EP0399201B1 - Flashlight warning system - Google Patents

Description

The invention relates to a light flash warning system, with a voltage source, with a flyback converter connected to the voltage source, with two storage capacitors connected to the flyback converter, with a flash tube connected in parallel with the storage capacitors, with an ignition circuit, with an electrical switch in series with the first storage capacitor and with a first electrical voltage sensing device that determines the charging voltage of the first storage capacitor and compares it with a predetermined first reference voltage.

From US-PS 36 44 818 such a flashing light warning system is known which has two storage capacitors, one of which is connected in series with an electrical switch. If the electrical switch is closed, both storage capacitors are charged to the same charging voltage. If the electrical switch is open, the first storage capacitor is charged via a resistor much more slowly than the second storage capacitor. These measures are intended to be able to influence the electrical energy supplied to the flash tube and thus the light flash energy as a function of the switch position.

This previously known flashing light warning system also has an electrical voltage sensing device which determines the charging voltage of the first storage capacitor and compares it with a predetermined reference voltage. However, this voltage sensing device does not control the electrical switch.

However, the known flashing light warning system has disadvantages. The electrical switch there is designed as a manually operated switch and enables, depending on his Switching state, only two possible energy levels that can be stored in the storage capacitors. The resistance that causes the slower charging of the second capacitor only leads to a substantially reduced charging of the first storage capacitor if the flyback converter is switched off after a predetermined period of time, if, for. B. the second storage capacitor is charged, that is, a complex control of the flyback converter is required. In the known light flash warning system, both capacitors must have the same dielectric strength, even if the first storage capacitor is charged to a lower voltage than the second storage capacitor. This means that the first storage capacitor must be selected accordingly in a costly manner and with a large space requirement.

A flashing light warning system is known from EP-A1 0 219 999, in which an electrically controllable switch is provided. This electrically controllable switch only charges the first storage capacitor when the second storage capacitor has been charged and discharged via the flash tube. These measures serve to generate a double flash of the flashing light warning system with a flash tube, the second flash of light generated being intended to have a greater intensity than the first flash of light generated.

This known light flash warning system has the disadvantage that it is only suitable for generating double light flashes. However, it is not possible to generate a flash of light with variable energy or flash light intensity.

The invention has for its object to provide a light flash warning system which is simple and inexpensive to manufacture and which, with reliable ignition of the flash tube, enables the energy or light flash intensity of the light flash generated to be largely influenced.

This object is achieved in that the switch is electrically controllable and that the first voltage sensing device opens the switch when the charging voltage of the first storage capacitor exceeds the first reference voltage.

Because the switch is designed to be electrically controllable, the switch can be influenced by further electrical devices of the flashing light warning system and the charging of the first capacitor can thus be controlled. The reference voltage can now be chosen almost as long as it is between the values of 0 volts and the maximum permissible charging voltage of the first storage capacitor. In the maximum case, the reference voltage can correspond to the maximum permissible charging voltage of the second storage capacitor if the maximum charging voltage of the first capacitor has been chosen to be correspondingly high. According to the invention, the voltage sensing device opens the electrically controllable switch when the charging voltage of the first storage capacitor exceeds the predetermined desired first reference voltage.

The flashing light warning system according to the invention has the advantage over the prior art in particular that the safe ignition of the flash tube is effected by the second storage capacitor having a comparatively small capacity and charged to full charging voltage. The electrical energy for the continued operation of the flash tube is then supplied by the first capacitor, possibly with a low charging voltage, but with a significantly higher capacitance than that of the second storage capacitor. By specifying the reference voltage, the charging voltage of the first storage capacitor and thus the light energy or light intensity of the light flash of the light flash warning system according to the invention can now be influenced within wide limits.

