DE2120777A1 - Strobe light arrangement - Google Patents

Description

2 6. 4.

Patent application

Multiblitz .Dr, -Ing. THERE. Mannesmann GmbH .. & Co »., K.G.,

5050 DPorz-Westhoven, Obexstrasse 89

Bli-tzl e height enano

The invention "relates to a seat lamp arrangement for Generation of high-intensity, short-wave radiation flashes using an ignition electrode ignitable electronic flash tube and a storage capacitor, which is located over the electronic flash tube discharges.

Such arrangements are used in connection with the photoinitiation of drying or hardening processes Used in e.g. paints or printing inks, whereby it is used for a short-term but intensive exposure from short-wave radiation while largely avoiding impermissible heating from long-wave radiation Radiation arrives. Tests of this kind have been carried out and have also produced positive results led, however, these positive results were not reproducible. Attempts to use certain flash tubes, Storage capacities and charging voltages once

209845 / 04-79 " ² "

had positive results and good drying and hardening effects showed, could no longer be reproduced at other times under apparently the same conditionso .

The invention "is based on an investigation into such Flashing light arrangements for the photoinitiation of Drying or hardening processes with the aim of the for a positive outcome of the related ver ™ seek to determine critical parameters and provide lessons for technical action that are reproducible Results ... ■ "

. According to the invention it is provided that the electronic flash tube with. such a small resistance is operated in the discharge circuit that the peak current of the Discharge is essentially only determined by the flash tube.

This state can be checked by then, for example, halving the Resistance in the discharge circuit has no significant influence on the lightning current. \

It has been shown that immediately after ignition in the initial stage of the lightning discharge, the resistance of the flash tube is extremely small, which is apparently due to the fact that the Sas in the Flash tube is not yet heated by the discharge. The flash tube resistance is initially in of the order of magnitude of Mi11iohm and is thus orders of magnitude smaller than the values of some Ohm, which acts as a flash tube resistance during the

209845/04

normal discharge are generally indicated. In this initial stage of the lightning discharge, the Onmsche resistance of the supply lines, even if this is small compared to the specified "normal" flash tube resistance and e.g. 0.1 ohm has a noticeable influence. A reduction in the supply resistance suddenly brought a considerable increase in the peak currents of the lightning discharge. It has has shown that a usable photochemical effect occurs in a reproducible manner. '

It is advantageous if the electronic flash tube is operated with such a small resistance in the discharge circuit that the lightning current has a pronounced, preferably forms oscillation going through zero.

If the lead resistance was sufficiently reduced, the lightning current oscillated, which passes through the hull point ^ d thereby one strong increase in the peak current in the first oscillation half-wave with a small half-width brought. This oscillation does not consist of a discharge and charge reversal of the storage capacitor, as it would occur in a normal resonant circuit. Rather, the capacitor becomes essentially exponentially discharged. It has now been shown that these are connected with vibrations high-intensity lightning discharges are particularly good photoehemisölie Show effects.

It is also particularly advantageous if a ■ Flash tube made of UV-permeable material with a

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has % m %% -m IsMX giving ** Arfeeit ρτ & BlItS ^. §H «ö." Low capacity of the storage capacitorii. And therefor a higher output frequency asu work. Yes trii- -

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Embodiments of the invention are as follows with reference to the accompanying drawings explained:.

Pig. 1 shows a circuit diagram of a device according to the invention

shows a flash tube preferably used in the invention.

Pig. 3 illustrates the measuring arrangement on which the invention is based lying examinations was used.

4a-e show lightning current curves which, in the case of a first type of tube with various resistances in the discharge circuit and a storage capacitor capacity of 5 M F, with the Pig. 3 were observed

Pig. 5a - β and Pig. 6a - e show the

Spreohende curves for a capacity of the storage capacitor of 10 to P or 25 j * P.

Pig. 7 shows the lightning current curves for another type of flash tube with different capacities of the storage capacitor.

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Fig. 8 shows corresponding representations for a flash tube of the same type as in Fig. 7 but with a lower gas pressure.

