Abstract:
There is disclosed a self-testing circuit interrupting device which provides uninterrupted power to a load during a complete electronic and electromechanical components self test to allow autonomous periodic automated self testing without damaging or resetting connected load equipment.

Description:
[0001]     This application claims the benefit of U.S. Provisional Application No. 60/711,194 filed on Aug. 24, 2005. 
     
    
     FIELD OF THE INVENTION  
       [0002]     The present invention is directed to the family of resettable circuit interrupting devices and systems which include, without limitation, ground fault circuit interrupters (GFCI&#39;s), arc fault circuit interrupters (AFCI&#39;s), immersion detection circuit interrupters (IDCI&#39;s), appliance leakage current interrupters (ALCI&#39;s), circuit breakers, contactors, latching relays and solenoid mechanisms. More particularly, the present application is directed to an autonomous periodic full function testing system for such devices and systems.  
       DESCRIPTION OF THE RELATED ART  
       [0003]     The electrical wiring device industry has witnessed an increasing call for circuit breaking devices or systems which are designed to interrupt power to various loads, such as household appliances, consumer electrical products and branch circuits. In particular, electrical codes require electrical circuits in home bathrooms and kitchens to be equipped with ground fault circuit interrupters, for example. Presently available GFCI devices, such as the device described in commonly owned U.S. Pat. No. 4,595,894, use a trip mechanism to mechanically break an electrical connection between one or more input and output conductors. Such devices are resettable after they are tripped by, for example, the detection of a ground fault. In the device discussed in the &#39;894 patent, the trip mechanism used to cause the mechanical breaking of the circuit (i.e., the connection between input and output conductors) includes a solenoid (or trip coil). A user controlled manually operated test button is used to test the trip mechanism and circuitry used to sense faults and a manually operated reset button is used to reset the electrical connection between input and output conductors.  
         [0004]     However, instances may arise where an abnormal condition, caused by for example a lightening strike, occurs which may result not only in a surge of electricity at the device and a tripping of the device but also a disabling of the trip mechanism used to cause the mechanical breaking of the circuit. This may occur without the knowledge of the user. Under such circumstances an unknowing user, faced with a GFCI which has tripped, may press the reset button which, in turn, will cause the device with an inoperative trip mechanism to be reset without the fault protection available.  
         [0005]     To insure that the devices are providing the protection that they are designed to provide, they should be tested by the user on a specific schedule and preferably every three or four weeks. This is not only impracticable for a home owner, but a very expensive, time consuming and difficult procedure in a building such as a hotel or large motel where each unit has a bathroom that is equipped with a GFCI which must be tested.  
         [0006]     What is needed is a fault interrupter such as a GFCI which performs autonomous periodic automatic self testing without interrupting power to a connected load during these tests.  
       SUMMARY OF THE INVENTION  
       [0007]     The present invention relates to resettable circuit interrupting devices, such as but not limited to GFCI devices that performs autonomous periodic automated self testing without interrupting power to a connected load if the test is passed and can include a reset lockout mechanism which prevents the resetting of electrical connections (or continuity) between input and output conductors if the circuit interrupter used to break the connection is non-operational or if an open neutral condition exists.  
         [0008]     The circuit interrupting device includes an input conductive path and an output conductive path. The input conductive path is capable of being electrically connected to a source of electricity. The output conductive path is capable of conducting electrical current to a load when electrical continuity is established with the input conductive path. The device also includes a circuit interrupter configured to break electrical continuity between the input and output conductive paths in response to the occurrence of a predetermined condition. Said circuit interrupter may be comprised of electro-mechanical mechanisms, such as movable electrical contacts and solenoids, and/or of semiconductor type switching devices. Predetermined or predefined conditions can include, without limitations, ground faults, arc faults, appliance leakage current faults, immersion faults and a test cycle. The device also includes a microcontroller (or logic circuit) which evaluates the predefined conditions and determines whether or not to activate the circuit interrupter, performs self-tests on the device electronics and electro-mechanical components, and performs other typical logic functions.  
         [0009]     In a first embodiment of the present invention, the circuit interrupter is comprised of two relays wired in parallel to provide power to the load. One relay is the main relay, which is normally energized and the other relay is the auxiliary relay which is energized only when a test is being performed. Each relay is electro-mechanically designed such that if its current carrying members are in the off position they cannot be in the on position, and sensors or additional relay contacts are employed to sense that the relay is in its off position.  