The flashing light warning system according to the invention has the further advantage that the maximum charging voltage or the dielectric strength of the first storage capacitor can be chosen to be smaller than that known before, because after the flash tube is ignited, the flashing light warning system continues to operate in order to maintain the arc of the light tube, compared to the ignition voltage, low voltages are sufficient. Frequently, the required ignition voltage of flash tubes is around 500 volts, whereas the voltage for maintaining the gas discharge of the flash tube is around 150 volts. By means of the measures according to the invention, the first storage capacitor can be chosen to be smaller compared to the prior art, and the construction of the flashing light warning system according to the invention is more economical than the prior art. In addition, the first storage capacitor of the flashing light warning system according to the invention takes up less space than the previously known.

Advantageous refinements and developments of the flashing light warning system according to the invention result from the subclaims.

The first voltage sensing device can advantageously have a voltage divider, consisting of two resistors, parallel to the first storage capacitor. The voltage drop at the center tap of the voltage divider is then proportional to the charging voltage of the first storage capacitor, but has a comparatively low absolute value compared to this charging voltage. This simplifies the further processing of the charging voltage in the voltage sensing device because comparatively low voltage values have to be determined and compared with a predetermined reference voltage.

The first voltage sensing device can advantageously have a comparator circuit, which as commercially available comparator is freely available. In this context, this comparator circuit can compare the voltage drop at the center tap of the voltage divider with a predetermined first reference voltage and open the electrical switch if the voltage drop exceeds the first reference voltage. A comparatively low voltage value can be used here as the reference voltage, which can easily be obtained from the DC voltage for supplying voltage to the primary side of the voltage converter.

It is also advantageous to provide a protective diode in parallel with the electrical switch, in order to prevent the electrical switch from being overloaded by overvoltages when the electrical switch is designed as a transistor, in particular as a field effect transistor, when the electrical switch is opened.

It is particularly advantageous if a power control circuit is provided for the flyback converter, the power control circuit reducing the output power of the flyback converter when the voltage sensing device opens the switch. If the charging voltage of the first storage capacitor exceeds the predetermined first reference voltage, the electrically controllable switch is opened and if no further measures are provided, the second storage capacitor is charged further with the full flyback converter power. This charging then takes place in very rough stages and very quickly and can possibly lead to an electrical overload of the second storage capacitor and cause its destruction because the dielectric strength of the second storage capacitor is comparatively high, but its capacitance is low. With the measures described above, the converter output power is reduced if only the second storage capacitor is charged, so that an electrical overload of the second Storage capacitor and thus its possible destruction is avoided.

It is advantageous if the power control circuit has an oscillator whose output power or electrical output signal is variable depending on the switch position of the electrical switch. It is particularly advantageous if the power control circuit has a rectangular oscillator, the output signal of which is electrically variable in frequency and / or in pulse width.

A second voltage sensing device can also be provided, which determines the charging voltage of the second storage capacitor and compares it with a predetermined second reference voltage and switches off the flyback converter when the charging voltage of the second storage capacitor exceeds the second reference voltage. With these measures, charging of the second storage capacitor beyond its maximum charging voltage is avoided on the one hand. On the other hand, the light flash warning system according to the invention can be easily and inexpensively adapted to flash tubes with different electrical properties and thus to the use of other storage capacitors. This also serves to protect the second storage capacitor against electrical overload and destruction.

In this context, the second voltage sensing device can advantageously have a voltage divider, which consists of two resistors and is arranged parallel to the second storage capacitor. Here, too, there is the advantage that a voltage can be determined at the center tap of the voltage divider that is proportional to the charging voltage of the second storage capacitor, but has a low absolute voltage value compared to the charging voltage of the second storage capacitor, and can accordingly be determined easily and safely and in the second voltage sensing device can be processed further.

The second voltage sensing device can also have a comparator circuit which compares the voltage drop at the center tap of the voltage divider of the second voltage sensing device with a predetermined second reference voltage, and switches off the flyback converter if the voltage drop exceeds the second reference voltage. Here, too, there is the advantage that a comparatively low voltage value can be used as the second reference voltage, which is simple and inexpensive DC supply voltage of the primary side of the voltage converter can be obtained.

