DE3044381A1 - POWER SUPPLY DEVICE FOR ELECTRICAL FLASH DEVICES - Google Patents

Description

FUJI KOEKI CORPORATION, Tokyo (Japan) YOSHITTJKI TAKEMATSU, Tokyo (Japan)

Power supply device for electric flash units

The invention relates to a power supply device

for electric flash units, especially a battery-operated one Power supply device with a DC voltage DC voltage converter, which contains an oscillator.

Flash devices are often used in various types of optical devices which require flash light to operate used. In particular, artificial light is used in photography to illuminate the subject. This artificial light is often generated with a flash tube.

With electric flash units for photographic purposes, high illuminance levels can be achieved by a charged capacitor is discharged through a gas-filled flash tube. In general, a DC power source with low voltage along with suitable circuit for generating the relatively high Uses DC voltage, which is required to add a flash capacitor for each flash tube firing load; this requires a large amount of energy. As a result, there is a difficult problem with lightning

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devices of this type in the conversion of electrical energy into lightning energy with high efficiency.

In particular, in electric flash devices, a power supply device is used to provide a large To charge the flash capacitor for a period of time to a voltage sufficient for the operation of a flash tube. A mechanical switch is usually used in the power supply device to switch the relative To convert low battery voltage into the relatively high directional voltage, for example for the flash tube Is denied. It is readily understood that under normal circumstances when using an electric Flash unit will be in standby mode for a significant portion of the time it is on located because the capacitor from the power supply device has already been charged to a suitable voltage and not yet as a result of actuation of the Discharge the camera shutter through the flash tube has been. During this period, the power supply device consumes energy released by the battery, without this being used usefully. In particular, if the device contains transformers, there can be a loss of energy be considerable. Over time, the battery detection decreases, so that a longer time elapses until the flash tube can be ignited. Eventually the battery voltage gets so low that the device is ready to ignite the flash tube is no longer capable "

The applicants have already proposed to avoid these disadvantages in that a power supply device is used with a feed circuit in which, after charging the lightning capacitor to a predetermined voltage

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automatically interrupts the delivery of power from the battery without the use of a mechanical switch will. In such a power supply device in which the power output from the supply circuit is automatic is interrupted, but takes a while after the power supply is turned on in the Transformer flowing primary current, whereupon the current output from the supply circuit containing the battery is interrupted when the current delivered by it reaches a predetermined current strength. In this lall must to set the flash duration, the point in time at which an oscillator stops oscillating can be set because the duration of the flash produced by a flash tube is different for different flash units.

The main object of the invention is now to provide an improved battery-operated power supply device, with which the aforementioned disadvantages are avoided, i.e. in the creation of a power supply device, which achieves high performance with little effort.

In particular, it is an object of the invention to to create a powerful power supply device for an electric flash unit, in which the Time point can be set in which the oscillator to oscillate and thus the current stops flowing when a lightning capacitor reaches a predetermined voltage has been loaded.

Another object of the invention is to provide a power supply device for an electric flash device

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to create that is economical and powerful and consumes little electrical energy because the power output from a battery is automatically generated and which is easy to use and operates with a very high degree of efficiency.

In addition, an object of the invention is for an electric flash unit a power supply device to create in which the point in time at which the current output from the supply circuit is interrupted with simple switching technology means in a large one Range can be adjusted.

To solve these tasks and to achieve more The invention provides an improved power supply device, in which the output voltage of a supply circuit corresponding to a battery voltage in a relatively high directional voltage is converted, which is delivered to a consumer. The battery voltage is output to an oscillator with a transistor, on whose control electrode a switch is connected to a suitable one Bias voltage is applied to make the oscillating gate oscillate. The output of the oscillator will be rectified, and the rectified voltage thus obtained becomes applied to the direct current consumer, for example to a flash tube or the like.

