DE1913417B2 - FLASH BULB - Google Patents

Description

35

The invention relates to a flash lamp with a flask having a volume of 1 cm ¹ or less, the combustible material of thread-like, curved or wrinkled metal foil chips having a small cross-section of 2 to 10 x 10- ⁴ mm ² distributes contains and m with a ^ the Combustion supporting gaseous medium is filled above atmospheric pressure. Such lamps used for photographic purposes are required to emit a large amount of light in a short period of time. According to international agreements, the time from applying the ignition voltage to reaching the peak value of the light output, the so-called peak time, should be around 13 ms. This implies certain requirements with regard to the filling, both with regard to the amount of the gaseous medium supporting the combustion, generally oxygen, as well as with regard to the shape of the introduced film chips, which for example consist of zirconium.

It is known to run a wide film strip through a rotating roller with transverse cutting edges Separate film shreds of small width. The chips are then pneumatic via a line sucked into the piston, crumpled by the impact on the piston wall and by the air flow in the Pistons distributed (US-PS 23 47 046).

In another arrangement, it is known that a chamber is provided in the suction line in which knock the shredded film onto the chamber wall several times with the swirling air stream and thereby & 5 are curved (US-PS 31 20 694).

The cross-sectional area of shredded film can be approximately ⁴ mm ² (DT-PS 9 33 191).

In a known flash lamp, the cross-sectional area of the film shreds is about 12-10 * mm ² . The length of the shredded film is about 101 mm. The film shreds are contained in a lamp bulb with a volume of 7 cm ³ . The pressure of the gaseous medium supporting the combustion is below atmospheric pressure, but it can also be above atmospheric pressure (GB-PS 10 Ö4 790).

In another known flash lamp, the cross-sectional area of the film shreds to about 4 amounts to 9-10 ⁴ mm ^2. The width of the film chips is approximately 30 μm and the thickness approximately 20 μm. They are housed in a flask with a flask volume of 1.2 cm ^3. The filling pressure is, for example, 5 atmospheres (DT-AS 11 93 806).

In the known lamps, the combustible material lies in arbitrarily shaped, relatively large loops in and on the lamp bulb. The time until the peak value is reached is considerably less than the generally established time of 13 ms, especially for lamps with a small bulb volume and high filling pressures.

The invention is based on the object of creating a flash lamp of the type mentioned at the beginning which the peak time is around 13 ms,

The solution to the problem is that the film chips have 8 to 50 creases, preferably 12 to 30 creases, per 100 mm length, each film chip being a ball with a cross section of 40 to 8 mm ² , preferably 30 to 12 mm ² , per 100 mm chip length.

The kinks in the shredded film essentially have a radius of curvature smaller than 0.3 mm. The included angle of each kink is im substantially less than 60 °.

The advantages achieved by the invention are in particular that the apex time extension can be achieved simply by bending the shredded film - without additional expenditure on combustible material. In addition to the lengthening of the apex time, the buckling results in a gain in light. While with the known flash lamps, the shredded film in large loops lie linearly on the bulb wall, the kinked film shreds are only in point form. This point-like contact with the piston wall apparently leads to a burning of shredded film without loss of energy due to large heat dissipation to the flask glass so that the amount of light emitted is higher.

Exemplary embodiments of the invention are illustrated in the drawings and are described in more detail below described. It shows

Fig. 1 shows a flash lamp with the multiple kinked film shreds.

F i g. 2 shows an enlarged section of a flashlight bulb with a previously customary shredded film filling and with a shredded film filling according to the invention.

F i g. 3 for each shredded film, the tangle formation as a function of the number of buckles.

F i g. 4 shows an arrangement for producing the kinked film shreds during lamp filling.

The flash lamp in FIG. 1 has a tubular piston 1 with an outer diameter of 6.3 mm, an inner length of 15 mm and a volume of 0.2 cm ³ , which is covered with a lacquer coating 2 as a splinter protection. The filling 3 consists of 14 mg of zirconium in the form of foil chips 4 with a

'■ f

Length of 100 mm. a width of 32 m and a thickness of 20 M. The individual Foiienschnitzel has about 27 bends, the radius of curvature of the bend is less than 03 mm and the included angle less than 60 ° De · skein cross-section is in this case for each cutlet 15 mm ² . The lamp is filled with oxygen at a pressure of 18 at. The ignition means is of the usual type with 5, and with δ and 7 the Sirom feeds to the ignition means are designated.

On the left side of Fig.2 are clearly the relatively large, often linear on the wall of the piston 1 adjacent loops in the hitherto customary Foil shredded filling 4 can be seen, while the illustration on the right-hand side of FIG kinked structure of the film shreds 4 and their mostly point-like contact with the piston wall in the Execution of the film filling according to the invention emerges.

FIG. 3 shows, in the order from left to right, individual film shreds in the conventional form, those with 13 kinks and those with 28 kinks. While the hitherto customary film shreds are distributed over a large area in loops, the other two representations show a cross-section of the ball that is forming which decreases as the number of bends increases.

During the deformation of the chips and filling of the lamp, as shown in FIG. 4 is reproduced, the foil slices fed in via tube 8! 4 is sucked at by an air stream of about 3, accelerated in the tube 9 and thrown against the wall of the chamber 10 by dt; kinked) impact film shreds are then again at by perpendicularly flowing to the original direction of air 2-3 through the accelerating tube 11 thrown against the wall of a second chamber 12 and thus get their final kink. The bent foil shreds reach the lamp bulb 1 via the tube 13 with the aid of the remaining air stream.

In the case of a lamp according to the exemplary embodiment, the peak time is 12 ms and the amount of light generated is 3,500 Ims. If the lamp is filled with 3 kinks per 100 mm carving length, the corresponding values are 10 ms and 3 1001 ms, while values of only 8 ms and 2,500 Ims are achieved when using previous film cuttings. Obviously, the peak time depends on the number of buckles. Compared to previously known flash lamps, a light gain of 40% is achieved.

For this purpose 3 sheets of drawings

Claims (6)

«F patent claims: 1. Flash lamp with a bulb with a volume of 1 cm ³ and less, which contains combustible material from thread-like, curved or crumpled metal foil shreds with a small cross-section of 2 to 10 - to ~ ⁴ mm ² and with a gaseous material that supports the combustion Medium is filled above atmospheric pressure, characterized in that the Film chips have 8 to 50 creases per 100 mm length, each film chip forming a ball with a cross section of 40 to 8 mm ² per 100 mm chip length 2. Flash lamp according to claim 1, characterized in that the film chips have 12 to 30 creases per 100 mm length and that film chip forms a ball with a cross section of 30 to 12 mm ² per 100 mm chip length. 3. Flash lamp according to claim 1 or 2, characterized in that the kinks of the film shreds have a radius of curvature smaller than O _n J mm. 4. flash lamp according to claim 3, characterized in that that the included angle of each kink is less than 60 °. * 5 5. Flash lamp according to claim 1, 3 and 4 or 2 to 4, characterized in that the film shreds from Consist of zirconium. 6. Flash lamp according to claim 1,3,4 and 5 or 2 to 5, characterized in that the film shreds are 100 mm long, 32 μ wide and 20 μ thick.