US2504549A - Starting and operating circuit for electric discharge devices - Google Patents

Starting and operating circuit for electric discharge devices Download PDF

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US2504549A
US2504549A US731488A US73148847A US2504549A US 2504549 A US2504549 A US 2504549A US 731488 A US731488 A US 731488A US 73148847 A US73148847 A US 73148847A US 2504549 A US2504549 A US 2504549A
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voltage
secondary winding
circuit
starting
windings
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US731488A
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Lemmers Eugene
Raymond L Keiffer
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General Electric Co
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General Electric Co
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B41/00Circuit arrangements or apparatus for igniting or operating discharge lamps
    • H05B41/14Circuit arrangements
    • H05B41/16Circuit arrangements in which the lamp is fed by dc or by low-frequency ac, e.g. by 50 cycles/sec ac, or with network frequencies
    • H05B41/20Circuit arrangements in which the lamp is fed by dc or by low-frequency ac, e.g. by 50 cycles/sec ac, or with network frequencies having no starting switch
    • H05B41/23Circuit arrangements in which the lamp is fed by dc or by low-frequency ac, e.g. by 50 cycles/sec ac, or with network frequencies having no starting switch for lamps not having an auxiliary starting electrode
    • H05B41/232Circuit arrangements in which the lamp is fed by dc or by low-frequency ac, e.g. by 50 cycles/sec ac, or with network frequencies having no starting switch for lamps not having an auxiliary starting electrode for low-pressure lamps
    • H05B41/2325Circuit arrangements in which the lamp is fed by dc or by low-frequency ac, e.g. by 50 cycles/sec ac, or with network frequencies having no starting switch for lamps not having an auxiliary starting electrode for low-pressure lamps provided with pre-heating electrodes
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S315/00Electric lamp and discharge devices: systems
    • Y10S315/02High frequency starting operation for fluorescent lamp

Definitions

  • This invention relates generally to circuits for electric discharge devices and more particularly to an improvement in the startin and operating circuits for electric discharge devices or lamps I, I, such as fluorescent lamps, therein illustrated comprise elongated tubular or cylindrical envelopes 2, 2 having sealed into the ends thereof filamentary electrodes 3, 4 and 5, 6, respectively, each such as low pressure positive column lamps. 5 herein illustrated as compris g a coil, p e y Circuits now in wide use with fluorescent lamps in the form of a coiled coil of tungsten wire actiare provided with means for heating the filamenvated With oxides of alkaline earth metals such tary electrodes and for impressing ahigh voltage as a mixture of barium and strontium oxides.
  • the envelopes 2, 2' contain gaseous atmospheres ing an electrical discharge therebetween.
  • Means such as a rare gas like krypton, neon, argon or are provided to delay the application of the high es e eo at a p essure of a few millivoltage until the electrodes have reached the meters and a small quantity of mercury which, desired electron emitting temperature.
  • the delay means or switch ref he order of ten micron The d vices l quires careful design, periodic replacement, relamay be low pressure positive column lamps of tively slow starting occasioned by the preheating e o sce ype provided with a suitable period, and varying operating characteristics with phosphor or fluorescent coating.
  • This fluorescent age, coating upon excitation by the radiation produced In the instant start circuit arrangements, by an electric discharge between the electrodes, switches are usually dispensed with however, the transforms the shorter-wave radiation due to the transformer voltage necessary to supply potential discharge into longer wave radiation such as radigreat enough to break down the gas column beation Within the visible range.
  • the electrodes For use of starttween the electrodes is over and above that necing, stripes or strips 1, l of conductive material essary for lamp operation.
  • conductive material essary for lamp operation.
  • Each startvated electrodes, which shortens electrode life. ing strip may be connected to one or both of the An object of our invention is to provide a new electrodes. It may be desirable, as set forth and and improved circuit for starting and operating claimed in application Serial No. 671,189, filed electric discharge devices employing filamentary 3e) May 21, 1946, now abandoned, and which is aselectrodes.
