US2384007A - Electrode - Google Patents
Electrode Download PDFInfo
- Publication number
- US2384007A US2384007A US458273A US45827342A US2384007A US 2384007 A US2384007 A US 2384007A US 458273 A US458273 A US 458273A US 45827342 A US45827342 A US 45827342A US 2384007 A US2384007 A US 2384007A
- Authority
- US
- United States
- Prior art keywords
- filament
- electrode
- tube
- leads
- electrodes
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J61/00—Gas-discharge or vapour-discharge lamps
- H01J61/02—Details
- H01J61/04—Electrodes; Screens; Shields
- H01J61/06—Main electrodes
- H01J61/067—Main electrodes for low-pressure discharge lamps
- H01J61/0672—Main electrodes for low-pressure discharge lamps characterised by the construction of the electrode
Definitions
- My invention relates to space discharge tubes, and more particularly to filamentary electrodes for such tubes.
- An object of my invention is the. provision of electrodes suitable for use in space discharge tubes operating on cold-cathode, which electrodes are characterized by their resistance to detrimental effects of high peak voltages and currents, and which are simple, sturdy, reliable and efficient, of low over-all and minimum cost, and of long useful life.
- Another object of my invention is the provision of an electrode of the type described which is hereinafter in connection with the following description, taken in light of the accompanying drawing.
- a conventional filamentary electrode usually takes the form of a substantially U-shaped mem- Fostoria, Ohio, assignor Ltd., a corporation of her. shaped from small-diameter, oxide-coate wire spiraled into comparatively large loops. The end portions of the wire are connected as terminals to suitable current leads. A source of electrical energy connected across the leads, sends heating current through the filament and raises the same to a temperature at which copious quantities of electrons are emitted.
- bare filamentary electrodes when unprotected by any form of shielding are affected seriously and adversely under repeated bombardment of the arc, as when the lamp is turned on and of! frequently. It is found that ionic bombardment results in sputtering of the electrode material. When sputtering occurs not only is the active material removed from the electrode filaments so that its electron-emitting qualities are impaired, but as well, the filaments are physically weakened, thus diminishing appreciably the effective life thereof.
- the sputtered or volatized electrode material deposits as a condensate on the interior walls of the tube in which the electrodes are mounted, forming a semi-opaque coating and materially reducing the transmission of light through the tube walls. This gives rise to the phenomenon encountered in the tube art.of darkening of the tubes during use.
- a further object of my invention is to provide filamentary electrodes which are suitable for cold-cathode operation, the filamentary portions of which in large measure are protected from shock, sputtering, and attendant destruction, which electrodes ensure rapid and steady operation of an associated tube and are instrumental in achieving improved light emission, and which avoid in large' rjafeasure or minimize appreciably other ide' and disadvantages set forth in the foregoing.
- a tube electrode having a filament or central filamentary portion l3.
- the filament 3 is made, for example, of tungsten, molybdenum, or other suitable refractory metal or metal alloy wire of approximately No. 42 gauge.
- the wire as shown, is doubly coiled, first into small diameter spiral loops and then into spiral loops of larger diameter. By virtue of the double coiling a large area of filament is presented per unit of length.
- This filament I3 has its ends l4, l5. and mid-portion 35 joined respectively, as by welding, to leads l6, l1, and central support IS.
- the leads and central support extend upwardly from the filament 3 and preferably are normal to the filament and in the same plane therewith.
- the leads, as well as the central support are made of rather large diameter wire as compared to the filament, and serve to hold the filament in substantially straight position.
- I coat the filament as well as the anchor points withan oxide-coating of high electron-emitting properties.
- the purpose of the oxide coating (or other electron-emitting material) is, of course, to ensure that sufiicient electrons will be emitted to initiate and maintain a satisfactory tube-arc, without requiring the central portion 3 to be brought to full incandescence.
- My new electrode aside from including a filament disposed on a substantially straight axis between leads l6 and I1, is further protected from disintegration and from developing local regions of possible failure, by ensuring that all parts of the filament l3 are at substantially the I achieve this end by short-cir- 'cuiting the leads I6, I! and support I8- by any suitable short-circuting-bar or element
- 3, terminates, for example, in a conventional glass press 32 of glass tube 34, while the leads l6, l! are either carried through the press.
- this side-arm extends, for example, outwardly at 24 in the plane of lead l6 and filament 3 and normally to lead l6, then is bent into a portion 25 extending out of the plane of lead l6 and filament l3, then is bent into a portion 26 which extends substantially parallel with lead l6 and below the central portion I3 (in the direction of an opposed electrode, not shown) and finally is bent into portion 21 which extends in spaced, oifset and substantially parallel relation with central portion l3 so as to guard the same.