Pig. 9 shows the dependence of photoehemisis Effect of the lightning frequency,

Device structure

A franfarmatur 10 "(Fig. 1), on its primary winding the AC mains voltage is present, has two secondary windings 14 and 16. On the secondary winding 14 is a Rectifier bridge .18, across which a storage capacitor 20 is charged »The storage capacitor 20 is connected to an electronic flash tube 22, whereby the ohmic resistance of the external discharge circuit (capacitor, leads without flash tube) through the resistor H symbolizes isto

The flash tube 22 is ignited via a ^ ignition electrode 24, which is located on the secondary side of an ignition transformer 26 in the usual way. About the primary winding of the ignition transformer 26, an ignition capacitor 28 discharges and generates an ignition pulse at the ignition electrode 24, through which the flash tube 22 is ignited. The ignition capacitor 28 is of the on the flash tube 22 lying DC voltage are charged via a voltage divider 30, 32. The discharge takes place periodically with twice the mains frequency, e.g. 100 Hertz, and with the The flash tube 22 is ignited at the same frequency.

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For this purpose, the secondary winding 16 of the Transformer IO via a GIeichriöhterbrÜoke 34 and a charging resistor 36 a capacitor 58 is charged, its tension with suitable bedding rises approximately after curve 40 (Pig. 1) and finally a thermistor 42 "is found, which is the ignition capacitor 28 via the Brifflär winding of the It & dtransformator « 26 discharges «The 33 liter capacitor also discharges the ignition path of the thyristor. This happens once during every half-period of the AC mains voltage, so that during each half cycle the storage capacitor 20 according to Kurt 44 is charged, the flash tube 22 is ignited and the Speieher condenser discharges through this "

The electronic flash tube 22 is shown in FIG. 2 in longitudinal section. It has a rel & tor * _f hang straight tubular Sntladungskanal 46th Dead spaces 48 ”50 are connected to this satellite charge channel on both sides, the volumes of each of the dead spaces being approximately equal to the volume of the discharge channels 46. The electrodes 52, 54 extend axially through the trees 48, 50 and end just in front of the Ends of the discharge channel so that no discharge takes place in the seams 48, 50. The electron light tube consists of

Quars.

Bae liiseclirieben © advised aueftihrungsbeiipitl In terms of the critical data, it is designed as follows:

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Capacity of the storage capacitor 20 s 2 lib F (low-resistance metal paper capacitor)
charging voltage of the storage capacitor: '' 3200 volts lead resistance R <5 milliohms tube data /

Discharge length 45 cm, internal diameter of the discharge channel 4 mm. Filling pressure 350 mm of mercury. Filling gas: Xenon.

Measuring arrangement

In Fig. 3 a measuring arrangement is shown schematically, with which the effects of the various parameters on the course and the photochemical effect of the generated lightning discharge were investigated. The same reference numbers are used for corresponding parts as in Fig. 1.

An ohmic measuring resistor R _{1 is} switched into the discharge circuit. The voltage drop across this measuring resistor was applied to the y-plates of a storage oscilloscope. The resistance R ₁ was varied in some of the experiments.

Measurements

Three different types of flash tubes were used:

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Type A is a common flash tube with an inner diameter of 4 mm and the smallest possible dead gas volume. . ·

Type. B is a flash tube with an inside diameter of 1Ό mm and, similar to type A, electrodes fused directly to the ends.

Type C is a flash tube similar to Pig. 2 with dead spaces at each end of the * discharge channel, whichever the latter also has an inside diameter of 4 mm.

In one embodiment, a straight type A flash tube, 40 cm long and 4 mm long, was filled with noble gas Worked inside diameter, the gas pressure of which was 270 mm of mercury. The storage capacitor was a metal paper capacitor. For different storage capacitors with 5 / t * F, 10 / ^ F and 25 / ^ F at different Lead resistances R and measuring resistors R. ,, resulted the discharge curves evident from FIGS. 4a to 6a to e.

It can be seen that the amplitude of the lightning currents increases only relatively little with a decrease in the lead resistance, for example from 550 amps to 595 amps, while maintaining the normal exponential discharge curve. At a certain, small lead resistance, on the other hand, a damped oscillation going through zero develops, whereby the amplitude of the oscillation increases very strongly, e.g. to 3640 amperes at 5 AF , are superimposed on the exponential discharge curve. 209 8 4 5/0479

You can get out of Pig. 4 to 6 also recognize that at 5 # F the decaying oscillation is completely negative, at 25 AF completely positive. A storage capacity of 10 UtJ results in an oscillation curve that is essentially symmetrical to the Uu line. It can also be seen that this waveform of Mg. 5 leads to a maximum current peak of 4730 amperes even under otherwise identical conditions.

