at least receive the radio frequency signal used to control the at least one socket. The electrical receptacle further includes at least one tamper resistant device at least partially disposed within the housing. The at least one tamper resistant device is configured to block the entry ports unless a mating electrical plug is inserted into the at least one socket.
Another embodiment of the invention relates to an electrical receptacle including a housing, at least one electrical socket being controllable by a radio frequency signal, at least one printed circuit board at least partially disposed within the housing and a circuit at least partially supported by the printed circuit board. The circuit is configured to control the at least one electrical socket. The electrical receptacle also includes an antenna supported within the housing configured to at least receive the radio frequency signal used to control the at least one electrical socket. The antenna is formed of a sheet material and has a first end and a second end. The first end of the antenna is coupled to the circuit.
Another embodiment of the invention relates to an antenna for an electrical receptacle. The antenna includes a body formed of a substantially flexible sheet material. The body has a first end and a second end. The first end of the antenna is configured to be coupled to a circuit that is configured to be at least partially supported by a printed circuit board at least partially disposed within the electrical receptacle.
Referring generally to the FIGURES, an electrical receptacle 10 and components thereof are shown according to an exemplary embodiment. Electrical receptacle 10 may be installed within or mounted to a wall, a ceiling, a floor and/or any other area or surface where it would be desirable to provide a connection point to a power source. According to the various alternative embodiments, electrical receptacle 10 can include one or more electrical sockets each configured as a two-prong electrical receptacle and/or may be configured as a receptacle other than that of a duplex receptacle (e.g., a single receptacle, a triplex receptacle, etc.). Alternatively, electrical receptacle 10 may include one or more outlets of any suitable configuration. For example, such configurations may include, but not be limited to, NEMA 1-15, 2-15, 5-15, 5-20, 6-15, 6-20, 7-15 or 7-20 configurations.
Electrical receptacle 10 is illustrated as a duplex-type receptacle having a first or upper electrical socket 12 and a second or lower electrical socket 14. Each of electrical sockets 12, 14 has entry ports for receiving a mating electrical plug. One or more of first electrical socket 12 and second electrical socket 14 are configured to be selectively actuated (e.g., powered on/off, etc.) via a wireless control device (e.g., a mobile control device and/or a stationary control device, etc.). For example, the one or more electrical sockets may be controlled by a device that utilizes radio frequency (RF) signals for controlling whether the electrical socket is on or off. According to the embodiment illustrated, first electrical socket 12 is configured to be actuated via a wireless a control device, while second electrical socket 14 is configured to be wired to a main power source such as 110 volts AC. According to the various alternative embodiments, both first electrical socket 12 and second electrical socket 14 may be configured to be selectively actuated via a wireless control device.
Referring to
Rack 24 provides a base or platform for supporting at least some of the components of electrical receptacle 10. According to an exemplary embodiment, rack 24 is a one-piece molded structure formed of a dielectric material, such as plastic, but alternatively, may be formed of any insulating material and provided in any number of pieces. Components can be supported on both a front and back side of rack 24. To support such components, rack 24 includes a number of projections that define a number of cavities, passageways and/or platforms configured to receive and support the components.
Supported at the back side of rack 24 is a first printed circuit board 26 and a second printed circuit board 28. According to an exemplary embodiment, first circuit board 26 includes a logic circuit, while second circuit board 28 includes a power circuit. First circuit board 26 and second circuit board 28 are supported by rack 24 in a spaced apart manner with first circuit board 26 being positioned above second circuit board 26.
To support first circuit board 26, rack 24 is shown as including a plurality of projections 30 (e.g., four, etc.), shown in
Referring to back to
According to the embodiment illustrated, hot current pathway structure 38 includes two separate structures, a first structure associated with the wirelessly controlled first socket 12 and a second structure associated with the always hot second socket 14. For example, hot current pathway structure 38 is shown as including a first structure having a hot input terminal 49, a first hot contact 50 for second electrical socket 14 and a hot output lead 52 coupled to second circuit board 28. Hot current pathway structure 38 is also shown as including a second structure having a hot input lead 54 coupled to second circuit board 28 and a second hot contact 55 for first electrical socket 12. The first structure of hot current pathway structure 38 is configured to be coupled to the power source by having an electrical wire engage a screw and clamp assembly 56 that is threaded into hot input terminal 49. The second structure of hot current pathway structure 38 is configured to be coupled to the power source by having hot input lead 54 soldered to second circuit board 28, which allows the power to first electrical socket 12 to be selectively controlled. According to an exemplary embodiment, hot output lead 52 and hot input lead 54 extend through openings defined in first circuit board 26 and are soldered to second circuit board 28. To support hot current pathway structure 38, rack 24 includes a series of projections provided along a right side of the rack that define a cavity having a shape corresponding to the shape of hot current pathway structure 38. Hot current pathway structure 38 is located to the interior of these projections so that the projections can electrically isolate hot current pathway structure from the other components supported on rack 24. These projections also electrically insolate, at least on the front side of rack 24, the first and second structures of hot current pathway structure 38. Although screw terminals are shown, these may be substituted with any suitable connection structure such as pigtails (or leads), push-in connections, modular connections and the like.
