DE2422201A1 - IGNITION SWITCH FOR FLASH BULBS - Google Patents

Description

Boeblingen, May 7th 1974
pr / se

Applicant: International Business Machines

Corporation, Armonk, N.Y. 10504

Official file number: New registration
Applicant's file number: EN 973 002

Ignition circuit for flash lamps

The invention relates to an ignition circuit for flash lamps with
a storage capacitor that can be charged by an energy source via a limiting resistor / that by a trigger pulse
can be discharged via a flash discharge lamp.

In many areas of technology, flash units with high
Light output and short repetition times are required. For
the necessary capacitors with large capacities
Relatively high charging currents and voltages are required for short repetition times / which, when a certain value is exceeded, maintain the discharge of a flash lamp that has been ignited even after the discharge of the storage capacitor has ended. Maintaining the discharge through the charging current of the storage capacitor can be achieved, for example, through the selection of suitable gas fillings or through structural measures
the flash lamps to reduce the difference between ignition and burning voltage or current and / or by circuitry
Measures on the circuits causing the discharge are avoided. From the large number of proposals, for example, see
See U.S. Patent 3,355,625. All the proposals known so far relate only to partial solutions to the above-mentioned problem, which do not make it possible to use flash lamps at high light outputs with a rapid discharge sequence, as they do
are required, for example, for automatic copiers

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to operate.

This object is achieved according to the invention by an ignition circuit for flash lamps with one through an energy source through one Limiting resistor, chargeable storage capacitor, which can be discharged by a trigger pulse via a flash discharge lamp, solved, which is characterized by a lying in the charging circuit, a maintenance of the discharge of the ignited Flash lamp with discharged storage capacitor preventing limiting resistor and a parallel connected to the Ignition point non-conductive low-resistance electronic switch, der, via a delay device with the trigger pulse source connected, is made conductive by the delayed trigger pulse a short time after the end of the lightning discharge.

Further features of the invention emerge from the subclaims and the description.

The invention will then be described with reference to FIGS. explained in more detail. Show it:

1 shows the schematic representation of an exemplary embodiment of the invention,

2 shows schematic representations of the various current-voltage curves when operating the circuit shown in Fig. 1,

3 shows another embodiment of the invention.

The circuit shown in Fig. 1 consists of an anode 11 and a cathode 12 having flash lamp 10, which with a Storage capacitor 13 connected in parallel to a voltage source 14 is connected. Between the positive terminal of the voltage source 14 and the storage capacitor 13 is a resistor

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stood 15, which with the capacitor 13 an R-C charging circuit for the flash lamp 10 forms. Between the anode 11 and a point connected to the resistor 15 and the storage capacitor 13 lies a diode 16 through which the occurrence of a flowing in the opposite direction during the triggering of the flash lamp Current is prevented.

The other side of the capacitor 13 is connected to the cathode 12 of the flash lamp and to the anode of a controllable silicon rectifier 17, the cathode of which is connected to the negative terminal of the Voltage source 14 is. The silicon rectifier 17 has a control electrode 18 through which it can be in can be transferred to its conductive state. In parallel with the controllable silicon rectifier 17 is a resistor 19 whose Impedance many times greater than the impedance of the resistor 15 is. The flash lamp 10 is ignited by an amplified high voltage pulse generated by a in the right part of the Trigger circuit 20 arranged in the circuit shown in FIG. 1 is generated. The terminal 21 of the trip circuit is on the one hand with the positive pole of a voltage source 32 delivering approximately 100 volts and, on the other hand, with a current-limiting resistor 22 connected, the other end of which is connected to a blocking capacitor 23 and the anode of a controllable silicon rectifier 24, the Control electrode is connected to an input terminal 26. The blocking capacitor 23 is connected to the primary winding of a transformer 27 connected in series. The other side of this primary winding is connected to the cathode of the controllable silicon rectifier via a line 28 24 and the terminal 29 of the voltage source 32 are connected. The secondary winding of the transformer 27 is on the one hand with the cathode 12 of the flash lamp 10 and on the other hand via a resistor 30 and a capacitor 31 with the anode 11 of the flash lamp tied together. The control terminal 26 is connected to the control electrode 25 of the silicon rectifier 24 and to a monostable multi, vibrator 33 connected, which delivers a narrow output pulse to a current driver 34 with each excitation. The current driver generates an output signal of a certain duration that the control electrode 18 of the controllable silicon rectifier 17 to-EN 973 002

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is performed, by which this is transferred to its conductive state for the duration of the control pulse supplied to it.

If an ignition signal is applied to the control electrode 26 and from there Transferred to the control electrode 25 of the controllable silicon rectifier, this becomes conductive and enables the discharge of the capacitor 23, through which in the primary winding of the transformer 27 a pulse is generated. This creates a trigger pulse in the secondary winding of the transformer, which over the resistor 30 and the capacitor 31 is transmitted as a narrow high-voltage pulse to the anode 11 of the flash lamp 10, where it superimposes the already applied voltage. This part of the circuit is isolated from the charging circuit by the diode 16. If the storage capacitor is fully charged by the voltage source 14, the gas in the flash lamp 10 is when it occurs of the high voltage pulse ionized at the anode 1T and a discharge of the storage capacitor 13 via the diode 16 and the Flash lamp 10 initiated. The lamp current caused by the trigger pulse is shown in FIG. 2 by curves a and b shown. The amount of current required to maintain the conductive state of the flash lamp 10 is indicated by the dashed line Line shown in the area of curve b.

