DE4141675A1 - Flashlamp operation circuit performing continuous on=off switching - utilises semiconductor switch with photodiode in control circuit monitoring limiting current during discharge of capacitor - Google Patents

Abstract

The lamp (5a) is wired in series with an inductor (7) whose stored energy is dissipated in the form of current through a free-wheel diode (8) in parallel with the combination (5a,7). A semiconductor switch (6) is opened on attainment of a limiting current (about 150 A). On reclosure, further triggering (4) of the lamp (5a) is unnecessary because of sufficent residual ionisation. The cycle is continued until the capacitor (2) is discharged. USE/ADVANTAGE - With photographic camera. Short arc lamp having electrodes less than 1 cm apart can be used about 3000 times, dissipating 10 to 20 J per flash.

Description

Almost all photo cameras today have a built-in electron flash. In principle, a circuit according to FIG. 1 is used. A supply DC voltage source 1 with the United supply voltage U charges the flash capacitor 2 with the capacitance C, which stores the flash energy. The discharge is triggered capacitively via the electrode 3 by a trigger pulse of approximately 5 kV on the line 4 . The discharge current I then rises to its peak value I _max in a few microseconds and then falls exponentially with the time constant τ = R _i C, since the flash lamp 5 has an approximately constant internal resistance R _i in the high-current part of the discharge. The loss resistance of the circuit is around 100 mΩ.

The time course of the discharge current is shown in FIG. 2. The internal resistance R _{i of} the flash lamp 5 is important for all of the following considerations. The following applies approximately:

R _i = d ^-2 · e ^1.5 · U ^-0.5 · p ^0.25

With
d = inside diameter (mm)
e = arc length (electrode spacing) (mm)
U = supply voltage (V)
p = Xenon cold filling pressure (bar)

The following compilation shows practically possible combinations of flash energy, arc length etc. for flash lamps with the most common internal diameter d = 2.0 mm, operated in the circuit according to FIG. 1.

Flash lamps with e <10 mm have a poor light efficiency and a completely insufficient lifespan due to I _max ≈ 1 kA. The current I _max can only be reduced to a value of ≈ 350 A with an inductance of acceptable size (L <20 µH) connected in series with the flash lamp. Flash lamps with e <20 mm are out of the question for built-in electron flashes.

Nevertheless, the desire of the camera manufacturers remains for flash lamps with e <10 mm, ideally even e ≈ 5 mm, because such lamps allow a much smaller reflector and the focusing of the flash light over longer distances would ease.

In addition, there is the requirement that the exposure control should be realized by switching off the discharge current I even with built-in electronic flashes. In the prior art, this requires flash lamps with R _i <2 Ω, which can only be realized with inner diameters d <1.5 mm and 15 <e <20 mm. For such flashes with switching the discharge current on and off for a wide variety of purposes, there are, for. B. circuits according to DE-A-39 40 657, which, however, do not have the use of short-arc flash lamps with 5 <e <10 mm and flash energies 10 <E <20 Ws.

So the desire for a short arc length of e <10 mm seems with known circuits and flash lamps incompatible with the Demands for:

• - sufficient flash energy 10 <E <20 Ws,
• - Switchability of the flash lamp at low discharge currents ≈ 150 A,
• - good light efficiency,
• - good lamp life (approx. 3000 flashes),
• - sufficient flash duration τ <1 ms,
• - Reasonable circuit effort.

The invention has for its object a circuit for the operation of a short-arc flash lamp and such a flash to create lamps that meet these requirements.

With such a circuit, this object is according to the invention solved with a charge from a supply voltage source flash capacitor, an electrode for capacitive triggering flash lamp, an inductance between the condensers sator and the flash lamp, one parallel to the series connection made of flash lamp and inductance switched freewheeling diode and a semiconductor switch connected in series to the flash lamp, the flash lamp constantly when generating a flash is switched on and off.

The flash lamp for this circuit advantageously has one Electrode distance 10 mm, an inner diameter <2 mm and a filling pressure of 5 bar.

