DE1255487B - Flash lamp with ignition pill - Google Patents

Description

Flash lamp with squib The invention relates to an ignition means for Flash lamps that finely distribute a certain amount in an airtight container, contain combustible material and oxygen. About the combustion process in the lamp vessel initiate, an ignition means is provided within the vessel. Most of them Flash lamps, this ignition means consists of two power leads inserted into the vessel, which are connected by an ignition wire. The ignition wire or the power supply near the ignition wire are provided with a squib, which is highly flammable Contains material and an oxidizing agent. To ignite a Voltage source connected. The current pulse flowing through the wire brings these to glow, causing the pill to ignite and burn in the lamp initiates. With the common BC ignition, the power source consists of a capacitor from Z. B. 100 to 200 pF, charged by a battery of about 22 or 15 volts will. To ignite the lamp, the capacitor is discharged via the ignition wire. Around the ignition wire to glow with the available electrical energy to bring this must be very thin. For example, ignition wires are with diameters from 16.2 to 16.6 µm is advantageous. The electrical resistance must be very small and about 0.5 ohms. However, the attachment of the ignition wire is required very small resistance difficult to manufacture. Even small changes in length of the ignition wire, which is only about 2 mm long anyway, or changes in the contact resistance from the ignition wire to the power supply leads to considerable deviations from the target resistance. When using this ignition means is because of the low Voltage of 15 to 22 V a particularly good contact between the lamp base and Luminaire socket required. This fact demands both of the lamp manufacturer as well as additional effort from the manufacturer of the sockets, such as nickel-plated lamp contacts or contact arrangements with scraping contact.

To avoid these disadvantages, there are already high voltage working Ignition means have been developed. In such a high-voltage ignition process in the flashlight as ignition means two power supply lines with ignition compound attached arranged in such a way that an ignition spark jumps over the filling gas and thereby the ignition mass to react.

It is a high-voltage ignition means known in which the power supply wears a non-conductive coating and the squib is attached to this coating is. The ignition spark breaks through this non-conductive coating, and that with the breakdown Any heat generated ignites the squib.

These cordless flashlights require igniters that provide voltages Generate well over 1000 V, whereby the energy requirement is very high, since the spark The energy contained only contributes to a very small extent to the heating of the ignition material. When flashovers in gases or breakdowns by solids, the largest part is the spark energy delivered to them. The necessary for the described ignition means very high voltages and the high energy consumption therefore require ignition devices that In terms of volume and weight, they are much larger than in the case of the ignition means made of filament and detonators attached to the power supply lines.

It is also already through the Austrian patent document 213 238 a flash lamp with two electrodes inserted into the vessel known, of which at least one is coated with ignition compound, but not with one another Ignition wire are connected. The ignition circuit is here via the combustible material closed, which is in contact with both electrodes. The ignition takes place by small sparks in the ignition material itself, i.e. by the passage of current through the Ignition mass. However, it has been found that a more secure contact between the electrodes cannot be achieved via the chip filling of the lamp. Both Today's miniature flash lamps are the shredded foils for various reasons concentrated in a certain part of the lamp envelope, and the zone of the Ignition means is completely free from shredded film. Because of the large spread of the contact resistance in the schnitzel and because of the small arcs that can almost always be observed between the shredded film and the surface of the squib is the hoped-for reduction the ignition energy did not occur.

The aim of the invention is to provide a wireless ignition means, which manages with lower ignition energy and a uniform ignition behavior and thus a good lamp quality is guaranteed.

Try the finely divided combustible metal powder and dielectric Primer containing binder through direct current passage until insertion due to the high resistance of the Primer of well over 100 Mn surprising and at first inexplicable result, that with a voltage surge of about 100 V the squib is ignited and the energy requirement is not only much lower than with the high-voltage ignition method, but is also lower than with the ignition wire method.

A flash lamp with an airtight sealed, finely divided, flammable material and oxygen-filled vessel, two leading into the vessel Power supply lines and ignition mass carried by the power supply lines, which are caused by the passage of current is ignited by the mass itself is characterized according to the invention that the two power supply lines inside the lamp by a pill from a finely divided, Ignition compound containing easily flammable metal and dielectric binder are bridged, the pill directly to the electrically conductive surfaces of both Power supply is in contact and the electrical measured in the range below 20 V. `Resistance of the squib is 1 MQ or more.

The ignition means therefore only consists of the two power supply lines electrically conductive surface bridged by a high-resistance squib are. There is no ignition wire to bypass the power supply.

The term "electrically conductive surface" is intended to mean that none Insulating layer to be broken down by an ignition spark between power supply and Ignition mass should be available. A slightly oxidized surface of the ignition wire, as found in most base metals and which do not have a significant voltage drop caused by the passage of the ignition current impulse should also be considered electrical conductive surface in the present sense apply.

