The present invention is directed to a system for sensing a signal in the primary side of a luminous lamp load driving circuit to detect an end-of-life lamp condition and provide for an adjustment or shut down of the load driving circuitry. More particularly, the present invention is designed to detect the transients across the direct current choke associated with an end of lamp life condition in order to provide a shut down signal for the load driving circuitry.
Ballasts using direct current chokes are known in the art. For example, U.S. Pat. No. 5,877,592 entitled Programmed-start parallel-resonant electronic ballast discloses a ballast having a direct current choke. In addition, patents describing protection circuits capable of detecting end-of-lamp-life conditions in lamps are known in the art. Examples of these circuits are described in U.S. Pat. No. 6,127,786 entitled Ballast having a lamp end of life circuit, U.S. Pat. No. 5,808,422 entitled Lamp ballast with lamp rectification detection circuitry, U.S. Pat. No. 5,777,439 entitled Detection and protection circuit for fluorescent lamps operating at failure mode, U.S. Pat. No. 5,635,799 entitled Lamp Protection Circuit For Electronic Ballasts, U.S. Pat. No. 5,606,224 entitled Protection circuit for fluorescent lamps operating at failure mode, U.S. Pat. No. 5,574,335 entitled Ballast containing protection circuit for detecting rectification of arc discharge lamp, U.S. Pat. No. 5,475,284 entitled Ballast containing circuit for measuring increase in DC voltage component, U.S. Pat. No. 5,142,202 entitled Starting and operating circuit for arc discharge lamp, U.S. Pat. No. 5,138,235 entitled Starting and operating circuit for arc discharge lamp, U.S. Pat. No. 5,111,114 entitled Fluorescent lamp light ballast system, U.S. Pat. No. 5,023,516 entitled Discharge lamp operation apparatus, and U.S. Pat. No. 4,429,356 entitled Transistor Inverter Device. Each of these patents is hereby incorporated by reference.
These patent teach different sensors in an electronic ballast, but fail to teach the use of a sensing circuit coupled to the dc choke for detecting the end of life condition. What is needed, then, is a Transient Detection of End of Lamp Life Condition Apparatus and Method.
The present invention describes an end-of-life sensor device or apparatus for an electronic ballast having a direct current power supply including a direct current choke. The direct current power supply is coupled to an inverter adapted to power a luminous lamp. The device includes an end-of-life sensor operable to detect changes in the voltage across the direct current choke. Once the appropriate level of voltage changes are detected for an end-of-lamp life condition, the sensor generates an end-of-life signal that is communicated to an inverter control circuit. This inverter control circuit will then change the operation of the inverter when the end-of-life signal is received to reduce the stress on the ballast. In the preferred embodiment, the inverter control circuit will shut down the ballast and stop operation of the inverter.
In one embodiment of the present invention where the ballast is shut down by the inverter control circuit, the start circuit connected to a restart inhibit circuit to inhibit the inverter from restarting and restoring power to the lamp load until the entire unit is de-energized.
A method for controlling a ballast is also taught by the present invention. The method is utilized in a ballast including a direct current choke and an inverter adapted to power a luminous load. The method includes detecting an end-of-life load condition on the direct current choke, and reducing the power provided by the inverter to protect the ballast components.
One advantage and object of the present invention is a prolonged life of the ballast. Yet a further advantage and object is provided in reducing the potential problems associated with an end-of-life failure in a luminous load.
Another advantage of the present invention is the elimination of the need for isolation on the sensing circuit. Sensing circuits connected directly to the lamps in ballasts using transformer isolation must also be isolated in order to ensure that the sensing circuit is properly isolated. The present invention eliminates this requirement by connecting the sensing circuit to the dc choke rather than directly to the lamps. More specifically, the sensing circuit includes an auxiliary winding coupled to the dc choke that allows sensing to be performed on the primary side of the ballast inverter.
