DE1232470B - Flash lamp - Google Patents

Description

Flashlight lamp The invention relates to a flashlight lamp that consists of a closed, transparent flask with a solid, a gas and consists of an ignition mechanism and upon ignition provides actinic radiation as a result chemical reaction between the solid and the gas.

The usual lamps of this type usually consist of a bulb made of glass, which is coated with one, two or more layers of lacquer and in which in a confused distribution metal wool made of wire or foil, usually zircon in the form of fibers, is present in an oxygen atmosphere. Next contains the lamp an electric ignition mechanism consisting essentially of a slurry and which can be ignited electrically. In a common design, a mush is out a mixture of zirconium powder, lead dioxide (Pb02) and nitrocellulose on a tungsten wire attached, which can be electrically annealed. When performing an electrical A current of sufficient strength explodes the pulp, which then the wire or foil ignites. The effective burning time of flash lamps is about 5 to 25 msec depending on the shape, design and size. The color temperature is about 4000'K. The color temperature can be increased by adding a blue layer of varnish is attached to the bulb of the flashlight so that it increases to about 5500 ° K can be. However, this causes a loss of light of about 30%.

The invention aims to control the color temperature of flash lamps increase and create opportunities for greater variation in behavior of flashlight lamps than with the previously common flashlight lamps to achieve.

It has been found that this can be achieved by having a Gas filling is used, which consists essentially of fluorine or one or more volatile fluorine compounds and which when ignited with the solid converts.

It has surprisingly been found that it is possible to have a reaction between a solid or one or more volatile fluorine compounds among To produce actinic light of such quantity and quality as that this can be used in a flashlight.

In addition, it was found that in many cases of such reactions higher color temperature than can be achieved with corresponding reactions in which instead of fluorine or fluorine compounds, oxygen is used.

A particular advantage of the lamps according to the invention is that that the temperature in the lamp during the reaction due to the great stability of the fluorine compounds formed during the reaction significantly lower their boiling point Compounds and even the boiling point of the corresponding oxides can exceed, which favors the quality and quantity of the radiation emitted.

Under the conditions prevailing in a flashlight when burning the decomposition temperature of A1203 is between about 5000 and 6000 ° K. This means, that the temperature during the combustion of aluminum has a value between 5000 and cannot exceed 6000 ° K. The boiling point of A1203 is around 3000 ° K. After completion of the combustion reaction, the inside of the piston is therefore with a Layer of A1203 covered, which is condensed from the vapor phase.

The decomposition temperature of Zr02 is about 4500 ° K. Of literature according to the boiling point is about 5000 ° K. During the reaction between zircon and Oxygen, the temperature cannot get so high that the Zr02 is evaporated. After the end of the reaction, the ZrO2 formed becomes the lowest Point of the piston found. Despite the fact that the temperature in a Zircon flash lamp cannot rise as high during the reaction as in an aluminum flash lamp, The former nevertheless delivers more light with a higher color temperature than the latter. This can be explained in the following way. In the reaction between aluminum and oxygen has less energy available for radiation than for reaction between zirconium and oxygen, since in the former case part of the energy is needed to vaporize of the A103 must be used. In practice it turns out that the temperatures do not show much difference during the reaction.

It turns out that among those in a flashlight after ignition Under the prevailing circumstances, many fluorine compounds with metals up to about 8000 ° K are stable. The temperature during the reaction with fluorine can thus be up to values which are usually not increased with flashlights filled with oxygen are achievable. The boiling points of the fluorine compounds are below about 3000 ° K, but the heat of vaporization of these compounds is generally lower than that of the corresponding oxygen compounds.

In lamps according to the invention, a precipitate of fluoride forms all over the piston surface. This means that this precipitate is through Forms condensation from the vapor phase.

For practical reasons, preference is given to a lamp that is volatile Fluorine compounds of metalloids contains which compounds form with the solid can convert. In general, no special measures are required for such a lamp to be taken to avoid premature reactions between fluorine and lamp parts prevent while by means of the metalloid the properties of the lamp and the texture and the amount of light emitted can be influenced.

Choosing a suitable combination of solid and fluorine or Fluorine compounds is essentially due to the ones released during the conversion Conditioned energy, which must be maximal in the absolute sense.

This means: a) the heat of formation of the possibly applicable volatile fluorine compound should be minimal and preferably negative; b) the under a) said fluorine compound should have the largest possible number of fluorine atoms per Contain molecule, among other things with regard to the filling pressure of the gas; c) the The heat of formation of the fluorine compound to be formed should be as great as possible; d) the Stability of the resulting connection at the occurring temperature should be a maximum be; e) should be the heat of vaporization of the compound formed in the reaction be minimal.