The power supply circuit for flash units created by the invention has a direct current supply circuit which contains a battery, a voltage converter for converting the from the direct current supply circuit '" tapped direct voltage into an alternating voltage, a

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Rectifier for rectifying the AC voltage and an output circuit with one fed by the rectifier Charge storage circuit for storing electrical charge and for delivering electrical energy to a consumer, as well as a sub-calculation device for the automatic interruption of the current output from the direct current supply circuit to the output circuit, when there is an electric charge in the charge storage circuit is stored, an operation quantity setting device for dividing an electrical operation quantity of a vibrating element of the voltage converter when the supply circuit delivers current to the output circuit, and a time control device Uj_ig for setting the point in time in which the interruption device interrupts the current delivery.

The power supply device according to the invention for an electric flash device has in particular a GMchstrom-supply circuit with one battery, one Voltage converter with an oscillator, a vibrating transformer, a vibrating switching element and ei ^ en Capacitor contains, a rectifier, a charge storage circuit and a YerDraucherkreis with a flash tube circle. The power supply device also has an interrupt device for automatic Interrupting the current output from the direct current supply circuit to the output circuit, an operating variable adjustment device for setting an electrical operating variable of a vibrating element of the voltage converter during the delivery of current from the DC supply circuit to the smoking circuit and a timing device for setting the time at which the sub-calculating device interrupts the delivery of current, and to display the status of the power supply device for the Flash unit.

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Embodiments of the Erfi.uci.Uug are based on the following of the accompanying drawings. In these, the same parts are denoted by the same reference numerals. It shows

Figure 1 is a detailed Sehaltschema a power supply device according to the invention for electric flash units

FIG. 2A shows the output current characteristic of a power supply device according to the invention

FIG. 2B shows another output current curve of a power supply device according to the invention

FIG. 3 shows an embodiment of the power supply device that is modified compared to FIG

FIG. 4 shows a detailed circuit diagram of a third embodiment the power supply device according to the invention

FIG. 5 shows a detailed circuit diagram of a fourth embodiment the power supply device according to the invention and

FIG. 6 shows a detailed circuit diagram of a fifth embodiment the power supply device according to the invention.

The power supply device shown in Figure 1 has a direct current supply circuit A, a voltage converter B for converting the output voltage of the direct current supply

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circuit A into a higher AC voltage, a rectifier C for rectifying the two alternating voltages from the voltage converter B, a charge storage circuit D for storing electrical energy that is output by the rectifier C in the form of direct current is, and for the delivery of electrical energy to a consumer circuit with a lightning bolt, a Ignition signal generator E for igniting the flash tube by applying an ignition signal to an ignition electrode of the flash tube, a consumer group in the form of a flash tube circuit F with a flash tube, a voltage signal control circuit G for setting a voltage wave in the voltage converter B and a timing circuit J for setting the point in time at which an oscillator stops oscillating and the current delivery from the supply circuit is interrupted.

The DC supply circuit A contains a battery 10. The voltage converter B contains an oscillator OC, one the swing initiating circle OS and a swing interrupting circle ST. In particular, the Voltage converter B is an oscillating transformer 11 with at least two windings, for example a primary winding 11a and a secondary winding 11b, an oscillating switching element in the form of a high-performance silicon transistor 12, a connector 13 initiating the oscillation, a current limiting resistor 14- and eix * en the swing initiating, mechanical switch, for example a push button switch 15, one of which Terminal is connected to the other end of the resistor 14. The primary winding is used to form the oscillator OG 11a of the oscillating transformer 11 at one end directly to the positive terminal of the battery 10 and at its other end with the collector of the oscillating

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transistor 12 connected. One end of the secondary winding 11b is connected to the control or base electrode of transistor 12 connected «.

The voltage converter B is essentially an oscillator with voltage feedback o The oscillating transistor 12 is a high-performance npn transistor, as explained above, and when the transistor is blocked, its emitter-collector path has a high internal resistance, so that the residual current of the Transistor 12 is very small and compared to that of a germanium transistor almost equal to ETuIl. To form the circle ST that interrupts the oscillation, a mechanical switch in the form of a push-button switch 16 is connected between the base and the emitter of the transistor 12. The Sas ichwingen initiating circle OS comprises the resistor 14 and the swing initiating push button switch 15 in the form of a closer which is closed by pressing the push button and opened by releasing the push button. The oscillating transistor 12 is a high-performance npn silicon transistor with a very low residual current of, for example, about 0.1 to 0.2 μΑ or almost zero.