Connecting the sensing circuit to the dc choke also eliminates the need for multiple sensing circuits. In ballasts powering multiple lamps in parallel, it is necessary to have sensing circuits coupled to each of the lamps in order to sense lamp failures. This increases the overall costs of these ballasts. By connecting the sensing circuit directly to the dc choke, only one sensing circuit is required, which reduces costs, and that circuit can sense failures in any of the lamps.
The sensing circuit of the present invention also eliminates the need for sensing filament conductivity, which is necessary in some prior art ballasts, and, as a result, can be used for instant-start lamps where there is only one wire from the ballast for each filament.
Other objects and further scope of the applicability of the present invention will become apparent from the detailed description to follow, taken in conjunction with the accompanying drawing wherein like parts are designated by like reference numerals.
Unlike most ballasts with End-of-Life shutdown circuits that sense an asymmetry or overvoltage at the lamp, this circuit senses a change in the current in the direct current (DC) choke. Load transients, i.e., repetitive fluctuations in the lamp voltage, whether caused by lamp replacement, power on, or an end-of-life lamp, cause a change in the current level into the inverter. During the transition from one current level to another, the voltage on the DC choke primary winding changes. This circuit is designed to sense these voltage changes and shut down the ballast when the voltage changes are caused by fluctuations in an end-of-life lamp. Voltages caused by transients due to lamp replacement and power on will not cause the ballast to shutdown. In other words, the circuit is designed to sense the sustained fluctuations in lamp voltage that occur in end-of-life lamps, yet not shutdown the ballast during temporary transients caused by lamp replacement and power on.
The startup and re-start inhibit circuit 110 includes a voltage divider powering time delay capacitor C9 across the base of inhibiting transistor Q2. During the initial charging for time delay capacitor Q9, the incoming power from the rectifier will travel through resistor series R9, R10, R11 as a start circuit to provide power at Zener diode D12. The initial voltage at the cathode of D12 rises to an operating voltage in excess of 18V, causing D12 to conduct in the reverse direction, and allowing approximately 1 mA to flow into the base of power transistor Q4. This biases power transistor Q4 ON and starts the push-pull inverter.
Restarting of the inverter 116 is then prohibited by operation of the restart inhibit circuit including the delay capacitor C9 and the inhibiting transistor Q2. Once capacitor C9 has been charged, inhibiting transistor Q2 will begin to operate as part of the voltage discharge circuit to pull the cathode of Zener diode D12 low to remove the operating voltage and the possibility of conduction by Zener diode D12 which will prohibit a restart of the inverter circuitry 116. (Note that “input line” is not defined.) The voltage divider comprised of R5, R6, R7, and R8 is used to bias inhibiting transistor Q2 on. However, the operation of this voltage divider is affected by a delay circuit including parallel-connected time delay capacitor C9. The voltage divider controls the charge rate on capacitor C9. Capacitor C9 is used to delay inhibiting transistor Q2 from turning on until after the initial start up of the inverter. This provides a delay in the operation of the inhibiting transistor Q2 to allow the initial startup of the inverter 116 and delay the inhibit circuit operation until after the initial start up has been completed. When the shutdown circuit 114 has activated and stopped operation of the inverter, the restart inhibit circuit 110 prevents the inverter 116 from restarting as long as the ballast 100 is energized. As may be understood by this circuit design, bulk electrolytic smoothing capacitor C4 must discharge to allow inhibiting transistor Q2 to shut off.
The voltage across smoothing capacitor C4 is also connected to the inverter 116. A conventional current fed, parallel resonant push pull inverter is made using capacitors C10-13, bipolar power transistors Q4 and Q5, transformer T1, and resistors R14-18. Power from smoothing capacitor C4 is coupled by a connection to transformer T1 at the mid-point of transformer winding T1:C. Power supplied to the mid-point of transformer winding T1:C is then transformed across the core of the transformer T1 to the secondary winding T1:A. The output of the secondary winding T1:A is connected through capacitors C11, C12, and C13 to provide the output at LW2 for powering the luminous lamp load 118.