The ignition voltage applied to the pill becomes continuous from zero increased by about 10 V / sec, ignition occurs at about 70 V on average. at When the voltage is switched on in pulses, the mean value for igniting the Pill necessary voltage about 50 V.

Is the DC voltage applied to the pill in the manner mentioned increases slowly without ignition already occurring, at 30 to 60 V it is on gradual decrease of the originally large resistance of more than 1 MS? around more than an order of magnitude to watch. This new low resistance remains largely preserved when reducing the voltage and when repeating the experiment. The squib has largely changed electrically. To ignite this pill a much larger electrical ignition energy is required.

The study of this phenomenon led to the assumption that an ignition mechanism is present, which differs fundamentally from the previously known mechanisms. The structure of the squib, made of metal powder and a dielectric binder and preferably also consists of an oxidizing agent, forms considered electrically a lengthwise and cross-linked stack of very small spark gaps or capacitors and parallel and series resistors of various sizes. Here the deposits on the capacitors are essentially caused by the metal particles that Dielectric through the binder and possibly through the oxide covering of the metal powder shown. If the voltage applied to the ignition system is increased slowly, it will take place in the range between 30 and 60 V breakdowns on individual capacitors of the meshwork, by probably destroying the binder in individual places. this leads to to a current flow in the affected mass particles under heating, from which the Formation of one or more current paths through the squib results in the explain irreversible increases in conductivity. As the partial copies However, if they follow one another in time, the heat released in the process can flow away and is unable to initiate the ignition process. However, it becomes by leaps and bounds a When a voltage of about 50 V is applied, so many partial capacitors breakdown practically at the same time, since the heat energy released here accumulates and leads to temperatures which are sufficient to initiate the ignition reaction. In the The heat released by the micro-spark gaps during spark breakdown must therefore as far as possible to adiabatic heating of the particles to be chemically reacted to lead.

The mentioned initial resistance of the pill, which is 100 Ma or more can, therefore, is the resistance. which is measured before that in the range from 30 V observed gradual decrease in resistance occurs. Is safest This resistance can be determined if you measure voltages below 20 V used.

It has been shown that pills with a much lower initial resistance than 1 M52 cannot be ignited with the same amount of energy. This result is understandable if one considers the ignition mechanism outlined above presupposes. For pills with such a small resistance, that is parallel to the Micro-spark gap resistance too small, d. i.e., a large part of the through The current passing through the pill heats these resistances and removes them from the micro-spark gaps Energy.

The desired conductivity and the necessary structure of the squib granulate by the choice of the binder, by the percentage of the binder on the total pill, through grain size and grain size distribution of the finely divided Metal of the squib can be achieved.

The finely divided metal preferably consists of zirconium powder with Grain sizes between 0.5 and 5 µm, with grain sizes below 0.5 and above 5 µm to about 20 «m occur sporadically. Lead dioxide and lead oxide have proven to be oxidizing agents Potassium perchlorate proven. which are finely divided with up to 35 Weight percent of the pill are added. Polyvinyl alcohol is suitable as a binding agent, the 0.4 to 4 percent by weight, preferably about 2 percent by weight, of the ignition mass matters. However, there are many other binders with similar dielectric properties Properties usable. The composition of the squib corresponds to the common pills for BC ignition.

The oxygen carrier can also be omitted entirely. Then however it is It is necessary that the squib is in an oxygen atmosphere when it is flashed and thus gaseous oxygen is trapped in the squib. Even if it is present a solid oxidizing agent in the pill mass promotes the oxygen atmosphere the flashing of the pill.

To flash the pill there are voltage pulses of about 100V or a few 100V advantageous. With voltages below about 70 V, ignition is not absolutely safe to achieve. The energy to be expended for flashing off is very low and amounts to about 0.3 mWsec. The necessary voltage pulses are in the secondary winding a miniature transformer produced by placing a capacitor across the primary winding this transformer is discharged. The charging of the capacitor from z. B. 30 uF takes place via a resistor through a z. B. 4.5 V supplying miniature battery.

The invention will now be explained with reference to the figures.

F i g. 1 shows the longitudinal section through a flash lamp according to the invention; F i g. 2 shows the circuit in a strobe light for burning down the inventive Lamps.