The rectifier G contains an electric valve in the form of a diode 17, the cathode of which is connected to the other end of the secondary winding 11b of the transformer 11 and which is polarized in the reverse direction with regard to the polarity of the battery 10 _o The charge storage circuit D contains a lightning capacitor 18, a current limiting resistor 19 , an indicator lamp consisting of a neon glow lamp 20, which is connected in parallel to the flash capacitor 18 via the current limiting resistor 19, and one of the neon glow lamp 20 connected in parallel

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Capacitor 21. The egg coating of the capacitor 18 is with the anode of the diode 17 and the other plate of the capacitor 18 is with the emitter of the transistor 12 and the negative pole of the battery 10 verDundee.

The Zündsignalge the E contains a charging resistor 22 connected to the one plate of said flash capacitor is veruunden 18 at its one end, a Zündkondensai> br 23 au its one pad to the other end of the charging resistor 22 is connected, a protection resistor 24, which is connected between the other coating of the ignition capacitor 23 and the negative pole of the battery 10, an ignition transformer 25 with a primary winding 25a and a secondary winding 25b and a parallel-connected synchronous switch 26 which is closed and opened synchronously with a camera shutter, not shown. The consumer circuit consisting of a flash tube circuit comprises a gas-filled flash tube 27. This has two flash electrodes 27a, 27b and an ignition electrode 27c, which is arranged on the outside of the flash tube 27 and is connected to the other end of the secondary winding 25 ^.

Between the base of the transistor 12 and the connection point Jo between the cathode of the diode 17 and the lightning capacitor 18 a swing control circuit G is provided. This contains a vibration control probe ± iSator 28, which is connected via a protective resistor 29 between the BaeLs of the transistor 12 and the connection point J ~ is. Furthermore, an oscillation display circuit H is provided which shows the operating status of the voltage converter B. and the secondary winding 11b of the oscillating transformer 11 is connected in parallel. The oscillation indicator circuit H consists of a series connection of a protective resistor 30, a diode 31 and one from one Neon glow lamp 32 existing indicator lamp.

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The most important feature of the invention is that a means is provided for adjusting the timing in which the current output from the Gleichstromöpeisekreis is automatically interrupted _o On de.u oscillating transformer 11 a display winding is wound to display an electrical operating variable of the oscillating transformer 11 33rd In the power supply device according to FIG. 1, the display winding 33 is wound on the oscillating transformer 11 and connected in series with an impedance element in the form of a variable resistor 34 · i "to form the circle J to end the oscillation.

The stray capacitance of the oscillating transformer 11 and the oscillating voltage of the oscillating capacitor 13 are used by switching the Transistor 12 to initiate the oscillation of the oscillator 00. After the swing "started h] 6tt, effected the capacitor 13 initiating the oscillation, that the oscillation voltage is reduced, because experiments show otherwise the oscillation voltage is too high. From the secondary side of the oscillating transformer 11 is a voltage is fed back to the BasLs of the transistor 12.

The switch 15 is closed and opened by hand. When the switch 15 is open, the oscillator OC can initially do not oscillate because the oscillating transistor 12 is still blocked. When the switch 15 is momentarily closed flows from the battery 10 of the supply circuit A through the resistor 14 and the switch 15 current to the base of the Transistor 12 so that forward bias is applied to this base. Immediately after passing

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of the transistor 12, current flows from the battery 10 through the primary winding 11a of the Sehwingtransßrmators 11 uud the collector-emitter path of the transistor 12 and at the same time current flows through the base-emitter path of the transistor 12, the battery 10 and the resistor 14 uid is applied in the capacitor 13 electrical charge. As a result, the voltage converter B starts to oscillate and becomes one in the secondary winding 11b high alternating voltage induced. Furthermore, in the display winding 33 induces a voltage. In this case, it is due to the stray capacitance of the windings of the transformer 11 or the oscillating capacitor 13 to be fed back Schwixig voltage also for switching through and blocking of the flywheel transformer 12 is used. The diode 1? of Rectifier G generates a high DC voltage by rectifying the high AC voltage.