The invention is based on the drawing he he purifies. Show it:

Fig. 3 shows a circuit according to the invention,

Fig. 4 curves to explain FIG. 3,

Fig. 5 is a flash lamp for the circuit of Fig. 3,

Fig. 6 shows an example of the discharge circuit of the circuit of Fig. 3,

Fig. 7, the control circuit for the discharge circuit of FIG. 6, and

Fig. 8 to 17 waveforms useful for explaining the Fig. 7.

The circuit according to FIG. 3 basically corresponds to the circuit according to FIG. 1. Added are:

• the semiconductor _switch 6 with a limit current I _limit <150 A,
• inductance 7 with 5 <L <20 µH,
• - The freewheeling diode 8 .

The flash lamp 5 a is a short-arc flash lamp with 5 e 10 mm and 0.2 <R _i <0.5 Ω. The circuit for control and trigger pulses will be explained later.

After the switch 6 is closed, the flash lamp 5 a is triggered and the discharge current I ( FIG. 4) would rise to 1 kA within a few microseconds without further measures, with the switch 6 or the flash lamp 5 a being destroyed (curve a in FIG. 4). To avoid this, the switch 6 when reaching its limit current I _limit of z. B. 150 A open. The discharge current I through the flash lamp 5 A continues, however, because the freewheeling diode 8 allows the flow to continue until the magnetic energy of the inductor 7 is reduced. Then the switch 6 is closed again, triggering the flash lamp 5 a again being unnecessary since sufficient restionization is still present. This game continues until you want to cancel the discharge of the capacitor 2 or it is empty. The envelope curve b of this switched discharge (curve c in FIG. 4) is therefore approximately a rectangle. The peak load of the free discharge (τ ≈ 50 µs) according to curve a is thus distributed over a time window of <1 ms, and this is precisely what enables a flash energy E = 10 Ws on a flash lamp with e = 5 mm or E = 20 Ws to be implemented on a flash lamp with e = 10 mm.

In practice, however, with this switched discharge Light efficiency of flash lamps of the usual arc length 13 <e <20 come close, circuit and flash lamp meet the following characteristics:

• 1. The switch 6 must have an on-resistance <100 mΩ and low switching losses (rise and fall times). In addition, it has to consume little control power and should have a high limit current of e.g. B. tolerated 150 A, at least briefly. This is already achieved with today's Mos-Fet or IGBT components.
• 2. The switching losses during a lightning discharge are dependent on the number N of switching operations (on / off) of the switch 6 . One tries to keep N down. Without inductance 7 , N would be approximately 10,000 with intolerable switching losses.
  Depending on the R _i and e of the 5 A flash lamp, there is a minimum of switching losses at L = 10 to 20 µH, which leads to N = 100 to 1000 switching operations. Then the switching losses are approx. 10% of E.
• 3. During the discharge of the capacitor 2 , the voltage U drops and thus with every new switching operation. So the on-time of the switch 6 can be steadily increasing in order to always use I _{limit of} the switch 6 and to minimize the number of circuits N. To control the switch 6 ver used a circuit that detects reaching I _limit and opens the switch 6 . However, it is more elegant to measure the reaching _limit by the light intensity of the flash lamp.
  In contrast, the off time of the switch 6 can be constant, since the magnetic energy stored in the inductor 6 does not change from circuit to circuit. The off time of the switch 6 should, however, be as small as possible in order to avoid cooling of the plasma and the associated losses.

An advantageous embodiment of the control circuit is described in FIG. 7.

