US2007920A - Short wave length electric lamp - Google Patents

Short wave length electric lamp Download PDF

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US2007920A
US2007920A US579587A US57958731A US2007920A US 2007920 A US2007920 A US 2007920A US 579587 A US579587 A US 579587A US 57958731 A US57958731 A US 57958731A US 2007920 A US2007920 A US 2007920A
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elements
sealed
press
filament
wave length
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Chester H Braselton
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SIRIAN LAMP Co
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SIRIAN LAMP CO
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J61/00Gas-discharge or vapour-discharge lamps
    • H01J61/70Lamps with low-pressure unconstricted discharge having a cold pressure < 400 Torr

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  • a claimt.z (ci. 17e-1)- 'I'his invention relates to short or low wave length electric lamps such as those producing ultra-violet rays or other low wave length radiationsfor application to actino-therapy and photo-- ⁇ chemistry.
  • Another object of the invention is to provide a low wave length light which arises froma uni-- formly distributed discharge of high intensity and steadiness comparable to a filament.
  • Fig. 1 isa front elevational view of an electric lamp made in accordance with the invention
  • Figs. 2, 3, and 4 are fragmentary longitudinal sectional views of several forms of electron emitting elements which may be used with the device;
  • Fig., 5 is a fragmentary elevational view of the lamp of Fig. l and illustrating an alternative step in the manufacture thereof;
  • Fig. 6 is a sectional elevation of another embodiment of the invention.
  • FIGS. 'I and 8 are fragmentary sectional views of other modifications of the invention.
  • Figs. 9 and 10 are perspective views showing modified forms of element structures
  • Fig. 11 is a perspective view of another embodiment cf the invention.
  • l Fig. 12 is a perspective View of an element construction showing one manner of mounting a ⁇ plurality of elements. ⁇ Y
  • tron emitting material which, when energized in the presence of an ionizable gas at a certain suitable pressure, forms an ionic discharge along the filament which surrounds the filament like a halo.
  • the effect is somewhat dependent on the resistance and length of the wire, the voltage used across the terminals, and the kind of gas used and the pressure thereof.
  • the lamp of the present invention operates on the same principle but makes use of a specific form of ionizable gas to give a definite result.
  • the envelope -III is preferably made of quartz or other material which will not absorb low wave length radiation to any extent and which may be made tubular being integral with the presses II and I2 in a manner well known in the art.
  • a short support rod I3 may be sealed in the press II and in like manner a sec# ond short support rod I 4 may be sealed in the press I2.
  • An electron emitting element I5 may have connected to its ends support rods I3 and I4.
  • a pair of leading-in wires I6 and Il may. be ⁇ connected respectively to the support rods I3 and I4 as indicated in the drawings.
  • Fig. 2 I have shown an enlarged sectional View of a portion of the element I5.
  • This element comprises a coil I8 of refractory resistance Wire such as tungsten, molybdenum, nichrome a manner well known in the art and having the .and tantalum wound in a concentrated form in outer surface of the coil coated with electron j emitting material I9.
  • This electron emitting material may be any ofthe well known materials such as the oxides of the alkaline earth metal group and may preferably be a mixture of calcium and barium oxides, the calcium oxide having the property of selective radiation and therefore increasing the amount of light produced by the y lamp.
  • the element I5 may be made as indicated in Fig. 3 where a coil 24 of wire is shown with electron emitting material 25 coated upon each individual turn of the coil so that there is la space between adjacent turns while another may be used, the essential feature being that at least portions of the filament are in 'contact with the electron emitting materia-l and there is a potential drop from end to end thereof. Also, if desired, the electron emitting material may be coated on electrodes inserted in the ends of the coil and between which the discharge takes place.
  • I may prefer to provide additional terminals at each end of the element as the coil
  • the diameter of this wire should be sufiicient to carry the additional current but it should not be large enough to cool down the ends of the filament. It may or may not be coated with electron emitting material, as desired.
  • the envelope may be filled with an inert gas, preferably one producing, when ionized,- radiation near the violet end of the spectrum such as argon with some helium and some neon if, desired and a metal vapor such as mercury vapor which produces the ultra-violet radiation.
  • an inert gas preferably one producing, when ionized,- radiation near the violet end of the spectrum
  • argon with some helium and some neon if, desired
  • a metal vapor such as mercury vapor which produces the ultra-violet radiation.
