DESC001446MA - Power source for flash lamps, e.g. for photographic purposes - Google Patents

Description

The previously known power sources for vacuum flash lamps consist of battery units, e.g. of several mono cells, which are mostly housed in the flash rod, i.e. the lamp holder for the flash lamps.

However, these known power sources for flash lamps are unsuitable for drawing high currents, even for only short-term high loads, since the resulting consumption is too high. The service life of these batteries is therefore very short under the stress described. However, since flash lamps with a correspondingly high light intensity have to be used very often in practice for the required lightening, a correspondingly high and thus expensive consumption of batteries has hitherto been unavoidable.

The inventive concept, which extends to a power source for flash lamps, e.g. for photographic purposes, avoids the disadvantages described in that, according to the invention, in addition to a battery unit a capacitor is provided which is charged by the battery and is used to ignite the flash lamp, and that the battery and the capacitor are arranged in a common housing. The housing preferably has the external dimensions of a normal lightning rod for two or more commercially available mono cells. The capacitor can be designed either as a static capacitor or as an electrolytic capacitor. The additional arrangement of a capacitor now ensures that with a low current draw from the battery and with a corresponding capacity measurement of the capacitor, the required high currents are available without any particular wear and tear on the battery, in each case for igniting flash lamps with a high light intensity.

Another inventive embodiment consists in that a resistor is provided between the battery, which can consist of one or more mono cells, and the capacitor. The main purpose of this resistor is to limit the battery current, i.e. the charging current for the capacitor, to such an extent that an optimally long service life of the battery is guaranteed in order to keep the time constant of the capacitor charging in line with practical requirements, e.g. photo technology, adapt.

This arrangement of a charging resistor between battery and capacitor is of course not limited to devices for vacuum lamps, but can also be used in an advanced manner for flash tubes with gas discharge paths and for glow tubes with positive light column.

It is also advisable to arrange a switch between the battery and the capacitor, which disconnects the electrical connection between the capacitor and the battery when not in use, so that no residual current can flow when using an electrolytic capacitor or, if the capacitors are damaged, a premature electrical connection Wear and tear on the battery is avoided. This switch can be designed as a simple manual switch or in such a way that it is automatically switched on when the lamp is inserted into the holder and also switched off automatically when the lamp is removed.

The common housing for the battery and the capacitor can have any shape and dimensions.

The figures show an embodiment according to the concept of the invention.

Fig. 1 shows a known stick battery which

Fig. 2 is a schematic longitudinal section through the housing of the power source and

3 shows an electrical circuit example. consists of three commercially available mono cells and shows that the arrangement according to the invention, corresponding to FIG. 2, can have the same external dimensions as the known power sources of a known type, e.g. housed in a rod-shaped lamp holder of the flash lamp.

A battery, e.g. a commercially available mono cell b and a static capacitor c, is arranged in a rod-like, known housing a, which also serves as a holder for a flash lamp. An electrical resistor d is connected between the capacitor c and the battery b. As a result, the maximum current to be delivered by the battery b for charging the capacitor c is limited. The switch e, which is also located between the capacitor c and the battery b, can switch off the circuit between the battery and the capacitor when the flash lamp is not in use.

The new arrangement can also be used preferentially in cases where several flash lamps are required at the same time, e.g. for certain lateral illuminations. These are connected to each other by common cables and are ignited at the same time by a trigger switch, e.g. a push button provided on the lamp holder.

Given the appropriate dimensioning of the individual parts, it is easily possible, as the figures show, to subsequently build the new power source into already existing lightning rods.

From the circuit example according to FIG. 3, the electrical circuit of the individual parts of the power source and their mode of operation can be easily recognized.

Claims (7)

1.) Power source for flash lamps, e.g. for photographic purposes, characterized by a battery unit (b) and a capacitor (c) to be charged by this and used to ignite the flash lamp, which are arranged in a common housing, which preferably has the external dimensions of a normal Lightning rod (a) for two or more commercially available mono cells. 2.) Power source according to claim 1, characterized in that the capacitor is designed as a static capacitor (c). 3.) Power source according to claim 1, characterized in that the capacitor is designed as an electrolytic capacitor. 4.) Power source in particular according to claim 1 or claim 1 and 2 or claim 1 and 3, characterized in that between the battery (b) and capacitor (c), in particular to limit the maximum current to be delivered by the battery, a resistor (d) is provided. 5.) Power source according to claim 1 or claim 1 and 2 and 4 or claim 1 and 3 and 4, characterized in that between the battery (b) and capacitor (c) an "on" and "off" switch (e) is arranged. 6.) Power source according to claim 5, characterized in that the switch (e) can be operated by hand and is preferably arranged on the lamp holder (a). 7.) Power source according to claim 5 or claim 5 and 6, characterized in that the switch (e) is designed such that it is automatically switched on when the lamp is inserted into the lamp holder (a), but is automatically switched off when the lamp is removed.