Although the short-arc flash lamp 5 a used in FIG. 3 is basically constructed in exactly the same way as flash lamps of "normal" arc length, there are the following different features which improve the service life and the light efficiency:

• 1. The xenon cold filling pressure p is usually limited to 1 bar, but can be increased to p = 5 bar in switching mode without the flash lamp exploding or having an impractically thick glass wall because the thermal pressure increase due to the current limitation (I _limit ) is defused. This can increase the light efficiency of the flash lamp by up to 20%.
• 2. The use of a flash lamp glass with a high proportion of Cs ₂ O has a particularly favorable effect on the short-arc flash lamps operating in switching mode because the blackening of the glass wall is suppressed by worn cathode material.
• 3. By limiting the current to I _limit in switching operation, the short-arc flash lamp _produces fewer undesirable blue and UV components in its xenon spectrum. Measures for color correction can therefore be omitted. The generation of useless IR radiation in the range of 700 to 1000 nm can also be greatly reduced because the lamp no longer needs buffering dead spaces in switching mode, in which the IR light would otherwise be generated.

FIG. 5 shows a flash lamp 5 a that can be used in the circuit according to FIG. 3 with a glass tube 9 with a high Cs ₂ O content and small dead spaces.

The circuit of FIG. 6 corresponds to FIG. 3, but the firing circuit is added. It contains a capacitor 10 with a capacitance C ₂ ≈ 0.33 μF, which is charged via the resistor 11 with R ₁ = 1 MΩ. If the switch 6 is opened, the capacitor 10 discharges via the diode 12 and generates a trigger pulse via the ignition transformer 13 . The diode 12 prevents renewed triggering when the switch 6 is closed .

The rest of the circuit works as described in FIG. 3.

The photodiode 14 is attached in the vicinity of the flash lamp 5 a and is used to measure I _limit . The signal is evaluated in the control circuit according to FIG. 7 and fed to the gate of the switch 6 .

The circuit of FIG. 7 includes an amplifier 15 for the current of the photodiode 14, a comparator 16, a monostable multivibrator 17, an inverter 18, a monostable multivibrator 19, a NOR gate 20, a NAND gate 21, an inverter 22, a Amplifier 23 and a monoflop 24 . The output signal of the amplifier 23 controls the switch 6 . A start signal for triggering a flash is fed to the monoflop 24 .

Fig. 8 shows the signal from the photodiode 14 at the point A.

The signal according to FIG. 9 at point B is amplified and rotated by 180 °, the DC voltage component is filtered out.

From a certain voltage level, the comparator 6 is set or reset, so that its output signal at the point C in FIG. 10 runs.

The two monoflops 17 , 19 and the NOR gate 20 form the pause times (flash lamp off). The signals at locations DEFG are shown in FIGS . 11 to 14.

The monoflop 24 specifies the total switch-on time (total burning time of the flash lamp 5 a). Its output signal at location H is shown in FIG. 15.

Nand gate 21 , inverter 22 and amplifier 23 provide the control signal to the switch 6 . The signals at points I, K are shown in FIGS. 16, 17.

It is essential that the flash lamp 5 is constantly switched on and off with the switch 6 ( FIG. 4) in order to prevent the limit current of the switch 6 from being exceeded.

Claims (3)

1. Circuit for the operation of a flash lamp ( 5 a) with a from a supply voltage source ( 1 ) rechargeable Blitzkon capacitor ( 2 ), an electrode ( 3 ) for capacitive triggering of the flash lamp ( 5 a), an inductance ( 7 ) between the con capacitor ( 2 ) and the flash lamp ( 5 a), a parallel to the series circuit of flash lamp ( 5 a) and inductance ( 7 ) ge connected freewheeling diode ( 8 ) and a series switch to the flash lamp ( 5 a) connected semiconductor switch ( 6 ), wherein the flash lamp ( 5 a) is constantly switched on and off when generating a flash. 2. Circuit according to claim 1, in which a photodiode ( 14 ) with a downstream control circuit ( Fig. 7) for the semiconductor switch ter ( 6 ) for monitoring the limit current of the flash lamp ( 5 a) is present. 3. flash lamp for a circuit according to claim 1 or 2, in which the electrode spacing is less than 10 mm, the diameter of the hollow cylindrical interior is less than 2 mm and the filling pressure p 1 <p <5 bar and the glass tube has a high proportion of Cs ₂ O contains.