  • Other metal vapors such as caesium and calcium may be found desirable in small quantities to increase the conductivity of the gas.
  • the element as shown may be mounted between the presses and the presses sealed or fused tothe envelope in a manner well known in the art.
  • the bulb may then be connected by means of a tube 20 to a vacuum pump and an oven placed over it and while the gases and vapors are being withdrawn" reached the filament current may be increased and the temperature of the lament raised slowly to about 800 C. to drive out the binder used for the electron emitting oxide.
  • the oven may be raised and the current through the element increased to raise the temperature to about 1200 C. or less for a moment, the pump being connected all this time to maintain a high vacuum.
  • the pump and the current may then be shut off and about 1/2 mm.
  • an inert gas such as neon may then be admitted intoI the bulb and the filament current turned on again to activate the electron emitting coating. Spots of localized discharge having a reddish color will then appear and spread until a diused discharge substantially fills the bulb which generally takes less than ten minutes to insure complete activation. At this period the activating current should not be too high so as to prevent burning out the filament or volatilizing the oxide on the surface thereof. When a discharge from all parts of the filament is apparent the activation is complete and the lamp may be again evacuated until no positive ionization occurs. At this point 5 mm. of helium gas and also 10 mm. of neon may be added to increase the conductivity and to cause the discharge to occur in all directions.
  • an inert gas such as neon
  • argon gas may be added until all ionic discharge stops except an intense one surrounding the filament and in the same direction as the filament. This discharge will vary with the light intensity as governed by the temperature of the emitting oxide. About 100 mm. of argon have been found to be sumcient to confine the ionic discharges along the length of the filament. The bulb may then besealed oiI.
  • the mercury or other metals for producing the .metal vapor may be introduced into the bulb by means of a small container 23 attached to one of the support rods by means of a wire 23a'and having a pin hole therein.
  • 'Ihis container may be lled with a compound of the metal used, as caesium or mercuric chloride and magnesium which when heated liberates caesium or mercury which condenses on the inner sides of the bulb.
  • mercury it will form a drop as 22, Fig. 1 and it is important to heat ⁇ this mercury sufficiently to vaporizeit in order to properly operate the lamp.
  • the helium gas which is a good conductor of heat when added to a pressure of 5 mm. is suicient to quickly vaporize y the mercury when the filament is energized.
  • the mercury may, if desired, be placed in the extending downwardly from the side of the tubulation tube 20 and'having a protuberance or 4bulb 20h at the lower end thereof in which the mercury 20c may be placed.
  • the tube 20a is long enough so that the bulb 20h is not heated when the oven is placed over the main bulb I0. Then when the bulb is ready vto be sealed off the mercury may be heated and the vaporv driven up ⁇ into the bulb ill'i through the tubulation' tube and then the latter closed off in the usual manner, or the tubulation tube may be closed off below the tube 20a and the mercury poured into the bulb I by invertilng it, after which the tube 20a may be closed oi in the usual manner.
  • Fig. 6 a modified form of the invention is shown.
  • the envelope 28 of glass or other material, transparent to the rays to be produced by the lamp is provided with a single press 29 formed integral therewith in the usual manner and the electron emitting element 30 is supported at its lower end upon a support rod 3
  • 'I'he element may be provided with the small coils
  • a pair of leadingin wires 33 and 34 may be connected respectively to the support rods 3
  • the electron emitting element 30 may be any of theelements already described and the envelope may be filled with gases or vapors as described in connection with the previous figure. Inasmuch as the metal vapors tend to condense on the walls of the bulb and other parts, the tubular construction of Fig. 1 may be preferred as in the construction of Fig.
  • Fig. 7 a modied form of the invention is shown wherein two electron emitting elements 36 and 31 are mounted at their lower ends respectively upon two support rods 36 and 39 which are sealed in the press 4G.
  • the upper ends of the elements 36 and 31 may be connected to a cross member l which may in turn be welded to a central support t2 which extends downwardly l and may also be sealed in the press 40.
  • Leadingin wires t3 and 44 may be connected respectively to the support rods 36 and 39 to make the necessary connections outside of the device.
  • the additional coil l5a carrying the excess current when the element is energized are shown at each end of each of the elements 36 and 31.
  • a metal filament has less resistance when cold there may be a tendency to produce a surge of current in the circuit when the device is initially connected to a source of energy and in order to prevent this I may desire to place a resistor having a negative temperature coefficient of resistance in series with the element or elements which will then provide a high resistance when the device is cold and as the resistance of the element increases due to the increase in temperature the resistance of the resistor will decrease.