  • Another object of our invention is to provide nect the starting strips 1, 1 through resistances, a new and improved means for impressing startinductors, or capacitances having relatively large ing and operating voltages across filamentary predetermined values of the order of megohms, to electrodes of an electric discharge device which one or both filamentary electrodes of each lamp will vary in phase and magnitude in accordance in order to reduce the starting voltage required with the state of ionization of the discharge me to initiate an arc discharge between the electrodes and to reduce or completely eliminate personnel
  • Further features and advantages of our invenshock hazard incident to the presence of starting tion will appear from the following description strips 1, l on the exterior surface of the enveof species thereof.
  • Fig. 1 is a diagram- 4.3 crescent lamps.
  • the starting strip and associated matic view of an electric discharge device and impedance is a starting aid and is not required a starting and operating circuit therefor incorwith all types of lamps for the successful operporating our invention.
  • Fig. 2 illustrates vecation of our invention.
  • Fig. 3 illustrates vectorially 5o lagging power factor load circuit 9, l0 and a operating characteristics of the circuit illustrated in Fig. 1.
  • Fig. 4 is a diagrammatic representation of a transformer embodying certain features of our invention.
  • leading power factor load circuit H] H are connected across a suitable source of potential, preferably a voltage step-up auto-transformer l2 in which a pair of secondary windings I 3 and I4 serving as ballasts for devices I, l, respectively,
  • the auto-transformer primary winding [5 in turn is connected across a source of power l6 which, for example, may be 115 volt, 60 cycle supply circuit.
  • the usual capacitor I! is added to the lead circuit to effect phase correction in the two lamp circuit.
  • starting and operating voltages may be impressed across the filamentary electrodes of an electric discharge device by three sources of voltage having one predetermined phase position to provide a resultant voltage of predetermined magnitude to assist in the starting operation of an electric discharge device or lamp, and which vary in phase, or vary in phase and magnitude to produce a substantial reduction the voltage upon and after establishment of an arc discharge in the lamp.
  • This potential source for example, may be an autotransformer with the primary winding section serving as one source of voltage, and a pair of secondary winding sections serving as the other two sources of voltage.
  • phase relationships of these winding sections vary with the state of ionization of the medium in the lamps as hereinafter explained.
  • selective control of electrode energization can take place in the heating circuits by proper proportioning and phasing between the three induced voltages.
  • control of the relative magnitudes and phases of these induced voltages we can reduce the resultant electrode voltages to a very low value, or to substantially zero, in response to the state of ionization of the medium through which the arc discharge takes place or in response to an electrical condition such as the current conducted by the lamps.
  • This reduction in voltage or bucking action may be accomplished by using a means responsive to the flow of current, such as a means responsive to the lamp current. Therefore, we provide a plurality of tertiary coils or windings l8, I9, 26 and 2
  • the filamentary electrodes are each connected in series with windings inductively coupled to the primary winding section l5 of the auto-transformer l2, and secondary winding sections l3 and I4.
  • electrodes 3, 4, 5 and 6 are connected in series with inductively coupled auto-transformer windings 22, I8 and 26; 23, I9 and 21; 24, 20 and 28; and 25, 2
  • each filamentary electrode heating circuit As a single unit, proper initial and substantially instantaneous heating current is supplied by'the windings in series therewith during starting, and is automatically removed by the bucking or neutralizing action of these windings upon initiation of an arc discharge and during operation of the lamps.
  • proper phase relationship is necessary.
  • a ballast or auto-transformer [2 may be constructed wherein four electrode heating windings, consisting of the same total number of turns, supply the necessary voltages.
  • Each heating section may have a total of 173 turns of wire on the transformer core of which 41 may be wound over the secondary winding section [3, 76 turns of wire wound over the auto-transformer primary Winding section i5, and 56 turns of wire wound over the secondary winding section I l.
  • the coils or windings serving electrode 3 and electrode 5 may be wound in the following manner: the windings 22 and 24 are wound over the secondary winding section [3 of the auto-transformer [2 in the opposite direction to that of secondary winding section 13; the winding sections it and 29 are wound over the primary winding section l5 of the auto-transformer 12 in the same direction as the auto-transformers primary winding section l5; and the winding sections 26 and 28 for the above electrodes 3 and 5 are wound over the secondary winding section M of the auto-transformer i2 wound the reverse direction to the secondary winding section id.
  • the secondary winding section l3 of the auto-transformer 12 is wound in the reverse direction to the primary winding section 55 and the secondary winding section I l of the auto-transformer [2.
