DE1589315B2 - CONTROL CIRCUIT FOR A GAS DISCHARGE LAMP - Google Patents

Description

The invention relates to a control circuit for a gas discharge lamp, which is operated by a pulse generator circuit is controlled from, with a direct current supply source, which is connected to a pulse shaper stage is, the parallel to the charge capacitance a diode, which is a reversal of the anode-cathode voltage prevents the gas discharge lamp and has an inductance via which the charging capacity when activated the gas discharge lamp can be discharged.

From DT-AS 10 65 632 a control circuit for a stroboscopic gas discharge lamp is known which is triggered at its control grid by a pulse generator circuit for its ignition. The discharge voltage for the gas discharge lamp is supplied by a storage capacitor, which is connected to a Resistance is chargeable from a DC power source. The two connections of the capacitor are over Flexible lines that are as short as possible are connected to the anode and cathode of the gas discharge lamp, these flexible lines have the properties of inductances. The condenser therefore forms a series resonant circuit with these inductances. This series oscillating circuit takes place a complete discharge of the capacitor via the gas discharge lamp when it is activated, on the other hand however, the capacitor can also be recharged to the opposite polarity and thus a reversal of the anode-cathode voltage of the gas discharge lamp take place as a result. To do this too prevent, a diode is connected in parallel with the capacitor, the polarity of which is such that it is reversed the anode-cathode voltage of the gas discharge lamp short-circuits it.

From GB-PS 8 39 768 a control circuit for a flashlight gas discharge lamp is known by a pulse generator circuit is controlled. The discharge voltage for the gas discharge lamp is from several capacitors are supplied, which are connected in parallel to each other and via an ohmic resistor can be charged from a direct current source. The individual capacitors are in each case Connected in parallel via an inductance and finally connected to the gas discharge lamp, so that in each case a capacitor and an inductor applied to the gas discharge lamp with discharge voltage Form switching stage: In this known circuit arrangement, however, no switching measures are required provided to prevent a reversal of the anode-cathode voltage of the gas discharge lamp.

From GB-PS 8 94 492 a control circuit for an electric discharge lamp is known in which the Discharge lamp ignited with the help of control pulses will. A storage capacitor is connected in parallel to the discharge lamp via an inductance in turn is charged via an ohmic resistor from a DC voltage source. Between the Resistance and the DC voltage source, the normally closed contact of a relay is connected, the winding of which the Forms inductance. If the capacitor has charged itself to a sufficient potential and the discharge lamp is maintained an ignition pulse, then the capacitor via the inductance and the discharge lamp unload. The relay responds and opens due to the discharge current flowing through the inductance its normally closed contact. This becomes the charging circuit for the capacitor while the discharge lamp is ignited opened so that the DC voltage source does not have any current flowing directly through the discharge lamp can deliver. In another embodiment of this known circuit there are two storage capacitors provided, each of which has an individually assigned charging resistor and one with this in Series-connected diode charged from an AC voltage source via the break switch of the relay will. The diodes are connected in the opposite direction to one another, so that one capacitor charged by the positive half-wave and the other capacitor by the negative half-wave will. The two capacitors are connected in series with each other, so that the stored in them The voltages add up, the discharge lamp approximates the peak voltage of the AC voltage source receives fed. In this circuit, the diodes are used to rectify the capacitors charging alternating voltage.

The object of the invention is to develop a control circuit of the type mentioned in such a way that it can be used to control such a gas discharge lamp, which is used as a heat radiation source in a fuser is to be used.

According to the characterizing part of the new claim, this object is essentially thereby solved that for the use of the gas discharge lamp as a heat radiation source in a fusing device a number of these pulse shaping stages are connected between direct current source and gas discharge lamp is. The supply of the discharge voltage to a gas discharge lamp suitable as a heat radiation source Even then, the gas discharge lamp is reliably supplied with several switching stages sure if this is for fuser use about twice per second must be ignited and sufficient to fuse a toner image to a substrate Must give off radiant energy. Since each switching stage has a diode assigned to the respective capacitor has a charging of the capacitor to a polarity of the usable discharge voltage opposite Polarity not possible, which also results in a reversal of the anode-cathode voltage Gas discharge lamp is safely avoided.

