NO117828B - - Google Patents

Description

Combustion flash lamp.

The invention relates to a combustion flash lamp which produces actinic light when a solid substance is burned with gas.

Such a lamp consists of a closed glass flask in which a solid substance and a gas are placed, which, after ignition, react under the emission of actinic light. The flask further contains an electrical ignition mechanism which produces a spark or a filament can be brought to glow. A mass may be arranged on the filament or the poles of the current supply wires which explodes when heated. This mass can consist of a mixture of a metal powder, an oxidizing agent and a binder.

Flash light lamps are used when photographing in order to still obtain a sufficiently illuminated photographic negative under unfavorable lighting conditions. For this purpose, the light time characteristics of the flash lamp must be adapted to the lighting characteristics of the camera shutter and the spectral distribution of the light emitted by the lamp must be matched to the spectral sensitivity of the film. The amount of light emitted by the flash lamp must be sufficiently large. In connection with this, the following requirements are placed on a combustion flash light lamp, among other things: 1. The flash light lamp must emit a large amount of light within a few milliseconds. 2. For color photography, the color temperature of the emitted light must be at least 4700°C, but preferably 5500°K.

3. The lamp must be dimensioned small.

4. The lamp must not explode during use.

5. The amount of light emitted must be little different for lamps of the same type.

Combustion flash light lamps are known which more or less meet these requirements. They usually contain as a solid substance zircon or an alloy of aluminum and approx. 10 wt. magne sium in the form of metal wool of wire or foil. Also other metals besides aluminium, magnesium and other alloys thereof, e.g. tungsten, molybdenum, lanthanum, tantalum, cerium, thorium, titanium have already been proposed for this purpose. Oxygen is usually used as gas. It is also possible to use fluorine or fluorides instead of the oxygen, e.g. oxygen fluoride (OF2) and nitrogen fluorides (NF3, N2F4). Furthermore, gaseous compounds can also be arranged which speed up or delay the combustion. The ignition mechanism's filaments are mostly made of tungsten or a tungsten-rhenium alloy. However, the filament can also consist of metals which, when heated, burn explosively in the gas present in the lamp, e.g. zircon, titanium, tantalum. Usually, an explosive mass of zircon powder, lead dioxide and nitrocellulose is applied to the filament. Other metals which in powder form can be used in the production of these masses are tungsten, magnesium, aluminium, antimony, silicon, iron, calcium. As oxygen-releasing compounds, chromates, peroxides, nitrates, chlorates or perchlorates can be used. The flask usually consists of lead glass and is coated on the outside with one or more layers of varnish to prevent glass shards from blowing out when the flask breaks.

The effective burning time of combustion flash lamps is usually between 5 and 25 milliseconds. The color temperature of the emitted light in the usual reaction amounts to approx. 4000 to 4500°K. The color temperature can be increased by covering the flask with a layer of blue lacquer. A value between 4700 and 6000 °K can then be achieved. However, this increase in color temperature is achieved at the expense of a loss from approx. 20 to 30 per cent of the emitted total amount of light.

It has already been proposed to increase the amount of light of combustion flash lamps by coating the flask wall on the inside with a substance which can reflect free radicals formed during combustion. The recommended precautions are based on the assumption that the light emitted by a combustion flash light lamp produces energized gaseous free radicals by radiation. Upon impact with the flask wall, these free radicals could lose their energy without emitting light. If the wall is coated with a material that reflects these radicals, the possibility of such a loss of energy would be reduced and the amount of light emitted would be increased.

Recommended substances for this purpose are alkali chlorides, potassium borate, boric acid, manganese chloride, barium chloride, sodium tungstate, phosphoric acid. As far as is known, these proposals have not found any practical application. Investigations showed that when used in the usual zircon-oxygen flash lamps, these substances only give a relatively small increase in the amount of light, and that in certain cases the amount of light is even less. When sodium chloride is used, it turns out, for example, an increase of the amount of light of a maximum of 5 per cent, when using sodium metaphosphate (NaPOa), however, the emitted light amount decreases by about 6 per cent. The film was obtained by flushing the flask with a 10 per cent resp. 30% solution of this salt in water (% by weight) and then dried.