  • Y In Fig. 8 such a construction is shown wherein the electron emitting element d5 is mounted at its lower end upon a support rod d6 which is sealed in the press 61 while its upper end is connected' to a cross member 49 mounted upon a central support 69 which may also be sealed in the press 41.
  • a rod or lament 59 of carbon may have its upper end attached to the other end of the cross member 48 and its lower end connected to a support rod 5l which may be sealed in the press 41, suitable means such as the tabs 52 being provided at each end of the carbon filament 5l! making the connections to the support rods.
  • Leading-in wires 53 and 54 may be connected respectively to support rods 66 and 5l and when connected in a circuit and a current initially turned on the carbon filament 56 has a high enough resistance to prevent a surge through the element 45 and as the element 45 and the carbon filament 50 heat up the resistance of the first increases while the resistance of the second decreases thereby permitting a gradual increase of current without the tendency to surge.
  • This insulation material may be any insulation material having a high insulation factor and being capable of adhering to the metal rods and of being degasified, such as a mixture of flnely divided aluminum oxide and a small quantity of aluminum chloride dissolved in water to make a paste.
  • insulating the parts might be used such as surrounding the support rods with tubes of glass, quartz, isolantite, lavite, and the like, which may be fused to the press to make a gas tight connection.
  • a construction is shown in which a pair of spaced apart electron emitting elements 56 and 51 are supported in substantially parallel relation in the envelope 58.
  • One end of the element 56 is mounted upon a support rod 59 which extends downwardly and is sealed in the press 6
  • the opposite end of the element 56 is mounted upon a support rod 62 which extends downwardly and is sealed in the press 60 and the corresponding end of the element 51 is mounted upon a support rod 63 which is also sealed in the press 60.
  • the additional coil l5a may also be used at the ends of the element as indicated and as already described in connection with the other iigures.
  • the leading-in wires'Gd and 65 may be connected respectively to support rods 59 and 63 and a short connector 66 may be connected between the rods 6I and62.
  • a short connector 66 may be connected between the rods 6I and62.
  • Fig. 9 While these elements in Fig. 9 are shown connected in series the same eiect may be obtained by connecting the elements in parallel as indicated in Fig. 10. Here the parts are just the 'same as shown in Fig. 9 with the exception of the leading-in Wires.
  • Leading-in Wires 61 and 68 connected respectively to the support rods 59 and 63 and corresponding to the leading-'in wires 64 and 65 of Fig. 9 may be connected together to one side of the circuit while two more leading-in wires 69 and 10 may be connected respectively to the support rods 6I and 62 and may also be connected together and to the other side of the circuit. This will place the two elements 56 and 51 in parallel with the current owing in opposite directions through the elements and thus they are given a uniform potential drop between the elements throughout the length thereof.y
  • and 12 may be mounted upon two support rods 15 and 16 respectively -by means of bands 11 and 18.
  • the support rods 15 and 16 may be sealed'in the press 19.
  • Each of the cathodes is provided with a heater element which extends through the center thereof and is insulated therel from.
  • is provided with a heater element while the cathode 12 is provided with a heater element 8
  • the lower ends of the heating elements are mounted respectively upon rods 84 and 85 which may also be sealed in the press 19.
  • Leading-in wires 86 and 81 may be connected respectively to thesupport rods 94 and 85 and complete the energizing circuit for the heater element.
  • leading-in wires 88 and 89 connected respectively to the support rods 15 and 16 for the cathodes, may be connected respectively to the leading-in wires 86 and 81 causing the cathodes to be connected to the high potential sides of the circuit;
  • Fig. 12 In which a plurality ofshort elements
  • 06 may be formed integral with a press
  • 0 may be bent in the form of a V with its vertex sealed in the glass disc
  • 2 may have its vertex sealed in the disc
  • 5 may be sealed in the disc
  • a pair of V-shaped support rods I4 and I5 may be sealed in the lower disc
  • the voltage drop across each element will be eighteen or nineteen volts.
  • any of the constructions shown may be combinedwith any of the others as for instance the fuse and carbon lament ballast may be used with the constructions shown in Figs. 9, 10, 11, and 12 as well as Figs. 1 to 6 inclusivev and the insulating materials may be applied to the support rods of any of the gures as described in connection with Fig. 7.