  • the heating sections serving electrodes 6 and 4 may be wound on the transformer core exactly in reverse to that of the above mentioned electrode windings for electrodes 3 and 5.
  • the resultant voltage Va is that voltage supplied to the control or heating circuit Iii-3
  • the resulting voltage VR 9.8 which is applied across the filamentary electrode 4 for heating purposes.
  • the resultant voltage Va may be substantially reduced to a predetermined operating value by proper proportionlng and phasing of the three induced voltages of the control or heating circuit ili--3l. Perfect bucking or neutralization is difficult to obtain because of the potential drop caused in the lamp filamentary electrode by the phase and magnitude of its arc current.
  • the resultant voltage Va is small enough to be negligible. Perfect correlation between the voltages of the windings to obtain substantially zero operating voltage during lamp conduction is not necessary for the successful operation of the circuit. In fact, a small amount of additional-cathode heat is sometimes desirable during operation of the lamp to lower cathode voltage or arc drop.
  • the heating of one of the electrodes of each lamp may be dispensed with. In that event, one heating circuit may be elimihated and the electrode associated therewith short-circuited.
  • Fig. 4 is a diagrammatic representation of a transformer described in application Serial No. 690,855 of Charles W. Kronmiller, filed August 16, 1946, which is assigned to the assignee of this application and which may embody the heating and bucking windings comprising our invention.
  • One aspect of our invention relates to a further improvement of devices of this nature wherein additional means or windings are provided to furnish variable magnitude and variable phase voltages which may be utilized to control selectively the energization of associated load cirnew and improved means for impressing a starting and operating voltage across the filamentary electrodes of an electric discharge device which will vary in phase and magnitude in accordance with the state of ionization of the discharge medium, or which may vary in accordance with or response to an electrical quantity such as lamp current. Accordingly, we provide a means for heating the filamentary electrodes and, after an 'arc discharge-occurs in the lamp, reduce electrode energization by bucking or neutralization.
  • an alternating current supply circuit a laggingpower factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections, one of said secondary winding sections connected to said lagging power 2.
  • an alternating current supply circuit a lagging power factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections loosely coupled to said primary winding section, one of said secondary winding sections connected to said lagging power factor load circuit and the other connected to said leading power factor load circuit, a control circuit, and means comprising three serially connected windings inductively coupled with said primary and secondary winding sections, respectively, for supplying to said control circuit a voltage of predetermined magnitude under no load conditions of the load circuits and for reducing said voltage in magnitude upon flow of current in said load circuits.
  • an alternating current supply circuit a lagging power factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and. the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections loosely coupled to said primary winding section, one of said secondary winding sections connected to said lagging power factor load circuit and the other connected to said leading power factor load circuit, a plurality of control circuits, and means including sets of three serially connected windings inductively coupled with said primary and secondary winding sections, respectively, for supplying to each of said control circuits a resultant voltage the magnitude of which is reduced to substantially zero upon the flow of current in the load circuits.
  • an alternating current supply circuit a lagging power factor load circuit, a leading power factor load circuit
  • transforming means connected between said supply circuit and the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections, one of said secondary winding sections connected to said lagging power factor lead circuit and the other connected to said leading power factor load circuit, a pair of control circuits, and means including three serially connected windings inductively coupled with said primary and secondary winding sections, respectively, for supplying to said control circuits a resultant voltage the magnitude of which varies in accordance with a predetermined electrical condition Of said load circuits.
  • an alternating current supply circuit a pair of .electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium
  • an electric transforming means connected to said supply circuit and comprising a primary windin section and a pair of secondary winding sections, the primary winding section and one of .said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected in circuit with a leading power factor means for supplying to the second mentioned discharge device a start-- ing and operating voltage
  • said electric transforming means comprising three serially connected windings each inductively coupled with said primary winding section and secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance with the state of ionization of said medium.