The in F i g. 1 shown dwarf flash lamp consists of an approximately tubular Glass vessel 1, which with zirconium foil chips 2 and for example 7000 Torr oxygen is filled. A copper pump pipe 4 is fused concentrically in the plate 3 of the lamp, which serves as the first power supply. An eccentric serves as the second power supply Fused copper clad wire 5, which is from the copper tube 4 a distance of 0.1 to 0.5 mm, preferably about 0.2 mm. According to the invention are both power supply lines bridged by a squib 6, which is connected to the surface both power supply lines is in contact. The squib 6 consists of finely divided Zircon powder, lead dioxide and about 2 percent by weight polyvinyl alcohol. For the production the primer is the binder in a solvent, e.g. B. in amyl acetate, dissolved and the zircon powder together with the solid oxidizing agent in this binder solution slurried. During the manufacture of the lamp, the two power supply lines are used melted into the plate 3, and the eccentric power supply 5 is against the pump tube 4 pressed. The elasticity of the copper clad wire 5 creates after releasing the power supply the desired distance of about 0.2 mm. After the plate 3 has been melted into the glass tube forming the lamp bulb 1 the ignition mass is brought to the power leads, which as a result of them Viscosity forms a bridge of ignition material across both power supply ends, which is then dried by evaporation of the solvent. But before that compressed air is still blown through the copper tube 4 so that its opening is not detonated by ignition material becomes clogged. After filling with zirconium, completing the glass tube and after the filling of the piston with oxygen via the pump tube 4, the latter is outside squeezed off the lamp and provided with a solder 7.

To ignite a lamp according to the invention, it is advantageous assumed the usual battery-capacitor circuit made by a pulse transformer is supplemented. The battery 8 charges the capacitor 11 via the current limiting Resistance 9 of z. B. 5 kQ and the charging circuit breaker 10 on. Will the camera contact 12 is closed, the capacitor 11 discharges through the primary winding 13 of the pulse transformer. In the secondary winding 14 of the pulse transformer, which has significantly more turns than the primary winding, this creates a free damped oscillation. When dimensioning the switching elements it was assume that the space and energy requirements of the arrangement with the greatest ignition reliability should be minimal. A ferrite pot core with a transmission ratio of approx 1: 200 and dimensions of 9.5 - 6 mm turned out to be optimal. For the primary winding 3 turns are preferably used, which results in about 600 turns on the secondary side result. The electrical power required for ignition is surprisingly small. The battery 8 preferably consists of 3 mono cells of a total of 4.5 V, while the capacitor is optimally dimensioned at around 30 pF. This results in a Energy to be used for ignition of about 0.3 malsec compared to 20 to 30 malsec for a BC ignition. 15 and 16 represent the two contacts of the lamp socket represent.

The wire bridge 17 from primary to secondary winding indicates that only one end of the thin secondary winding 14 is led out. The other end is preferably due to mass.

The primary winding consists of copper wire with a diameter of 0.2 mm, the secondary winding made of copper wire with a diameter of 0.05 mm. All of the components can be conveniently placed in a plastic housing with dimensions of around 40 - 20 - Accommodate 20 mm.

The switch 10 is arranged in the strobe light that it closes when a lamp is inserted and opens again when it is removed from the lamp socket and is coupled, for example, to the ejector. By interrupting the charging current when the flash unit is not in operation, premature discharge of the battery due to the capacitor leakage current is avoided.

Claims (1)

Claims: 1. Flash lamp with an airtight, vessel filled with finely divided, combustible material and oxygen, two in the power supply lines leading the vessel and the ignition material carried by the power supply lines, which is ignited by the passage of current through the mass itself, characterized in that that the two power supply lines inside the lamp by a pill from a finely divided, Ignition compound containing easily flammable metal and dielectric binder are bridged, the pill directly to the electrically conductive surfaces of both Power supply is in contact and the electrical measured in the range below 20 V. Resistance is 1 Me or more. z. Flash lamp according to claim 1, characterized in that the squib made of zirconium powder with grain sizes essentially between 0.5 and 5 [.mu] and 0.4 to 4 percent by weight of polyvinyl alcohol as a binder consists. 3. Flash lamp according to claim 2, characterized in that the squib Contains up to 35 percent by weight of oxidizing agents such as lead dioxide. 4. Flash lamp according to claim 1 to 3, characterized in that the one power supply from the concentrically fused copper pump tube and the other power supply from one eccentrically melted wire is that both power supplies have a smallest Have a distance of 0.1 to 0.5 mm and at the point of smallest distance through the squib are bridged. 5. Method for producing a flash lamp according to Claim 1 to 4, characterized in that the two power supply lines according to their Melt with their ends so pressed against each other that they are about at the point that the squib is supposed to bridge, touch that the power supply lines subsequently released so that between them due to their elasticity the desired distance arises that the ends of the power supply lines in ignition ground are immersed, which due to their viscosity creates a bridge over the power supply ends forms, and that finally the ignition compound bridging the power supply lines is dried will. Publications considered: Austrian patent specification No. 213 $ 23.