Not applicable.
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Not applicable
Households and businesses are supplied with 120-volt alternating current (AC) for use in providing electrical power to a number of devices, including small appliances and lighting. AC is typically supplied to a receptacle in a wall outlet. When the need for electrical power is located at a distance from the wall outlet, an extension cord may be used to deliver the power to where it is needed. One end of the cord plugs into the wall outlet receptacle, and the opposing end of the cord provides a receptacle for use in connecting the electrical load.
Not all electrical loads require AC. Some require direct current (DC). DC can be obtained from a wall outlet using a rectifier to rectify the AC. Many consumer electronic devices such as computers and cordless telephones use DC instead of AC.
The range of devices using AC or DC varies considerably and is growing. The number of devices that may be plugged into a wall outlet receptacle is limited. Various devices exist to increase the number of receptacles and in some cases a series of loads have their own receptacles.
For example, strings of holiday lights have a plug for the AC wall outlet at one end and a receptacle at the other end so that additional strings can be plugged into and thereby powered by the first string. This arrangement is not without its problems. The current that can be drawn by several strings put together can pose a hazard. Accodingly, many holiday light strings carry a fuse to limit current. However, when up to three strings are connected together the fuse used to limit current must still pass considerable current, perhaps six or seven amperes. Consequently, consumers who may use more than three strings to decorate have to use at least two receptacles and still run the risk of an electrical hazard.
Strings of holidays lights have been developed by the present inventor that operate on DC rather than AC. These strings have rectifiers in the plug or the first light socket that convert the incoming AC to DC and provide fuse protection for the circuit.
As the nature and variety of appliances and uses for electricity increases, so too does the desire to control use so that products are not damaged and good use is made of the electricity consumed. Also, there is greater interest in the measurement of electricity consumed. Thus, there is a need for a device that provides a convenient source of electrical current, including AC or DC, and potentially offers unprecedented control over the current being used.
The present invention is a device for delivering electrical current. In one embodiment, it is an extension cord with a receptacle on one end that allows control and monitoring of the electrical current it delivers to the device plugged into its receptacle. In another embodiment, it is a three-wire AC extension cord that provides electrical power to a first load while delivering AC to a second electrical load plugged into it. In a modification of this embodiment, the first load is a DC load such as a string of lights.
The present invention comprises a plug connected to a receptacle using three electrically conducting wires: a line wire, a neutral wire and a third wire that simply terminates in the plug without electrical contact there. The receptacle has an on-board power control device that is arranged electrically in parallel with the receptacle's contacts. The power control device delivers electrical power to a load attached to the neutral wire and the third wire. Depending on the configuration of the power control device, the electrical power can be AC or DC, can be fused, stepped down in voltage, or can be controlled in other ways.
A feature of the present invention is the on-board power control device. This device serves as a “mother board” for a wide range of applications without modification of the balance of the device. Furthermore, because it is easily replaceable and may have “daughter boards,” can be used to adapt the present device for other uses.
Another feature of the present invention is the manner in which the power control device taps into the power of the line and neutral wires, or just the neutral wire, to provide the desired control to the third wire.
Still another feature of the present invention is the ability to provide a separate fuse for the third wire load. In the context of a holiday light string, the ability to fuse each string separately makes it possible to use more than three strings in sequence and to use fuses with smaller ratings for each string. This feature means each light string is safer.
These an other features and their advantages will be apparent to those skilled in the household electrical arts from a careful reading of the Detailed Description of Preferred Embodiments, accompanied by the following drawings.
In the drawings,
The present invention is a device for use in delivering electrical current to one or more loads. One load may be powered directly by the device and, indeed, may be incorporated into the device. The other load is plugged into the device and is thus powered indirectly.
As shown in
Wires 20, 22, 24, are all electrical conductors insulated from the environment and each other, and are preferably formed as a flat “ribbon.” First wire 20 is a line conductor; second wire 22 is a neutral conductor; and third wire 24 supplies electrical current directly to a load, as will be described herein.
