DE1193806B - Flashlight for photographic purposes - Google Patents

Description

Flash lamp for photographic purposes They are flash lamps known for photographic purposes with a fused glass bulb, the one Contains filling made of fiber-like cut aluminum strips. The piston is made Made of blown glass and has the shape of an ellipsoid of revolution about 2.5 cm long the large axis, not including the space required for the lamp base is.

These lamps are filled with oxygen at a pressure above atmospheric pressure but below 2 atmospheres.

The prior art also includes teaching; instead of aluminum to use zirconium as a combustible fiber material, however, the practice has so far been on This suggestion passed by, since the use of zircon because of the proportionate has shied away from high prices and saw no advantage in the use of zircon.

The inventor set himself the task of using the previous flash lamps to shrink and generate a larger amount of light per unit of bulb volume.

A flash lamp for photographic use with a fused Glass bulb that is a loose, flammable, fibrous material and an igniter as well as an oxygen filling, is to be characterized according to the invention be that the combustible fibrous material in a known manner from zircon and that the pressure of the oxygen is greater than 2 atmospheres.

The invention is based on the knowledge that when using zirconium the peak pressure that occurs during combustion is considerably lower than the peak pressure when burning aluminum.

According to a further embodiment of the invention, the lines are introduced into the lamp bulb by means of an external pinch foot. Such a shape of the pinch foot is particularly suitable when it is important to keep the lamps in to accommodate a so-called magazine, from which quickly and easily a new lamp can be promoted to the point at which the flash lamp ignited, d. H. is used.

There is a further improvement of the flashlight lamp according to the invention in that the lamp body is made from a drawn glass tube instead of a blown one Lamp bulb consists. A drawn glass tube has the same wall thickness and everywhere therefore allows higher internal pressures than a blown lamp bulb, thus enables for a given piston volume the use of a larger amount of zirconium and the use of a higher oxygen pressure.

In the case of a piston, the pump nozzle can be made from a drawn glass tube Attach it with the outer pinch foot to the other end of the drawn glass tube than the outer pinch foot.

In the case of flash lamps of the construction according to the invention, the pressure can be used of oxygen to at least 5 atmospheres and increase the concentration of the fibrous Choose zirconia in the flask between about 15 and 25 mg / em3 of the flask volume.

A lamp with a bulb volume of about 1.2 cm3 and a zirconium filling of about 25 mg has already proven its worth.

The zirconium filling should consist of strips, for example About 20 µm thick and about 30 µm wide.

The invention will now be based on an exemplary embodiment in conjunction are explained in more detail with the drawing.

F i g. Fig. 1 shows an enlarged, partly in section Front elevation of a flashlight lamp according to the invention, and F i g. 2 shows a side view at right angles to the view according to F i g. 1.

The flashlight lamp according to the invention comprises a closed glass bulb 1, which is approximately tubular in shape and consists of a short piece of drawn glass tube which is closed at one end by an integral flat outer pinch foot 2 which connects in the axial direction to the lamp bulb. The other end of the piston 3 is constricted and ends in a pump nozzle 4. Since glass tubes, which are produced by the usual drawing processes, naturally have a fairly constant wall thickness and since the piston 1 consists of a piece of drawn glass tube, it also has one practically uniform wall thickness, at least in the tubular part. As a result of the production from one piece of drawn glass tube, the bulb 1 can easily be produced with thicker side walls than the usual blown glass bulbs which have generally been used up to now for flashlight lamps of this type. In the example specifically shown, the thickness of the side wall of the bulb 1 was about 0.68 mm, while the wall thickness of the conventional blown lamp bulbs for flash lamps was about 0.45 to 0.50 mm. The dimensions of the bulb 1 are many times smaller, for example by a factor of 5 or 6, than the smallest commercial light bulbs. The piston has an internal volume of less than 2 cm3, preferably about 1.2 cm3. The cylindrical part of the piston has an outside diameter of about 11 mm and a length of about 19 mm. The side surfaces 5 of the pinch foot 2 are preferably flat and parallel to one another and to the bulb of the lamp. As can be seen from the drawing, transverse guide channels or grooves 6 are provided in the flat sides 5 of the pinch foot 2, which can engage in the guide rails of a lamp magazine or a filling chamber (not shown) of a flashlight device.