  • While certain specic pressures have been rethe pressure may be varied depending on the desired size of the discharge. A lower pressure tends to permit the discharge to extend further away from the filament and a higher pressure tends to confine it closer to the lament. -l It is preferred however that the gases used be chemically pure or at least do not have an excess of one per cent of impurities. 4
  • An electric lamp for producing short low wave length radiation comprising an envelope, a
  • An electric lamp for producing low wave length radiation comprising an envelope, and electron emitting element having an electron emissivity not less than that of calcium oxide within said envelope, an ionizable gas containing mercury vapor surrounding said element, and a carbon resistor in series with said element and having a negative temperature coecient of resistance, said element constituting the sole source of the radiation.
  • An electric lamp for producing low Wave length radiation comprising an envelope, an electron emitting element having an electron emissivity not less than that of calcium oxide within said envelope, means to support said element, an ionizable gas containing mercury vapor surrounding said element, means to insulate said supporting means from said gas, and a carbon resistor having a negative .temperature coeilicient of resistance in series with said element, said element constituting the sole source of the radiation.

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  • Discharge Lamp (AREA)

Description

July 9, 1935 c'. H. BRAsx-:LTON 2,007,920
SHORT WAVE LENGTH ELECTRIC LAMP Filed Deo. '7, 1931 s Sheets-sheet 1 July 9, 1935 c. H. BRAsELToN SHORT WAVE LENGTH ELECTRICLAMP Filed Deo. 7, 1931 -5 shets-Sheet 2 July 9, 1935. c. H. BRAsELToN SHORT WAVE LENGTH ELECTRIC LAMP Filed Dec. 7, 1931 5 Sheets-Sheet 3 Patented July 9, 1935 y PATENT orFic 2,007,920 v sHoR'r wAvELENG'rH ELECTRIC LAMP Chester l-l. Braselton, New York, N. Y.,`assignor to Sirian Lamp Company,.Newark, N. J., a corporation ot' Delaware Application December 7,
a claimt.z (ci. 17e-1)- 'I'his invention relates to short or low wave length electric lamps such as those producing ultra-violet rays or other low wave length radiationsfor application to actino-therapy and photo--` chemistry.
Heretofore the practical source of actinic radia- -tions which have been available are sunlight,
the arc light, and the mercury vapor lamp. The sunlight is too variable to be considered industrially. Arc lights are also variable in operation and are costly to operate due to the continuous consumption of the electrode material. Mercury vapor lamps besidesvhaving a high initial cost require direct current for operation and have a short life due to change of quartz surface. They also require auxiliary equipment.
It is one of the objects of the present invention to provide a low wave length electric light which maybe operated on commercial circuits without any auxiliary equipment and with low power consumption and long life.
Another object of the invention is to provide a low wave length light which arises froma uni-- formly distributed discharge of high intensity and steadiness comparable to a filament.
Other objects of the invention and objects relating tothe construction and assembly'of the various parts will be apparent as 'the description of the invention proceeds.
One embodiment of the invention has been illustrated in the accompanying drawings in whichz.
Fig. 1 isa front elevational view of an electric lamp made in accordance with the invention;
` Figs. 2, 3, and 4 are fragmentary longitudinal sectional views of several forms of electron emitting elements which may be used with the device;
Fig., 5 is a fragmentary elevational view of the lamp of Fig. l and illustrating an alternative step in the manufacture thereof; v
Fig. 6 is a sectional elevation of another embodiment of the invention;
Figs. 'I and 8 are fragmentary sectional views of other modifications of the invention;
Figs. 9 and 10 are perspective views showing modified forms of element structures;
Fig. 11 is a perspective view of another embodiment cf the invention; and l Fig. 12 is a perspective View of an element construction showing one manner of mounting a` plurality of elements.` Y
In my application Serial No. 459,048, filed June 3, 1930, entitled Electrical discharge device, I have shown and described an electric lamp in which a lamentary wire is coated with an elec- 1931, Serial No. 579,587
tron emitting material which, when energized in the presence of an ionizable gas at a certain suitable pressure, forms an ionic discharge along the filament which surrounds the filament like a halo. The effect is somewhat dependent on the resistance and length of the wire, the voltage used across the terminals, and the kind of gas used and the pressure thereof. The lamp of the present invention operates on the same principle but makes use of a specific form of ionizable gas to give a definite result.
