DE3700421A1 - CIRCUIT ARRANGEMENT FOR OPERATING A LOW-PRESSURE DISCHARGE LAMP - Google Patents

Abstract

In a circuit arrangement for the high-frequency operation of a low- pressure discharge lamp (LP1) with a push-pull frequency generator (3), a smoothing capacitor (C4) and an active harmonic filter (5), a switch-off device with a fast trigger circuit is provided. The trigger circuit consists of one or more series-connected Zener diodes (DZ1, DZ2), which connect the gate of the switch-off thyristor (TH) to the positive pin of the smoothing capacitor (C4). In addition, the trigger circuit contains a resistor (R9), which connects the gate of the switch-off thyristor (TH) to its cathode. If the low-pressure discharge lamp (LP1) fails, the trigger circuit ensures that the switch-off thyristor (TH) is switched-through within a few milliseconds and thus inhibits operation of the circuit arrangement. Destruction of the smoothing capacitor (C4) by the pumping operation of the active harmonic filter (5) is thus prevented. <IMAGE>

Description

The invention relates to a circuit arrangement for high-frequency operation of a low pressure discharge lamp according to the preamble of claim 1.

In German patent applications P 36 23 749.3 and P 36 11 611.4 are such circuit arrangements without Switch-off device for operating fluorescent lamps suggested. The disadvantage of these circuits is that if the discharge lamp fails, the circuit an order is not disabled. Because of the mode of operation of the active harmonic filter the ongoing energy in the smoothing capacitor If it is pumped back, it can be too if the lamp fails destruction of the smoothing capacitor and possibly of the entire circuit.

On the other hand, from DE-OS 29 41 822 Shutdown device known as in the preamble of the first claim is listed. This shutdown device includes a trigger circuit with a precisely dimensioned diac using the thyristor after a delay of approximately one second. There is a delay time of up to one second however for a circuit arrangement with an as Pump system designed harmonic filter too long because it to a strong already in far shorter times Voltage rise at the smoothing capacitor can come.

The object of the invention is therefore a trigger circuit to create the thyristor inside a few milliseconds and turns into one Switching off the circuit arrangement leads. The triggers circuit should also consist of as few and inexpensive components can be created.

This task is characterized by the characteristics of the 1st claim solved.

If the low-pressure discharge lamp fails, the capacitors of the active harmonic filter on Smoothing capacitor causes a voltage rise. If the voltage rise exceeds the breakdown voltage of the one or more in series switched zener diodes of the trigger circuit, so switch these diodes through and thus directly trigger the Shutdown thyristor. This then also goes in a conductive state and thus withdraws from it connected to the positive pole of the mains rectifier Transistor the control power. The transistor will locked and the oscillation of the push-pull frequency nerators ended. By connecting the gate of the Thyristor through a resistor with the cathode of the Thyristor is protected and its Switching accuracy ensured.

The circuit arrangement can be used to operate a several parallel or several successive low pressure discharge lamps are used.

The invention is based on the following figures illustrated in more detail.  

Fig. 1 shows the block diagram of an inventive circuit arrangement for a low pressure discharge lamp.

Fig. 2 shows the complete circuit diagram of an inventive circuit arrangement for operating a low-pressure discharge lamp.

The block diagram in FIG. 1 shows the basic structure of a circuit arrangement according to the invention for a low-pressure discharge lamp. The circuit arrangement includes a high-frequency filter 1 , a line rectifier 2 and a push-pull frequency generator with a control circuit 3 , the switching transistors in series bridging the DC output of the line rectifier 2 . Between the center tap M 1 of the switching transistors and the positive pole of the rectifier 2 , the low-pressure discharge lamp LP 1 is connected via a series resonance circuit 4 . In addition, an active harmonic filter 5 is easily seen, which is connected on the one hand to the positive pole of the rectifier 2 and on the other hand to the center tap M 1 . Furthermore, the circuit arrangement has a shutdown device. The latter consists of a series connection of a diode D 12 , a resistor R 7 and a thyristor TH and a resistor R 8 . The series connection connects the base of the transistor T 1 with the negative pole of the rectifier, while the resistor R 8 between the center tap M 5 between the diode D 12 and the opponent was R 7 and the positive pole of the smoothing capacitor C 4 is connected. For triggering, the gate of the thyristor TH is connected via two Zener diodes DZ 1 , DZ 2 to the positive pole of the smoothing capacitor C 4 and via a resistor R 9 to the cathode of the thyristor TH .