Also supported at the front side of rack 24 is a mounting strap 58 that facilitates the mounting of electrical receptacle 10 to an electrical box (e.g., wall box, etc.). Mounting strap 58 is an elongated member that defines a longitudinal axis of electrical receptacle 10. Referring to
First end tab portion 62 and second end tab portion 64 extend outward from a bottom and top end of the housing of electrical receptacle 10 respectively, while medial portion 60 is substantially encased within the housing. First end tab portion 62 and second end tab portion 64 define one or more apertures 66 for receiving a mechanical fastener (e.g., screw, clip, etc.) that secures electrical receptacle 10 to the electrical box. According to an exemplary embodiment, first end tab portion 62 includes a grounding clip, shown as a self-grounding clip 68 in
To further facilitate an effective grounded connection between electrical receptacle 10 and the electrical box, a ground contact terminal 70 is provided on mounting strap 58. According to an exemplary embodiment, ground contact terminal 70 (shown in
According to an exemplary embodiment, medial portion 60 is, for the most part, relatively narrow when compared to first and second end tab portions 62 and 64. The reduced width of medial portion 60 may advantageously provide additional clearance for the antenna while still providing sufficient strength and rigidity for first and second end tab portions 62 and 64. The reduced width of medial portion 60 may also advantageously provide dielectric isolation or spacing between mounting strap 58 and a live voltage terminal. Medial portion 60 defines a pair of apertures 76 and 78 that are configured to receive the third prong of a standard plug that has been inserted into first socket 12 or second socket 14 for establishing a grounded connection. The width of medial portion 60 is increased in the areas of apertures 76 and 78 to accommodate the apertures. According to the embodiment illustrated, aperture 76 is provided at a bottom end of medial portion 60, while aperture 78 is offset from a top end of medial portion 60. According to the various alternative embodiments, the locations of the apertures may vary depending on the orientation in which a plug is configured to engage first and second sockets 12 and 14.
Referring back to
Referring back to
To support mounting strap 58, rack 24 includes a series of projections that define a central cavity 86 (shown in
Further supported at rack 24 is an antenna 88 configured to transmit and/or receive radio frequency (RF) signals for controlling (e.g., powering on/off, etc.) at one of first electrical socket 12 and second electrical socket 14. According to the embodiment illustrated, antenna 88 is configured to transmit and/or receive RF signals for controlling only first electrical socket 12. Antenna 88 is designed to be an improvement over other antenna designs such as a wire antenna. Specifically, antenna 88 is designed to advantageously reduce the likelihood that antenna 88 will be susceptible to interference and/or become detuned during use (e.g., when an appliance having a relatively long electrical cord is plugged into first electrical socket 12, etc.).
In the case of a wire antenna, wherein the wire antenna is routed just under the face plate of the electrical receptacle, the wire antenna will create a radioactive plane in front of the entire electrical receptacle. As a result, when a plug of an extension cord or any other cable is inserted into a socket of the receptacle, the extension cord creates interference for the antenna and detunes antenna impedance, which ultimately affects the radio performance of the antenna. Further, a wire antenna is likely to be routed along a substantial area under the face plate (including areas around or under the sockets of the electrical receptacle). As a result, when a plug is inserted into the socket, the plug will likely be covering the antenna which may also affect the radio performance of the antenna.
Referring to
Referring to
According to the embodiment illustrated, the radio field of antenna 88 is substantially confined to the area between slots 89, unlike a wire antenna wherein the radio field would extend across an entire front area of the electrical receptacle. Thus, depending on the placement of antenna 88 within the housing, antenna 88 will be able to avoid becoming detuned when a plug of an extension cord or any other cable is inserted into electrical socket 12 or 14. According to an exemplary embodiment, antenna 88 is centrally located relative to rack 24 and is orientated substantially perpendicular to mounting strap 58 and the longitudinal axis of electrical receptacle 10. Such a position allows antenna 88 to avoid being covered by a plug inserted into electrical socket 12 or 14, and also allows the radio field created by antenna 88 to be sufficiently distanced from electrical socket 12 and 14.
