Abstract:
An electric arc detection apparatus and method is based on AC current rectification phenomena in air plasma that causes low frequency amplitude modulation of high frequency currents and voltages in the ballast when disconnecting the lamp (Lamp) from the electronic ballast with power applied. A protection circuit shuts off the inverter of the ballast so the duration of the arc is diminished so that the arc becomes almost non-visible. The protection circuit senses the input of the ballast inverter resonant tank, which is free of transients caused by resonance, detecting arc rectification frequency which is about 25-30 times less than the inverter carrier frequency, and turns on a switching device for stopping oscillations in the inverter. When the lamp (Lamp) is reconnected to the ballast, it resets the protection circuit and the ballast inverter restarts automatically.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to electronic ballasts for powering a high frequency electrodeless fluorescent lamp. An electric arc appears in the lamp connector when disconnecting the lamp under power. It is destructive to the ballast and dangerous to the personnel replacing lamps. Also, arcing may be caused by poor connections in the fluorescent lamp wiring or disconnecting of crimped wire from the connector and may create a fire hazard. 
     2. Description of the Related Art 
     Since the fluorescent lamp is powered from a current source with high operating frequency (250 kHz or more), such as a self oscillating DC to AC inverter, a stable arc path is established between connector pins or between the connector pin and a lamp wire, even if two separated portions are placed by a distance of up to 1-2 inches from each other. At high frequency, recombination time of particles (electrons and ions) in arc plasma becomes comparable with AC frequency. When crossing zero current, it is not enough time for particles to be recombined in gas molecules and to stop the current flow and cancel the arc. Therefore, it should be done artificially by stopping oscillation in the ballast inverter with a shut down circuit susceptible to the arc. 
     There are a few known drawbacks, however. When the arc appears in the connector, there is no actual change in ballast high frequency voltages and currents that could be used for arc detection, as the voltage drop across the arc is negligible in relation to lamp rated voltage. Additionally, there is a large increase in ballast voltages and currents during normal lamp starting and they are also effected by low frequency 100/120 Hz steady-state modulation caused by the AC line rectifier. To avoid false responses, the arc detection circuit should not be susceptible to all of these disturbances, which occur during normal lamp operation. 
     The prior art teaches arc cancellation in the lamp connector by mechanically interlocking the ballast inverter when unplugging the lamp. In some ICETRON/ENDURA electrodeless lamps, additional pins are used in the connector to disconnected some components of the ballast inverter without which oscillations in the inverter cannot exist. However, the required three-wire connector is thick, expensive, and not applicable for a lamp that is placed a distance from the ballast. 
     Other references disclose different sensing means for arc detection, but they are only associated with low frequency AC devices, like electrical welding equipment, and not applicable for an arc in high frequency ballasts. Furthermore, the purpose of such devices is arc stability. In contrast, the purpose of the present invention in a ballast is arc cancellation. 
     Therefore, a protection method and circuit with fast arc cancellation capability is still needed. Another feature of the protection circuit should be a reset capability for restarting a reconnected lamp. The protection circuit is also required in the event that the ballast is mistakenly turned on without a lamp. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 a  illustrates arc current and ballast output voltage plots in transition from regular operation to arc condition caused by unplugging an electrodeless lamp. 
     FIG. 1 b  illustrates the same parameters as those in FIG. 1 a  at a point when current rectification in the arc is starting. 
     FIG. 2 shows a ballast circuit diagram with a block diagram of an arc detection and cancellation circuit of the present invention. 
     FIG. 3 shows a circuit diagram of ballast with a self oscillating inverter and an arc cancellation circuit. 
     FIG. 4 shows an arc detection and cancellation circuit with a notch filter. 
     FIG. 5 illustrates arc current and output voltage plots of the ballast with arc cancellation, taken when unplugging an electrodeless lamp. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In FIG. 1 a , the upper plot is ballast output voltage V out  and the bottom plot is ballast output current I out  powering a lamp via a connector when the ballast is not provided with arc protection. The left side of the plots represents normal ballast operation with a lamp plugged in to the connector, just starting its movement away from the connector. It is at the very beginning of arcing, when the gap between connector pins is very small, that low voltage can break the gap. As the elements between which the arc has formed move further, the current waveform changes. Small steps are evident in arc AC current I out  at zero crossings. This represents a beginning of the recombination process in plasma. But plasma in the gap still continues breaking in both directions by AC output voltage. 