The invention is explained in more detail using an exemplary embodiment shown in the drawing. in the individual shows

F i g. 1 shows the circuit diagram of a control circuit designed according to the invention and

F i g. 2A, 2B and 2C show voltage and current curves, as they are in the circuit arrangement according to FIG F i g. 1 occur.

In the arrangement according to FIG. 1 is a gas discharge lamp 2 is provided, which consists of a with a suitable Gas, e.g. B. Xenon gas, filled quartz tube and contains two electrodes 4 and 6, which are attached to the are melted down at each end. An ignition release coil surrounds the gas discharge lamp between the two electrodes 4 and 6. This coil is connected to a conventional pulse generator circuit 10, which for example can be constructed in the form of a relay circuit or with a controlled rectifier and when switched on, a high-voltage pulse is generated for the ignition release coil 8. This impulse causes within the lamp the formation of a high voltage field between the electrodes 4 and 8, on which a voltage is present, whereby the gas is ionized inside the lamp and an arc between the Electrodes are created. During ionization, the gas discharge lamp provides a low resistance for the pulse shaping circuit 12, which is described in more detail below.

A conventional DC voltage device 14 generates a voltage at the input terminals of the pulse shaping circuit 12. The function of the pulse shaping circuit 12 is not only to generate a pulse for the gas discharge lamp 2 with an amplitude suitable for a maximum service life of this lamp and duration, but also in influencing the emission of radiant energy by the lamp in a strength suitable for fusing the toner in the fibers of the recording sheet.

In Figure 2 it is shown that the capacitors 16 and 18 charged to an initial voltage before the gas discharge lamp 2 is triggered which depends on the respective capacitance value, the resistance value of the resistor 20 and the time. The series connection of a diode 22 and a resistor 24 is parallel to the capacitor 16 intended. In the same way, the capacitor 18 is the series connection of a diode 26 and a resistor 28 connected in parallel. The diodes 22 and 26 are connected in such a way that they at the said starting point are polarized in the reverse direction and are therefore not conductive. Between the connection points of the An inductance 30 is provided for the diode 22 with the capacitor 16 and the capacitor 18 with the diode 26. Between the latter connection point and the electrode 4 of the gas discharge lamp 2 is another Inductance 32 is provided.

If the gas discharge lamp 2 is activated by the pulse generator circuit 10 immediately after reaching the aforementioned starting point or at time to , the capacitors 16 and 18 discharge via the inductances 30 and 32 and the low resistance of the ionized lamp 2. The course of the current through the inductance 30 and 32 corresponds to the value of the inductances. The current through the lamp from the starting time to is shown in FIG. 2A and applies to an exemplary embodiment of the circuit arrangement according to the invention. From this current curve it can be seen that the initial current through the lamp increases gradually.

The inductances 30 and 32 limit the maximum current flowing in the lamp 2. Once the Current flow through the inductors drops, the energy stored by their magnetic field is dissipated, whereby the inductors continue to deliver current to the lamp. In Fig. 1 this corresponds to the point in time fi. The energy stored in inductors 30 and 32 is thus consumed in the lamp. the Diode branches of the pulse shaping circuit in parallel with the capacitors 16 and 18 are at time ii polarized in the forward direction and represent a discharge circuit for the capacitors the conductive diodes 16 and 18 formed low resistance current paths reduce the difference in the positive polarity of the normally negative assignment (in the drawing the one with the negative pole of the Voltage source 14 connected assignment) of the capacitors 16 and 18 with respect to their respective other Occupancy. This reduction in the voltage reversal across the capacitors causes a similar reduction the voltage reversal at electrodes 4 and 6 of gas discharge lamp 2.

The small degree of voltage reversal on capacitors 16 and 18 can be achieved by omitting the low resistances 24 and 28 in the circuit according to FIG. 1 can be further reduced. These resistances serve to limit the current and thus to protect the respective diode. Because of the short duration of the current flow through these diodes, these resistors 24 and 28 can also be dispensed with, if the diode data is selected accordingly. Dioden with sufficient current carrying capacity are available and can be used as a replacement for the series connection of a diode and a current limiting resistor will. The current flow through the diodes is shown in FIG. 2C.