Receptacle 14 includes a housing 40 with a power section 44 and a fuse section 48. Power section 44 slides into fuse section 48, as shown, but with minor modification, fuse section 48 could be made to slide into power section 44. When power section 44 is fully seated in fuse section 48, the two are secured together with a locking screw 50. First, second and third wires 20, 22, 24, enter housing 40 through power section 44; two holes 56, 58, formed in fuse section 48 are dimensioned for receiving the prongs 62 of a plug 64 from an electrical appliance or other electrical load.
As shown in
In fuse section 48 are three more channels. A first channel 106 contains a buss bar 110 with a spring contact 112 in electrical connection, and preferably also integrally connected, to it. Spring contact 112 is adapted to be resiliently urged to the side but remain engaged with one prong 62 of plug 64 that enters hole 56.
A second channel 118 has a fuse holder 122, holding a fuse 124, and also, connected electrically and preferably integrally, a spring contact 126 that operates in an manner similar to that of spring contact 112. The choice of fuse 124 will help to limit the current passing therethrough in the event of a power surge or demand that exceeds that rating of the circuit.
Note that fuse 124 and buss bar 110 extend beyond fuse section 48 toward power section 44 so that, when fuse section 48 and power section 44 are joined, buss bar 110 and fuse 126 make contact with first and second terminals 86, 88m at the bottoms of channels 94, 98, respectively, and, thus form two electrical paths. The first path runs from first wire 20, through terminal 86 and buss bar 110, to spring contact 112. The second path runs from third wire 24 through terminal 88 and fuse 124, to spring contact 126. These paths can be used to deliver fused AC from plug 10 to an electrical device plugged into receptacle 14.
As power and fuse sections 44, 48, are separated, note that buss bar 110 and fuse 126 remain with fuse section 48 and break contact with terminals 86, 86, respectively. Terminals 86, 88, because they are deep in channels 94, 98, are not likely to cause injury to a user who may be separating the two sections in order to change fuse 126, replace buss bar 110 with a fuse, fuse holder and spring contact, or replace a power control board 130, the function of which will shortly be described.
Power control board 130 is a small circuit board that may hold electrical components and microprocessors selected for particular functions. The choice of components will dictate how board 130 controls power to third wire 24 and, when desired, to first and second wires 20, 22, as well.
A first end 134 of control board 130 is received power section 44 in channel 102 and held in place by four supports 142. Its second end 146 extends from power section 44 when power section 44 has been separated from fuse section 48 but, when they are joined, will be received in a channel 152, located between channels 106 and 118 of fuse section 48, where another four supports 154 help to hold control board 130 in position.
Control board 130 is maintained in electrical connection with first and second terminals 86, 88, using terminal connectors 160 of the type illustrated in FIG. 9. These have a saddle section 162 that engages the end of a wire, a flexing cap 168 to receive the end of a buss bar or fuse, and a board contact 170 for contacting or gripping components on control board 130.
A terminal connector 174 of the type shown in
Power control board 130 may have any of the following functions. It may facilitate the delivery of AC or DC power to third wire 24 either with full voltage or stepped down; it may cause that power delivered to third wire 24 to vary in voltage or to pulse or to switch on and off in response to a computer program, in response to sensors, or on command. The commands can be based on a local switch carried by receptacle 14 or a remotely transmitted signal. Power control board 130 may control the voltage across first and second wires 20, 22, as well. Power control board 130 may also monitor the electrical power passing through wires 20, 22, 24.
An example of the use of power control board 130 is shown in FIG. 12. The device shown in
The load on string 192, namely, the series of lights 208, is separately fused, as could be each of three or more additional strings connected to string. If lights are low watt, efficient bulbs, up to six strings of lights can be strung together operating from power from a single wall receptacle, with low rated, one ampere fuses limiting the current in each string.
It will be apparent to those skilled in the art of electrical appliance power supplies that many modifications and substitutions can be made to the foregoing preferred embodiments without departing from the spirit and scope of the present invention, defined by the appended claims.
Number | Name | Date | Kind |
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3968355 | Smallegan | Jul 1976 | A |
4717350 | Lax | Jan 1988 | A |
5371441 | Nilssen | Dec 1994 | A |
6132257 | Wang et al. | Oct 2000 | A |
6190207 | Wang | Feb 2001 | B1 |
Number | Date | Country | |
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20040166735 A1 | Aug 2004 | US |