Since each winding of the oscillating transformer 11 is wound in the sense of an increase in the base current, as a result of the Positive feedback of the transformer 11, the transistor 12 is switched through, the collector current almost linear in time increases. The transient component of the base current decreases when the base current reaches a peak value, which is determined by the induced voltage and the resistance 14 ·. As a result, the increment of the collect- tor current non-linear and it no longer increases. When the core of the transformer 11 is saturated, the collector current decreases of transistor 12 no longer closes, so that the base current of transistor 12 and the collector current then decrease decreases rapidly, whereby the transistor 12 is blocked.

As a result of the blocking of the transistor 12, the current flow through the primary winding 11a of the oscillating transformer

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away

Tor 11 is quickly interrupted, whereupon the energy 1/2 L ₁ χ I D stored in the oscillating capacitor 13 has the effect that a reverse voltage is applied to the base of the transistor 12 as a result of the winding direction of the primary winding 11a. L- is an inductance (H) and I is a peak value of the collector current. In this state, the Kon ensator 13 is charged with an oscillating current because the transistor 12 is blocked, and after a halo period of the oscillation of the charging current for the capacitor 13, the direction of the current flowing in the primary winding 11a of the oscillating transformer 11 is reversed, so that sx the base of the transistor 12 a forward bias is applied and the oscillator OC begins to oscillate again.

Thus, when the switch 15 that initiates the oscillation is momentarily closed, current flows from the battery 10 of the DC supply circuit A via resistor 14 and switch 15 to capacitor 13 and appears then a positive potential at the base of the transistor 12, which causes the transistor 12 to be turned on. The oscillator OC continues to oscillate because of the electromagnetic energy in the inductance of the transformer 11 induced and as electrical energy in the form of a Base of the transistor flowing current is released again, which is required for the oscillation.

The switch 15 does not always need to be opened immediately after its closing has initiated a function has, but it can be designed as a switch that has a certain time, for example about " 3 seconds to 3 ^ minutes after closing again opens.

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Through the diode 51 the pulsation indicator circuit H the alternating voltage induced in the secondary winding lib of the oscillating transformer 11 is rectified, whereby only half of this amount to the neon glow lamp 32 Voltage applied and the lamp 32 less L- istung records. As a result of this lower power consumption, the fed-back current increases and remains the transistor 12 activated for a long time. The neon glow lamp 32 of the oscillation indicator circuit H shows by its lighting up, d'jss oscillator OC oscillates, and is dark when the oscillator 32 does not oscillate.

The current delivered by the rectifier 0 flows into a loop, which from the secondary winding 11b of the oscillating transformer 11, the base emitter path of the Oscillating transistor 12, the ßlitzkondensator 18 and the diode 17 is formed.

The operation by which the oscillation of the voltage converter B is stopped will be described below based on the result of the experiment. When the oscillator OC begins to oscillate, a current in the order of magnitude of 50 mA initially flows through the lightning capacitor 18 via the diode 17, the secondary winding 11b of the transformer 11 and di '? Base-emitter path of the transistor 12 and at the same time via the diode 17 and the capacitor 13. During the storage of electrical charge in the lightning capacitor 18, the current flowing through this gradually decreases to 150 uA, so that the current to the base of the transistor 12 of the voltage converter B decreases and therefore the current output from the battery 10 to the primary winding 11a of the transformer 11 is automatically interrupted by the transistor 12,

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because its base current for the switching process is no longer available sufficient.