In Fig.2B is the voltage across the capacitors 16 and 18, the hatched area showing the voltage reversal also at the gas discharge lamp shows.

When the voltage and current reach the extinguishing values of the gas discharge lamp, the gas it contains is released deionized, which ends its conductive state. In Fig. 2A. 2B and 2C, this corresponds to the point in time ß, to which the capacitors 16 and 18 in the pulse shaper circuit 12 for the next fixing process the heat fixing device.

The effectiveness of the pulse shaper circuit described above in terms of increased reliability, extended service life and favorable operating properties becomes even clearer through the following considerations.

A gas discharge lamp is exposed to cathode sputtering when the voltage is reversed. As is well known, occurs this causes a blackening of the tube, which is caused by a deposit of opaque vaporized metal of the Electrode on the inside of the tube. The blackening of the insides of the tube occurs generally in the area of the cathode and can withstand high current peaks and temperatures as well as that Ion bombardment can be traced back to the tungsten electrode, which wears it out will.

After an electrode sputtering over a longer period of time, the blackening expands in Direction towards the other end of the gas discharge lamp. Electrode sputtering is undesirable because it reduces the emitted radiant energy for the toner to be fixed. As from the description of the Circuit arrangement according to Fi'g. 1 shows that

the pulse shaping circuit 12 limits the current peaks in the lamp as well as deformation the leading edge of the current pulse flowing in the lamp. Due to the gradual increase in Leading edge of these pulses and limiting the amplitude becomes the electrode sputtering and its wear decreased.

If a voltage reversal in the gas discharge lamp is made possible during the ionization process, so the function of their electrodes is also reversed. The cathode becomes the anode and the anode becomes the cathode. If the voltage reversal is sufficient for this function reversal, then atomization is not only sufficient the cathode but also observed at the anode, increasing the overall wear and tear on the electrodes is increased.

In the circuit arrangement according to FIG. 1 used capacitors can be made of metal plates be formed that bend when the voltage is reversed. These capacitors have a very low Resistance and a low inductance, so that it is preferably used in view of its low loss will. After numerous voltage reversals, however, the metal plates soften so that they decrease their spacing and change the capacitance of the capacitor, thereby reducing its life is decreased. By connecting the diode in parallel with a resistor, the undesired Voltage reversals are reduced to a manageable minimum, reducing the life of the Capacitors is maximum. It should be noted that the use of polarized capacitors is possible without having to fear destruction due to excessive voltage reversal.

Since a heat fixing device must perform at least two fixing processes per second, is through the reduction in the voltage reversal on the capacitors in the circuit arrangement according to FIG. 1 faster recharge of these capacitors

ίο for the next fusing cycle by the power source 14 possible.

In addition to the faster charging of the capacitors, there is also a lower load on the current source 14 given to charge the capacitors to the desired value after each fixing process.

From the above explanations it can be seen that the circuit arrangement according to the invention is a enables effective and reliable operation of heat fixing devices. These better results are achieved through the use of a pulse shaper circuit similar to that in the gas discharge lamp flowing current in a suitable manner and at the same time the undesired voltage reversals on the capacitors and the gas discharge lamp required for this purpose.

Of course, the in the F i g. 2A, 2B and 2C none of the current and voltage curves shown represent practical operating values. They only serve to show the pulse shapes that can be achieved and the relevant times for their occurrence.

1 sheet of drawings

Claims (1)

Claim: Control circuit for a gas discharge lamp, which is controlled by a pulse generator circuit is, with a direct current supply source, which is connected to a pulse shaper stage, which is parallel to Charging capacity a diode that reverses the anode-cathode voltage of the gas discharge lamp prevents and has an inductance over which the charging capacity when controlling the Gas discharge lamp can be discharged, characterized in that for use of the gas discharge lamp (2) as a heat radiation source in a fuser, a number of them Pulse shaping stages (16, 22, 30; 18, 26, 32) between direct current source (14) and gas discharge lamp is switched.