Fig. 2 shows the exact circuit diagram of a circuit arrangement with the shutdown device according to the invention for operating a low-pressure discharge lamp. A block of a current-compensated filter choke FD and a filter capacitor C 1 are connected in parallel to the input of the mains rectifier in each supply line. This high-frequency filter is followed by the mains rectifier with diodes D 1 to D 4 and a backup capacitor C 2 parallel to the DC output. The self-regulating push-pull frequency generator consists of the two transistors T 1 , T 2 with the same polarity, with the reverse current diodes D 6 , D 7 , the series resistors R 2 to R 5 , the control transformer and the starting generator with the resistors R 1 , R 6 , the starting capacitor C. 3 , the diode D 5 and the diac DC . The control transformer works on the feedback principle and is made up of the primary winding RK 1.1 and the two secondary windings RK 1.2 and RK 1.3 . The lamp LP 1 is connected to the electrode E 1 with a center tap M 1 between the two transistors T 1 , T 2 and to the other electrode E 2 with the positive pole of the mains rectifier. Except where a series resonant circuit of Resonanzindukti is tivity L 1, coupling capacitor C 5 and the resonance capacitor C 6 is provided, wherein the resonance inductor L 1 and the coupling capacitor C 5, between the primary winding RK 1.1 of Steuerübertragers and the corresponding terminal of the electrode E 1 and the resonance capacitor C 6 between the connections on the heating circuit side to the electrodes E 1 and E 2 are connected.

In addition to the switching paths of the transistors T 1 , T 2 there is a smoothing capacitor C 4 .

The functioning of such a circuit arrangement with push-pull frequency generator and series resonance circuit for igniting and operating a low pressure outlet lamp can be the book "electronics circuits" by W. Hirschmann (SIEMENS AG), page 148 will not and will not be discussed here.

The circuit arrangement also has an active harmonic filter. The filter consists of two diodes D 8 , D 9 connected in series and in the direct current forward direction to the supporting capacitor C 2 , the center tap M 2 between the two diodes D 8 , D 9 via a capacitor C 7 with the center tap M 1 between the two Transistors T 1 , T 2 and via a capacitor C 8 with the center tap M 3 between resonance inductor L 1 and coupling capacitor C 5 is connected. In addition to the first two diodes D 8 , D 9, the harmonic filter also contains two further diodes D 10 , D 11 connected in series and in a forward direction in direct current, the center tap M 4 between these two diodes D 10 , D 11 also being connected via a capacitor C 9 is connected to the center tap M 1 between the two transistors T 1 , T 2 .

How the harmonic filter works together act with the push-pull frequency generator is in explained the following:

• Clock 1: The transistor T 2 becomes conductive and thus pulls the potential of the point M 1 down to the potential of the negative pole on the smoothing capacitor C 4 . The pump capacitors C 7 , C 8 , C 9 are charged according to the potential difference "instantaneous value of the voltage across the capacitor C 2 " to "potential at the negative pole of the smoothing capacitor C 4 ", at the apex of the mains voltage to U _N · √.
• Clock 2: The transistor T 2 blocks, the potentials at the points M 1 and M 3 are raised suddenly and thus also raise the potentials of the capacitors C 7 , C 8 , C 9 . The capacitors C 7 , C 8 , C 9 receive a higher potential than that of the smoothing capacitor C 4 and can thus discharge into this capacitor C 4 .
• Clock 3: The transistor T 1 turns on and raises the potential of the point M 1 to the potential of the positive pole on the smoothing capacitor C 4 . The resonance inductor L 1 is charged in the opposite direction.
• Clock 4: The transistor T 1 blocks and thus causes the resonance inductance L 1 to discharge into the capacitors C 7 , C 9 and thus also C 8 . The pump capacitors C 7 , C 8 , C 9 are thus also charged in the area of the line voltage zero crossing, since the potential of the pump capacitors C 7 , C 8 , C 9 in this area becomes nega tively the instantaneous value of the backup capacitor C 2 .

Then cycle 1 follows again and the energy transport begins again. Energy is pumped into the smoothing capacitor C 4 once per period of the HF operating frequency. In the area of the mains voltage peak value, the pump capacitors C 7 , C 8 , C 9 are charged to the peak value of the mains voltage, then the voltage and thus the energy drop again. In the smoothing capacitor C 4 , energy corresponding to the instantaneous value of the pulsating direct voltage at the supporting capacitor C 2 is pumped during the mains voltage half-wave, reduced by the energy stored in the resonance inductor L 1 .

In the area of the mains voltage zero crossing, the mains voltage-related potential difference between the negative pole of the smoothing capacitor C 4 and the positive pole of the mains rectifier is zero. Nevertheless, there is a voltage difference: The energy stored in the resonance inductance L 1 is pumped back in this area partly through the capacitors C 7 and C 8 into the smoothing capacitor C 4 . In this way, the harmonic filter ensures a sinusoidal mains current consumption and a linear dependence of the lamp power on the mains voltage.

The continuous pumping back of energy can lead to an overload and thus a destruction of the smoothing capacitor C 4 if the lamp fails. The circuit arrangement therefore additionally has a switching device with trigger control. This consists of a series circuit of a diode D 12 , a resistor R 7 and a thyristor TH , which connects the base of the transistor T 1 with the negative pole of the power rectifier. In addition, the center tap M 5 of the diode D 12 and the resistor R 7 is connected via a resistor R 8 to the positive pole of the smoothing capacitor C 4 . The trigger control consists of the two Zener diodes DZ 1 , DZ 2 , which connect the gate of the thyristor TH to the positive pole of the smoothing capacitor C 4 , and the resistor R 9 , which connects the gate of the thyristor TH to its cathode.