; / enri the oscillator OC is unable to oscillate, wM also induces electromagnetic energy in the display winding 35 of the timing control circuit J for interrupting the oscillation, so that current flows through this display winding O ⁷ J and the variable resistance 34. As a result of the current flowing through the variable resistor 34, the stored electromagnetic energy is consumed, so that the oscillator 00 stops oscillating. The point in time at which the oscillation stops can be set by changing the resistance value of the variable resistor 34 of the timing circuit J. If the resistance value of the variable resistor 34- is set to 500 ohms, the current flowing from the battery 9 10 to the primary winding 11a initially has a current strength of 3 A ₀ During the storage of electrical charge in the lightning capacitor of the charge storage circuit D, this current gradually increases to 100 mA. from what is not sufficient for the operation of the oscillator OC with the oscillating capacitor 12. This is shown in Figure 2A by the curve OL. At the time T- ^ ₁ corresponds to the oiner current strength of 100 mA, the oscillator OC stops oscillating and consequently the current output from the battery 10 also stops. If the variable resistor 34- is set to a resistance value of 10 kiloohms, it consumes less energy than with a resistance value of 500 ohms, so that a larger current is fed back to the base of the transistor 12. In this pail, the current flowing through the primary winding 11a decreases from the initial value of 3 A by the time T to 50 mA, // Ie is represented by the curve £? P in Figure 2B, and becomes the current output from the battery 10 automatically interrupted. In Figures 2A

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ft 304A381

and 2B, T _Q denotes the point in time "at which the oscillation begins", with T-, the point in time at which the oscillation ceases when the variable resistor 3 ^ - has a resistance value R ^, of 500 ohms, and with T is the point in time at which the oscillation stops when the variable resistor 34 has a resistance value Rp of 10 kiloohms. Here, R ₁ ^ R- and To-Tn ^ To-TL - set the point in time at which the oscillation stopped

When the flash capacitor 18 of the charge storage circuit D is charged to the predetermined, suitable voltage, the neon glow lamp 20 lights up to indicate that the flash unit is ready to fire the flash tube 27, which is then followed by closing the shutter located in the camera synchronized switch 26, the flash tube 27 can be ignited. It is easy to see that this switch only needs to be closed momentarily while the camera shutter is being operated. When the switch 26 is closed, the ignition capacitor 23 emits its electrical charge via the switch 26 and the primary winding 25a, so that a high-voltage pulse of, for example, 3000 V is induced in the secondary winding 25b of the ignition capacitor 25 and is applied to the ignition electrode 27c of the flash tube 27, in which he ionizes part of the gas. The flash capacitor 18 is then discharged through the gas located between the flash electrodes 27a and 27b, so that a bright flash of light is generated

After the lightning capacitor 18 has been discharged, there is only a small voltage across it, so that the oscillation control capacitor 28 its electrical charge over the

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the base-emitter path of the transistor 12 (and the oscillating capacitor 13), the flash capacitor 18 (and the flash tube 27) and the capacitor 28 emit. As a result of the discharge of the capacitor 28, a positive potential appears at the base of the transistor 12. Under these conditions, the oscillator OC is activated in some cases and Ixx deactivated in other cases. In Deiden cases, the transistor 12 is switched through as a result of the positive potential applied to its base, whereupon the oscillator begins to oscillate again.

On the other hand, the oscillation of the oscillator OC can be reliable and terminated quickly if so desired by closing the vibration break switch 16 the oscillator OG is short-circuited. The oscillation of the oscillator OC is automatically restored initiated when the flash capacitor 18 releases its electrical charge via the flash tube 27. In this case it is the residual current is less than a few microamps, so that no switch is required in supply circuit A,

In the power supply device according to FIG. 1, the high-power transistor 12 used in the voltage converter B ensures that no battery energy is lost, even if the switch 15 remains closed for a long time <> As a result, the power supply device works satisfactorily. It is also simple in structure, easy to manufacture and more economical than the well-known power supply device, because the oscillator OC by momentarily closing the switch that initiates the oscillation, 15 can be made to vibrate. The power supply device according to Figure 1 is easy to use, because they were not from the photographer for the next

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Flashing of the flash tube 27 needs to be prepared, but the oscillator OO begins to oscillate automatically after the flash tube 27 flashes, although the current output from the supply circuit A has been interrupted because the oscillator 00 has stopped has to swing ·.

An important advantage of the power supply device according to Figure 1 is that by "changing the Impedance value of the impedance element of the timing circuit J for interrupting the oscillation is a certain one Characteristic curve & es voltage converter B can be achieved can and therefore the power supply is suitable for all litz devices. Another advantage of the Power supply device consists of the fact that by changing the impedance value of the changeable Resistor 34- existing impedance element of the Time control circuit J adjust the point in time at which the oscillation is interrupted over a wide range can.