Referring to
According to an exemplary embodiment, antenna 88 is designed for the reception and transmission of RF control signals at for example approximately 900 MHz frequency, and preferably 908 MHz frequency. According to the various alternative embodiments, antenna 88 may be designed for the reception and transmission of RF control signals at any of variety of frequencies, including frequencies greater than and less than the 900 MHz frequency provided above. For example, the antenna may be designed to work at any suitable frequency. This may include, but is not limited to, frequencies in the radio spectrum including, but not limited to the range of 3 Hz to 300 GHz. According to the embodiment illustrated, antenna 88 has a length of approximately two inches, a width of approximately 0.3 inches and a thickness of approximately 0.015 inches. Similar to the frequency provided above, these dimensions are provided for exemplary purposes only. According to the various alternative embodiments, antenna 88 may be designed to be any of a number of sizes, including sizes greater than and less than the sizes provided above.
To support antenna 88, an antenna holder 100 is provided. Antenna holder 100 is supported at the front side of rack 24 and is formed of an insulating or dielectric material, such as plastic. Referring to
The shape of antenna holder 100 defines a routing passage for antenna 88 within the housing of electrical receptacle 10 that may advantageously maximize the effectiveness and/or adjustability (e.g., tuning, etc.) of antenna 88. For example, second support section 106 of antenna holder 100 positions an active portion of antenna 88 above mounting strap 58 and the other components supported on rack 24. Also, third support section 108 of antenna holder 100 may optionally have a length that is longer than third portion 98 of antenna 88. Such a configuration may advantageous allow the overall length of antenna 88 to be extended (e.g., for tuning the antenna for different applications, etc.) while still allowing antenna 88 to be supported within antenna holder 100. Further, positioning antenna holder 100 in a central portion of electrical receptacle 100 in an orientation so that antenna 88 extends substantially perpendicular to the longitudinal axis of electrical receptacle 10 may advantageously provide room within the housing for one or more tamper resistant devices as detailed below.
Antenna holder 100 has locking channels 110 provided along each lateral side of first support section 104 and third support section 108 for retaining antenna 88 within antenna holder 100 and against bottom wall 102. Referring to
To retain section portion 96 of antenna 88 against second support section 106 of antenna holder 100, antenna holder 100 includes locking flanges 120. Referring back to
To secure antenna holder 100 to rack 24 such that antenna holder 100 is at least partially disposed in the housing, antenna holder 100 includes a pair of first latching elements, shown as projections 126 having barbs at their distal ends, that are configured to releasably engage a pair of second latching elements, shown as projections 128 having barbs at their distal ends, provide on rack 24. Engagement between projections 126 and projections 128 provides an interference fit that prevents antenna holder 100 from moving outward relative to rack 24.
Further supported on the front side of rack 24 is a light element, shown as a light pipe 130 in
Referring to
Further supported on the front side of rack 24 is a user interface, shown as a push button 140 in
Referring to
According to an exemplary embodiment, push button 140 is a substantially cylindrical member having a substantially circular cross section. At second end 144, push button 140 includes a first annular portion 146 and a second annular portion 148. Second annular portion 148 defines an end surface that extends at least partially through face portion 16 and is configured to be engaged by a user. First annular portion 146 extends radially outward from second annular portion 148 and defines a front surface or shoulder that engages a shoulder formed on face portion 16 to retain push button 140 within the housing when assembled. Push button 140 is configured for axial movement relative to face portion 16 and rack 24 when pressed by a user. According to an exemplary embodiment, a biasing element (e.g., spring, etc.) is provided at first end 142 to return push button 140 to a ready position after being actuated.
Referring back to
An assembled view showing light pipe 130 and push button 140 engaging antenna 88 and antenna holder 100 is shown in
To at least partially enclose and conceal the components supported on the front side of rack 24, sub-face or face portion 16 is provided. Face portion 16 defines first electrical socket 12 and second electrical socket 14 by including entry ports or apertures for receiving the prongs of a male plug. Referring to
Face portion 16 is further shown as including indicia 168 between entry ports 158 and ground plug receiving opening 160 of first electrical socket 12. Indicia 168 can include numerals, letters, symbols or other markings that can be viewed from the exterior of electrical receptacle 10 and which may provide an instructional message to a user. According to the embodiment illustrated, indicia 168 comprises the term “controlled” to instruct a user as to which of the electrical sockets is wirelessly controlled. According to the various alternative embodiments, the indicia may optionally be omitted or appear in any other suitable location.