In the pinch foot of the bulb 1 , an ignition arrangement 7 is fused, which comprises two lead-in wires 8 which are fused into the pinch foot 2 during manufacture of the lamp so that they penetrate it and extend approximately in the longitudinal direction more or less parallel close to each other in the lamp bulb . Outside the pinch foot 2 , the lead-in wires 8 are provided with suitable connection contact parts, which can consist of an open wire loop 9, which are bent around the end of the pinch foot so that they run along the opposite flat side surfaces 5 and end just before the guide groove 6. Inside the piston 1, the lead-in wires 8 are rigidly connected to one another, for example by a bead 10 made of glass or another suitable insulating material, in which the lead-in wires are embedded. The insertion wires 8 end in the lower region of the part of the lamp bulb adjoining the pinch foot, away from the tip 3. They are connected at the inner ends by an ignition thread 11 , which preferably consists of a short straight piece of fine tungsten wire, which in a suitable manner has a Can have a diameter of about 17 to 18 [, m. The inner ends of the lead-in wires 8 are connected to coatings 12 of a suitable ignition material. The coatings 12 contact the wire 11 and ignite when the wire is heated by the passage of current. The igniter material from which the heads or coatings 12 are made can consist of a known mixture of finely powdered zirconium, potassium perchlorate and magnesium (maximum grain size about 44 #Lm), which are bonded with a suitable binder, such as 2- to 5o / oiger Solution of nitrocellulose in amyl acetate. The best results are obtained, however, especially when the ignition wire 11 has a diameter of about 17 to 18 μm, and when the mixture has the following, also known composition, namely about 60 to 90.1 / o zirconium, 1 to 8% magnesium and 3 to 351 / o potassium perchlorate.

The piston 1 contains a filling of oxygen and of a quantity of loosely distributed thread-like strands of an easily combustible metal which consists of zirconium or an alloy mainly containing zirconium. The thread-like, combustible material 13 is preferably in the form of finely cut strips of a thin metal foil of the composition given above; the finely cut strips can be of the type known in the trade as shredded film. The strips have a width of approximately 12 to 37 µm and a thickness which can also be in this range between 12 and 37 µm. The fibrous, combustible material is loose and distributed as evenly as possible in the interior of the piston above the ignition thread 11 in order to ensure the best burning conditions for the material.

The oxygen is in the flask 1 through a pump port at the top End 3 of the piston filled, this pump port is after evacuation and the Introducing the gas filling melted, as can be seen at 4, so that the piston is hermetically sealed.

To reinforce the piston 1 and to make it shatterproof, the outside of the piston is coated with a protective paint layer 14, for example made of cellulose acetate. The inside of the piston can remain free and unprotected by a layer of paint.

With the previous flash lamps with the usual blown glass bulbs, which have relatively thin side walls, the amount of the combustible filamentary filling per unit volume of the lamp bulb had to be kept below about 2 mg / cm3 of the bulb volume if an aluminum filling was used, and below about 6 mg / cm3 when using a zirconium filling. In addition, the pressure of the combustion-maintaining gas in the flask was not allowed to exceed approximately 2 atmospheres in order to keep the intensity of the reaction in the flask when the filling was burned and thus the resulting pressure low enough to ensure adequate safety against explosions. The quantitative limitation of the light-emitting reaction materials in the bulb for safety reasons, of course, in turn limits the light output that can be achieved per unit volume of conventional lamps with blown bulbs. However, it has been shown that when using a glass bulb 1 with very small dimensions, for example a volume of less than 2 cm3, which consists of a short piece of a drawn glass tube, and by using a thread-like filling 13 made of zirconium, it is possible to safely load the flask with far larger amounts of light-emitting reaction materials (namely with combustible material 13 and gas that maintains combustion) than was previously possible without causing the danger of the lamp exploding when flashing. This is possible because, because of the natural properties of drawn glass tubes, at least the side walls of the bulb have a relatively uniform thickness and are free of thin wall areas, and zirconia has the property of burning on the spot inside the bulb and not, as was previously the case in flashlight lamps used aluminum to form small, burning metal particles or spheres, which are thrown around the interior of the piston with great energy and high speed. As a result, a light output per unit of flask volume is obtained that is many times that which could be achieved with the previously common flashlight lamps.