Returning to the transformer T1, capacitor C10 is connected across the primary side winding T1:C of transformer T1. The end points of the primary winding T1:C of transformer T1 and parallel connected capacitor C10 are connected to the collectors of power transistors Q4 and Q5 respectively. The bases of power transistors Q4 and Q5 are driven by transformer drive winding T1:B. The first end of transformer drive winding T1:B is connected through resistor R16 into the base of power transistor Q4. The second end of transformer drive winding T1:B is directly connected to the base of power transistor Q5. This provides a push-pull configuration inverter as is known in the art. The present invention is designed to be utilized with either push pull or half-bridge types of load driving circuitry. The inverter is also connected to the peak detection circuit 108 and the shutdown circuit 114. The base of power transistor Q4 is connected through resistors R14 and R15 and the base of power transistor Q5 is connected through R16 and R17 to the peak detection circuit 108. The bases of power transistors Q4 and Q5 are also directly connected to the shutdown circuitry 114.
The peak detection circuit 108 is connected to the direct current choke 106, the inverter 116, and the integration circuit 112. Transients are developed across the direct current choke inductor L3 through the connection with the power transistors Q4 and Q5 of the inverter 116. The emitters of power transistors Q4 and Q5 are connected through choke inductor L3 to the output of the rectifier 104 utilizing diodes D1, D2, D3, and D4. This provides a direct coupling of the choke 106 to the inverter 116 such that the transient voltages occurring during operation of the inverter 116 are transferred to the choke 106.
A negative voltage with respect to emitters of Q4 and Q5 is developed through the connection of the diode D5 and capacitor C5 across the auxiliary winding 117 of the choke inductor L3. This negative voltage is utilized in the peak detection circuit 108, the integration circuit 112 and the shutdown circuitry 114.
The peak detection circuit uses a positive rectified value established across the output of the winding of the choke 106 through the utilization of diode D7 which will charge choke capacitor C6 with a choke voltage. Choke capacitor C6 has two functions in the ballast 100. The first is to store energy for the DC bias for the power bipolar transistors Q4 and Q5 in the inverter. The second function is to provide a peak detection voltage that is proportional to the peak voltages across the DC choke.
Once the ballast 100 and lamps 118 have started and stabilized, the voltage on choke capacitor C6 reaches a stable average value with some ripple due to the current provided to the bases of the power bipolar transistors Q4 and Q5. Change monitoring capacitor C7 is arranged to act as a change monitoring component with detection resistors R1 and R2 to detect changes in the voltage on choke capacitor C6. The voltage on change monitoring capacitor C7 lags changes in the voltage across choke capacitor C6 due to resistors R1 and R2. Following a load transient, the voltage on the auxiliary winding 117 of choke inductor L3 rings high, and charges choke capacitor C6 and change monitoring capacitor C7 to a higher voltage. When end-of life transients occur, the charging rate differential between the two capacitors C6 and C7 produces a voltage differential between the base and emitter of detection transistor Q1, also known as peak pulse generator Q1 and peak detection switch Q1. Thus, when the ringing voltage exceeds the steady-state voltage by at least one volt, the voltage across detection resistor R1 is sufficient to turn PNP detection transistor Q1 ON.
Once detection transistor Q1 has been turned on, pulse-stretching capacitor C14 is rapidly charged during the duration of the ringing voltage across choke capacitor C6. After the ringing has subsided, the voltage across capacitor C14 decays through resistor R14. Thus short ringing pulses across choke capacitor C6 result in longer pulses appearing across pulse-stretching capacitor C14. Darlington transistor Q6 functions as a voltage follower with a high input impedance and a low output impedance so that the voltage at the emitter of Q16 tracks the voltage across pulse-stretching capacitor C14 without significantly disturbing that voltage. Each time a pulsed voltage is developed across capacitor C14, integrating capacitor C8 is charged through charge rate control resistor R3. This pulse occurs during each transient on the choke 106 that is of sufficient magnitude. Thus, the peak detection circuit 108 generates pulses when the peak values of the ac voltage waveform across the dc choke 106 rapidly increase beyond the steady-state voltage across the dc choke 106.