If a signal is applied to the input terminal 26 in order to switch on the controllable silicon rectifier 24, the monostable multivibrator 33 is triggered at the same time, which generates an output signal after a predetermined time interval. This time interval is dimensioned in such a way that the gas in the flash lamp is deionized and the conductivity is thereby terminated. The end of the delayed pulse occurring at the output of the monostable multivibrator 33 switches on the current driver 34, which in turn switches on the controllable silicon rectifier 17 via the control electrode 18. The result of the delayed activation of the controllable silicon rectifier is shown in FIG. 2 by curves e and f, which reflect the current flow and the change in voltage on the storage capacitor.
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While the controllable silicon rectifier 17 is in its non-conductive state, the charging circuit for the consisting of the elements 15 and 13 R-C network the controllable silicon rectifier 17 and the connected in parallel Resistor 19. Since the resistor 19 limits the charging current to a considerable extent, this is not sufficient to prevent the discharge in the Maintain flash lamp 10. If the controllable silicon rectifier 17 is switched on later by the current driver 34 (curve g), so it forms a low-resistance element for bypassing the resistor 19 and enables an almost normal charging speed. The charging current flowing when the controllable silicon rectifier is switched on is passed through point 36 of Curve e shown. If the capacitor 13 is fully charged, the current flow is reduced to such an extent that the controllable silicon rectifier 17, as represented by point 37 of curve e in FIG., Is no longer in its conductive state. This will result in greater intervals between the individual discharges the state of charge of the storage capacitor 13 is maintained. The current driver 34 is preferably set so that that its switching signal ends shortly thereafter. This ensures that the controllable silicon rectifier is prevented from occurring of the next trigger pulse is switched off.

By connecting the resistor 19 and the controllable in parallel Silicon rectifier 17 enables precise control of the charging current, which results in an undesirable continued duration the discharge of the flash lamp 10 is avoided. The delay between the occurrence of a flash trigger signal at input terminal 26 depends on the properties of the flash lamp used away. The required delays are generally of the order of a few milliseconds, since after this time the gas in the lamp is deionized again, so that the recharging of the storage capacitor 13 can begin. The switching signal for the controllable silicon rectifier 17 need not, as shown in the present embodiment, with the Flash trigger signal coupled to the input terminal 26, it

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Rather, it can also be derived from other sources, the signals of which are in a certain temporal relationship to that of the The flash trigger signal applied to input terminal 26 is available.

In the circuit shown in Fig. 1, the negative terminal the power source 14 must be grounded. In this case, the capacitor terminals and the cathode of the flashlamp would be when the Controllable silicon rectifier 17 assume an indefinite voltage above ground potential, while they are switched on controllable silicon rectifier are approximately at ground potential during the charging process of the capacitor. In Fig. 3 Another embodiment of the invention is shown, in which the arrangement shown in Fig. 1 corresponding elements are denoted by the same reference numerals. In this exemplary embodiment, the cathode of the controllable silicon rectifier 17 and the flash lamp must be earthed. The positive terminal of the current source 14 is then switched on when the controllable silicon rectifier is conductive 17 are approximately at earth potential. If the controllable silicon rectifier is not conductive, the positive one takes Terminal of the power source to undefined values. In this case, the flash lamp 10 is shown in comparison to that shown in FIG Device polarized in reverse. One terminal of the storage capacitor and the flash lamp is then always at ground potential, like this this is also the case in the absence of a controllable silicon rectifier. The embodiment shown in Fig. 3 has has the advantage that the flash lamp does not assume any undefined values above zero during part of the flash cycle.

An advantage of the in FIGS. 1 and 3 circuits shown is that the resistor 15 and thus the time constant the charging circuit at a given value of the storage capacitor 13 can be reduced in size, so that the flash lamp with a higher Flash frequency can be operated with the same pulse energy. Since the charging voltage at the terminals of the lamp only after entry the deionization is present, a maintenance of the discharge by the charging current of the capacitor is excluded. Included

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can be one of those required to maintain the discharge Voltage similar, but limited by a high resistance Voltage can be used to switch the controllable silicon rectifier current to ensure that the Flash lamp is in its non-conductive state when the controllable silicon rectifier is switched on.

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Claims (5)

- 8 PATENT CLAIMS Ignition circuit for flash lamps with a storage capacitor that can be charged by an energy source via a limiting resistor, which can be discharged by a trigger pulse via a flash discharge lamp, characterized by a lying in the charging circuit, a maintenance of the discharge of the ignited flashlight (10) when discharged Storage capacitor (1S) preventing limiting resistor (19) and a parallel connected to it, at the time of ignition non-conductive low-resistance electronic switch (17), which, via a delay device (33) with a trigger pulse source (26) connected by the delayed trigger pulse a short time after the end of the lightning discharge is made conductive. 2. Ignition circuit according to claim 1, characterized in that that the electronic switch (17) consists of a controllable silicon rectifier. 3. Ignition circuit according to Claims 1 and 2, characterized in that that the delay device (33) is designed as a monostable multivibrator. 4. Ignition circuit according to Claims 1 to 3, characterized in that that the negative terminal of a power source (14) is grounded, such that the cathode (12) of the flashlamp (10) and the storage capacitor (13) when the controllable silicon rectifier (17) is switched off on an above Ground potential and, when the silicon rectifier is switched on, are approximately at ground potential. 5. Ignition circuit according to claims 1 to 4, characterized in that that the anode (11) of the flash lamp (10) and one terminal of the storage capacitor (13) are grounded in such a way that that with conductive controllable silicon rectifier (17) EN 973 002 409883/0816 the positive terminal of the power source (14) is almost open Ground potential and with non-conductive controllable silicon rectifier on an indefinite, over the potential lying on the earth potential. en 973 002 409883/0816 Blank page