  • an alternating current supply circuit a pair of electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium, and an electric transforming means connected to said supply circuit and comprising a primary winding section and a pair of secondary winding sections,
  • said electric transforming means comprising a winding inductively coupled to the primary winding section for producing a voltage of substantially constant magnitude and phase, and a pair of windings serially connected therewith each inductively coupled with said secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance cuit and comprising a primary winding section and a pair of secondary winding sections loosely coupled to said primary winding section, the primary winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected
  • an alternating current supply circuit a pair of electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium
  • an electric transforming means connected to said supply circuit and comprising a primary winding section and a pair of secondary winding sections, the primary winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected in circuit with aleading power factor means for supplying to the second mentioned discharge device a starting and operating voltage, said secondary winding sections being loosely coupled to said primary winding section and serving as ballast inductances for said devices, and said electric transforming means comprising three serially connected windings each inductively coupled with said primary winding section and secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance with the state of ionization of said medium.
  • an alternating current supply circuit a pair of electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium, means facilitating the starting of an arc discharge between said electrodes comprising a strip on each of said devices extending an appreciable distance between associated electrodes and connected to one of said electrodes, and an electric transforming means connected to said supply circuit and comprising a primary winding section and a pair of secondary winding sections, the primary winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary Winding section and the othersecondary winding section connected in circuit with a leading power factor means for supplying to the second mentioned discharge device a starting and operating voltage, said electric transforming means comprising three serially connected windings each inductively coupled with said primary winding section and secondary windin sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance with the state
  • an inductive device comprising a magnetic core structure having wound thereon primary winding means for connection to an alternating current supply circuit and a pair of secondary winding means, and a plurality of tertiary winding means for producing a resultant voltage the magnitude of which varies in accordance with the current conducted by said secondary winding means and comprising a tertiary winding inductively associated with said primary winding means for producing a reference voltage of substantially constant magnitude, a second tertiary winding inductively associated with one of said secondary winding means for producing a component of voltage variable in magnitude and phase in response to the current conducted by said one secondary winding means, and a third tertiary winding inductively associated with the other of said secondary winding means for producing a second component of voltage variable in magnitude and phase in response to the current conducted by said second secondary winding means, the sum of said reference voltage and said components being reduced upon the flow of current through said secondary winding means.
  • a voltage transforming means of the auto-transformer type comprising a magnetic structure having wound thereon primary winding means for connection to an alternating current supply circuit and a pair of secondary winding means and three serially connected tertiary winding means for producing a resultant voltage the magnitude of which varies in accordance with the current conducted by said secondary winding means and comprising a tertiary winding inductively associated with said primary winding means for producing a refer-,-
  • ence voltage of substantially constant magnitude a second tertiary winding inductively associated with one of said secondary winding means for producing a component of voltage variable in response to the current conducted by said one secondary winding means, and a third tertiary winding inductively associated with the other of said secondary winding means for producing a second component of voltage variable in response to the current conducted by said secondary winding means, the sum of said reference voltage and said components being reduced upon the flow of current through said secondary winding means.
  • an inductive device comprising a magnetic core structure having thereon primary winding means for connection to an alternating current supply circuit and a pair of secondary winding means, the primary winding means and one of said secondary winding means constituting a lagging power factor circuit and the primary winding means and the other secondary winding means connected in circuit with a leading power factor means, and a plurality of tertiary winding means for producing a resultant voltage the magnitude of which varies in accordance with the current conducted by said secondary winding means and comprising a tertiary winding inductively associated with said primary winding means for producing a reference voltage of substantially constant magnitude, a second tertiary winding inductively associated with one of said secondary winding means for producing a component of voltage variable in magnitude and phase in response to the current conducted by said one secondary K winding means, and a third tertiary winding inductively associated with the other of said secondary winding means for producing a second component of voltage variable in magnitude and phase in response to the magnitude and phase
  • control circuit and three serially connected control windings for energizing said control circuit and for supplying thereto a resultant voltage the magnitude of which varies in accordance with the currents conducted by said load circuits, one
  • a transformer for the quick starting and eflicient stable operation of an arc discharge lamp of the type having two electrodes at least one of which has a heating coil comprising, in combination, a magnetic core having a primary winding section and a secondary winding section, a magnetic shunt on said core between said sections which provides a leakage flux path therebetween, a primary winding on said primary core section, a secondary winding on said secondary core section, said primary and secondary windings being serially connected in auto-transformer relation for providing a relatively high open circuit starting voltage across the electrodes of a lamp of the above-mentioned type and for providing a substantially lower operating voltage for such a lamp when load current flows through said windings by reason of the leakage reactance of said transformer which is produced by said magnetic shunt, a pair of auxiliary electrode heater supply windings mounted respectively on said primary and secondary core sections, said auxiliary windings being serially connected with each other to supply a relatively high resultant starting voltage to a lamp electrode heater coil and to supply a substantially

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Description

April 18 1950 E. LEMMERS ETAL. 25%?549 STARTING AND OPERATING CIRCUIT FOR ELECTRIC DISCHARGE DEVICES Filed Feb. 28, 1947 2 Sheets-Sheet 1 Fig.1.