On a back side of face portion 16, face portion 16 includes four projections 170 configured to nest with and engage back portion 18. Projections 170 define an outer periphery of electrical receptacle 10 and include connection holes 22 configured to receive screws 20. On the interior of the back side, face portion 16 is configured to receive a tamper resistant device that is intended to prevent electric shock if someone attempts to insert a conductive element, other than an electrical plug, into a socket of electrical receptacle 10. According to the embodiment illustrated, face portion 16 is configured to receive a first tamper resistant device associated with first electrical socket 12 and a second tamper resistant device associated with second electrical socket 14. Face portion 16 includes projections for receiving and seating such tamper resistant devices.
Referring to
When an electrical plug having a pair of prongs is inserted into face portion 16 through entry ports 158, slider 174 initially blocks entry into the electrical socket. As the prongs of the plug are inserted further, slider 174 slides into a second position such that aperture 184 comes into alignment with one of apertures 180 and 182. Once slider 174 transitions completely to the second position, slider 174 aligns with entry ports 158 to allow a first prong of the plug to bypass on a side of slider 174 and a second prong the plug to pass through aperture 184. As such, the width of slider 174 is designed such that the other prong gains clearance straight through to the receptacle contact when aperture 184 aligns with one of entry ports 158. In this position, slider 174 presses against leaf spring 176 and is held in the alignment position by the prongs of the plug which are inserted therein. When the prongs are removed, the biasing force of leaf spring 176 urges slider 174 back into the misaligned position.
In the case where an object is inserted into only one of entry ports 158, slider 174 remains confined in the misaligned position or the first position. For example, when an object is inserted into only one of entry ports 158, slider 174 is pushed down towards platform 178 and is confined by a lower rib or projection 186. Thus, even if a determined attempt is made to force the object into only one of entry ports 158, projection 186 blocks slider 174 from movement out of the first position where aperture 184 is misaligned with entry ports 158. The object is thereby prohibited from making contact with a contact of the electrical socket.
Referring to
Face cover 188 includes a substantially planar portion 190 that is substantially similar in appearance to the front surface of cover portion 16. According to the embodiment illustrated, face cover 188 includes entry ports 191 for aligning with entry ports 158 and receiving normal or polarized prongs of a male plug, as well as ground prong receiving openings 192 for aligning with ground receiving openings 160 and to accommodate a three-wire plug. Face cover 188 is also shown as including a light receiving opening 194 for aligning with light receiving opening 162 and accommodating light pipe 130 and a user interface receiving opening 196 for aligning with user interface receiving opening 164 and accommodating push button 140. Light receiving opening 194 and user interface receiving opening 196 are advantageously sized so that face cover 188 can be added to and removed from electrical receptacle 10 without having to remove light pipe 130 or push button 140. Face cover 188 is further shown as including indicia 198 between entry ports 190 and ground plug receiving opening 192 associated with first electrical socket 12. As illustrated, indicia 190 comprises the term “controlled” to instruct a user as to which of the electrical sockets is wirelessly controlled.
To allow for the selective coupling of face cover 188 to electrical receptacle 10, face cover 188 includes one or more projections, shown as connection posts 200, the extend outward from a back side of portion 190. According to the embodiment illustrated, face cover 188 includes four connection posts 200 that are spaced apart around a peripheral edge of portion 190 near the corners. Connection posts 200 are configured to be received by connection openings 202 defined by face portion 16 (shown in
It is important to note that the terms used herein are intended to be broad terms and not terms of limitation. For purposes of this disclosure, the term “coupled” shall mean the joining of two members directly or indirectly to one another. Such joining may be stationary in nature or movable in nature. Such joining may be achieved with the two members or the two members and any additional intermediate members being integrally formed as a single unitary body with one another or with the two members or the two members and any additional intermediate member being attached to one another. Such joining may be permanent in nature or alternatively may be removable or releasable in nature. Such joining may relate to a mechanical and/or electrical relationship between the two components.
It is also important to note that the construction and arrangement of the elements of the electrical receptacle as shown in the exemplary embodiments are illustrative only. Although only a few embodiments of the present invention have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited in the claims. Accordingly, all such modifications are intended to be included within the scope of the appended claims.
The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. Any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and/or omissions may be made in the design, operating conditions and arrangement of the preferred and other exemplary embodiments without departing from the spirit of the present invention as expressed in the appended claims.
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