"I'hus in Fig. l the envelope -III is preferably made of quartz or other material which will not absorb low wave length radiation to any extent and which may be made tubular being integral with the presses II and I2 in a manner well known in the art. A short support rod I3 may be sealed in the press II and in like manner a sec# ond short support rod I 4 may be sealed in the press I2. An electron emitting element I5 may have connected to its ends support rods I3 and I4. A pair of leading-in wires I6 and Il may. be `connected respectively to the support rods I3 and I4 as indicated in the drawings.
In Fig. 2 I have shown an enlarged sectional View of a portion of the element I5. This element comprises a coil I8 of refractory resistance Wire such as tungsten, molybdenum, nichrome a manner well known in the art and having the .and tantalum wound in a concentrated form in outer surface of the coil coated with electron j emitting material I9. `This electron emitting material may be any ofthe well known materials such as the oxides of the alkaline earth metal group and may preferably be a mixture of calcium and barium oxides, the calcium oxide having the property of selective radiation and therefore increasing the amount of light produced by the y lamp.
If -desired the element I5 may be made as indicated in Fig. 3 where a coil 24 of wire is shown with electron emitting material 25 coated upon each individual turn of the coil so that there is la space between adjacent turns while another may be used, the essential feature being that at least portions of the filament are in 'contact with the electron emitting materia-l and there is a potential drop from end to end thereof. Also, if desired, the electron emitting material may be coated on electrodes inserted in the ends of the coil and between which the discharge takes place.
In order to take care of the additional current flowing when the element is energized I may prefer to provide additional terminals at each end of the element as the coil |5a whichA may consist of a few turns of tungsten or other wire capable of standing a high temperature positioned at each end of the element and welded to the support rods as shown in Figs. 1 and 2. The diameter of this wire should be sufiicient to carry the additional current but it should not be large enough to cool down the ends of the filament. It may or may not be coated with electron emitting material, as desired. I
The envelope may be filled with an inert gas, preferably one producing, when ionized,- radiation near the violet end of the spectrum such as argon with some helium and some neon if, desired and a metal vapor such as mercury vapor which produces the ultra-violet radiation. Other metal vapors such as caesium and calcium may be found desirable in small quantities to increase the conductivity of the gas.
In constructing such a device the element as shown may be mounted between the presses and the presses sealed or fused tothe envelope in a manner well known in the art. The bulb may then be connected by means of a tube 20 to a vacuum pump and an oven placed over it and while the gases and vapors are being withdrawn" reached the filament current may be increased and the temperature of the lament raised slowly to about 800 C. to drive out the binder used for the electron emitting oxide. When no more gas is found in the bulb the oven may be raised and the current through the element increased to raise the temperature to about 1200 C. or less for a moment, the pump being connected all this time to maintain a high vacuum. The pump and the current may then be shut off and about 1/2 mm. of an inert gas such as neon may then be admitted intoI the bulb and the filament current turned on again to activate the electron emitting coating. Spots of localized discharge having a reddish color will then appear and spread until a diused discharge substantially fills the bulb which generally takes less than ten minutes to insure complete activation. At this period the activating current should not be too high so as to prevent burning out the filament or volatilizing the oxide on the surface thereof. When a discharge from all parts of the filament is apparent the activation is complete and the lamp may be again evacuated until no positive ionization occurs. At this point 5 mm. of helium gas and also 10 mm. of neon may be added to increase the conductivity and to cause the discharge to occur in all directions. Then' enough argon gas may be added until all ionic discharge stops except an intense one surrounding the filament and in the same direction as the filament. This discharge will vary with the light intensity as governed by the temperature of the emitting oxide. About 100 mm. of argon have been found to be sumcient to confine the ionic discharges along the length of the filament. The bulb may then besealed oiI.
The mercury or other metals for producing the .metal vapor may be introduced into the bulb by means of a small container 23 attached to one of the support rods by means of a wire 23a'and having a pin hole therein. 'Ihis container may be lled with a compound of the metal used, as caesium or mercuric chloride and magnesium which when heated liberates caesium or mercury which condenses on the inner sides of the bulb. Where mercury is used it will form a drop as 22, Fig. 1 and it is important to heat `this mercury sufficiently to vaporizeit in order to properly operate the lamp. I have found that the helium gas which is a good conductor of heat when added to a pressure of 5 mm. is suicient to quickly vaporize y the mercury when the filament is energized.