The invention is based on the following

recognition.

Measurements of the amount of light from zircon NF3 flash lamps show that with decreasing bulb volume, the light yield decreases per weight unit of zircon. A reduction in the amount of light per unit weight of zircon was also found when, at the same flask volume in zircon-oxygen flash light lamps, the amounts of zircon and oxygen in the same ratio are considerably greater than the usual amount was chosen. With the flask volume remaining the same and with an increase in the amount of zircon and oxygen of 17.5 per cent, the light yield only increased by approximately 14.5 per cent. The light absorption determined in these investigations was caused by combustion products (ZrF4, Zr02) which are already precipitated during the flash light period or condensed on the flask wall. Of course, this light absorption increases with decreasing surface area of the flask wall or with a higher concentration of combustion products. Moreover, because of the shorter distances in a smaller flask and because of the greater concentration gradient, the deposits of the combustion products on the flask wall can take place more quickly, i.e. at an earlier stage of the combustion process. The fact that the mentioned effect is more pronounced with a fluorine-containing gas-filled flash lamp than with an oxygen-filled flash lamp is probably connected to the fact that the more volatile fluoride compounds (boiling point ZrF41 200°K, boiling point ZrOsæ 4,000°K) condense very quickly from the gas phase on the relatively cold flask wall, while the considerably less volatile oxides deposit more slowly in the form of liquid droplets or solid particles on the wall.

The average light absorption of the layers on the bulb wall of a flash lamp with a bulb content of approx.

2 ml and a zircon filling from 22 to 25 mg and a

stoichiometric amount of oxygen amounts to approx. 40 percent after burning.

The deposit on the flask wall is white and even with a flash light lamp stoichiometrically filled with a fluorine-containing atmosphere, while with an oxygen-filled flash light the deposit is uneven, gray and black-spotted, even with an excess of oxygen. The latter is attributable to a non-quantitative combustion, whereby incompletely burned reaction products that are dark in color can condense on the flask wall. In addition, the hot, incompletely burned reaction products have a strong reducing effect on the material of the flask wall. When the wall of the flask usually consists of lead glass, lead is even excreted with the formation of black spots from the glass, which could be determined by chemical analysis. The incomplete combustion can only be slightly improved by the use of excess oxygen. The presence of an excess of okygen increases the possibility of a lamp explosion.

It was also found that the chipping of the flask wall, which practically occurs with every flash light lamp when flashing, is produced by combustion products condensing on the flask wall. Because of this condensation, a lot of heat is released locally, whereby the flask wall is heated unevenly.

The invention is intended to prevent or at least delay the deposition of light-absorbing layers on the bulb wall of flash light lamps to the extent that only after the emission of a considerable amount of light or even later does the excretion of combustion products take place.

The invention further aims at a quantitative combustion of the solid so that no reducing incompletely burnt reaction products affect the flask wall and can darken it.

The invention therefore relates to a flash light lamp, which delivers actinic light by the reaction of a solid substance with a gas in a closed glass flask, the flash light lamp being characterized by the inner wall of the flask being coated with one or more thin layers of colorless substances, which first evaporate at temperatures such as occurs in the actinic reaction and at least below 800°C and which gives off light-coloured, gaseous decomposition products, as the substances do not react with the gas atmosphere in the lamp in the same way as the possible decomposition products.

A flash light lamp's wall lining according to the invention can consist of organic as well as inorganic substances or both.

As organic substances, it comes into consideration at relatively low temperatures, i.e. at approx. 800°C volatilizing or decomposing colorless polymeric fluorinated carbon compounds containing little or no hydrogen. Examples of such compounds are: polytetrafluoroethylene, polymonochlorotrifluoroethylene, polydichlorodifluoroethylene.