     As the gap further increases, the recombination process advances, so air-plasma mixture in the gap stops breaking in one direction. This is shown by intervals in which high frequency current pulses follow randomly in one direction only. Depending on the concentration of particles in different spots of plasma, it call be broken in one direction and unbroken in the opposite direction. This means that a connector pin may operate as a cathode and the opposite pin as an anode, or vise versa. Accordingly, when the arc conducts, the ballast resonant capacitor provides extra current to the lamp in one direction and when it does not conduct, the capacitor absorbs extra current in the opposite direction. Therefore, a low frequency component appears in the output ballast voltage V out . 
     Further, low frequency oscillations create a situation in which higher absolute peak voltages are being applied in one direction and lower absolute peak voltages are being applied in the opposite direction. Therefore, the air/plasma mixture has a tendency of breaking in one direction (rectification effect). The low frequency oscillations become relatively stable, as illustrated in FIG.  5 . This system can be classified as an oscillator with negative impedance wherein the air/plasma mixture represents this negative impedance. 
     In the inverter of FIG. 2, low frequency amplitude modulation caused by arc rectification affects almost all voltages and currents in the ballast. However, these voltages and currents are inconvenient for arc detection since they are also affected by resonance during normal lamp starting. According to the invention, inverter resonance tank input voltage V ac  (see FIG. 2) is utilized for detecting the arc in the connector, since this voltage is directly affected by arc rectification and is not affected by resonance. 
     The arc detection method is based on detection of the AC rectification phenomena that characterizes an electrical arc in air-plasma when it is powered from an AC current source. The above method comprises steps of generating an arc through an air gap as a result of disconnecting the lamp from an operating ballast, alternatively rectifying positive and negative ballast voltage pulses by the arc, generating low frequency amplitude modulation of the ballast output voltage, sensing input voltage of ballast inverter resonant tank, determining a low frequency signal of the voltage corresponding to the rectification frequency, filtering out such signal from all other signals applied to the resonant tank, rectifying the signal, and holding energy of the rectified signal for a few of its periods. This resulting signal is utilized to shut down the ballast inverter and cancel the arc. 
     The circuit illustrated in FIG. 2 includes elements of a known ballast circuit including a DC/AC inverter connected between a DC power source and a lamp connector. The DC power source may be a rectified AC source, a battery, or any other source of DC power. 
     The DC/AC inverter includes a capacitor C 25  connected between common and DC voltage +Vbus. Also connected between +Vbus and common are switching transistors M 1  and M 2 . The gates of M 1  and M 2  are separately connected through resistors R 16  and R 15 , respectively, to outputs of an inverter control circuit. The point between M 1  and M 2  is connected to a first terminal of DC capacitor C 1 . A series resonant tank circuit is connected between a second terminal of C 1  and common. 
     The series resonant tank circuit includes inductor L 1  and capacitor C 3 . Lamp connector pins P 6  and P 8  are connected to respective terminals of the series resonant tank capacitor C 3 . A feedback circuit is connected between a point between L 1  and C 3  in the resonant tank circuit and an input of the inverter control circuit. 
     These features of a DC/AC inverter are known in the art. 
     The arc detection and cancellation circuit of the present invention (as illustrated in FIG. 2) includes a low pass signal filter circuit sensing the voltage V ac  at the input of the inverter resonant tank designed to select low frequency voltage signal components that corresponds to arc rectification frequency, a rectifier connected to the output of the filter circuit for rectifying this voltage signal, an energy storage circuit for holding energy of these signals, a threshold device for noise immunity, and a latching switching device for shut down of the inverter and PFC through a disable terminal via diodes D 47  and D 49 . 
     In the embodiment illustrated in FIG. 3, a self oscillating inverter is formed by switching transistors M 1  and M 2  driven by a feedback transformer T 9 , DC capacitor C 1 , and the series resonant tank with inductor L 1  and capacitor C 3 . An electrodeless lamp is connected in parallel to the resonant capacitor C 3  through connector pins P 6  and P 8 . The inverter start circuit comprises a discharge capacitor C 13 , a diac X 28  and a resistor R 6  connected to positive bus rail +Vbus. DC bus voltage is formed by a boost type AC/DC converter. It can be a power factor corrector (PFC), driven by a PFC controller (not shown in FIG.  3 ). An arc detection and shut down circuit comprises a low pass signal filter (R 25 , C 27 ), a rectifier of the low frequency signal caused by the rectification process in the arc (diodes D 44 , D 45 ), a storage capacitor C 28 , a discharge resistor R 27  and, a switching transistor M 4 . 