- extends, for example, outwardly at 28 in the plane of lead I! and filament l3 and normally to lead then is bent into a portion 29 which extends out of the plane of lead I? and filament
- accordingly, are disposed on opposite sides of filament l3 and are substarially parallel with each other.
- preferably reach individually along the entire lengthof filament I3, or are of such length as to overlap in reach along the length of the filament. 1
- the wire preferably is made of metal or metal alloy, such as iron or stainless steel, which with increase in temperature displays an increase in electrical resistance, or, in other words, which displays a high temperature coefficient of resistance.
- a fluorescent tube including two of my electrodes and otherwise constructed along conventional lines was tested on cold-cathode operation, using a 460 volt power unit.
- the tube was found to have a life approximating 3000 hours.
- a check test was run on a hot-cathode tube ofconventional design. This tube was short-circuited at its hot-cathode terminals. to adapt the same for icold-cath'ode operation.
- a power unit of the type )ust mentioned was employed under precisely the same energizing conditions as before. The tube thus operated displayed a life of approximately 2000 hours.
- the first of the lamps of conventional design placed across the condensive side of the second power unit needed replacement after about 12,834 cycles of operation.
- the second lamp connected across the inductive side, required replacement after 18,147 cycles of operation.
- My new lamp may be expected to display a practical life of 2800 hours, with at least 2500 hours minimum. My lamps can be produced without difficulty. and with the electrodes properly constructed. it is safe to predict that the minimum life of the commercial form of tubes employing my new filament may be raised to 3000 hours.
- Electrode comprising a filament made 02 doubly coiled small gauge, oxide-coated wire, leads extending from the ends of said filament, a guard comprising side-arms, of heavy gauge metal of high temperature coefiicient of resistance, extending outwardly and downwardly from said leads and under and along the length of said filament in spaced parallel relation thereto, and means short-circuiting said leads.
- An electrode for space discharge tubes comprising, a substantially linear filamentary portion; current leads extending from the ends of said filamentary portion; and a support wire extending from an intermediate point along said filamentary portion, said leads and said support wire being short-circuited.
- An electrode for space discharge tubes comprising, a filamentary, electron-emitting portion; leads extending upwardly from opposite ends of said filamentar portion; a support wire extending upwardly from said filamentary position intermediate the ends thereof, said leads and said support wire being short-circuited; and a guard comprising side-arms extending outwardly from said leads intermediate their lengths and downwardly to substantially parallel guarding position with respect to said filamentary portion.
- An electrode for space discharge tubes comprising, in combination, an oxide-coated fila ment. a guard having a side-arm of high temperature coefficient of electrical resistance positioned adjacent said filament and in electrical connection therewith, and means permanently short-circuiting said filament and said guard.
Description
p 4, 1945- c. P. B-OUCHER 2,384,007
ELECTRODE Filed Sept. 14, 1942 amen Ko a C/mmcs J? BOUCHER,
Patented Sept. 4, 1945 ELECTRODE Charles Philippe Boucher, to Boucher Inventions,
Delaware Application September 14, 1942, Serial No. 458,273
4 Claims.
My invention relates to space discharge tubes, and more particularly to filamentary electrodes for such tubes.
An object of my invention is the. provision of electrodes suitable for use in space discharge tubes operating on cold-cathode, which electrodes are characterized by their resistance to detrimental effects of high peak voltages and currents, and which are simple, sturdy, reliable and efficient, of low over-all and minimum cost, and of long useful life.
Another object of my invention is the provision of an electrode of the type described which is hereinafter in connection with the following description, taken in light of the accompanying drawing.
My invention, accordingly, resides in the several elements, features of construction and operational steps, and in the relation of each of the same to one or more of the others, all as described herein, the scope of the application of which is indicated in the appended claims.
In the single figure of the drawing, there is shown in perspective view a preferred embodiment of the filamentary electrode of my invention.
As conducive to a more thorough understanding of my invention, it may be noted at this point that the use of filamentary electrodes in space discharge tubes has long been customary practice. The electrodes give rise to very satisfactory results when operated either at sub-standard voltages or even at the rated potentials of ordinary 110 or 220 volt service mains. When the electrodes are provided with an electron-emitting coating as is customary practice at this t me, tube operation is reasonably insured almost regardless of the pressure conditions maintaining within the tube.