FIG. 3 shows a modified version compared to FIG Embodiment of the power supply device. In this, a vibrating transformer 11 has a primary winding 11a, a secondary winding 11b and a control winding lic β This is between the base and the Positive pole of a battery 10 of a direct current supply circuit A is arranged. The lic control winding is on one end via a protective resistor 14 and a switch which is used to initiate the oscillation 15 to the positive terminal of the battery IO and to its other End connected to the base of an oscillating transistor 12 and the secondary winding 12b of the oscillating transformer 11 O

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In the power supply device according to Figure 3 flows Current from the battery of the DC supply circuit A through the resistor 14, the switch 15 and the control winding lic of the oscillating transformer 11 to the base of the transistor 12, which is thereby switched through. Current then initially flows from the battery 10 via the primary winding 11a of the oscillating transformer 11 and “ie Collector-emitter path of the transistor 12 and current also flows through the control winding lic, the base-emitter path of the transistor 12, the battery 10 and the resistor 14 and is in the capacitor 13 electrical charge saved. As a result, the voltage converter B begins to oscillate and induces it in the secondary winding 11b a high AC voltage. In this case, the control winding lic stabilizes the oscillation of the oscillator OC. When the oscillator 00 begins to oscillate, the oscillating transformer 11 emits electromagnetic Energy from its control winding lic as a feedback current to the base of transistor 12. The power supply device according to Figure 3 therefore has similar Advantages such as those shown in FIG. 1 and the others Advantage that the swing is stabilized.

The embodiment of the invention shown in FIG has, similar to the device shown in Figure 1, a DC supply circuit A with a battery 10, a voltage converter B for converting a DC voltage output from the battery 10 into a AC voltage, a rectifier 0 for generating a DC voltage by rectifying that of the Voltage converter B output alternating voltage, a charge storage circuit D for storing energy, the is delivered to a consumer circuit, an ignition

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30U381

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signal transmitter E for igniting a flash tube in a consumer circuit in the form of a flash tube circuit F and an oscillation display circuit H. The power supply device also has a timing circuit J arranged on the output side of the voltage converter B. to control the point in time at which an oscillator OC of the voltage converter B ceases to oscillate.

The timing circuit J has an opening provided on the secondary side of the oscillating transformer 11 display winding 33, and an impedance adjusting in the form of a variable resistor 34- ₀ The display winding 33 is at one end with with one end of a secondary winding 11b and the base of the oscillation transistor 12 and at the other end one end of the variable resistor 34-connected. Its other end is connected to the secondary winding 11b of the oscillating transformer 11 and the base of the transistor 12 together with a neon glow lamp 32 of an oscillation indicator circuit H

When the switch 15 which initiates the oscillation is momentarily closed, current initially flows from the battery 10 of the direct current supply circuit α via a current limiting resistor 14- and the switch 15 to a / Schwingen / cTas introductory capacitor 13, in which electrical charge is then stored o As a result of the electrical charge of the Capacitor 13, an oscillating transistor 12 is switched through, whereupon the oscillator 00 begins to oscillate. By the oscillation of the oscillator OG becomes a high alternating voltage in the secondary winding 11b of the oscillating transformer 11 indeiert, which is then rectified by a diode 17 of the rectifier C. Consequently Direct current flows in a loop that is drawn from the secondary winding 11b, the base-emitter path of the

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Transistor 12, dom ^ litz capacitor 18 and the diode is formed, and at the same time in a loop by the secondary winding lld, the Bfäs emitter path of the transistor 12, the protective resistor 24, the ignition capacitor 25 and the diode 17 is formed. As a result, the flash capacitor 18 and the ignition capacitor become 23 loaded.

V / enn in the secondary winding 11b of the oscillating transformer 11 a high alternating voltage is induced, an alternating voltage is also induced in the display winding 33, so that through the variable resistor 34- a current flows. As a result, the electrical energy induced in the secondary winding 11b and the display winding 33 becomes consumes and takes due to the shunt formed by the changeable 7 / resistance 3 ^ of the base of the transistor 12 supplied current. As a result, the timing circuit J operates similarly to the previous ones described embodiments. In the power supply facility According to FIG. 4-, part of the secondary winding 11b of the oscillating transformer 11 can be used as an initial winding 33 can be used if the secondary winding 11b is provided with a tap. Therefore, the vibration transformer 11 can be easily manufactured because the only tap is provided on the secondary winding 11b must become.

