DE4128551A1 - Stroboscope with external energy source - uses blocking transducer switched network between energy source and flash capacitor - Google Patents

Abstract

The stroboscope, providing individual light flashes with exactly the same energy, has an external energy source (1) providing the charging voltage for a capacitor (2) which is discharged via the flash light tube (3). A blocking transducer switched network (4) is inserted between the energy source (1) and the capacitor (2), for providing a preset charging voltage dependent on the required flash voltage, to allow direct charging of the capacitor (2). Pref. the flash voltage is variable, with the switched network (4) switched out when a max. flash capacitor charging time is exceeded. USE/ADVANTAGE - For video camera recording. Ensures long working life of flash light tube and equal brightness for each frame.

Description

The invention relates to a stroboscope with an ex ternal energy source through which a charging voltage is available is provided, a flash capacitor, which by means of through the charging voltage provided by the energy source is rechargeable, and a flash tube through which the charged Flash capacitor is discharged.

Stroboscopes generate short, rapidly successive light impulses. To do this, the charged flash capacitor is connected to the Discharge flash tube.

The discharge takes place by impact ionization of the gas filling Flash tube as soon as a high voltage pulse <10 kV to the Ignition antenna of the flash tube is placed.  

The flash capacitor, which is the energy for the flashes or Stores light pulses between flashes or light impulses are charged. To the external used Not to overload the energy source is traditionally the charging current is limited.

In known stroboscopes is used to charge the Blitzkon a voltage source (mostly mains voltage, possibly with doubling), which is connected via a resistor Flash capacitor recharges. The main disadvantages of this Technology result as follows: Since no deionization pause can be observed the loading speed can be greatly reduced. So that results a low achievable flash frequency. Because the lightning capacitor is recharged immediately after flashing, would otherwise the at comparatively high flash frequencies Gas filling the flash tube stay ionized and it becomes a continuous discharge (ignition). The life The duration of the flash tube would be strong by such an operation reduced.

The charge voltage of the flash capacitor depends on the less output voltage of the power supply and the flash frequency apply  from. There is no regulation. This creates Hel fluctuations, for example in video recordings appear particularly disruptive.

A high power dissipation arises in the resistor, up to can be approximately 50% of the total output, resulting in a correspondingly high heat development results. With that be off a power <50 W either large resistances required, which lead to a considerable increase in costs and weight, or the operating time must be limited.

The efficiency can be increased by limiting the current de resistance through a coil or an inductor is set. This advantage is, however, due to new aftermath parts bought: The coil forms one together with the flash capacitor Resonant circuit. Depending on the lightning frequency is due to resonance the flash capacitor is charged to double the voltage, which may well be desirable. The tension now hangs but both from the supply voltage and from the Flash frequency.

The charging current at low frequencies and large codes To be able to limit gates is a coil with high inductance  vity and high current carrying capacity required. In addition to the There is a significant weight increase in cost; the heat development limits the operating time.

Existing stroboscopes with ar switching power supply use either resistors or inductors Current limiting or charging the capacitor for a very long time sam on. The disadvantage is a low one Flash frequency.

The invention has for its object to a stroboscope create whose single flashes have exactly the same flash energy have, whereby, e.g. B. in video mode, the single shot men have the same brightness.

This object is achieved in that in Current direction between the energy source and the Blitzkon capacitor a flyback switching power supply is arranged with that provided by the energy source Charge voltage up to the required lightning voltage malleable and the flash capacitor without intermediate connection for current limiting components can be charged directly. Due to the current source character of the flyback switching network partly there is a current limit for charging the flash capacitor at frequencies above 1000 Hz  required; Furthermore, the control can be designed that the lightning voltage changes in specific areas will remain constant in individual frequency ranges.

A flyback switching power supply is particularly suitable for Charging the flash capacitor as the output voltage is close can be varied as desired. Other circuits like Flux converter or push-pull switching power supplies (voltage sources), work with an almost constant output voltage and would become Current limitation in turn require a coil.

The combination of the flyback switching power supply with one special control circuit allows a much exact tere control of the charging process. The flyback converter switching network part does not work due to the wide output voltage range with a fixed frequency, rather is an adaptation to the drawer condition of the capacitor required. But with that in addition the output current is limited, resistance or coil the conventional stroboscopes are no longer required.