A conventional filamentary electrode usually takes the form of a substantially U-shaped mem- Fostoria, Ohio, assignor Ltd., a corporation of her. shaped from small-diameter, oxide-coate wire spiraled into comparatively large loops. The end portions of the wire are connected as terminals to suitable current leads. A source of electrical energy connected across the leads, sends heating current through the filament and raises the same to a temperature at which copious quantities of electrons are emitted.
Experience shows, however, that in many instances, an are between paired, spacedelectrodes tends to settle across points on the electrodes of lowest potential difference. This action, of course, exposes those points to excessive disintegration. Alternatively, in many instances, the arc settles on sharp, angular portions of the filaments, as at corners or bends. The are locally attacks the filaments at these points much more vigorously than it does the remainingportions, so that comparatively early failure may reasonably be anticipated. Such local failure is accelerated particularly in those cases where, in accordance with recent practice, the electrode terminals are shortcircuited for cold-cathode operation, and substantial potentials are impressed across the paired electrodes, such as 460 volts or more.
Similarly, bare filamentary electrodes when unprotected by any form of shielding are affected seriously and adversely under repeated bombardment of the arc, as when the lamp is turned on and of! frequently. It is found that ionic bombardment results in sputtering of the electrode material. When sputtering occurs not only is the active material removed from the electrode filaments so that its electron-emitting qualities are impaired, but as well, the filaments are physically weakened, thus diminishing appreciably the effective life thereof. The sputtered or volatized electrode material deposits as a condensate on the interior walls of the tube in which the electrodes are mounted, forming a semi-opaque coating and materially reducing the transmission of light through the tube walls. This gives rise to the phenomenon encountered in the tube art.of darkening of the tubes during use.
The use has been proposed of filament guards, but such guards as heretofore employed have not proven successful in hot-cathode tubes adapted for cold-cathode operation. The are has been found to strike rather indiscriminately on the guards or on the filament. The filament is subjected to shock, breakdown and failure at the corners, bends, or points or lowest voltage. In those instances where the arc does strike first on the guards. then the are often is found to move relatively slowly from the guards over to the etsob same potential.
1 preferably intermediate their lengths. manner it is ensured that voltage distribution filaments, so that an appreciable time interval .is interposed before the tube comes up to its rated light emission.
A further object of my invention, therefore, is to provide filamentary electrodes which are suitable for cold-cathode operation, the filamentary portions of which in large measure are protected from shock, sputtering, and attendant destruction, which electrodes ensure rapid and steady operation of an associated tube and are instrumental in achieving improved light emission, and which avoid in large' rjafeasure or minimize appreciably other ide' and disadvantages set forth in the foregoing.
Referring now more particularly to a preferred embodiment of my invention, attention is directed to the single figure of the drawing, wherein is shown a tube electrode having a filament or central filamentary portion l3. The filament 3 is made, for example, of tungsten, molybdenum, or other suitable refractory metal or metal alloy wire of approximately No. 42 gauge. The wire, as shown, is doubly coiled, first into small diameter spiral loops and then into spiral loops of larger diameter. By virtue of the double coiling a large area of filament is presented per unit of length. This filament I3 has its ends l4, l5. and mid-portion 35 joined respectively, as by welding, to leads l6, l1, and central support IS.
The leads and central support extend upwardly from the filament 3 and preferably are normal to the filament and in the same plane therewith. The leads, as well as the central support, are made of rather large diameter wire as compared to the filament, and serve to hold the filament in substantially straight position. Thus, the presence of angular bends is avoided in the active filament |3 of my new electrode construction and longer life of the filament, or electrode, as a whole, accordingly is achieved.
After the filament I3 is anchored to the leads and to support I8, I coat the filament as well as the anchor points withan oxide-coating of high electron-emitting properties. The purpose of the oxide coating (or other electron-emitting material) is, of course, to ensure that sufiicient electrons will be emitted to initiate and maintain a satisfactory tube-arc, without requiring the central portion 3 to be brought to full incandescence.
My new electrode, aside from including a filament disposed on a substantially straight axis between leads l6 and I1, is further protected from disintegration and from developing local regions of possible failure, by ensuring that all parts of the filament l3 are at substantially the I achieve this end by short-cir- 'cuiting the leads I6, I! and support I8- by any suitable short-circuting-bar or element |9, dis
posed either at free ends of these elements or In this throughout the electrode assembly is uniform. The end of support 8. opposite from the filament |3, terminates, for example, in a conventional glass press 32 of glass tube 34, while the leads l6, l! are either carried through the press.
or directly through the reentrant portion 33 of the tube.