In the event that the voltage across the smoothing capacitor C 4 has a certain maximum value of z. B. 500 V (see circuit example below), the two Zener diodes DZ 1 and DZ 2 with the same total breakdown voltage are conductive and thus trigger the shutdown thyristor TH . This removes the control energy from the base of transistor T 1 by dissipation to the negative pole of the mains rectifier; the transistor is blocked and the resonance circuit of inductance L 1 , capacitor C 6 and capacitor C 5 is de-energized. By connecting the thyristor TH through the resistor R 8 to the positive pole of the mains rectifier, the thyristor TH is kept in the conductive state, so that any renewed use of vibration is prevented. The diode D 12 blocks the AC voltage from the anode circuit of the thyristor TH . Only after switching off the power supply does the thyristor TH lock and the push-pull frequency generator can start again after switching on the power supply.

In the list below are the scarves used tion elements for a circuit arrangement with Fast shutdown to operate an 18 W low pressure discharge lamp reproduced:  

• FD : EF 20/2 × 120 mH current compensated
  C 1 : 0.1 µF / 250 V ∼
  D 1 - D 4 , D 5 , D 12 : 1 N 4005
  C 2 : 68 nF / 250 V ∼
  D 6 - D 11 : fast diode 600 V / 1 A
  C 4 : 4.7 µF / 450 V =
  R 8 : 56 kΩ / 2 W.
  DZ 1 : U _Z = 200 V
  DZ 2 : U _Z = 300 V
  R 9 : 1 kΩ / 0.3 W.
  R 1 , R 6 : 510 kΩ / 0.5 W.
  C 3 : 47 nF / 100 V =
  DC : Diac U _B approx. 32 V , I _B <0.05 mA
  RK 1.1 , RK 1.2 , RK 1.3 : RK 13 × 7 × 5 n 1.1 = 7 turns n 1.2 = n 1.3 = 1 turn
  R 2 , R 3 : 10 Ω / 0.5 W
  R 7 : 100 Ω / 1 W.
  TH : Thyristor U _{D / R} = 500 V , I _H <3 mA, I _AV max. 3 A
  T 1 , T 2 : MJE 13 005
  R 4 , R 5 : 1 Ω / 0.5 W
  C 7 , C 9 : 4.7 nF / 630 V =
  L 1 : EF 20 / 1.55 mH
  C 8 : 3.3 nF / 630 V =
  C 5 : 150 nF / 400 V =
  C 6 : 10 nF / 630 V =

Claims (2)

Circuit arrangement for high-frequency operation of a low-pressure discharge lamp (LP 1 ), the circuit having the following features:

• - A mains rectifier ( 2 ) with a backup capacitor (C 2 ) connected in parallel to the DC output
• - an input connected to the DC output of the mains rectifier (2) push-pull frequency generator (3) with two alternately switching transistors (T 1, T 2) and a drive circuit, wherein a center tap (M1) between the two transistors (T 1, T 2) is provided
• - A series resonance circuit ( 4 ) consisting of resonance inductance (L 1 ), coupling capacitor (C 5 ) and resonance capacitance (C 6 )
• - Connection lines for the low-pressure discharge lamp (LP 1 ), with one line the first electrode (E 1 ) of the lamp (LP 1 ) via the resonance inductance (L 1 ) with the center tap (M 1 ) between the two transistors (T 1 , T 2 ) and a further line connects the second electrode (E 2 ) of the lamp (LP 1 ) with the positive and / or negative pole of the mains rectifier ( 2 )
• - A smoothing capacitor (C 4 ) parallel to the switching paths of the two transistors (T 1 , T 2 ) of the push-pull frequency generator ( 3 )
• - An active harmonic filter ( 5 ), consisting of one or more parallel to each other in series connections of two diodes (D 8 , D 9 ; D 10 , D 11 ), which are connected in series to the backup capacitor (C 2 ) in the forward DC direction and in each case at least one capacitor (C 7 , C 8 , C 9 ) which connects the center tap (M 2 , M 4 ) between the two diodes (D 8 , D 9 ; D 10 , D 11 ) with a point on the connecting line of connects the first electrode (E 1 ) of the lamp (LP 1 ) to the center tap (M 1 ) between the two transistors (T 1 , T 2 ).
• - A shutdown device consisting of a series connection of a diode (D 12 ), a resistor (R 7 ) and a thyristor (TH) with a trigger circuit, which connects the base of the transistor (T 1 ) connected to the positive pole of the rectifier ( 2 ) with the Minus pole of the mains rectifier ( 2 ) connects and a resistor (R 8 ), which connects the positive pole of the smoothing capacitor (C 4 ) with a center tap (M 5 ) between the diode (D 12 ) and the thyristor (TH) ,

characterized in that the trigger circuit for the thyristor (TH) of the shutdown device consists of one or more series-connected Zener diodes (DZ 1 , DZ 2 ) which connect the gate of the thyristor (TH) to the positive pole of the smoothing capacitor (C 4 ) as well as a resistor (R 9 ), which connects the gate of the thyristor (TH) to the cathode of the thyristor (TH) .