It is preferred to use volatile fluorine compounds of metalloids which do not need more than 20 kcal for decomposition per fluorine atom under standard conditions (at 1 atmosphere pressure and 25 ° C.). These are e.g. B. Compounds such as nitrogen fluoride (NF " N, F4), oxygen fluoride (0F2) and iodine fluoride (JF" JF,). Mixtures of such compounds can also be used. Under standard conditions, the enthalpy of formation (JH) and the dissociation energy per fluorine atom of these compounds are in kcal / g atom. d H dissociation energy OFz .............. -r 7.6 -E-3.8 NF. .............. -27 -9 NZF4 .............. -2 -1 / s For JF, and JF, these values are not exactly known, but small.

The gas can also contain small amounts of volatile substances, z. B. to influence the rate of combustion. It was z. B. found that the combustion rate can be increased by adding a small amount to the filling gas Amount of a gaseous or volatile hydrocarbon compound is added.

In the case of lamps according to the invention, the usual filling pressures can be used from Z. B. use 1 atmosphere or more.

As the substance to be burned come due to the aforementioned considerations mainly the elements of III. Main group of the periodic table, the rare ones Earth, the actinides and the elements of subgroup IV of the periodic system and silicon into consideration. These are the elements: boron, aluminum, scandium, Ytterbium, lanthanum, cerium and other rare earths, actinium, thorium, uranium, titanium, Zirconium, hafnium and silicon. Combinations of these elements, e.g. B. in shape of alloys or mixtures, possibly not belonging to the group mentioned Elements can be used.

The practical application of a number of the elements mentioned will be inhibited by the high price. This applies e.g. B. for scandium, ytterbium, rare Earth, actinium and hafnium.

Some elements can be easily made into thin wires or foils produce, which can be introduced into the lamp in the form of metal wool. This is true e.g. B. with aluminum, zirconium and thorium.

It can also consist of a powder of the elements mentioned and a binder thin foils are made, which are housed in the form of long fibers in the lamp will.

It is also possible to use two electrodes with an explosive pulp a mixture of a powder e.g. B. of boron or silicon and a binder to envelop. By igniting a spark between the electrodes, the lamp can be ignited.

The choice of a possible ignition slurry is essentially determined by the in The fluorine compound present in the lamp is conditional. This pulp must be at least at the time of ignition reach such a temperature that the fluorine compound begins to decompose and the reaction between fluorine and the solid is started.

The color temperature of the lamps according to the invention is in many cases higher than with corresponding lamps with oxygen filling, so that these lamps for Color photography or daylight material can be used without being strong blue-colored lacquer layers must be provided on the piston. One if necessary required Increase in color temperature will therefore be less Bring light loss with it than with corresponding flashlight lamps with oxygen filling.

The invention is explained in more detail below with reference to the drawing, which shows some exemplary embodiments.

F i g. 1 shows a flashlight lamp with a diameter of 22 mm on a two times enlarged scale; F i g. Fig. 2 shows a flash lamp with a Diameter of 16 mm on a two times enlarged scale.

The flash lamp according to FIG. 1 has a volume of 7.75 cm3 and contains 26 mg of zirconium in the form of metal wool 1. The lamp also has power supply lines 2 and 3, which are connected to one another by a tungsten filament 4. On this Combination contains a small amount of ignition pulp 5. The pulp persists made of zircon powder, lead peroxide and nitrocellulose, which are effective as binders is.

When the lamp is filled with oxygen up to a pressure of 70 cm is broadcast after the ignition 9600 lutne seconds; the time between ignition and reaching the maximum luminous flux is about 20 ursec. the The color temperature of the emitted light is around 4000 ° K.

The flash lamp according to FIG. 2 has a volume of 3.85 cm3 and contains 11 mg of zircon in the form of metal wool. The reference numbers denote the same Parts as in Fig. 1. The lamp is also oxygenated up to a pressure of 70 cm filled. After ignition, the lamp emits around 3900 lumen seconds; the time between ignition and reaching the maximum luminous flux is about 20 ursec. The color temperature of the emitted light is also around 4000 ° K. The mentioned Numbers refer to colorless lamps. Example 1 Became a lamp according to FIG. 1 filled with OFZ up to a filling pressure of 70 cm, the total amount was generated light after ignition 13 400 lumen seconds, the time between ignition and reaching the maximum luminous flux was about 40 ursec, and the color temperature was 450 ° K higher than the oxygen-filled lamp.

Example 2 If NF was used instead of OFZ with constant filling pressure, these values were 6500 lumen seconds, about 90 ursec or about 550 ° K.

Example 3 If a lamp according to FIG. 2 with OFZ up to one print of 70 cm filled, these values were 5100 lumen seconds, about 30 ursec or 500 ° K.