According to the invention, the piston 1 is therefore filled with thread-like, combustible zirconium material 13. The individual fibers have a cross-sectional area in the range from about 4 to 9-10-4 mm 2; the concentration is at least 15 mg / cm3 of the flask volume and can be up to 25 mg / cm3; the filling consists of oxygen or another gas that maintains combustion under a pressure of at least a few atmospheres. In a preferred embodiment of a flashlight lamp according to the invention, a bulb 1 with a volume of approximately 1.2 cm 3 was used; the flask was charged with about 24 mg of finely cut zirconium foil, the individual strips of which were about 20 μm thick and about 30 μm wide, and the filling was oxygen at a pressure of at least about 5 atmospheres, preferably between 5 and 6 atmospheres. A flash lamp according to this embodiment of the invention thus works with a concentration of combustible, fibrous material in the bulb of approximately 20 mg / cm3 of the bulb volume, which is a multiple (namely more than three times) the concentration in conventional flash lamps. Such flash lamps, in which the bulb is coated on the outside with a clear protective lacquer layer 14, deliver a brief flash of light of approximately 7500 to 7800 lumen seconds with a peak intensity between approximately 4-105 and 5-105 lumens. If the igniter 12 is appropriately dimensioned, the intensity peak is approximately 15 milliseconds after the electrical circuit has been closed by the ignition wire 10 of the lamp. The light output per unit volume of the bulb space of the flashlight lamps according to the invention is therefore significantly more than 3-103 lumen seconds / cm3 of the bulb volume and in the case of the embodiment described even more than 6-103 lumen seconds / cm3, which is a multiple, namely approximately three times that what the most powerful flashlight lamps on the market are able to achieve according to our knowledge, namely about 2 - 103 lumen seconds / cm3 bulb volume. It is obvious that a flash lamp with the properties described above is an excellent light source for ordinary, inexpensive types of cameras that do not have a synchronized lamp contact and that require flashing with the shutter open, i.e. when the shutter is set to T or B.

Claims (7)

Claims: 1. Flash lamp for photographic purposes with a fused glass bulb that is a loose, flammable, fibrous material and contains an ignition device and an oxygen filling, characterized in that that the combustible, fibrous material consists of zirconium in a manner known per se and that the oxygen has a pressure greater than 2 atmospheres. 2nd lamp after Claim 1, characterized in that the lines by means of an external pinch foot are introduced. 3. Lamp according to claim 1 or 2, characterized in that the Lamp bulb consists of a drawn glass tube. 4. Lamp according to claim 1 to 3, characterized in that the pump nozzle of the piston is located on the outer pinch foot opposite end of the glass tube is located. 5. lamp according to claim 1 to 4, characterized in that the pressure of the oxygen is at least 5 atmospheres and that the concentration of fibrous zirconium in the flask is between about 15 and 25 mg / cm3 of the flask volume. 6. Lamp according to claim 1 to 4, characterized in that that the flask volume is about 1.2 cm3 and the amount of fibrous zircon in the flask be approximately 25 mg. 7. Lamp according to claim 1 to 4, characterized in that that the zirconium filling consists of strips that have a thickness of approximately 20 [tm and have a width of about 30 gm. Publications considered: German U.S. Patent No. 725 911; U.S. Patent Nos. 2,393,711, 2,860,502.