In one embodiment of the stroboscope, in which the flash capacitor voltage constant after reaching the lightning voltage is held, the flash capacitor will open as quickly as possible charged until the set flash voltage is reached. To the next time the flash is triggered, the capacitor chip  then kept constant. Especially at low frequencies Zen is thus countered by an interim discharge works.

Charging the flash capacitor after the Flash for a short blocking time in the microsecond range interrupted to deionize the gas filling in the Ensure flash tube.

The charging time of the flash capacitor is also monitored. This helps to keep the electronics and flash tube going ignite the flash tube to secure it. If e.g. B. the stroboscope with a flash frequency close to the deionization time the filling gas of the flash tube must work or the flash tube re briefly thermally with increased flash energy is loaded and the flash tube may ignite the flash capacitor does not open in the set time Loading. The power supply switches off immediately and thus secures the flash tube and the electronics. After the expired the switching stroboscope goes into operation again.

If with the stroboscope using a monitoring circuit a temporary shutdown of the flyback converter switching network partly occurs when the specified charging time of the flash condenser sator is exceeded, the operation is immediately under  broken if the flash capacitor in the given time cannot be charged to the desired voltage. This allows the flash tube to ignite safely and quickly be recognized, the tube and the circuit are over load protected.

Some additional advantages are thus achieved, namely high efficiency, low volume and low light weight, uniform brightness, short loading time, a high flash frequency, one by deionization pause safe operation, monitoring of the charging process and an optional constant or variable charging voltage.

The last point is an essential one shaft. The charging voltage is not only constant, but can also be selected variably. With the conventional Circuit technology was such a setting only in stages possible (taps on the transformer etc.) and because of the small due to constant charging voltage also makes little sense. Especially with Video applications, however, is an exactly adjustable brightness required.

If on the unloading side or in the unloading circuit of the Flash capacitor a thyristor is arranged, the Functionality of the stroboscope can be further improved,  because if in the discharge of the flash capacitor in the Flash tube the flowing current under a certain If the value drops, the correspondingly arranged thyristor blocks within a few microseconds The locking delay time of the Thyristors is shorter than the deionization time Flash tube. Thus, the previously used for deionization required time during the period up to the lock Delay time for charging the flash encoder be used. This results in higher performance or possible higher frequencies with safer operation due to longer ones Break times of the flash tube. The thyristor can with the Flyback converter switching power supply without one, as with others Capacitor charging principles necessary switching element turned on be set because the generated by the flyback switching power supply Charging pause automatically the necessary to lock the thyristor Interruption of the current flow.

In the following, the invention is illustrated by means of embodiments explained in more detail with reference to the drawing.

In the drawings: Figures 1, 2, 3 and 4 embodiments of the circuit according to the invention of the stroboscope;. and FIGS . 5 and 6 procedures during the flash period under different embodiments of the invention.

In a flyback converter switching network part 4 shown in Fig. 1 flows in the first of the two working phases a li near increasing current in the primary winding. The level of the current results from the supply voltage of the external energy source 1 , the inductance and the duty cycle. In the second phase, the primary circuit is interrupted and the transformed primary current flows in the secondary winding. When charging a flash capacitor 2 there is a section of an almost undamped oscillation.

The control used works on two levels: the two work phases are carried out alternately until the flash capacitor 2 is charged to the desired flash voltage. Then the lightning or capacitor voltage is kept constant.

The current in the primary circuit is interrupted as soon as a target worth is reached. The primary circuit is closed again as soon as the secondary current has decayed to near zero. As a result, the diodes on the secondary side switch to zero passage from.  

Furthermore, the charging of the flash capacitor 2 after the flashing can be delayed by an adjustable time in order to give the gas filling time for deionization.

The precise control of the charging process makes it possible to monitor the charging time. If the flash tube 3 should ignite, the flash capacitor 2 cannot be charged in the given time. The controller switches in this case, the flyback converter switching power supply 4 for a short time in which the flash tube 3 can cool down.

The following advantages result for the stroboscopic operation: The charging of the flash capacitor 2 takes place only after a defined pause.

The firing of the flash tube 3 can be detected extremely quickly (a few milliseconds in contrast to a few seconds in conventional circuits).