In order to enable a periodically recurring generation of light flashes with the light flash warning system according to the invention, it is particularly advantageous if a clock generator is provided for periodically firing the flash tube. The clock frequency of the clock generator and thus the flash frequency of the flashing light warning system according to the invention is advantageously chosen so that it is lower than the charging frequency for charging the first and second storage capacitors, on the one hand to enable reliable ignition of the flash tube with each flash of light and on the other hand to flashes of light with the to generate predetermined light flash energy by the charging voltage of the first capacitor.

It is particularly advantageous if the power control circuit has an RC element, the charging time constant of which can be changed by a fifth resistor in parallel with a sixth resistor. The RC element then determines the basic frequency with which the flyback converter is controlled. If the electrical switch is closed, the sixth resistor is connected in parallel with the fifth resistor, so that the charging time constant of the RC element changes and the frequency with which the flyback converter is driven is changed. For simple parallel connection of the sixth resistor with the fifth resistor of the RC element, a third transistor can be advantageously provided in series with the fifth resistor and in parallel with the sixth resistor, which transistor can be controlled by the voltage sensing device.

An embodiment of the flashing light warning system according to the invention is shown in the drawings and is explained in more detail below with reference to the drawings.

• Figur 1 schematisch ein elektrisches Schaltbild einer erfindungsgemäßen Lichtblitzwarnanlage und
• Figur 2 Spannungsverläufe über der Zeit eines Oszillators der Lichtblitzwarnanlage nach Figur 1.

Show it

• Figure 1 shows schematically an electrical circuit diagram of a flashing light warning system according to the invention and
• FIG. 2 voltage curves over the time of an oscillator of the flashing light warning system according to FIG. 1.

In Figure 1, the positive pole of a voltage source (S), the z. B. an aircraft can be conductively connected to the primary winding of a flyback converter (W), which on the other hand is connected to the negative pole of the voltage source (S) via a second transistor (T2), which is designed as a metal oxide layer field effect transistor. A clock generator (T) is supplied with voltage from the voltage source (S), which generates periodic output signals and thus controls an ignition circuit (Z) which is also supplied with voltage from the voltage source (S).

The secondary-side turn of the flyback converter (W) is conductively connected via a first diode (D1), which acts as a rectifier diode, to an anode of a flash tube (B), the cathode of which is connected via a second diode (D2) and a third diode (D3), which are connected in anti-parallel, is connected to the other terminal of the secondary winding of the flyback converter. The cathode of the flash tube (B), the cathode of the second diode (D2) and the anode of the third diode (D3) are connected in parallel to the negative pole of the voltage source (S). The flash tube (B) has an ignition electrode which is conductively connected to the ignition circuit (Z).

The cathode of the rectifier diode (D1) is connected to the negative pole of the voltage source (S) via a first capacitor (C1), which is used as the first storage capacitor, and a fourth diode (D4), which acts as a discharge diode. A first transistor (T1) is connected in series with a fifth diode (D5) in parallel with the fourth diode (D4) Metal oxide layer field effect transistor is formed. The fifth diode (D5) serves to protect the first transistor (T1) against overload when the first capacitor (C1) is discharged.

Furthermore, a voltage divider consisting of a first resistor (R1) and a second resistor (R2) is provided in parallel to the first storage capacitor (C1), the resistors of which are on the one hand connected to the cathode, to the first diode (D1) and on the other hand to the negative pole the voltage source (S) are conductively connected. A second capacitor (C2), which is used as a second storage capacitor or auxiliary capacitor, is in parallel with a second voltage divider, consisting of a third resistor (R3) and a fourth resistor (R4), on the one hand with the cathode of the rectifier diode (D1) and on the other hand, conductively connected to the negative pole of the voltage source (S).