As inorganic substances, those at a relatively low temperature, i.e. below approx. 800°C, oxygen or a halogen-emitting colorless compounds, which also become colorless after reduction. These compounds must be anhydrous and preferably not hygroscopic, as otherwise the intended improvement of the light output will not be achieved.

In the case of lamps where the wall temperature on the inside during combustion very quickly, i.e. within a few milliseconds, exceeds the value of approx. 800°C, it is meanwhile also possible to use inorganic substances which only above this temperature give off oxygen or halogen to a sufficient extent.

Good results are obtained with nitrates, chlorates and perchlorates, especially of the alkali metals, as the use of KNO and KC103 is very fruitful. This effect can also be determined with peroxides and other compounds, which release oxygen when heated, and with compounds of alkaline earth metals.

Preferably, a wall lining is used which consists of a first layer on the inner wall of the flask of one of the aforementioned organic polymers and a second layer of one of the aforementioned inorganic compounds.

By using a wall lining of an organic polymer, an improvement in the light output of 10 per cent can be achieved, with an inorganic substance an improvement of approx. 12 percent

By combining both, it can be achieved

an improvement of 14 per cent. These percentages were measured on lamps with a content of approx. 2 ml, a zircon filling from 22 to 25 ml and a stoichiometric oxygen filling. In the case of lamps with a smaller volume and the same zircon quantity and oxygen quantity or a larger quantity, improvements of more than 20 per cent can be achieved by the use of the combination layers.

The use of films or thin layers of organic compounds on the inner wall of the flask of combustion flash light lamps with oxygen is known. As far as it could be determined in practice, this application no longer exists. This is likely to be attributed to the fact that the proposed wall lining, e.g. of cellulose acetate, but taking into account that the gas atmosphere in the lamp is not inert and burns during the flash, or splits in

tarry, black colored products. The gas filling oxygen is then avoided so that the possibility

for an incomplete combustion of the solid substance is increased, and thus also the possibility of a light-absorbing layer being deposited on the wall and splintering of the copper wall due to uneven heating. It was found that films of combustible substances such as e.g. hydrocarbons or also nitrocellulose corresponding to ammonium salts and water-containing compounds, both in the case of zircon-oxygen and also in the case of zircon-fluorine lamps, produces a noticeable reduction in the amount of light emitted.

The wall lining of flash light lamps according to the invention not only results in a higher amount of light. The thickness and light absorption of the wall lining of oxides, fluorides and incompletely burned products is very different from lamp to lamp in the case of ordinary flash light lamps of the same type and the same production series after flashing. When using the wall lining in the flash light lamp according to the invention, however, the dispersion of the amount of light becomes smaller.

A considerable advantage of the combined wall lining in flash light lamps according to the invention is that the chipping of the flask wall due to uneven heating is suppressed to a high degree. The wall lining clearly slows down the condensation of the combustion product on the flask wall to the extent that during the flash phase, in which the oxygen has not yet been consumed, no cracks appear in the flask wall. The danger of explosion is thus very small with lamps in this embodiment according to the invention.

In the case of combustion flash light lamps according to the invention, with the bulb volume remaining the same, the amount of solid matter and the pressure of the gas atmosphere can be increased, compared to these in ordinary flash light lamps, when a wall lining of chlorates, perchlorates, nitrates is used, possibly in combination with a film of monochlorotrifluoroethylene. In order to reduce the risk of explosion, the pressure of the gas atmosphere and thus the amount of gas in the flask is preferably chosen to be less than what is necessary for a complete conversion with the solid substance. When using the wall lining, despite the non-stoichiometric ratio between the solid and the gas atmosphere, no incomplete combustion occurs. In this way, it was e.g. possible to further increase the light yield compared to a corresponding lamp. By taking appropriate precautions, it can be ensured that the gain in the amount of light with flash light lamps according to the invention completely benefits the intended purpose. This can be achieved, among other things, by the lamp in the places where the light disappears unused or is absorbed, e.g. the inner or outer side of the lamp base, and possibly the ring around the lamp base, is coated with a light-reflecting layer. In the case of certain types of flash light lamps, this ring serves to fix current supply wires on the outside of the lamp base, and clamps these to the lamp base. The ring mostly consists of corrugated cardboard but can also be made of light-reflecting material.