The mercury may, if desired, be placed in the extending downwardly from the side of the tubulation tube 20 and'having a protuberance or 4bulb 20h at the lower end thereof in which the mercury 20c may be placed. The tube 20a is long enough so that the bulb 20h is not heated when the oven is placed over the main bulb I0. Then when the bulb is ready vto be sealed off the mercury may be heated and the vaporv driven up `into the bulb ill'i through the tubulation' tube and then the latter closed off in the usual manner, or the tubulation tube may be closed off below the tube 20a and the mercury poured into the bulb I by invertilng it, after which the tube 20a may be closed oi in the usual manner.
When a lamp such as described above has been intense light will be produced by the ionic discharge along the filament which will be colored in accordance with the gases used. Thus the mercury vapor with the argon will produce an' tically uniform without any deterioration of the filament or coating and the temperature of the filament is notr excessive so that the light of the lamp is greatly increased over anything heretofore known or used.
In Fig. 6 a modified form of the invention is shown. In this case the envelope 28 of glass or other material, transparent to the rays to be produced by the lamp is provided with a single press 29 formed integral therewith in the usual manner and the electron emitting element 30 is supported at its lower end upon a support rod 3| sealed in the press 29 and at its upper end upon a support rod 32 which extends horizontally toward the wall of the envelope and then downwardly where it may be sealed in the press 29.`
'I'he element may be provided with the small coils |a as already described in connection with the other figures. A pair of leadingin wires 33 and 34 may be connected respectively to the support rods 3| and 32 to form the means for connecting the device in an electrical circuit. The electron emitting element 30 may be any of theelements already described and the envelope may be filled with gases or vapors as described in connection with the previous figure. Inasmuch as the metal vapors tend to condense on the walls of the bulb and other parts, the tubular construction of Fig. 1 may be preferred as in the construction of Fig. 6 the path between the two support rods 3| and I sealed ofi and connected to an electric circuit an l 32 on the press 29 isso short that afllm of metal von the press may tend to short circuit the device. Due to the conductivity ofthe gas within the envelope there may be a tendency, in case the element burns out. to arc, which so lowers the resistance of the device as to endanger the fuses in the main circuit. I therefore may prefer to incorporate a fuse in the element circuit either within or outside of the envelope so that this fuse will burn out if an arc should start and protect the main fuses in the circuit. In Fig. 6 such a fuse 35 is shown connected as a part of the lead wire 33 at the bottom of the envelope within the stem'tube and just below the press 29. Thus positioned the fuse comeswithin the base of the lamp and is not noticeable.
In Fig. 7 a modied form of the invention is shown wherein two electron emitting elements 36 and 31 are mounted at their lower ends respectively upon two support rods 36 and 39 which are sealed in the press 4G. The upper ends of the elements 36 and 31 may be connected to a cross member l which may in turn be welded to a central support t2 which extends downwardly l and may also be sealed in the press 40. Leadingin wires t3 and 44 may be connected respectively to the support rods 36 and 39 to make the necessary connections outside of the device. The additional coil l5a carrying the excess current when the element is energized are shown at each end of each of the elements 36 and 31.
Due to the fact that a metal filament has less resistance when cold there may be a tendency to produce a surge of current in the circuit when the device is initially connected to a source of energy and in order to prevent this I may desire to place a resistor having a negative temperature coefficient of resistance in series with the element or elements which will then provide a high resistance when the device is cold and as the resistance of the element increases due to the increase in temperature the resistance of the resistor will decrease. Y In Fig. 8 such a construction is shown wherein the electron emitting element d5 is mounted at its lower end upon a support rod d6 which is sealed in the press 61 while its upper end is connected' to a cross member 49 mounted upon a central support 69 which may also be sealed in the press 41. A rod or lament 59 of carbon may have its upper end attached to the other end of the cross member 48 and its lower end connected to a support rod 5l which may be sealed in the press 41, suitable means such as the tabs 52 being provided at each end of the carbon filament 5l! making the connections to the support rods. Leading-in wires 53 and 54 may be connected respectively to support rods 66 and 5l and when connected in a circuit and a current initially turned on the carbon filament 56 has a high enough resistance to prevent a surge through the element 45 and as the element 45 and the carbon filament 50 heat up the resistance of the first increases while the resistance of the second decreases thereby permitting a gradual increase of current without the tendency to surge.