An even more effective Ctromversigungseinrichtung according to the invention is shown in Figure 5 and also has a DC supply circuit A with a battery 10, a voltage converter B comprising a vibrating transformer 11 and for converting the from the

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A rectifier G for rectifying the output from the 3voltage converter B, a charge storage circuit D with a lightning capacitor 18, a; Zändsignalgeber E, a ^ litzröhrenkreis F and a provided on the input side of the voltage converter B timing circuit J, which is used to interrupt the Schwin; ens serves and is formed by the primary winding 11a of the Sehwingtr-jnsformator 11 and a variable resistor yv , which is held parallel to the primary winding ILa.

In the power supply device according to FIG 5 is a capacitor 1> electric charge from the battery 10 via a Stromoegr'mzungswiderstand 14 and the 3 ₀ hvvin, en CONTAINER introductory saddle 15 when this is closed. When the capacitor Iy is charged to the voltage of the transistor 12, the latter is passed through and the oscillator OG is activated as a result. When the oscillator OG is activated, current flows through the primary winding 11a of the oscillating transformer 11 and a high alternating voltage is generated in the secondary winding 11b. The alternating voltage is rectified in the rectifier G, with the output of which the lightning capacitor 18 and the ignition capacitor 2.5 are charged. '.Vährend of loading the ßlitzkondensutors L8 decreases the current flowing through the secondary winding 11b to the base of transistor 12 from power, so that ?, the transistor is blocked and thereby the automatic swinging is interrupted !, oh _o

The current delivered from the battery 10 to the E ^J rLmärwickIung 11a is initially approximately, 5,. 1 // while the lightning condenser 18 is being charged, the through the

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Primary winding 11a flowing current, gradually from.

The timing circuit J for interrupting the swing is from the primary winding 11a of the oscillating transformer 11 and the variable V / resistance 54- formed. This consumes electrical induced in the primary winding 11a Energy. In this case, the electric power consumed by the transformer 11 is of the impedance of the closed circuit, which is formed by the primary winding 11a and the variable resistor J4 is, so that the from the oscillating transformer 11 to the Base of transistor 12 fed back voltage as a function of the Jidistorw-ert of the variable resistor 34- is changed. With a small resistance value de .; Resistance 34- is that of the winding lla and the Y / iderstand 54- energy consumed while they with a large './ideri.and value of the resistor 34- small is.

Ih the power supply device according to Figure 5 is for Formation of the timing control circuit J of the variable resistor 34 with the primary winding 11a of the transformer 11 tied together. Hence the power supply device according to Figure 5, the advantages that fewer parts are required and the circuit is simple because the primary winding Lla is also used as a display winding. Furthermore, the same advantages are achieved as with doη previously described embodiments.

Another embodiment of the power supply device according to the invention is shown in FIG. Here, the timing circuit for interrupting the oscillation on the output side of the voltage converter B and Lm base circuit is a! 'Ram; Lstors 12 arranged. Here on

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As best seen in Figure 6, is between the secondary winding 11b of the oscillating transformer 11 and the base-emitter path of the transistor 12 is a variable Impedance element in the form of a changeable ϊ / resistance 34 connected, which at its one end to the secondary winding 11b and at its other end with the emitter of transistor 12 is connected. As a result, the timing circuit J becomes to stop the oscillation from the secondary winding 11b of the transformer 11 and the variable resistor 34 is formed.

During operation, when the voltage converter B is activated, the secondary winding 11b of the oscillating transformer 11 A high alternating voltage is induced in a rectifier C is switched into line. With its output is a charge storage circuit in a flash capacitor 18 D an electric charge stored, ". -Driving the store of the -litz capacitor, the voltage converter B is deactivated, so that the power supply from the battery 10 is automatically interrupted. In this case it becomes a part of the current to be supplied to the base of the transistor 12 via a shunt formed by the variable resistor 34 and consumes energy in the process. As a result, the times at which the swing or the Stop current delivery, set by selecting the resistance value of the variable resistor 34 ·.