     An advanced arc detection and shut down circuit illustrated in FIG. 4 comprises a low pass notch filter that is formed as a series combination of a RC low pass signal filter (R 31 , C 29 ) and a low frequency block signal filter (R 33 , C 31 ). This circuit has an input terminal A and an output disable terminal B corresponding to the terminals with the same designations of FIG.  3 . The notch filter is tuned up to pass the low frequency signal generated by the electrical arc. 
     During normal operation of the ballast in FIG. 3, high carrier frequency rectangular voltage V ac  is applied to input A of the arc detection circuit. This voltage is filtered out by low pass filter R 25 /C 27 . As a result, voltage across capacitor C 27  is well below a diode drop voltage and has no effect on the input of the transistor M 4 . When arcing occurs and a low frequency rectification begins in the arc, a low frequency amplitude modulation is superposed on the high frequency voltage V ac . RC filter R 25 /C 27  has a low loss regarding a modulation frequency that is, at least, an order less than that of the carrier frequency, so that frequencies associated with normal lamp operation are filtered out. As an example, in the case of an ICETRON/ENDURA electrodeless lamp having carrier frequency of about 250 kHz, modulation frequency in the arcing connector is in the range of about 8-10 kHz. It creates a low frequency signal at the “A” input having a peak to peak voltage of a few tens of volts that is attenuated by the filter. 
     At least a few volts of the low frequency signal is applied across the diode D 44 . In the circuit of FIG. 3, for reasons of simplicity only a positive wave of the signal charges the capacitor C 28  via the diode D 44 . The negative wave is shorted by the diode D 44 . When voltage across the gate of the transistor M 4  reaches the turn-on threshold of the transistor, the transistor M 4  starts being turned “on” with low frequency. It creates more disturbances at the input “A” of the arc detection circuit as well as higher voltage across the capacitor C 28 , and ultimately stops switching of the transistors M 1  and M 2 . The capacitor C 28  stores voltage that keeps the transistor M 4  in the “on” condition during the recombination process of electrical particles in plasma. When impedance in the air gap changes from low to high, a latching signal from DC bus via the resistor R 24  applies to the input “A” of the arc detection circuit. 
     The diode D 44  can be selected as Zener diode that protects the gate of the transistor M 4  from over voltage. Since Zener diodes have high parasitic capacitance, the capacitor C 29  can be omitted. The shutdown transistor M 4  shorts out the capacitor C 13  through the disable terminal B via a diode D 46  and limiting resistor R 30 , preventing the ballast from restarting the inverter after the shutdown. It also shuts off the PFC controller (not shown in FIG. 3) via a diode D 49  and provides a reset capability. When the lamp is reconnected, it couples input “A” of the arc detection circuit to the “common”, the capacitor C 28  discharges via the resistor R 27 , and the shut down transistor M 4  turns off, releasing the PFC controller and the capacitor C 13  that charges and turns on the diac X 28 . 
     The operation manner of the arc detection circuit of FIG. 4 is similar to that of FIG.  3 . By comparison, the input filter in FIG. 4 provides more noise immunity against transients generated during the inverter start up and against 100/120 Hz ripple coming from the AC line. Beyond that, R 31  and C 29  correspond to the filter formed by R 25  and C 27 ; D 51  and D 50  correspond to rectifying diodes D 44  and D 45 ; C 30  corresponds to storage capacitor C 28 ; R 32  corresponds to discharge resistor R 27 ; and M 5  corresponds to shutdown transistor M 4 . 
     The further useful feature of the arc detection and shut down circuit in FIG. 3 is its ability to interlock the ballast start circuit when the ballast is powered on without a lamp connected. This circuit shorts out starting capacitor C 13  before it is charged to the threshold voltage of diac X 28 . 
     As an example of a low cost solution for an ICETRON/ENDURA arc detection and shut down circuit such as that illustrated in FIG. 3, the following components can be used: R 24 -1 MΩ; R 25  and R 27 -470 kΩ; C 27 -1 nF; C 28 -470 pF; D 44 -1N5248B; D 45 , D 46 , and D 49 -1N4148; D 47 -IN4005GP; M 4 -IRFD014. With the above components, it takes about 5 msec to cancel an arc caused by disconnecting the lamp from the ballast, as illustrated in FIG.  5 . This makes the arc non-visible and not dangerous. 
     The embodiments described above are intended to be illustrative and not limiting. It is recognized that various equivalents, alternatives, and modifications are possible within the scope of the appended claims.