When these precautions were implemented, it turned out that compared to lamps where these precautions had not been implemented, the amount of light increased by approximately 4 per cent.

Melting of the flask using a reducing flame in the case of lead glass flasks must be avoided. The discolouration to dark colors of the glass that then occurs results in a loss of light due to absorption.

In the following, the invention will be explained in more detail with the help of drawings, tables and design examples. Fig. 1 and 2 show sections through a flash lamp according to the invention. Fig. 3a is a picture of part of a flask wall of a normal flash light lamp after use. Fig. 3b is a picture of part of the flask wall of a flash light lamp according to the invention after use. Fig. 1 shows an enlarged section of a possible embodiment of a flash light lamp according to the invention. A glass flask 1 contains metal wool 2, e.g. of zircon "shred" and an ignition mechanism consisting of an explosive mush 3, which is applied to the pole of the current supply wire 5. The current supply wires 5 are connected to each other through a filament 4 of tungsten. They are held together using a glass bead 6.

The flask is coated on the outside with a lacquer layer 7, e.g. of ethyl cellulose, which may have a blue color. On the inside, the flask is covered with a layer 8 which either consists of a fluorinated polymer-carbon compound, or of an inorganic substance which, when properly heated, can give off oxygen or a halogen.

Fig. 2 shows the same lamp. In this embodiment, the flask 1 is coated with two layers 8 and 9, of which layer 8 consists of a fluorinated polymer-carbon compound and layer 9 of an inorganic substance, which can emit oxygen or a halogen when suitably heated.

Covers 8 and 9 are available, e.g. in the following manner: A. Coating of a fluorinated polymeric carbon compound.

For example, the placement of a layer of polymonochloro-trifluoroethylene is described.

Monochlorotrifluoroethylene is dissolved in a suitable volatile organic solvent, e.g. acetone, benzene or ether. The flask 1 is then filled to the desired height with this solution, after which the flask is immediately sucked empty using a capillary tube. The varnish layer is then dried. Metal wool 2 and ignition mechanism 3, 4, 5 and 6 are then placed in the flask in a known manner, the flask is filled with the desired gas and remelted.

B. Overcoating of a substance which, when properly heated, emits oxygen.

As an example, the application of a layer of potassium nitrate is described. KNO, dissolve in water, This solution is heated to 80 to 90°C and poured into a flask heated to a temperature of 100 to 120°C to the desired height. The flask is immediately sucked empty by means of a capillary tube and then processed further according to A.

C. Combined cover.

As an example, the placement of a layer 8 of polymonochlorotrifluoroethylene and then a layer 9 of potassium nitrate is described. First, according to A., a layer of polymonochlorotrifluoroethylene is placed on the inner side of the flask wall. After the solvent has been removed, e.g. during drying under heating, the layer 8 is dusted with finely crystalline potassium nitrate. For this purpose, a few mg of KN03 are shaken in a hot flask (30-50°C), whereupon the quantities not adhering to layer 8 are removed. In this way, an even, thin layer of salt is left on the polymer layer.

The fine crystalline material can e.g. is obtained by pouring a completely saturated aqueous solution of the substance in question at normal temperature into a 5 to 10 times larger volume of acetone while stirring. The precipitated fine crystalline material is filtered off and dried, after which it is ready for use.

In the following tables I to VIII, a number of examples according to the invention and the resulting increase in the amount of light are indicated.

Table 8 refers to flash light lamps according to fig. 1, where the layer 8 consists of a fluorinated carbon compound. The internal volume was 1.9 mm<3>, the amount of zircon wool was 23 mg, and a stoichiometric amount of oxygen was present in the lamp. In order to enable a reliable comparison, in each experiment the flasks equipped with a layer 8 were mixed with a number of untreated flasks. In a statistical distribution, the treated and untreated lamps went through the manufacturing process on the machine. The light quantities were determined and the mean values were compared with each other, the higher light quantities being expressed as a percentage of the mean light quantity of the non-treated lamps. This also applies to the experiments mentioned in Tables II, III and IV.