In the power supply device according to figure 6 is the timing circuit J for interrupting the oscillation has a simple structure and is easy to manufacture because it is sufficient the variable resistance 34 · between the secondary winding 11 of the oscillating transformer 11 and the base of the transistor 12 to be arranged.

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In the embodiments described above, one npn transistor is used in each case. But you can also use a pnp transistor in the frame of the invention achieve the same operation and advantages.

It can be seen that the objects of the invention are achieved with the embodiments described above and other advantages can be achieved.

The invention is not limited to the embodiments described above, since these from Those skilled in the art can be modified within the scope of the inventive concept.

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Claims (1)

Claims (!. ^ Power supply device for electric flash units, characterized by a DC supply circuit containing a battery, a voltage converter for converting the DC voltage output from the DC supply circuit into a AC voltage, a rectifier for rectifying the AC voltage and an output circuit with a Charge storage circuit fed by the rectifier for storing electrical charge and for releasing electrical energy to a consumer, furthermore an interrupt device for automatic interruption the current output from the DC supply circuit to the output circuit, if in the charge storage circuit a electrical charge is stored, an operational variable te lie device for setting an electrical operating variable of a vibrating element of the voltage converter, when the supply circuit emits current to the output circuit, and a time control device for setting of the time at which the interruption device the power supply interrupts. 2. Power supply device according to claim 1, characterized characterized in that the voltage converter is a vibration transformer with a primary winding and a secondary winding, furthermore an oscillator with a vibrating switching element, which is via the primary circuit is connected to the battery of the DC supply circuit and when the oscillator is not oscillating has a high blocking resistance, and that the interrupting device has the oscillating switching element of the oscillator includes. -26- 130024/081? 3 · Power supply device according to. Claim 1, characterized characterized in that the time control device for the interruption of the current delivery has a time control circuit for stopping the oscillation comprising an indicator winding for indicating an electrical Operating variable of the voltage converter and an impedance setting element for setting the current flow through owns the display winding. 4-0 power supply device according to claim 1, characterized characterized in that the time control device is provided on the oscillating transformer of the voltage converter Display winding and a variable impedance element connected to dfeser. ο power supply device nadi claim 1, characterized characterized in that the timing device comprises a primary winding of the oscillating transformer of the voltage converter and a variable impedance element, that is connected to the primary winding. 6. Power supply device nadk claim 3 »thereby characterized in that the timing circuit is arranged on the output side of the voltage converter and a display winding for displaying an electrical output of the voltage converter and with the Display winding connected impedance adjustment element comprises. 7 · Power supply device according to claim 6, characterized in that the time control circuit has a display -27- 130024/0817 winding comprises, which is connected to the secondary winding of the oscillating transformer, and an impedance adjustment element between the display winding and the
Base of a transistor of the oscillator seeds
is. 8. Power supply device according to claim 6, characterized in that the ^ eitsteuerkreis the secondary winding of the oscillating transformer uud includes a variable resistor connected to the secondary winding and the base-emitter path of the oscillating transistor is connected « 9ο power supply device according to claim 1, characterized by an oscillation control circuit for
Control of the activation of the voltage converter. 10. Power supply device according to claim 9j thereby characterized in that the oscillation control circuit comprises a oscillation control capacitor which serves to to apply a bias voltage to a control electrode of the oscillating switching element after a lightning capacitor of the charge storage circuit has been discharged. 11. Power supply device according to claim 10, characterized in that the oscillation control capacitor between the control electrode and a connection point between the rectifier and the charge storage circuit is switched. 12. Power supply device according to claim 1, characterized by an oscillation display circuit for
Display of the vibration state of the voltage converter. -28- 1 30024/0817 13. Power supply device according to claim 12, characterized in that the oscillation display circuit from one with the secondary winding of the oscillating transformator connected series circuit of a protective resistor, a diode and a neon tube consists. 14. Power supply device according to claim 2, characterized in that the oscillating transformer has a control winding for stabilizing the oscillation of the oscillator. 130024/0817