DE1073625B - ELECTRONIC FLASHING DEVICE WITH VOLTAGE REGULATION OF THE STORAGE CAPACITY - Google Patents

Description

GERMAN

The invention relates to an electronic flashlight device with a storage capacity derived from a power source low DC voltage via a voltage shaper with a high DC voltage and with a converter depending on the voltage present on the storage capacity Switching on or off relays in a circuit parallel to the storage capacity.

Voltage converters, as used in flash units of the type mentioned, also consume in the unloaded state, d. H. After the storage capacity has been charged, electrical energy continues. It is therefore it has already been proposed to provide the device with means that the charging of the capacity stop automatically as soon as the voltage has reached a certain value by activating the converter switch off. But then because of the leakage current of the capacitance and the cross current through other branches the circuit a slow discharge of the storage capacity takes place, it must be ensured that when the capacitor voltage drops, the converter is briefly switched on again and the Storage capacity is reloaded.

Such an automatic switching on and off of the voltage converter can be done by means of a relay happen through which a current depending on the voltage of the storage capacity flows. It is known, to place the relay switching the converter in a circuit parallel to the storage capacity, so that the current flowing through the relay is approximately proportional to the voltage on the storage capacitor. Such a device works very poorly, because with the usual relays the current values for the tightening and stand for the drop approximately in the ratio 1: 2, so that the voltage of the storage capacity between switching off and switching on the voltage converter in a similar ratio fluctuates. In order to obtain a uniform light output from the flash unit at all times, However, the voltage fluctuations of the storage capacity between switching off and switching on again are allowed of the converter can only be relatively low.

In an effort to reduce the voltage fluctuations mentioned, one has the device described improved by placing a glow lamp in series with the winding of the relay and the series connection of relay and neon lamp is proportional to the voltage of the storage capacity Voltage supplied, which is z. B. tapped at a voltage divider parallel to the storage capacity. In this way, however, the voltage fluctuations in the storage capacity could only be reduced to one amount that is at least equal to the sub-electronic flash unit

with voltage regulation

the storage capacity

Applicant:

Deutsche Elektronik G.m.b.H., Berlin-Wilmersdorf, Forckenbeckstr. 9-13

Karl Ackermann, Berlin-Charlottenburg, has been named as the inventor

differentiated between the ignition and extinction voltage of the glow tube, but usually a multiple of this The difference is because the ignition voltage of the glow tubes is generally only a fraction of the charged voltage Storage capacity is.

The invention now solves the problem of improving the explained known measures and the voltage fluctuations the storage capacity between switching off and switching on to an extent that was previously not possible reduce small values. In the case of the flash device according to the invention, this is in the case of the storage capacity parallel circuit and the converter switching relay in series with a per se known resistance, the resistance value of which decreases steadily when the voltage occurring across it gets bigger. So there is a voltage-dependent resistor in series with the relay, its Resistance value decreases with increasing voltage and thus a steadily curved current-voltage characteristic has (so-called VDR resistance). How the fluctuation range of the voltage of the storage capacity in is narrowed in the desired way, will then be explained with reference to the drawing.

A particularly strong narrowing of the fluctuation range occurs when, furthermore, in the circuit in in a manner known per se, a glow lamp is located.

The invention will now be explained using two exemplary embodiments. In the drawing shows

1 shows some voltage characteristics to explain the mode of operation,

Fig. 2 shows a first embodiment of a flashlight device according to the invention,

.; ... 909 710/257

3 shows a second exemplary embodiment for a flashlight device, in which the switching elements of the power circuit lying parallel to the storage capacity are used of the ignition circuit of the flash lamp are used, and

FIG. 4 shows the profit for a device according to FIG. 3 in a graphical representation.

In FIG. 1, for example, the linear current-voltage characteristic of a relay (8 in FIGS. 2 and 3) is shown _{for an operating voltage of 500 V = for the storage capacity.} With a given DC resistance of the relay winding, the current i is set by a linear series resistor (11 in the circuit examples). Since the values for the pick-up and drop-out excitation are approximately 2: 1 with conventional relays without special measures in the magnetic circuit, switching on and off with such a relay is not a solution, as the voltage available at the storage capacitor is also correspondingly Ratio 2: 1, i.e. in a range that is far too large. An upstream VDR resistor (voltage-dependent resistor) results in a significantly more favorable voltage ratio of 1.3: 1 (curve B) for the same excitation values (i ₀ , i "). The series resistor 11 should only be chosen to be just as large as is necessary to regulate the resistance tolerances of the relay winding and the VDR resistor, since a larger series resistor has an unfavorable effect on the characteristics of the circuit in the sense of straightening curve B.