         [0010]     A self test sequence is initiated by moving the auxiliary relay to its on position while the main relay is also in its on position. The main relay is then moved to its off position, verification that the main relay is in its off position is made, and then the main relay is restored to its on position. Finally, the auxiliary relay is restored back to its off position. Should any step fail, a self destruct mechanism is activated to permanently remove power to the load.  
         [0011]     The auxiliary relay may be physically smaller than the main relay, as it need only carry current briefly. One or both of the relays may be under direct control of a fault detector, or they may be controlled by a microcontroller or logic circuit which has a fault detector as an input. To avoid accidental engagement of the auxiliary relay, its control circuit may employ an energy reservoir (such as a capacitor) which is charged slowly before engagement and which discharges quickly to maintain the auxiliary relay in a closed position.  
         [0012]     In a second embodiment, a single relay is provided with two conducting positions (each connected to the same load) and a center-off position. This embodiment allows a single motion to both disconnect and re-connect power to the load, said single motion performed (by the microcontroller or logic circuit) proximate to the power line voltage zero cross. A self test sequence in this second embodiment consists of moving the relay contacts from one conducting position to the other. The slight abnormality of the voltage wave at the load should not disturb connected load equipment, but can be detected by sensors to verify proper relay operation.  
         [0013]     The time delay between electronic activation of the relay and its eventual movement may be design characterized, factory calibrated, and/or automatically adaptively adjusted after installation. Together with a power line voltage zero cross detection circuit, relay movement timing can be precisely controlled to occur proximate to the zero cross. Damping means may be employed to reduce contact landing bounce.  
         [0014]     LED emitter/detector pair, hall sensors, or the load voltage waveform itself may be employed to sense relay position. An additional load may be applied downstream of the relay mechanism, either briefly or continuously, to negate load capacitance while sensing load voltage.  
         [0015]     In a third embodiment of the invention, a single relay and precise timing are employed. A self test sequence consists of causing a brief “hiccup” type of motion of the relay which will very briefly disconnect and immediately re-connect power to the load. This motion is preformed proximate to the power line voltage zero cross. The slight abnormality of the voltage waveform at the load should not cause any disturbance in connected equipment, but can be detected by sensors to verify proper relay operation.  
         [0016]     It is to be noted that a continuously held relay at its near closed position may require a much greater closing force to be applied than the opening force that is required. This difference facilitates very brief disconnect times. Also, it should be noted that regardless of the style of relay used, relay electromechanical characteristics may require that the reconnect signal be applied to the relay even before the disconnect signal has caused a disconnect.  
         [0017]     The time delay between electronic activation of the relay and its eventual movement may be design characterized, factory calibrated, and/or automatically adaptively adjusted after installation. Together with a power line voltage zero cross detection circuit, relay movement timing is precisely controlled to occur proximate to the zero cross. Damping means may be employed to reduce contact landing bounce.  
         [0018]     LED emitter/detector pairs, hall sensors, or the load voltage waveform itself may be employed to sense the relay position. An additional load may be applied down stream of the relay mechanism, either briefly or continuously, to negate load capacitance while sensing load voltage.  
         [0019]     The foregoing has outlined, rather broadly, the preferred feature of the present invention so that those skilled in the art may better understand the detailed description of the invention that follows. Additional features of the invention will be described hereinafter that form the subject of the claims of the invention. Those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiment as a basis for designing or modifying other structures for carrying out the same purposes of the present invention. While the present invention is embodied in hardware, alternate equivalent embodiments may employ, whether in whole or in part, firmware and software. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the invention in its broadest form.  
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0020]     Other aspects, features, and advantages of the present invention will become more fully apparent from the following detailed description, the appended claim, and the accompanying drawings in which similar elements are given similar reference characters, wherein:  
         [0021]      FIG. 1  is a block diagram of a first embodiment of structure in accordance with the principles of the invention;  
         [0022]      FIG. 2  is a chart of the sequence of events during operation of the autonomous periodic automated self test cycle of the embodiment of  FIG. 1 ;  
         [0023]      FIG. 3  is a block diagram of a second embodiment of structure in accordance with the principles of the invention;  
         [0024]      FIG. 4  is a chart of the sequence of events during operation of the autonomous periodic automated self test cycle of the embodiment of  FIG. 3 ;  
         [0025]      FIG. 5  is a block diagram of a third embodiment of structure in accordance with the principles of the invention;  
         [0026]      FIG. 6  is a chart of the sequence of events during operation of the autonomous periodic automated self test cycle of the embodiment of  FIG. 5 ; and  
         [0027]      FIG. 7  is a mechanical drawing of one implementation of the main or auxiliary relay in the first embodiment in accordance with the principles of the invention.  
