Temperature overloads typically occur due to a problem at the terminals of an electrical receptacle, where wires are attached to the receptacle. When the attaching wires are improperly connected, such as being too loose, there is unexpected electrical resistance. In some cases, the metal of the attaching wires is different than the metal of the electrical receptacle, causing a resistance mismatch.
When a receptacle includes only one thermal sensor, if the thermal problem is close to the sensor, the thermal overload circuitry will be properly triggered. However, if the thermal problem is not close to the sensor, then the thermal overload circuitry has a high risk of not triggering properly due to heat conduction issues. For example, brass, commonly used in receptacles, is a poor heat conductor, while copper, silver and gold are good heat conductors.
If a receptacle having only one thermal sensor is fitted with heat conducting bridges between respective terminals and the thermal sensor, desired triggering is still not achieved due to differences in resistance and symmetry among the bridges.
Each thermal sensor comprises an L-shaped bimetal, a spring located at the base of the bimetal, the axis of the spring being perpendicular to the plane of the bimetal, and a housing for the spring. During operation, the spring is held in place by the horizontal base of the bimetal. When the temperature of the bimetal exceeds a threshold, the base flips to another configuration, releasing the spring.
A shut-off mechanism comprises a shot pin, a vertical spring, two contacts and a latch. The latch is coupled to the thermal sensors so that when one of the thermal sensors triggers, the latch moves to release the vertical spring, and the vertical spring causes the shot pin to pop upwards, separating the contacts and interrupting operation of the receptacle.
Electrical receptacle 1 has load conductor 2; neutral conductor 3; hot conductor 109 having ramp 8; enclosure 5; contact plate 6; shot pin 20 with circular groove 16, base 17, lip 18 and trip part 10 having arm 22; horizontal spring 14; vertical spring 15; latch 30 with L-shaped end 32, U-shaped end 34, and oval opening 36; support base 40 with groove 45; first contact 50; second contact 52; bimetals 60, 70, 80, 90, 100; housings 62, 72, 82, 92, 102; horizontal springs 64, 74, 84, 94, 104; screws (also referred to as terminals) 66, 76, 86, 106; and plug prong contact pairs 68, 78, 88, 98; and hot terminal plate 108.
Electrical receptacle 1 accommodates two plugs. A top plug (not shown) has two prongs that insert into plug prong contact pairs 68 and 88. A bottom plug (not shown) has two prongs that insert into plug prong contact pairs 78, 98. During normal operation, current flows from hot terminal 106 to screw plate 108 then to hot conductor 109 through contacts 50, 52, then via load conductor 2 to load terminal 86, and/or plug prong contact pairs 88, 98, then to the connected device (not shown) plugged into the receptacle, and back to neutral plug prong contact pairs 68, 78 and/or neutral terminals 66, 76, in a generally similar manner as a standard ground fault circuit interrupt (GFCI) receptacle (not shown).
Electrical receptacle 1 has five thermal sensors.
A first thermal sensor comprises bimetal 60, housing 62 and spring 64, and is responsive to temperature changes at screw 66 and plug prong contact pair 68 that are in contact with neutral conductor 3.
A second thermal sensor comprises bimetal 70, housing 72 and spring 74, and is responsive to temperature changes at screw 76 and plug prong contact pair 78 that are in contact with neutral conductor 3.
A third thermal sensor comprises bimetal 80, housing 82 and spring 84, and is responsive to temperature changes at screw 86 and plug prong contact pair 88 that are in contact with load conductor 2.
A fourth thermal sensor comprises bimetal 90, housing 92 and spring 94, and is responsive to temperature changes at load plug prong contact pair 98 that is in contact with load conductor 2.
A fifth thermal sensor comprises bimetal 100, housing 102 and spring 104, and is responsive to temperature changes at screw 106 that is in contact with hot terminal plate 108 that is in contact with hot conductor 109.