The capacitor voltage is extremely stable, its level does not depend on the supply voltage or the flash frequency which results in a uniform brightness.

The flash or condensers can be used to control the power in operation  sator voltage be changed specifically.

In the embodiment according to FIG. 2, the supply voltage made available at the external energy source 1 is 24 volts. With a constant supply voltage, the level of the primary current is determined with sufficient accuracy by the switch-on time of a monoflop.

Phase 1 begins when it is determined on a comparator K 2 that the lightning voltage is lower than the nominal value of the U, and when it is determined on a comparator K 1 that the secondary current is less than the predetermined minimum secondary current ISmin (voltage drop across diodes D 1 , D 2 ), with triggering a monoflop MF 1 . The output of the monoflop MF 1 controls a transistor T 1 , which then turns on. A current begins to flow in the primary winding of the transformer 4 a of the flyback switching power supply 4 . The level of the current results from the level of the supply voltage, the inductance of the primary winding and the turn-on time of the transistor T 1 .

Phase 2 begins as soon as the monoflop MF 1 drops. The transistor T 1 blocks, the current now flows in the secondary winding and charges the diode D 3 to the flash capacitor 2 . The current in the secondary winding produces a voltage drop across the diodes D 1 , D 2 . If this voltage drop is smaller than the comparison value ISmin, the output of the comparator K 1 , which was switched off during phase 2 , switches on again. The monoflop MF 1 can be triggered again; phase 1 , etc.

When the lightning voltage is reached, the comparator K 2 switches off and prevents the monoflop MF 1 from being triggered again. If the lightning voltage drops, charging cycles are carried out again.

In the event of a flash, a monoflop MF 2 is triggered via the element 5, as a result of which the flash capacitor 2 is prevented from being recharged for a specific time. The pause for deionizing the flash tube 3 already mentioned is thus achieved.

In contrast to the embodiment just described according to FIG. 2, the mono flop MF 1 is replaced by a flip-flop FF in the embodiment according to FIG. 3. Instead of switching on the transistor T 1 for a certain fixed time, the voltage drop across a resistor R 1 is evaluated. The transistor T 1 is switched off when the comparison value for the primary current IPmax is reached. The rest of the charging circuit works as in the embodiment according to FIG. 2.

For the sake of clarity, the circuit part for monitoring the charging time is not shown. Another mono flop MF 3 is started after the deionization pause. If U-Soll is not reached as long as the Monoflop MF 3 is set, the charging time has been exceeded, which leads to a short cooling pause.

Due to fluctuating input voltage in the embodiment according to FIG. 3, regulation of the primary coil peak current is necessary.

The embodiment of the circuit shown in FIG. 4 differs in terms of a thyristor 6 connected between the flash capacitor 2 and the flash tube 3 from the embodiment according to FIG. 1. As a result, as can be seen from FIGS . 5 and 6, the deionization time Flash tube are already largely used for charging the flash capacitor 2 .

Claims (6)

1. stroboscope with an external energy source ( 1 ), through which a charging voltage is made available, a flash capacitor ( 2 ), which can be charged by means of the charging voltage provided by the energy source ( 1 ), and a flash tube ( 3 ), Via which the charged Blitzkon capacitor ( 2 ) is discharged, characterized in that in the current direction between the energy source ( 1 ) and the flash capacitor ( 2 ) a flyback switching power supply ( 4 ) is arranged by means of which the energy source ( 1 ) provided charging voltage can be transformed up to the required flash voltage and the flash capacitor ( 2 ) can be charged directly without the intermediary of current limiting components. 2. Stroboscope according to claim 1, wherein the flash capacitor voltage kept constant after reaching the lightning voltage and is therefore frequency-independent. 3. Stroboscope according to claim 1 or 2, wherein the flash voltage is variable. 4. A stroboscope according to any one of claims 1-3, wherein the recharge of the flash capacitor ( 2 ) after a flash only takes place after a blocking period. 5. Stroboscope according to one of claims 1-4, in which means of a monitoring circuit is used to temporarily switch off the flyback converter switching power supply ( 4 ) when the predetermined maximum charging time of the flash capacitor ( 2 ) is exceeded. 6. Stroboscope according to one of claims 1-5, in which a thyristor ( 6 ) is arranged between the flash capacitor ( 2 ) and the flash tube ( 3 ).