The integration circuit 112 accumulates the pulses passing through Darlington transistor Q6, and provides a controlled charge rate and discharge rate to monitor the frequency at which the transients occur. Integrating charge storage capacitor C8, charge rate control resistors R3 and discharge rate control resistor R4 are used to integrate the pulses of current from Darlington transistor Q6 into a voltage that increases with repeated transients. Integrating charge storage capacitor C8 is sized to prevent false triggering of the shutdown circuit 114 when the ballast 100 is originally energized, and during short duration load transients, such as lamp removal and replacement. This is accomplished by making the charge rate higher than the discharge rate for integrating charge storage capacitor C8. The discharge time constant of integrating charge storage capacitor C8 and R4 will be determined by C8 and R4, however, integrating charge storage capacitor C8 will charge much faster through R3. If the voltage developing across integrating charge storage capacitor C8 is from a singular transient and is not associated with the repetitive transients of an end of lamp life condition, then the voltage developed across C8 will be insufficient for the shutdown circuit and this charge will be allowed to discharge through resistor R4 as an unwanted charge. If a repetitive transient occurs, then integrating charge storage capacitor C8 will charge at a faster rate than the discharge rate, and a sufficient voltage will be developed to operate the shutdown circuit 114. The voltage across integrating charge storage capacitor C8 is utilized by the shutdown circuitry to stop the operation of the inverter.
The shutdown circuit 114 is connected to the integration circuit 112, and the inverter 116. During normal operation, a negative voltage of approximately 15 volts with respect to the emitters of power transistors Q4 and Q5 is generated across capacitor C5 by the configuration of choke inductor L3, diode D5 and capacitor C5 to be a reverse polarity voltage from the normal operating voltage on smoothing capacitor C4. When an end-of-life condition is detected, the voltage on integrating charge storage capacitor C8 activates the control switch by reaching the Zener voltage of diode D10, also known as an end-of life signal monitor D10. Zener diode D10 then conducts and allows current to flow from integrating charge storage capacitor C8 to the gate of thyristor Q3, also known as a reverse voltage flow control Q3. Thyristor Q3 is a silicon controlled rectifier (SCR) that is controlled by the bias provided across Zener diode D10 and resistor R13. The base of power transistor Q4 is connected into the shutdown circuitry by diode D13 to be connected to thyristor Q3. The base of power transistor Q5 is similarly connected through diode D14 to be connected to the thyristor Q3. When the Zener diode D10 conducts, this current gates Q3 ON, which presents a negative voltage to the bases of inverter power transistors Q4 and Q5, and stops the oscillations of the inverter. By using this configuration, the shutdown circuit 114 can pull the bases of power transistors Q4 and Q5 low in order to shut down the operation of the inverter 116 and remove power from the lamp load 118. Once the operation of the inverter 116 has been stopped, the inverter 116 will be inhibited from re-igniting by the startup and re-start inhibit circuit 110.
In this manner, an apparatus for detecting end of lamp life conditions on the primary side of the inverter transformer has been established by utilizing transients occurring across a DC choke.
A simplified method of operation of an inverter may be understood with reference to the circuit of
Although the present invention has been described using analog circuit elements, the applicant contemplates that the present invention might be implemented digitally as well. For example, the embodiment of the integration circuit 112 shown in
Thus, although there have been described particular embodiments of the present invention of a new and useful Transient Detection of End of Lamp Life Condition Apparatus and Method, it is not intended that such references be construed as limitations upon the scope of this invention except as set forth in the following claims.
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