Electrical receptacle 1 has a shut-off mechanism, also referred to as a shot pin trigger assembly, comprising shot pin 20, trip part 10, vertical spring 15, contacts 50, 52 and latch 30.
Shot pin 20 is positioned vertically in oval opening 36 of latch 30. At approximately its midsection, shot pin 20 is enclosed by trip part 10 having arm 22. Vertical spring 15 is coiled around shot pin 20 underneath trip part 10. Base 17 of shot pin 20 has circular groove 16. In the un-triggered position, bottom lip 18 of circular groove 16 engages with the bottom edge of oval opening 36, and horizontal spring 14 exerts force on the inside of U-shaped end 34 of latch 30 to pull oval opening 36 so as to engage circular groove 16 in base 17 of shot pin 20, thereby restraining shot pin 20, i.e., keeping shot pin 20 in an un-triggered state.
When the temperature of bimetal 100 in the thermal sensor associated with hot terminal plate 108 exceeds a predetermined temperature threshold, the horizontal part of L-shaped bimetal 100 moves upward allowing spring 104 to push housing 102 into latch 30, opposite to and overcoming the force of horizontal spring 14, thereby removing the restraining edge of oval opening 36 from circular groove 16 in base 17 of shot pin 20, and enabling vertical spring 15 to pop shot pin 20 upwards, moving ramp 8 on hot conductor 109 to disconnect contacts 50, 52, which disconnects load plug prong contact pairs 88, 98 and/or load terminal 86. After shot pin 20 triggers, its top is visible, serving as an indication that the temperature of the receptacle has become too hot for operation. After turning off, the receptacle remains permanently non-conducting.
The other four bimetals serve to allow shot pin 20 to pop in similar manner, except housings 62, 82 serve to pull latch 30 whereas housings 72, 92, 102 serve to push latch 30, as best seen in
Table 1 compares the exterior dimensions, in inches, of receptacle 1, a standard dual outlet receptacle and a ground fault circuit interrupt (GFCI) dual outlet receptacle. With reference to
In the above-described embodiment, the bimetals are shown as being L-shaped. However, any other shape such as straight or domed is also usable. In these cases, other elements of the receptacle are adjusted accordingly.
An embodiment with four thermal sensors is similar to the above-discussed embodiment with five thermal sensors, except that bimetal 90 is absent, leaving bimetals 60, 70, 80, 100 corresponding to screws 66, 76, 86, 106. Thermal detection efficiency generally improves with the number of bimetals used.
The present temperature sensing features could be added to a GFCI receptacle.
It is desirable that the benefits of thermal overload protection be available even when conventional outlets are used. Embodiments wherein a portable device with thermally protected receptacles is plugged into a conventional outlet will now be discussed.
Protruding from the back of receptacle adapter 200 are neutral blade 201, load blade 202 and ground blade 203, referred to as a set of blades, which are intended to be plugged into a conventional outlet. In other embodiments, two sets of blades are provided, so that the receptacle adapter is simultaneously plugged into two conventional outlets.
In operation, an appliance or the like is plugged into one of the outlets in receptacles 210A, 2101B, which in turn is coupled to a conventional outlet. The thermal sensing and power cutoff occurs in receptacles 210A, 210B, as described above with regard to receptacle 1.
In operation, an appliance or the like is plugged into one of the outlets in receptacles 310A, 310B, which in turn is plugged into a conventional outlet. When switch 325 is placed in the on position, load wire 302 of cord 315 is electrically connected to load wire 312. The thermal sensing and power cutoff occurs in receptacles 310A, 3101B, as described above with regard to receptacle 1.
Although illustrative embodiments of the present invention, and various modifications thereof, have been described in detail herein with reference to the accompanying drawings, it is to be understood that the invention is not limited to these precise embodiments and the described modifications, and that various changes and further modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the invention as defined in the appended claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 11/429,169, filed May 4, 2006, having a common inventor and a common assignee herewith.
Number | Date | Country | |
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Parent | 11429169 | May 2006 | US |
Child | 11715224 | US |