"The peak current is, moreover, essentially proportional the voltage to which the storage capacitor is charged. The changes accordingly photochemical effect of the lightning discharge in which apparently predominantly UV radiation is produced.

The teaching of this investigation for type A flash tubes is thus summarized:

a) With a given flash tube, the lead resistance is reduced until the flash tube forms an oscillation going through zero.

»■ ■.

b) In such a condition, there may be a variation in Storage capacity take place until the oscillations are symmetrical to the zero line.

This state is reproducibly associated with high peak currents in the initial stage of the discharge, which show a good photochemical effect if the current intensity exceeds a certain level. In the investigations described, a peak current - measured in the measuring arrangement described under the assumption of a purely ohmic resistance R ₁ - of about 2000 amperes was found to be necessary

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to achieve useful results.

With a type B flash tube, the conditions were similar to those with the type A flash tubes, however the optimum of the obtained oscillation effect with larger capacities of the storage capacitor, about 25 - 30 / M-F The photochemical effect was, however, worse than that of type A flash tubes under the same conditions.

In the case of type G flash tubes, there was no pronounced Optimum of the oscillation effect depending on the Capacity of the storage capacitor 20. This results from the curves recorded with such flash tubes in Figures 7a-d and Figures 8a-d. The capacity, and thus the work stored in the storage capacitor 20, affects just the number of oscillations that occur before the capacitor is discharged.

As can be seen from a comparison of FIGS. 7 and 8, in the case of tubes of type C - in contrast to type A and B - practically no dependency within wide limits from the filling pressure of the tube »Fig. 7 was on a flash tube with a filling pressure of 350 mm of mercury recorded, Fig. 8 on a flash tube with a filling pressure of 250 mm of mercury. at Type A or B flash tubes produce vibration effects of the type described only with relative low filling pressures <280 mm mercury.

The photochemical effect of the radiation flashes generated in this way was examined on the basis of printing ink samples, using as a measure of the effectiveness of the

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Radiation flashes the number of flashes was used, the to sufficient drying (no mistaking) the Printing inks were required. Control examinations were carried out using a part as a reference each sample was covered by an aluminum sheet. The following results were obtained:

The best drying effects occurred for all flash tubes or only drying effects at all, when the flash tube was operated in a state in which the described vibrations are markedly observed became. Type A is a little better than type B. With type C flash bulbs, on the other hand, about Paktor 10 achieves better drying effects than with the other tubes.

For type C flash tubes, there was an approximately linear relationship between the capacitance of the storage capacitor and thus the lightning work (Wsec) and the drying effect are observed.

There was also the dependency of the drying effect, namely the number of required for drying Flashes examined for a given work of each individual flash. This resulted in the falling logarithmic Dependence on FIG. 9. It is then advantageous to work with higher frequencies in order to keep them as short as possible Achieve drying times.

summary

It is therefore advantageous to use a type C flash tube. The lead resistance should

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Claims (2)

Claims 1 ο) Flashlight arrangement, for generating high- ^^ intense, short-wave radiation flashes using an ignition electrode ignitable electronic flash tube and a storage capacitor, which is located over the electronic flash tube discharges, characterized in that the electronic flash tube (22) with such a small resistance (R) is operated in the discharge circuit that the peak current the discharge is essentially only determined by the flash tube. 2. flashing light arrangement according to claim 1, characterized in that the electronic flash tube (22) is operated with such a small resistance (R) in the discharge circuit that the Lightning current forms a pronounced oscillation, preferably going through zero. Flashing light arrangement according to claim 2, characterized in that a flashing tube (22) made of UV-permeable material with a discharge channel is provided, the one outside of the discharge channel (46) - lying dead space (48, 50) contains, the volume of which at least is equal to the volume of the discharge channel (46), 209 84 5 / 0-479 Flashing light arrangement according to claim 3, characterized in that the flash tube (22) has a tubular discharge channel (46) made of quartz with an inner diameter of less than 5 millimeters, but which, on the other hand, is not completely filled by the discharge, and that the discharge channel (46) Connect dead spaces (4Φ, 50) on both sides, each of which has a volume at least equal to the volume of the discharge channel (46) ^: Flashing light arrangement according to one of Claims 1 to 4, characterized in that the flash tube is operated stroboscopically at a frequency of half to twice the Uetzfrequency, e.g. between 25 and 100 Hertz, the work of each individual flash corresponding to the load capacity of the tube is measured « , - ■ 209845/0479