BE369011A - - Google Patents

Description

  

  Incandescent electric lamp "

  
It has already been proposed, to oppose the vaporization of illuminating bodies: metallic incandescent electric lamps, to put these incandescent bodies: in an atmosphere of inert gas and poor conductor. heat, and reduce losses through heat conduction and convection

  
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of a special conformation. of conductor obtained by winding, flattening or constricting in a small space.

  
For incandescent projection lamps or for those kinds of lamps the light of which radiates in a determined direction, flat illuminating bodies are employed, in a suitable known manner, and especially sheets of hardly fusible metal, since luminous bodies of this kind make it possible to obtain the greatest possible density of light.

  
It has now appeared that with these sheets used as flat surfaces in gas-filled lamps, by known means, an improvement in specific consumption is not achieved, as explained by <EMI ID = 2.1>

  
The means for reducing the losses by heat conduction and by convection, sufficiently to bring about an improvement in the specific consumption, would be, according to the known method, to increase the cross section :. A sheet of

  
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sheet, thicker, heat conduction and convection loss laws should be! proportionately smaller.

  
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radiation of: light remains constant for a constant temperature ;. 'But this means a more unfavorable specific consumption, since the decrease in parts by conduction. heat and convection, when using sections; transverse-augmented ;, occurs only when to, the increase in the cross-section, is connected a considerable increase; of the radiating surface, only when the gain of light is greater than the increase in losses by heat conduction and by convection.

  
Following this. invention, .an improvement of. specific consumption may be hearth. obtained for bodies; 'illuminants * made up; by a material laminated in the known manner, especially by sheets of hardly fusible metals and without a special conformation of the conductor, covering one side of the body; lighting from a screen placed at a small distance from this body, and not letting the current pass.

  
By this cover, a space is established separated from the rest of the gas filling of the lamp, space in which

  
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temperature of this quiet gas atmosphere is much higher than that of the gas which surrounds and moves on the

  
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essentially lower '. But. as the losses due to gas filling should be; reduced not only with regard to heat conduction, but also with regard to heat radiation, the side of the screen facing the illuminating body should be provided with a highly polished metal covering, by which the caloric energy: radiated was reflected.

  
The heat drop between the side of the sheet protected by the screen and the outer side of the screen is very great :, so that the heat loss is greatly reduced and that an improvement in consumption is obtained. specific

  
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The screen will be made of bad materials. heat conductive, and suitably porcelain, magnesia, and especially zirconium oxide. He will be able to

  
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metal and, on its outer side, in a material which is a poor conductor of heat. The metal screen can be

  
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returns heat to the illuminating body *

  
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according to the present invention, intended for a projection lamp

  
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may occur.

  
By a similar one. arrangement, voltage.

  
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continuation: the reduced length of the illuminating body, this. which requires admission from. relatively large current. This can be remedied by cutting the sheet in the known manner, as shown in Fig. 2. We use the slots in a fairly limited number

  
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highly polished and shiny, which reflects heat energy by reflection.

  
Instead of .sections, transverse of flat shape remaining equal: towards the current conductors, it is also possible to use illuminating bodies having transverse sections: decreasing towards these conductors; (for example, having the shape of a cap, a cone or also a disc), when, according to this:
invention, the cross-section is proportioned so that the temperature of the illuminating body is equal in. all places: between conductors:,.

  
The cross section decreasing towards the conductors

  
current presents: towards them an increasing resistance, that. one can proportion in such a way :, by means of

  
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electrical resistance is equal in all places between the conductors ;.

  
This process is sufficient in itself to equalize the temperature; when the illuminating body is brought to incandescence in the vida, which, practically, hardly happens. The illuminating body must be much more often put: in incandescence in an atmosphere of inert gas, and one must therefore take special account of: the influence of the gas filling on the incandescent illuminating body, otherwise the places, reinforced would be much more strongly heated than the <EMI ID = 18.1>

 

Claims (1)

is smaller than for other parts of the illuminating body. <EMI ID = 19.1> therefore carry out a temperature equalization so that this temperature, during the state of incandescence, is equal in all places between the conductors, of the <EMI ID = 20.1> the temperature must be determined empirically for each form of illuminating body. Sheet illuminators can be constructed. in a particularly simple and easy way by removing them from the surface of a cone or a cylinder. This avoids mechanical stress on the material, such as; than compression, extension, which makes it possible to use sheets <EMI ID = 21.1> The formation of a conical illuminating body is shown, <EMI ID = 22.1> in two halves. Fig. 4 shows a cut out part, not yet folded back, of a conical lighting body according to the present <EMI ID = 23.1> the additional parts serving &#65533; equalization of resistance- and temperature, which are prolonged- by the <EMI ID = 24.1> that they rest on the surface of the cone. The placement of this conical illuminating body in the lamp and near the screen is <EMI ID = 25.1> 1. - Electric incandescent lamp, - with illuminating body of flat shape made up of excavations; of metals hardly .fuses, mainly in wolfram sheets, and filled with inert gas and a poor conductor of heat, characterized in that the illuminating body is covered by a <EMI ID = 26.1> which screen does not pass the current and prevents the. gas flow from the edge of the sheet to the outside * <EMI ID = 27.1> cation 1, characterized in that the screen is made of a material which is a poor conductor of heat. <EMI ID = 28.1> dications 1 and 2, characterized in that the screen is made of metal on its side facing the illuminating body and in a <EMI ID = 29.1> cations'la 5, characterized in that the metal screen is highly polished and shiny on its inner surface. 5.- Electric incandescent lamp, having an illuminating body whose cross section decreases towards the conduc- <EMI ID = 30.1> Sée in that the cross section of the illuminating body is distributed in such a way, for example by means of reinforcement of the walls, by dimensions or by other means pursuing the Wan goal, that the temperature in all places of. body. lighting is as uniform as possible. <EMI ID = 31.1> <EMI ID = 32.1> built by extracting it from: the surface of a cone or a cylinder.