The voltage at the center tap of the first voltage divider, consisting of the first resistor (R1) and the second resistor (R2), is fed to the inverting input of a first comparator circuit (V1), the non-inverting input of which is conductively connected to a reference voltage source (UR). The output of the first comparator circuit (V1) is conductively connected to the control input of the first metal oxide layer field effect transistor (T1) and controls it. Furthermore, the output of the first comparator (V1) is conductively connected to the base of a third transistor (T3) which is designed as a bipolar transistor. The emitter of the third transistor (T3) is connected to a voltage stabilization circuit (US) and to an input of the reference voltage source (UR).

The collector of the third transistor (T3) is connected via a fifth resistor (R5) to a sixth Resistor (R6) and connected via a third capacitor (C3) to the negative pole of the voltage source (S) and to an input of a high-frequency oscillator (O).

The voltage at the center tap of the second voltage divider, consisting of the third resistor (R3) and the fourth resistor (R4), is fed to the non-inverting input of a second comparator (V2), the inverting input of which is connected to the output of the reference voltage source (UR). The output of the second comparator (V2) is conductively connected to the high-frequency oscillator (O). Furthermore, the voltage in the connecting line between the second diode (D2) and the third diode (D3) and the secondary winding of the flyback converter (W) is tapped and fed to an inverting input of a third comparator (V3), whose non-inverting input with the negative pole the voltage source (S) is conductively connected. The output signal of the third comparator (V3) is also fed to the high-frequency oscillator (O).

The high-frequency oscillator (O) controls the second metal oxide layer field-effect transistor (T2) via a driver or amplifier (A). This control takes place depending on the charging time constant of the RC element, formed from the third capacitor (C3) and the sixth resistor (R6) or formed from the third capacitor (C3) and the sixth resistor (R6) in parallel with the fifth resistor (R5 ). Furthermore, the output signal of the high-frequency oscillator (O) is dependent on the voltages at the center taps of the voltage parts and thus on the output signals of the second comparator (V2) and the third comparator (V3).

The function of the flashing light warning system according to the invention. Figure 1 is now explained in more detail with reference to the voltage profiles in Figure 2:
FIG. 2 shows the output voltage (U1) of the high-frequency oscillator (O) as a function of a time (t), the reference symbol (A), the switch-off time periods and the reference symbol (E) the switch-on time periods of the high-frequency oscillator (O) mark.

It is assumed that at the beginning of this consideration the circuit of the flashing light warning system according to the invention according to FIG. 1 is de-energized. As soon as the flashing light warning system according to the invention is conductively connected to the voltage source (S), the high-frequency oscillator (O) begins to oscillate and generates an output voltage (U1) according to FIG. 2a. In FIG. 2a, the first switch-on time period (E1) is constant over a first time period, whereas the switch-off time period (A), based on very long switch-off time periods at the beginning of the function of the flashing light warning system according to the invention, in the present exemplary embodiment the first switch-off time period (A1), depending on the time is getting lower and z. B. reaches the second switch-off time (A2) at a predetermined time.

During the first switch-on period (E1), the second transistor (T2) is turned on via the amplifier (A), so that current flows through the primary-side winding of the flyback converter (W). The electrical energy that flows through the primary-side winding of the flyback converter (W) leads, after the opening of the second transistor (T2), to a corresponding current flow in the secondary-side winding of the flyback converter (W). Determined by the number of turns of the primary-side and secondary-side turns of the flyback converter (W), the comparatively low voltage of the current source (S) is transformed to values sufficient for the ignition of the flash tube (B) and for the charging of the capacitors (C1 and C2). After the first predetermined switch-on time (E1) has elapsed, the second transistor (T2) is opened and the primary-side winding of the flyback converter (W) is separated from the voltage source (S). The current induced in the secondary-side turn of the flyback converter (W) flows rectified via the rectifier diode (D1) to the first storage capacitor (C1) and the second storage capacitor (C2), among other things, and charges these two capacitors, since at this point the first transistor is also charged (T1) is closed.