<x>) Polymer A: High vacuum degassed polymonochlorotrifluoroethylene with a viscosity of 75 cp at 99 °C, a melting point of 38 °C and a density of 1.92.<2>) Polymer B: As polymer A, but not degassed. Table II refers to the same type of flash light lamps. Layer 8 consists of a substance that emits oxygen when properly heated. Otherwise, the procedure was exactly the same.

From these and from other investigations it appears that generally the best results are obtained with the cheap potassium nitrate. Table III refers to the combined wall lining according to fig. 2 (layers 8 and 9) with the same lamp type.

In table IV, experiment 23 refers to a lamp with a combined covering according to fig. 2 (layers 8 and 9), in which the amount of zircon has been increased from 23 mg to 26 mg, with a stoichiometric oxygen filling. Experiment 24 refers to a lamp with a flask content of 1.25 ml instead of 1.9 ml, a zirconium charge of 22 mg and a stoichiometric amount of oxygen.

Table V refers to the light absorption of the bulb wall of the lamp according to the invention. The stated values are always mean values of three measurements if nothing else is mentioned. The design of the lamp is as per table I.

By way of comparison, it should be noted that with a corresponding untreated flash lamp before flashing, the bulb wall has a light absorption of 1 per cent and after flashing one of 41 per cent.

Table VI refers to a lamp according to fig. 2, in which the amount of zircon is increased to 26.5 mg, while the amount of oxygen is chosen stoichiometrically. The design of the lamp is as per table I.

The additional tables VII and VIII refer to lamps with a fluorine-containing gas filling.

Table VII refers to the lamp according to fig. 2 with an internal volume of 1.9 cm<3> and a filling of 10 mg zircon, a stoichiometric KF3 filling (calculated after ZrF4 formation).

Table VIII refers to a lamp according to fig. 1 with a flask content of 1.9 cm<3>, a zircon filling of 22 mg and a stoichiometric amount of NgF4 (calculated after ZrF formation).

Fig. 3a shows a photographic image (magnification 30 times) of the flask wall of a conventional zircon-oxygen flash light lamp after flash. Fig. 3b is a picture (30 times magnification) of the flask wall of a flash light lamp according to the invention with a combined wall coating of polymer A and KN03 after flash. This flask wall has neither black color nor breakage due to uneven heating.

Claims (7)

1. Flash light lamp, which delivers actinic light by the reaction of a solid substance with a gas in a closed glass flask, characterized in that the inner wall of the flask is coated with one or more thin layers of colorless substances, which first evaporate at temperatures as they appear at the actinic. reaction and at least below 800°C and which give off colourless, gaseous decomposition products, since the substances do not react with the gas atmosphere in the lamp in the same way <*> as the possible decomposition products. 2. Flash light lamp according to claim 1, characterized in that the wall covering consists of a polymer of a fluorinated carbon compound. 3. Flash light lamp according to claim 1, characterized in that the wall covering consists of polymonochloro-trifluoroethylene. 4. Flash light lamp according to claim 1, characterized in that the wall covering consists of an oxygen- or halogen-emitting compound when heated which, after reduction, remains colorless and is water-free. 5. Flash light lamp according to claim 1, characterized in that the wall covering consists of a chlorate, perchlorate or nitrate or mixtures of these compounds. 6. Flash light lamp according to claim 1, characterized in that the wall covering consists of a first layer on the bulb wall of polymonochloro-trifluoroethylene and a second layer placed thereon of a salt from the group of alkali chlorates, -perchlorates and -nitrates. 7. Flash light lamp according to claim 1, characterized in that the wall coating consists of a first layer on the flask wall of a polymer, fluorinated carbon compound, and a layer applied to the first with a compound that releases oxygen or halogen when heated, which remains colorless after reduction and does not contain water.