It may be desirable in view of the electrical conductivity of the gases used to insulate all of the exposed parts other than the electron emitting' element (or carbon lament of Fig. 8) from the gas. This may be done by coating the support rods with an insulating compound such as that described for coating heating filaments in my application entitled Mounting of elements in radiation devices, Serial No. 578,940, illed December 4, 1931. This insulation material may be any insulation material having a high insulation factor and being capable of adhering to the metal rods and of being degasified, such as a mixture of flnely divided aluminum oxide and a small quantity of aluminum chloride dissolved in water to make a paste. When this material is heated in an oxidizing atmosphere the aluminum chloride reacts with oxygen to form aluminum oxide liberating chlorine. The aluminum oxide thus chemically formed is so iinely divided as to form an intergrain cement between the particles of the main body of aluminum oxide thus forming when the reaction is completed an entire body of insulating material containing no inactive matter and which adheres very closely to a wire or other metal parts upon which the insulation material is applied. Such material is shown at 55 applied to the exposed parts of Fig. 7 and it is to be understood that these coated parts should be degasied previously to assemblying the device as it is diiiicult to raise the temperature thereof suciently to degasify them during the evacuation of the envelope.
Other means of insulating the parts might be used such as surrounding the support rods with tubes of glass, quartz, isolantite, lavite, and the like, which may be fused to the press to make a gas tight connection.
In Fig. 9 a construction is shown in which a pair of spaced apart electron emitting elements 56 and 51 are supported in substantially parallel relation in the envelope 58. One end of the element 56 is mounted upon a support rod 59 which extends downwardly and is sealed in the press 6|) while the corresponding end of the element 51 is mounted upon a support rod 6l also' sealed in the press 60. The opposite end of the element 56 is mounted upon a support rod 62 which extends downwardly and is sealed in the press 60 and the corresponding end of the element 51 is mounted upon a support rod 63 which is also sealed in the press 60. The additional coil l5a may also be used at the ends of the element as indicated and as already described in connection with the other iigures. The leading-in wires'Gd and 65 may be connected respectively to support rods 59 and 63 and a short connector 66 may be connected between the rods 6I and62. When the wires 64 and 65 are connected across a circuit current will ow through the elements 56 and 51 in the same direction although these elements are in series with each other and all points on the element 56 therefore will have the same potential difference from corresponding points on the element 51 and there will be a tendency for a discharge to appear between the two elements as well as the halo of discharge longitudinally of each element.
` While these elements in Fig. 9 are shown connected in series the same eiect may be obtained by connecting the elements in parallel as indicated in Fig. 10. Here the parts are just the 'same as shown in Fig. 9 with the exception of the leading-in Wires. Leading-in Wires 61 and 68 connected respectively to the support rods 59 and 63 and corresponding to the leading-'in wires 64 and 65 of Fig. 9 may be connected together to one side of the circuit while two more leading-in wires 69 and 10 may be connected respectively to the support rods 6I and 62 and may also be connected together and to the other side of the circuit. This will place the two elements 56 and 51 in parallel with the current owing in opposite directions through the elements and thus they are given a uniform potential drop between the elements throughout the length thereof.y
In Fig. 11 a still further modication ot the invention is shown in which a pair of unipotential cathodes 1| and 12, made of suitable sheet metal and coated with electron emitting material 13 and 14 respectively, may be mounted upon two support rods 15 and 16 respectively -by means of bands 11 and 18. The support rods 15 and 16 may be sealed'in the press 19. Each of the cathodes is provided with a heater element which extends through the center thereof and is insulated therel from. Thus the cathode 1| is provided with a heater element while the cathode 12 is provided with a heater element 8| these elements being connected at their upper ends to a cross Imember 82 supported upon an oiset central support member 83 which extends downwardly and is sealed in the press 19. The lower ends of the heating elements are mounted respectively upon rods 84 and 85 which may also be sealed in the press 19. Leading-in wires 86 and 81 may be connected respectively to thesupport rods 94 and 85 and complete the energizing circuit for the heater element. The
leading-in wires 88 and 89, connected respectively to the support rods 15 and 16 for the cathodes, may be connected respectively to the leading-in wires 86 and 81 causing the cathodes to be connected to the high potential sides of the circuit;
When the cathodes are raised to electron emitting temperature the discharge will take place between them and will be substantially uniform'due to the fact that the potential of each cathode is uniform throughout the -length thereof.