As long as a current flows in the secondary-side turn of the flyback converter (W), the connection point between the secondary-side turn of the flyback converter (W) and the second diode (D2) or the third diode (D3) has a negative potential which corresponds to the inverting input of the third comparator (V3) is supplied. In this case, the output signal of the third comparator (V3) is designed such that the high-frequency oscillator is stopped. That is, as long as a current flows in the secondary-side turn of the flyback converter (W), the oscillator (O) remains ineffective and the output signal of the high-frequency oscillator (O) remains at 0 volts, so that the second transistor (T2) is blocked.

As soon as the electrical energy of the secondary-side winding of the flyback converter is collected in the first storage capacitor (C1) and in the second storage capacitor (C2), the potential at the connection between the secondary-side coil of the flyback converter and the second diode (D2) or the third diode ( D3) its value so that the output signal of the third comparator (V3) assumes a potential opposite to the previous state and the high-frequency oscillator (O) is released. The result of this is that the output signal of the high-frequency oscillator assumes a value other than 0 and the second transistor (T2) is switched on again for the first switch-on period (E1). After this further first switch-on period (E1) has elapsed, the same processes are repeated as previously described. Because, however, that Storage capacitors (C1 and C2) are no longer empty, but have been partially charged with electrical energy by the previous processes, after this further switch-on period (E1) the electrical energy is transported from the flyback converter (W) into the storage capacitors (C1 and C2) more quickly. This has the consequence that the potential at the connection between the secondary-side winding of the flyback converter and the diodes (D2 and D3) has a correspondingly shorter negative value, so that the high-frequency oscillator is blocked correspondingly shorter. This means that the switch-off times decrease with increasing charging of the storage capacitors (C1 and C2). This results in the profile of the output voltage (U1) of the high-frequency oscillator (O) shown in FIG. 2a.

The previously described processes continue until the first storage capacitor (C1) has reached a predetermined first voltage threshold value. The charging voltage of the first capacitor (C1) is correspondingly reduced at the first voltage divider, consisting of the first resistor (R1) and the second resistor (R2), and is fed to the first comparator (V1). This comparator (V1) compares the charge voltage value of the first capacitor (C1) with a predetermined threshold value, which is predetermined by the reference voltage source (UR). As soon as the voltage at the center tap of the first voltage divider and thus the charging voltage of the first capacitor (C1) reaches or exceeds the predetermined reference voltage, the output signal of the first comparator circuit (V1) changes its potential, so that the first transistor (T1) is opened. This has the consequence that when the flyback converter (W) is switched on further via the second transistor (T2), the electrical energy induced in the secondary turn of the flyback converter (W) is only fed to the second capacitor (C2), but no longer to first capacitor (C1). This means that as soon as the first transistor (T1) is open, there is no further Charging the first capacitor (C1). As soon as the first comparator (V1) changes its output signal accordingly, the third transistor (T3) is turned on at the same time. As a result, the charging time constant of the RC element, which previously consisted of the sixth resistor (R6) and the third capacitor (C3), is changed because the fifth resistor (R5) is now connected in parallel to the sixth resistor (R6) is. As a result, the RC element determining the switch-on period of the high-frequency oscillator (O) no longer consists only of the resistor (R6) and the capacitor (C3), but of the resistor (R6) in parallel with the resistor (R5) and the capacitor (C3). This shortens the switch-on period of the high-frequency oscillator (O) as soon as the first capacitor (C1) is charged. The purpose of reducing the switch-on period of the high-frequency oscillator when the first storage capacitor (C1) is charged is to prevent the second storage capacitor from being overloaded. The first storage capacitor (C1) usually has a large storage capacity and is therefore often depicted as an electrolytic capacitor. However, it has a comparatively low dielectric strength. The second storage capacitor (C2) is to ensure the reliable ignition of the flash tube (B). Therefore, it has a comparatively high dielectric strength. However, its storage capacity is comparatively low.