     
    
     DETAILED DESCRIPTION  
       [0028]     The present invention relates to resettable circuit interrupting devices, such as but not limited to GFCI devices that performs autonomous periodic automated self testing without interrupting power to a connected load if the test is passed.  
         [0029]     Referring to  FIG. 1 , there is shown a block diagram of a first embodiment of structure to obtain autonomous periodic automated self testing of a circuit interrupting device. Line phase  100  and neutral  102  conductors are coupled through differential transformer  104 ,  106  to movable contacts  108 ,  110  of main relay  112  which is a double pole double throw relay. Stationary contacts  114 ,  116 , which cooperate with movable contact  108 , are coupled to main relay sense circuit  118  and the load phase terminal respectively. Stationary contacts  120 ,  122 , which cooperate with movable contact  110 , are coupled to main relay sense circuit  118  and the load neutral terminal respectively. Heat sensitive elements such as fuses  124  can be connected in series with the load phase and neutral conductors. Positioned in close proximity to the fuses is a heating element which is energized by self destruct control  126  which is connected to and controlled by microcontroller  128 . The movable contacts  130 ,  132  of auxiliary relay  134 , which is a double pole double throw relay are electrically connected to the movable contacts of main relay  112 . Stationary contacts  136 ,  140  of relay  134  are connected to covering relay sense which is connected to the microcontroller to indicate the open/close state of the contacts of relay  134 . Auxiliary relay control  146 , which is selectively energized by microcontroller  128 , controls the flow of current to the coil of auxiliary relay  134 . Main relay control  148 , which is selectively energized by microcontroller  128 , controls the flow of current to the coil of main relay  112 . Load sensor  150  is connected across the load phase and neutral conductors and is connected to indicate the presence or absence of voltage at the load conductors to microcontroller  128 . A fault inducer  152  which is controlled by microcontroller  128  is connected to induce a fault in the line phase and/or neutral conductors for sensing by the differential transformers  104 ,  106 . Fault detector  154  is connected to send a fault signal to microcontroller  128  upon sensing a fault in the differential transformers. Power supply  156  is provided to supply power to the microcontroller and each of the other circuits as required. Fuses  124  are used to disconnect the load from the line terminals.  
         [0030]      FIG. 2  is a chart of the sequence of events during operation of the autonomous periodic automated self test operation of the embodiment of  FIG. 1 . It is to be noted that  FIG. 2  is self explanatory and, therefore, in the interest of brevity, the various steps of the cycle as shown in  FIG. 2  will not be further described.  
         [0031]     Continuing with  FIGS. 1 and 2 , the steps of the self test sequence is as follows; 
        Verify the fault detector is reporting no fault;     Induce a fault;     Verify the fault detector reports a fault;     Deactivate fault inducer;     Verify the fault detector no longer reports a fault;     Verify that the main relay is in its on position;     Verify that the auxiliary relay is in its off position;     Verify that load power is present;     Move auxiliary relay to its on position;     Verify that the auxiliary relay is in its on position;     Move main relay to off position;     Verify that the main relay is in its off position;     Verify that load power is present;     Move main relay back to its on position;     Verify that the main relay is back in its on position;     Move the auxiliary relay back to its off position;     Verify that the auxiliary relay is back in its off position;     Verify that load power is present.        
 
         [0050]     It is understood that one or more of the steps above may be eliminated and/or other steps may be included, and that electronics tests including those involving the fault detector are largely independent of the electromechanical tests (of the relay mechanism) and can therefore take place before, during, or after such electromechanical tests.  
         [0051]     If any of the above itemized steps is negative or times out, either the relay control mechanisms  146 ,  148 , or the self destruct control  126  can be employed to remove power from the load. If the self destruct control  126  is employed, fuses  124  which are in series with the phase and neutral conductors are raised to a high temperature using a heating element such as a resistor which can be sandwiched between and used to heat the fuses until they melt. The fuses and the heating element can be located in an insulating wrapper.  