Instead of using one long electron emitting element or two elements in series as shown in the figures already described it may be desirable when the device is used on the ordinary lighting circuit of volts to split up the electron emitting elements into a number of separate units so as to reduce the voltage per unit to a value as low as between 10 and 40 volts. One way of doing this is illustrated in Fig. 12 in which a plurality ofshort elements |00, |0|, |02, |03, |04, and |05 are mounted in series, the elements being positioned as far apart from each other as possible so that the discharge along one unit cannot interfere with the discharge along any other.
To this end a glass rod |06 may be formed integral with a press |01 and may have an enlargement or disc |08 at its upper end and a disc |09 at its lower end adjacent the press |01. A support rod ||0 may be bent in the form of a V with its vertex sealed in the glass disc |08 and its free ends extending outwardly and being bent downwardly to support the upper ends of .the elements |00 and |0I. A second V-shaped support rod ||2 may have its vertex sealed in the disc |08 similarly to the rod I0 and may support at its Ifree ends the elements |02 and |03. Similarly a V-shaped support rod ||5 may be sealed in the disc |08 and may support the upper ends of the elements |04 and |05 in the manner shown. In like manner a pair of V-shaped support rods I4 and I5 may be sealed in the lower disc |09 so as to come respectively underneath points between aoomao the lead wires I|8 and |I8 are connected across the circuit the current will flow in through the A lead wire H8, through the support rod H6, up through the rstelement |00,through the support rod H0, down through the element |0|, through the support rod I4, up through the element |02,
through the support rod ||2, down through the element |03, vthrough the support rod IIS, up through the element |04, through the support rod H3, down through the element |05, and out through the support rod |1 and lead in wire ||9.
By using six elements as shown the voltage drop across each element will be eighteen or nineteen volts.
It is to be noted that any of the constructions shown may be combinedwith any of the others as for instance the fuse and carbon lament ballast may be used with the constructions shown in Figs. 9, 10, 11, and 12 as well as Figs. 1 to 6 inclusivev and the insulating materials may be applied to the support rods of any of the gures as described in connection with Fig. 7.
While certain specic pressures have been rethe pressure may be varied depending on the desired size of the discharge. A lower pressure tends to permit the discharge to extend further away from the filament and a higher pressure tends to confine it closer to the lament. -l It is preferred however that the gases used be chemically pure or at least do not have an excess of one per cent of impurities. 4
Many modifications of the invention may be resorted to 4Without departing from the spirit thereof, and I do not therefore desire to limit myself vto what has been shown and described in this application except as such limitations are included in the appended claims;
What I claim is:
l. An electric lamp for producing short low wave length radiation comprising an envelope, a
lamentary conductor within said envelope, a
coating of electron emitting material upon the surface o'f a portion of said conductor, and an ionizable gas surrounding said conductor and containing approximately 5 mm. of helium, 10 mm. of neon, 10'0 m'm. of argon, and a quantity of mercury vapor.
2. An electric lamp for producing low wave length radiation comprising an envelope, and electron emitting element having an electron emissivity not less than that of calcium oxide within said envelope, an ionizable gas containing mercury vapor surrounding said element, and a carbon resistor in series with said element and having a negative temperature coecient of resistance, said element constituting the sole source of the radiation.
3. An electric lamp for producing low Wave length radiation comprising an envelope, an electron emitting element having an electron emissivity not less than that of calcium oxide within said envelope, means to support said element, an ionizable gas containing mercury vapor surrounding said element, means to insulate said supporting means from said gas, and a carbon resistor having a negative .temperature coeilicient of resistance in series with said element, said element constituting the sole source of the radiation.
CHESTER H. BRASEL'ION.
US579587A 1931-12-07 1931-12-07 Short wave length electric lamp Expired - Lifetime US2007920A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2473900A (en) * 1942-01-15 1949-06-21 Gen Electric Electrode coating process
US3076050A (en) * 1959-05-20 1963-01-29 Strategic Material Corp Electrode structures and processes for utilizing the same
US4031399A (en) * 1975-02-24 1977-06-21 Beckman Instruments, Inc. Fluorometer

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2473900A (en) * 1942-01-15 1949-06-21 Gen Electric Electrode coating process
US3076050A (en) * 1959-05-20 1963-01-29 Strategic Material Corp Electrode structures and processes for utilizing the same
US4031399A (en) * 1975-02-24 1977-06-21 Beckman Instruments, Inc. Fluorometer

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