As long as both storage capacitors (C1 and C2) are charged in parallel via the flyback converter (W), it is advantageous to shorten the charging time with correspondingly large switch-on times, such as. B. with the switch-on times shown in Figure 2a (E1) to charge the two storage capacitors (C1 and C2) in large bursts of energy. However, as soon as the first storage capacitor (C1) is faded out from further charging by opening the first transistor (T1) and only the second storage capacitor (C2) is charged via the flyback converter, it is advantageous to increase the switch-on time shorten in order to avoid that the second capacitor (C2) is supplied with excessive bursts of energy from the flyback converter (W).

If this measure were not used, it can happen in extreme cases that after the first storage capacitor (C1) is switched off, the second storage capacitor (C2) is practically fully charged, even overcharged, with a further long switch-on period (E1), which may be necessary. can lead to electrical overloading of the second storage capacitor and possibly to its destruction. The corresponding advantageous reduction in the switch-on time (E) is shown in FIG. 2b. There, the profile of the output voltage (UA) of the high-frequency oscillator is shown over a time (t) after the first transistor (T1) has been opened and the first storage capacitor (C1) has reached its predetermined charging voltage and is no longer charged. The on time (E) is shortened in FIG. 2b to a second on time (E2) and in the present exemplary embodiment is only about half the first on time (E1) in FIG. 2a. Due to the shortened switch-on time (E2), the switch-off time controlled by the third comparator (V3) is shortened at the beginning of the fading out of the first storage capacitor (C1), so that a comparatively short third switch-off time begins at the start of the further charging of the second speaker capacitor (C2) (A3) results, which is correspondingly further shortened as the charging of the second storage capacitor (C2) progresses until z. B. in the course of further charging results in a shortened fourth switch-off time period (A4) compared to the third switch-off time period (A3).

The second charging voltage of the second storage capacitor (C2) is also gem in accordance with the flashing light warning system according to the invention. the embodiment sensed. For this is a second voltage divider, consisting of the third resistor (R3) and the fourth resistor (R4) are provided, the potential at the center tap of which is directly proportional to the charging voltage of the second storage capacitor. The proportional at the center tap of the second voltage divider is fed to the second comparator (V2), which compares this potential with a threshold voltage likewise specified by a reference voltage source (UR). This threshold voltage usually corresponds to the maximum charging voltage or the dielectric strength of the second storage capacitor (C2) and is usually chosen by the choice of the second capacitor (C2) such that it corresponds to the ignition voltage required for the reliable ignition of the flash tube.

As soon as the potential at the center tap of the second voltage divider and thus the charging voltage of the second storage capacitor (C2) has reached the specified reference voltage, the second comparator (V2) changes its output signal at the output and also blocks the high-frequency oscillator (O) via an input. This blocking of the high-frequency oscillator (O) is maintained as long as the potential at the center tap of the second voltage divider or the charging voltage of the second capacitor does not drop. If one assumes that the leakage rates of conventional storage capacitors are usually comparatively low, the high-frequency oscillator (O) is now switched off practically until the flash tube (B) is ignited via the ignition circuit (Z). It also follows from the foregoing that in order to generate a flash of light with a predetermined intensity of flash, the charging of the storage capacitors (C1 and C2) described above had to be completed before the ignition circuit (Z) applies the ignition pulse to the flash tube (B) via the auxiliary electrode .

In order to enable the periodic generation of light flashes with the light flash warning system according to the invention the clock generator (T) is provided, which drives the ignition circuit (Z) periodically. Such periodic generation of flashes of light is e.g. B. when using the flashing warning system according to the invention as a flashing warning system for aircraft, in particular for airplanes, in which such flashing warning systems, for. B. are arranged in the wing ends or on the fuselage of the aircraft.

In summary, it can be said that the essential features of the described exemplary embodiment on the flashing light warning system according to the invention are as follows:
The switch-on period of the high-frequency oscillator (O) is variable depending on the charging voltage of the first storage capacitor. The switch-off period of the high-frequency oscillator (O) is also dependent on the charging voltage of the first capacitor and on the charging voltage of the second capacitor (C2). This applies both to the periods in which the storage capacitors (C1 and C2) are charged, as well as the time after the storage capacitors (C1 and C2) have been charged until the flash of light is triggered by the ignition circuit (Z) generating a time pulse. .

