NO117993B - - Google Patents

Description

Flash light lamp.

The invention relates to a lightning lamp where power supply wires which have been led out through the melting edge between the flask neck and the discharge tube are clamped against the flask neck by means of a flat ring of insulating material lying close to the flask, the lamp base being pressed flat on two opposite sides which are approximately 90° rotated in relation to each other to the exit points for the power supply wires.

As is well known, a single-use lamp must be replaced with a new one when shooting with flash lamps. The photographer who uses this lamp must always have several lamps with him. It is therefore advantageous that this lamp requires as little space as possible and has the least possible weight. The development of lightning lamps in recent years has already led to the lamps being made with significantly smaller bulbs than before. In this context, it has already been proposed to provide such lamps with a dwarf base, which is significantly cheaper than the previously used support stand. Until now, it was common to attach a non-detachable lamp base to the lamp neck, which meant that after the lamp had been used once, it had to be thrown away together with the used lamp.

As the lamp is equipped with a detachable holder, these disadvantages are removed. due to the mutual adaptation of the shape of the outer circumference of the lamp neck and the lamp holder's insertion opening, the insertion of the socketless lamp into the lamp holder is realized so that the photographer, when he turns the lamp somewhat on its axis if necessary, can purely emotionally guide it into the correct position in the holder, under which at the same time the elastic power supply means are tensioned in the lamp holder. Once the lamp has been inserted into the holder, the power supply means will hold them in this position. If the lamp has been lit, it can be removed by a simple pulling movement out of the holder, and a new lamp can be inserted into the holder. This greatly facilitates a quick replacement of the lamps. This is a special feature of the combination that is of great importance for photography.

The above-mentioned precautions provide a flash light lamp whose manufacture is not only simple, but whose handling is extremely convenient for the user.

As a result of the fact that the power supply wires according to the invention lie on the largest circumference of the lamp base, it can be clamped against the lamp neck by means of a single ring with an unbroken circular inner circumference. This ring itself can again be used as a stop when inserting a lamp into the holder. The placement of the power supply means on a larger cross-section than the control surfaces not only has the advantage that the search for the correct insertion position in the holder is made easier, but also that when the lamp is pressed into the holder, a first contact between the lamp and the holder is provided by of the current transmission means.

Thereby, these organs are cleaned at the same time. The shape of the guide rafts can be extremely simple, flattened or completely flat guide surfaces have proven to be excellently suitable.

The flash lamps generally have a transparent varnish on the outside of the bulb - a layer that serves to hold the bulb pieces together in the event of an unwanted crushing of the lamp when it is lit. It is common to only apply this transparent lacquer layer when the lamp is completely finished and thus the lamp base is attached to the bulb. In the case of the lamp according to the invention, as the lamp base is missing, a different order of the work steps can be used. Before the fusion of the dwarf plinth, the lacquer layer can be applied, which is preferably done as the first work step. The actinic burning material is then introduced into the flask provided with a lacquer layer and the stand is suspended in the flask and the ring of insulating material pushed onto the flask neck. The small discharge tube on the neck of the flask is then melted again. Due to this processing, the varnish on the flask and in the immediate vicinity of the re-melting point becomes sticky to a certain extent so that it acquires adhesive properties. As a result, the ring of insulating material is automatically glued to the flask neck, and at the same time you get an excellent attachment for the power supply lines to the flask neck.

With the help of the figures, the invention will be explained in more detail. Fig. 1 and 2 show on an enlarged scale two side views of the lamp according to the invention. These. side views are mutually rotated at an angle of 90°. Fig. 3 shows an elevation of the lamp according to the invention. Fig. 4 also shows on an enlarged scale an elevation of the lamp holder seen from the lamp insertion side. Fig. 5 is a schematic sketch of the lamp and of the lamp holder in a position where the lamp can be inserted by axial displacement in the lamp holder. Fig. 6 shows a schematic section through a reflector with a fixed lamp holder and with a lamp ejection device.

The lamp in fig. 1, 2 and 3 have a flask 1 in which are two incandescent lamps 2 which are supported by a dwarf base. This dwarf base consists of the pole wires 3 and 4 and the bead 5. Furthermore, the flask 1 comprises the actinic burning material 6 which can not only have the wire form shown, but can also have the form of strips or foils. On the flask neck 7, in the fusion plane A—A, a small discharge pipe is placed, of which the drawing only shows the fused end 8.

In the manufacture of such a lamp, a certain amount of actinic burning material 6 is introduced into the flask 1, before the discharge pipe and the dwarf stand are placed. The dwarf base is then suspended above the supply edge in the flask in such a way that the bent pole wires 9 and 10 with its curvatures lies on the border A—A. The ring 11 is then pushed onto the flask neck 7. The ring consists of insulating material, e.g. of corrugated cardboard. Before the actinic material is brought in, the outside of the flask 1 is also coated with a transparent lacquer layer. When all these precautions have been taken, the discharge tube 8 is brought into the fusion plane A—A and fused. The flask is now pumped out and then oxygen is introduced into the flask. The discharge tube is then fused and the lamp is ready for use. When heating the flask 1 by melting the discharge tube 8 in the melting plane A—A, the transparent varnish layer becomes sticky to a certain extent. During the subsequent cooling of the flask, the varnish layer becomes harder and thereby serves as an adhesive for the ring 11 on the flask. As can be seen in particular from fig. 3, the diameter d of the inner circumference 12 of the ring 11 is dimensioned so that the ring 11 tightly encloses the part of the flask neck 7 which has the largest dimension (e). Consequently, the bent ends 9 and 10 of the pole wires are pressed firmly against the outside of the flask neck by means of the ring.