Still further, protection is afforded the filament |3 by the provision of a guard in the form of side-arms indicated generally at 20, 2|, attached to and projecting respectively from leads [6, I1.
,While these side-arms 20, 2| could be attached at anchor points l4, l5, it is undesirable to have the arc, which strikes on the side-arms 20, 2|, transferred to the central portion l3 at these anchor points because of the possibility of local attack. Accordingly, I prefer to join the side-arms 20, 2| to leads I6, I! at points 22, 23 intermediate the lengths of the leads.
Referring first to side arm 20, this side-arm extends, for example, outwardly at 24 in the plane of lead l6 and filament 3 and normally to lead l6, then is bent into a portion 25 extending out of the plane of lead l6 and filament l3, then is bent into a portion 26 which extends substantially parallel with lead l6 and below the central portion I3 (in the direction of an opposed electrode, not shown) and finally is bent into portion 21 which extends in spaced, oifset and substantially parallel relation with central portion l3 so as to guard the same.
Similarly, side-arm 2| extends, for example, outwardly at 28 in the plane of lead I! and filament l3 and normally to lead then is bent into a portion 29 which extends out of the plane of lead I? and filament |3 in an opposite direction to portion 25 of guard 20. The guard then is bent into a. portion 30=which extends substantially parallel with lead I1 and below central portion l3 preferably to a point below side-arm portion 21 of side-arm 20, and finally is bent into portion 3| which .extends in spaced, substantially parallel relation with filament I3 and portion 21. Sfde-arm portions 21, 3|, accordingly, are disposed on opposite sides of filament l3 and are substarially parallel with each other. The portions 21, 3| preferably reach individually along the entire lengthof filament I3, or are of such length as to overlap in reach along the length of the filament. 1
While it is not essential that the side-arms 20, 2| be so constructed, I prefer to form them of strong heavy gauge wire, to provide a large area on which the effect of the tube are striking thereon may be distributed. The wire preferably is made of metal or metal alloy, such as iron or stainless steel, which with increase in temperature displays an increase in electrical resistance, or, in other words, which displays a high temperature coefficient of resistance.
When a sufficiently high potential is first established across a space discharge tube employing electrodes constructed in accordance with my invention, the gas filling of the tube becomes excited and an arc settles quickly on one or both of the prong portions 21, 3| of the corresponding overlapping side-arms. At all times, the filamentary central portion l3 will be effectively shielded and protected from initial shock attendant upon striking the arc. By forming the sidearms, 20, 2| of materialhaving high resistance characteristics, as aforesaid, the resistance of the side-arms increases appreciably with rise in the temperature thereof. The arc, accordingly, migrates rapidly up the side-arms to the corresponding lead 16 or J1, and thence down to the central portion l3, where it settles for steady operation. In this manner, it is ensured that the tube quickly approaches conditions of maximum luminosity, upon closure of the primary energizing circuit.
A fluorescent tube including two of my electrodes and otherwise constructed along conventional lines, Was tested on cold-cathode operation, using a 460 volt power unit. The tube was found to have a life approximating 3000 hours. In running life tests on my new tube unit, a check test was run on a hot-cathode tube ofconventional design. This tube was short-circuited at its hot-cathode terminals. to adapt the same for icold-cath'ode operation. A power unit of the type )ust mentioned was employed under precisely the same energizing conditions as before. The tube thus operated displayed a life of approximately 2000 hours.
In another series of tests, two high voltage power units each having a condensive side (supplying a leading current) and an inductive side (supplying a lagging current), were connected in parallel at their input sides and operated from the same switch, so that voltage and temperature conditions and irregularities of the primary circuit would be the same for both units. One of the power units was connected with two tubes employing my new electrode'construction. Two ordinary 40 watt tubes of standard design, now on the market and made by one of the larger manufacturers, but with their terminals shortcircuited, were placed across the other power unit. The current wa made and broken some 276 times per hour.
During the course of the test it was observed that my lamp energized across the condensive side of the corresponding power unit, failed after 29,256 cycles of on and ofi operation. My other lamp, energized on the inductive side of the power unit, still was in excellent condition. it being conservatively estimated that it could have withstood an additional 4000 to 5000 cycles of striking.
By contrast, the first of the lamps of conventional design placed across the condensive side of the second power unit needed replacement after about 12,834 cycles of operation. The second lamp, connected across the inductive side, required replacement after 18,147 cycles of operation. A third similar lamp, provided on the condensive side and replacing the first said lamp, was in turn worn out after 16.146 cycles of operation. It would appear that under comparable conditions of test my new lamp may be expected to display a. life of approximately double that of prior known lamps under similar operating conditions. My new lamp may be expected to display a practical life of 2800 hours, with at least 2500 hours minimum. My lamps can be produced without difficulty. and with the electrodes properly constructed. it is safe to predict that the minimum life of the commercial form of tubes employing my new filament may be raised to 3000 hours.