Example 4 When a lamp according to FIG. 2 with NF, filled to a pressure of 70 cm, these values were 2200 lumen seconds, about 70 ursec or 650 ° K. Example 5 A lamp according to FIG. 1 was filled with a mixture of OFZ and NF. If the partial pressure of the 0F2 was 20 cm and that of the NF, 50 cm, 9000 lumen seconds were emitted after ignition; the time required to reach the maximum luminous flux was about 70 ursec; the color temperature was about 150 ° K higher than that of the same lamp after filling with oxygen at the same pressure. When the lamp was filled with a mixture of OFZ and NF, the partial pressures being 50 and 20 cm, 13,800 lumen seconds were emitted; the maximum luminous flux was reached after about 50 ursec, and the color temperature was about 500 ° K higher than that of the same lamp filled with oxygen. Example 6 If, instead of zirconium, an alloy of aluminum and magnesium (7%) was used in a lamp according to FIG. 2 is used, a light yield of 4000 lumen seconds and a maximum time of 35 ursec were measured with a filling of 7 mg of this alloy and 95 cm OFZ. If OFZ was replaced by oxygen under the same pressure, the light output was no more than 2140 lumen seconds and the maximum time was 17 ursec. In the former case, the color temperature of the emitted light was higher.

The time interval between the ignition of the flashlights after the Invention and the time at which the maximum luminous flux is reached (maximum time), is too long for some types of camera shutter mechanisms. As already said, the burning speed can be increased and thus the maximum time shortened, by adding a gaseous or volatile hydrocarbon compound to the filling gas will. Such a shortening surprisingly results in a greater light yield the lamp.

Hydrocarbons suitable for this purpose are the gaseous ones and volatile compounds of carbon and hydrogen with rough formulas like CuH2n + 2, CnH2n, C, tH2n-2 and others, which per carbon atom are preferably at least Contain 2 hydrogen atoms and at about -30 ° C still at least one vapor pressure of 1 cm. Even cyclic hydrocarbon compounds that meet these requirements meet are applicable. Useful connections include: Methane, ethane, propane, butane, isobutane, n-pentane, n-hexane, n-heptane and isomers, Ethylene, propylene, butene-1, butene-2, isobutylene, pentene-1, 2-methylbutene-1, 3-methylbutene-1, Hexene-1 and isomers, Hepten-1 and isomers, allene, isoprene, benzene.

It is found in general that even small amounts of these hydrocarbons have a great influence on the burning rate. For every hydrocarbon a few simple experiments can be used to determine which amount is optimal Results can be achieved. Usually a few centimeters of filling pressure are sufficient, to get the desired reduction in the maximum time.

This effect is explained in more detail with reference to Examples 7 to 10.

Example 7 When a lamp according to FIG. 2 filled with a gas mixture of OFZ and CaH8 (propane) in the specified manner, the results indicated in the table below were obtained. Table I. Light output Amount of Zr 0F3 C8H8 in lumen maximum seconds per milligram mg cm cm Zr ursec 13.2 70-385 30 13 70 0.25 385 25 12.6 69.5 0.5 400 20 12 69 1.2 445 9 11.5 68.5 1.5 450 7 11 68 2 390 5 Example 8 The OFz of Example 7 was replaced by NF . The data in Table II below were obtained. Table II Light- Amount of Zr NFs C3H8 yield maximum time Lumen mg cm cm seconds ursec 11 120 - 3640 about 70 11 150 - 4180 about 70 11 147 4 5470 15 11 160 6 4950 8 Example 9 Experiments with other hydrocarbons together with NF, in a lamp according to FIG. 2 resulted in the following: Table III Light- Amount of Zr NF3 KW yield time Lumen mg cm cm seconds ursec 11 147 C, Hs 4 5470 15 11 147 CH, 6 3130 40 11 147 C, H8 3 5560 14 11 147 CBHg 4 about 5000 8 11 147 n-C7H "3 5500 11 Example 10 A lamp with a volume of 7.75 cm8 according to FIG. 1 with 30.8 mg of zirconium and NF, up to a pressure of 147 cm and propane with a pressure of 4 cm delivered about 8800 lumen seconds during ignition, the color temperature was 4600 ° K. The same lamp with a filling of 30.8 mg zirconium and oxygen at a pressure of 151 cm delivered about 9500 lumen seconds, but the color temperature was only 3900'K.

Claims (1)

Claims: 1. Flash lamp with a closed, transparent Piston containing a solid, a gas and an ignition mechanism, where at Ignition actinic radiation is released as a result of chemical reaction between the Solid and the gas, characterized in that the gas consists essentially of fluorine or one or more volatile fluorine compounds that are formed upon ignition convert with the solid. z. Flash lamp according to Claim 1, characterized in that that the lamp contains volatile fluorine compounds of metalloids that interact with convert the solid. 3. flash lamp according to claim 1, characterized in that that the solid consists entirely or in part of one element or a combination of Elements of the III. Main group, the rare earths, the actinides, the IV. Subgroup of the periodic table and silicon. 4. Flash lamp according to claim 1, characterized in that the lamp is also a gaseous or volatile one Contains hydrocarbon compounds. 5. Flash lamp according to claim 2, characterized characterized in that the lamp contains volatile fluorine compounds of metalloids, their energy required for decomposition per fluorine atom under normal conditions does not exceed 20 kcal. 6. flash lamp according to claim 2, characterized in that that the solid of zirconium and the fluorine compound of oxygen fluoride and / or There is nitrogen fluoride.