As seen in particular in fig. 3, the circumference of the flask neck 7 has a shape deviating from the circular shape. The circumference is composed of the flat parts B—C and D—E which lie opposite each other, and the intermediate slightly curved parts C—D and E—B. On the parts C—D and E—B are the bent ends 9 and 10 of the pole wires 3 and 4. The distance between the surfaces B—C and D—E is denoted by f. The distance between the curved surfaces C—D and E—B corresponds to approximately the diameter e of the circumference of the ring 11. This shape of the flask neck serves to automatically bring the lamp, when it is inserted into the lamp holder 13, into the correct position in relation to the slightly curved elastic plate-shaped contacts 14 and 15. The holder cover 16 made of metal comprises a body 17 of insulating material which has such a hollow that in it there is not only room for the contacts 14 and 15 but also a room 18 into which the flask neck 7 can go. Hereby, the electrical, springy contacts 14 and 15 come into contact with the bent ends of the power supply wires 9 and 10 and the flat boundaries B—C and D—E are adapted to the surfaces F—G and H—J in the hollow 18. In the embodiment shown, it is therefore only possible to have two positions for the lamp neck 7 in the lamp holder 13, offset by 180° from each other. The elastic contacts 14 and 15 further ensure that the lamp is held in the holder 13 in such a way that under normal conditions it is fixed in it and with a single pulling movement can be removed from the holder. In addition, the elastic design of the contacts 14 and 15 has the advantage that when the lamp is introduced onto the lamp contacts, i.e. onto the wire ends 9 and 10 resting on the flask neck 7, they exert a scraping effect so that any dirt, oxide layers and the like become removed.

This is evident from the schematic sketch in fig. 5, the flat parts of the flask neck of which the upper part is denoted by 19 in fig. 5, interacts with the flat parts 20 and 21 in the insertion opening for the lamp holder 13. Below that, the bent current supply wire ends 9 and 10 automatically come into contact with the elastic holding contacts 14 and 15. This can be seen in particular from fig. 5 that the cardboard ring 11 also serves to determine the distance over which the flask neck 7 can be moved in the holder 13. In addition, in this embodiment, the outer diameter g of the ring 11 (see fig. 3) is chosen in accordance with the outer diameter h (see fig. 4) of the metal button 16 for the lamp holder 13.

At the one in fig. 4 and 5, the lamp holder 13 is provided with fastening pins 22 and 23. As this lamp holder is designed so that one holder contact 14 is in electrically conductive connection with the sheath 16, and the other holder contact 15 is connected to the bottom contact 24 which is electrically isolated from the sheath 16 by an insulating body 25, the holder 13 can be placed in a bayonet socket which is common for lightning lamps.

At the one in fig. 6 shown embodiment of the lamp holder, the holder is firmly connected to a reflector 31. This reflector 31 has a recess 32 near its tip. At this point, a rear-extending sleeve 33 is attached to the reflector. This sleeve 33, which by means of an insulating body not shown carries the holder contacts 34 and 35 and is further provided with guide surfaces that correspond to the guide floats 20 and 21 in fig. 5, therefore serves as a lamp holder. In this embodiment, the holder contacts 34 and 35 are connected to a power source (not shown) via a switch (not shown) by means of the electrical wires 36 and 37 shown in dashed lines. Around the bushing 33 is also attached a ring 38 consisting of plate material which, over the shoulder 39, carries the bearing sleeve 40. In this bearing sleeve 40, a pin 41 is placed which can be displaced in the longitudinal direction. This pin 41 carries on its right end a wider part 42 serving as an ejector and on the left end a push button 43. Furthermore, the lamp holder 33 is provided on the back with an opening 47 such that the ejector 42 can slide through this opening . The reflector 31 also has a handle 48 on the back.

If this reflector is held firmly, e.g. with the right hand in the handle 48 and if the ejector 42 is in the position shown, then a flash light lamp 49 can be inserted through the opening 32 in the holder 33 on the one in fig. 5 shown way. Below, the ring 50 of insulating material placed on the lamp holder again limits the distance over which the lamp holder 51 can be inserted into the holder 33. If the lamp has been lit, it can be removed by pressing the thumb of the right hand against the push button 43, as part 42 comes in contact with the tip 44 of the fused discharge tube 45 and upon further movement of this button, the lamp is pushed out of the holder. When a new lamp is inserted, press the lamp push-button again in the position shown.

Claims (2)

1. Lightning lamp, where the parts of the power supply wires located outside the lamp body are clamped against the lamp base by means of a flat ring of insulating material, the lamp base being flattened on two opposite sides which are approximately 90° turned in relation to the output part the seat locations for the power supply wires, characterized in that the ring has an unbroken circular inner circumference which is adapted to the widest part of the lamp base cross-section. 2. Flash light lamp according to claim 1, characterized in that the ring is attached to the flask by means of a transparent varnish layer which at least covers the bulb part of the lamp on the outside.