Thus it will be seen that there has been provided in this invention improved filamentary electrodes in which the various objects hereinbe fore noted, together with many thoroughly practical advantages, are successfully achieved. It will be seen further that the electrodes lend themselves to durable, efficient and economical use in gaseous discharge tubes operated on coldcathode. It will also be seen that the filaments of m electrodes individually are maintained at uniform potential throughout, are free of angular bends or projections, and are guarded effectively against sudden bombardment or shock, so as to avoid disintegration or sputtering either locally or generally.
As many possible embodiments may be made of my invention and as many changes may be made in the embodiment hereinbefore set forth. it is to be understood that all matter described herein is to be interpreted as illustrative and not in a limiting sense.
I claim:
1. .An electrode comprising a filament made 02 doubly coiled small gauge, oxide-coated wire, leads extending from the ends of said filament, a guard comprising side-arms, of heavy gauge metal of high temperature coefiicient of resistance, extending outwardly and downwardly from said leads and under and along the length of said filament in spaced parallel relation thereto, and means short-circuiting said leads.
2. An electrode for space discharge tubes, comprising, a substantially linear filamentary portion; current leads extending from the ends of said filamentary portion; and a support wire extending from an intermediate point along said filamentary portion, said leads and said support wire being short-circuited.
3. An electrode for space discharge tubes comprising, a filamentary, electron-emitting portion; leads extending upwardly from opposite ends of said filamentar portion; a support wire extending upwardly from said filamentary position intermediate the ends thereof, said leads and said support wire being short-circuited; and a guard comprising side-arms extending outwardly from said leads intermediate their lengths and downwardly to substantially parallel guarding position with respect to said filamentary portion.
4. An electrode for space discharge tubes comprising, in combination, an oxide-coated fila ment. a guard having a side-arm of high temperature coefficient of electrical resistance positioned adjacent said filament and in electrical connection therewith, and means permanently short-circuiting said filament and said guard.
CHARLES PHILIPPE BOUCHER.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US458273A US2384007A (en) | 1942-09-14 | 1942-09-14 | Electrode |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US458273A US2384007A (en) | 1942-09-14 | 1942-09-14 | Electrode |
Publications (1)
Publication Number | Publication Date |
---|---|
US2384007A true US2384007A (en) | 1945-09-04 |
Family
ID=23820100
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US458273A Expired - Lifetime US2384007A (en) | 1942-09-14 | 1942-09-14 | Electrode |
Country Status (1)
Country | Link |
---|---|
US (1) | US2384007A (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3013175A (en) * | 1957-05-01 | 1961-12-12 | Sylvania Electric Prod | High output discharge lamp |
-
1942
- 1942-09-14 US US458273A patent/US2384007A/en not_active Expired - Lifetime
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3013175A (en) * | 1957-05-01 | 1961-12-12 | Sylvania Electric Prod | High output discharge lamp |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
GB1005386A (en) | Improvements in discharge lamps with cathode shields | |
US2733371A (en) | Internally conducttvely coated | |
US2549355A (en) | Fluorescent lamp | |
US2384007A (en) | Electrode | |
US2315286A (en) | Gaseous discharge lamp | |
US2429118A (en) | Electrode for fluorescent tubes | |
USRE23073E (en) | Space discharge tube and electrode | |
US1925648A (en) | Lighting device | |
US2171234A (en) | Discharge device and electrode | |
US2351616A (en) | Electric discharge device | |
US2488716A (en) | Electric high-pressure discharge tube | |
US2177710A (en) | Fluorescent sign lamp | |
US2060610A (en) | Electrode structure for electric discharge lamps | |
US2283216A (en) | Cathode for discharge tubes | |
US3307069A (en) | Electric discharge lamp | |
US3328622A (en) | Electric discharge device having primary and secondary electrodes | |
US3013175A (en) | High output discharge lamp | |
US1951138A (en) | Gaseous electric discharge lamp device | |
US2313646A (en) | Gaseous discharge lamp | |
US2353635A (en) | Cathode for discharge tubes | |
US2784347A (en) | Electric high pressure discharge lamps | |
US2329126A (en) | Electric discharge device and electrode therefor | |
US2039772A (en) | Electric radiation device | |
US2153008A (en) | Electric discharge lamp | |
US2269843A (en) | Glow relay |