         [0052]     Referring to  FIG. 3 , there is shown the block diagram of a second embodiment of structure for autonomous periodic automated self testing a circuit interrupter; and  FIG. 4  which is a chart of the sequence of events during operation of the autonomous periodic automated self test operation of the embodiment of  FIG. 3 . The event sequence in  FIG. 4  is self explanatory and, therefore, in the interest of brevity, a further narrative description of the various steps of the cycle as shown in  FIG. 4  would only be repetitious and, therefore, is not here provided. Referring to  FIG. 3 , the various blocks of circuits which are common with the blocks of circuits of the first embodiment shown in  FIG. 1  will not again be referred to in this detailed description. In the embodiment of  FIG. 3 , instead of using two relays connected in parallel, a single relay is used which has a center off position and two conducting positions where each position is connected to the same load. This embodiment allows a single motion to both disconnect and reconnect power to the load, thereby minimizing the time during which the load is disconnected from power. Referring to  FIG. 3 , the single motion is performed proximate to the power line voltage zero cross. A self test sequence consists of moving the relay contacts from one conducting position to the other. Relay sense  162  is employed to verify the relay indeed moved from one conducting position to the other. The slight abnormality of the voltage waveform at the load will not disturb equipment connected to the load conductors, and is detected by load sense  150  to verify proper relay operation. To accommodate capacitive loads, which would slow down rapid changes of voltage, load load  151  is activated by microcontroller  128  as needed to bleed excess charge off the load thereby allowing load sense  150  to accurately detect the slight abnormality of the load voltage waveform. The time delay between electronics activation of the relay and its eventual movement may be design characterized, factory calibrated, and/or automatically adaptively adjusted after installation. Together with power line voltage zero cross detector  164 , relay movement is precisely controlled to occur proximate to the zero cross. Damping means may be employed to reduce contact landing bounce. LED emitter/detector pairs, hall sensors, or the load voltage waveform itself may be employed to sense relay position. An additional load (for example load load  151 ) may be applied downstream of relay mechanism  160 , either briefly or continuously, to negate load capacitance while sensing load voltage.  
         [0053]     Referring to  FIG. 5 , there is shown the block diagram of a third embodiment of structure for autonomous periodic automated self testing a circuit interrupter; and  FIG. 6  which is a chart of the sequence of events during operation of the autonomous periodic automated self test operation of the embodiment of  FIG. 5 . The event sequence in  FIG. 6  is self explanatory and, therefore, in the interest of brevity, a narrative description of the various steps of the cycle as shown in  FIG. 6  would only be repetitious and, therefore, is not here provided. Referring to  FIG. 5 , the various blocks of circuits which are common with the blocks of circuits of the first embodiment shown in  FIG. 1  will not again be referred to in this detailed description. In the embodiment of  FIG. 5 , a single relay  170  and precise timing are employed. A single test sequence, see  FIG. 6 , consists of causing a brief “hiccup” motion in the relay  170  by using the relay control  172  to disconnect and immediately thereafter reconnect power to the load. This motion is performed proximate to the power line voltage zero cross which is determined by zero cross detector  164 . The slight abnormality of the voltage waveform at the load should not disturb connected equipment, and can be detected by load sense  150  to verify proper relay operation. When using this embodiment, it should be noted that a relay that is continuously held at its near closed position may need a greater force to close than is needed to open. Additionally, regardless of the style of relay used, relay electromechanical characteristics may require that the reconnect signal is issued to the relay before the disconnect signal has caused a disconnect. The time delay between electronics activation of the relay and its eventual movement may be design characterized, factory calibrated, and/or automatically adaptively adjusted after installation. Together with power line voltage zero cross detection by the circuit of box  164 , relay movement can be precisely controlled to occur proximate to the zero cross. Damping means may be employed to reduce contact landing bounce. LED emitter/detector pairs, hall sensors, or the load voltage waveform itself may be employed to sense relay position. An additional load (for example load load  151 ) may be applied downstream of relay mechanism  170 , either briefly or continuously, to negate load capacitance while sensing load voltage.  
         [0054]     Referring to  FIG. 7 , there is shown a mechanical drawing of a preferred embodiment of relay  112  or relay  134  of the first embodiment of the present invention. One important feature of this design is that current-carrying members  61 ,  62 , on disk  60  can be verified to have moved to a non-current-carrying “off” position, and when verified to be there cannot possibly be applying power in their current-carrying “on” position. During a self test sequence, microcontroller  128  activates coil  64 , sending piston  65  to hit notch  66  of disk  60 . Disk  60  is forced to rotate one quarter turn about pivot  63 . While “on”, current-carrying members  61 ,  62 , carry current from line terminals  71 ,  72 , to load terminals  73 ,  74 , respectively. While “off”, current-carrying members  61 ,  62 , carry voltage from sense terminals  81 ,  82 , to sense terminals  83 ,  84 , respectively.  
         [0055]     While there have been shown and described and pointed out the fundamental features of the invention as applied to the preferred embodiments, as is presently contemplated for carrying them out, it will be understood that various omissions and substitutions and changes of the form and details of the device described and illustrated and in its operation may be made by those skilled in the art, without departing from the spirit of the invention.