If the operating voltage of the device (on the storage capacitor) is higher than that according to the characteristic Determined best overall voltage of the chain circuit from series resistor, relay and VDR resistor, as is usually the case, one can be dimensioned for the voltage difference Glow lamp can be switched on. Thereby the characteristic becomes essentially, i. H. im interested Area shifted parallel upwards to higher voltage values (curve C). The tension becomes even cheaper at 1.16: 1.

Fig. 2 shows the circuit diagram of a device for charging a storage capacitor 1 from a battery 2 via a pendulum converter consisting of chopper 3 and step-up transformer 4 with rectifier circuit 5, 6, 7 according to D el on. The chopper circuit is routed via the contacts ^{1 of} the relay 8, which is connected in series with a VDR resistor 9, a glow lamp 10 and a regulating resistor 11 in parallel with the storage capacitor. Think of a circuit connected to terminal 12 of the device, via which the capacitor 1 is suddenly discharged if necessary. With recharging, the voltage on the storage capacitor and on the circuit 8, 9, 10, 11 increases, initially up to a value at which the glow lamp 10 ignites. A specific voltage, which continues to rise in the following, is thus established at the VDR resistor 9 and, according to its characteristics, a specific current. As soon as this has reached the value i ₀ (FIG. 1), the relay 8 picks up and prevents the charging process; The operating voltage is now on the capacitor. If the energy stored in it is not withdrawn, the voltage in the shunt circuit then slowly drops due to the current consumption and thus the current through this circuit decreases more sharply. As soon as the holding current value of the relay falls below a voltage drop of 10%, the relay drops out and charging starts again.

Fig. 3 shows the circuit diagram of an electronic flashlight device, namely only the discharge circuit via the flash tube 13.

ίο As shown in Fig. 3a for explanation, is in such a device for the ignition circuit 14, 15 of the flash tube and for a flash readiness indicator Glow lamp 16 requires a voltage divider 17, 18 which is also parallel to storage capacitor 1 lies.

Fig. 3 b now shows an example of how the circuits 8, 9, 10, 11 on the one hand and 14, 15 (or 16,), 17, 18 on the other hand can be merged. The part of the to the left of the dash-dotted line

ao circuit is in the power supply unit, while the part shown on the right is in the flash tube 13 supporting housing, the lamp rod, is housed.

Fig. 4 shows the benefit of the economy circuit on the basis of two curves in which it is shown how many flashes of light with a current source of a given number of ampere-hours depending on the flash sequence, d. H. the time that elapses between two flashes, but during which the device remains switched on, can be generated.

Claims (3)

Patent claims: 1. Electronic flashlight with a storage capacity obtained from a power source low DC voltage is charged with a high DC voltage via a voltage converter and with a converter depending on the available storage capacity Voltage switching on or off relay in a parallel to the storage capacity (1) Circuit, characterized in that the relay (8) switching the converter (3, 4) is in series with a known resistor (9) whose resistance value decreases steadily when the the tension occurring on it becomes greater. 2. Apparatus according to claim 1, characterized in that further in the circuit in per se known Way a glow lamp (10) is located. 3. Apparatus according to claim 1 or 2, characterized in that the switching elements (8, 9, 10, 11) of the parallel to the storage capacity (1) lying circuit for feeding the ignition circuit (14,15) of the flash tube (13) or for Ready indicator (16) are used. Considered publications:
German patent application T 9346 IX / 57 c (published on July 14, 1955); German utility model No. 1 684 376;
Patent Specification No. 12 461 of the Office for Inventions and Patents in the Soviet Zone of Occupation in Germany; British Patent No. 649,320;
"Bild und Ton" magazine, 1955, issue 7, pp. 193 and 197 to 199. 1 sheet of drawings © 909 710 / 25Tt. 60