Claims (17)

1. A photoflash warning installation, with a voltage source (S), with a B.O.-type converter (W) connected to the voltage source (S), with two storage capacitors (C1, C2) connected to the B.O.-type converter (W), with a flashtube (B) connected in parallel with the storage capacitors (C1, C2), with an exciter circuit (Z), with an electrical switch (T1) in series with the first storage capacitor (C1), and with a first voltage sensing device which determines the charging voltage of the first storage capacitor (C1) and compares this with a predetermined first reference voltage, characterised in that the switch (T1) is electrically controllable and that the first voltage sensing device opens the switch (T1) when the charging voltage of the first storage capacitor (C1) exceeds the first reference voltage.
2. A photoflash warning installation according to claim 1, characterised in that the first voltage sensing device comprises a voltage divider consisting of two resistors (R1, R2) in parallel with the first storage capacitor (C1).
3. A photoflash warning installation according to claim 1, characterised in that the first voltage sensing device comprises a first comparator circuit (V1).
4. A photoflash warning installation according to claim 2 and claim 3, characterised in that the comparator circuit (V1) of the first voltage sensing device compares the voltage drop at the central tap of the voltage divider of the first voltage sensing device with a predetermined first reference voltage and opens the electrical switch (T1) when the voltage drop exceeds the first reference voltage.
5. A photoflash warning installation according to claim 1, characterised in that a protective diode (D4) is provided in parallel with the electrical switch (T1).
6. A photoflash warning installation according to claim 1, characterised in that a power control circuit is provided for the B.O.-type converter (W) and that the power control circuit reduces the output power of the B.O.-type converter (W) when the first voltage sensing device opens the switch (T1).
7. A photoflash warning installation according to claim 6, characterised in that the power control circuit comprises an oscillator (O).
8. A photoflash warning installation according to claim 7, characterised in that the power control circuit comprises a square wave oscillator (O), the output signal of which can be varied electrically with respect to its frequency and/or pulse width.
9. A photoflash warning installation according to claim 6, characterised in that the power control circuit has an RC element (R6, C3), the charging time constant of which can be varied by means of a fifth resistor (R5) in parallel with the sixth resistor (R6).
10. A photoflash warning installation according to claim 9, characterised in that a transistor (T3), which can be controlled by means of the first voltage sensing device, is provided in series with the fifth resistor (R5) and in parallel with the sixth resistor (R6).
11. A photoflash warning installation according to claim 1, characterised in that a second voltage sensing device is provided, which determines the charging voltage of the second storage capacitor (C2) and compares it with a predetermined second reference voltage, and which switches off the B.O.-type converter (W) when the charging voltage of the second storage capacitor (C2) exceeds the second reference voltage.
12. A photoflash warning installation according to claim 11, characterised in that the second voltage sensing device comprises a voltage divider consisting of two resistors (R3, R4) in parallel with the second storage capacitor (C2).
13. A photoflash warning installation according to claim 11, characterised in that the second voltage sensing device comprises a comparator circuit (V2).
14. A photoflash warning installation according to claim 12 and claim 13, characterised in that the comparator circuit (V2) of the second voltage sensing device compares the voltage drop at the central tap of the voltage divider of the second voltage sensing device with a predetermined second reference voltage and switches off the B.O.-type converter (W) when the voltage drop at the central tap of the voltage divider of the second voltage sensing device reaches the second reference voltage.
15. A photoflash warning installation according to claim 1, characterised in that a clock generator (T) is provided for the periodic excitation of the flashtube (B).
16. A photoflash warning installation according to claim 1, characterised in that the switch is a transistor.
17. A photoflash warning installation according to claim 16, characterised in that the transistor is a field effect transistor (T1).

Images