InwanTors: Eugene Lewnmerfla April 18, 3956 E. LEMMERS ET AL 2,504,549
STARTING AND OPERATING CIRCUIT FOR ELECTRIC DISCHARGE DEVICES Filed Feb. 28, 1947 2 Sheets-Sheet 2 25 l5 l6 l9 2/ 29 28 27 26 /4 Inve nior s Eugene Le m m er s Rey rn orwci L. l \e i FFer,
Th ei 9" A1 orn e3.
Patented Apr. 18, 1950 STARTING AND OPERATING CIRCUIT FOR ELECTRIC DISCHARGE DEVICES Eugene Lemmers, Cleveland Heights, and Raymond L. Keilfer, Chagrin Falls, Ohio, assignors to General Electric Company, a corporation of New York Application February 28, 1947, Serial No. 731,488
15 Claims.
This invention relates generally to circuits for electric discharge devices and more particularly to an improvement in the startin and operating circuits for electric discharge devices or lamps I, I, such as fluorescent lamps, therein illustrated comprise elongated tubular or cylindrical envelopes 2, 2 having sealed into the ends thereof filamentary electrodes 3, 4 and 5, 6, respectively, each such as low pressure positive column lamps. 5 herein illustrated as compris g a coil, p e y Circuits now in wide use with fluorescent lamps in the form of a coiled coil of tungsten wire actiare provided with means for heating the filamenvated With oxides of alkaline earth metals such tary electrodes and for impressing ahigh voltage as a mixture of barium and strontium oxides. for short duration across the electrodes for start- The envelopes 2, 2' contain gaseous atmospheres ing an electrical discharge therebetween. Means such as a rare gas like krypton, neon, argon or are provided to delay the application of the high es e eo at a p essure of a few millivoltage until the electrodes have reached the meters and a small quantity of mercury which, desired electron emitting temperature. In prior during operation of the lamps, has a low pressure art arrangements the delay means or switch ref he order of ten micron The d vices l quires careful design, periodic replacement, relamay be low pressure positive column lamps of tively slow starting occasioned by the preheating e o sce ype provided with a suitable period, and varying operating characteristics with phosphor or fluorescent coating. This fluorescent age, coating upon excitation by the radiation produced In the instant start circuit arrangements, by an electric discharge between the electrodes, switches are usually dispensed with however, the transforms the shorter-wave radiation due to the transformer voltage necessary to supply potential discharge into longer wave radiation such as radigreat enough to break down the gas column beation Within the visible range. For use of starttween the electrodes is over and above that necing, stripes or strips 1, l of conductive material essary for lamp operation. In addition, there is which for example may be a metallic paint or a relatively high voltage gradient at the cathodes graphite mixed with potassium silicate, may be during starting without preheating of the actiapplied to the surface of devices I, l. Each startvated electrodes, which shortens electrode life. ing strip may be connected to one or both of the An object of our invention is to provide a new electrodes. It may be desirable, as set forth and and improved circuit for starting and operating claimed in application Serial No. 671,189, filed electric discharge devices employing filamentary 3e) May 21, 1946, now abandoned, and which is aselectrodes. signed to the assignee of this application, to con- Another object of our invention is to provide nect the starting strips 1, 1 through resistances, a new and improved means for impressing startinductors, or capacitances having relatively large ing and operating voltages across filamentary predetermined values of the order of megohms, to electrodes of an electric discharge device which one or both filamentary electrodes of each lamp will vary in phase and magnitude in accordance in order to reduce the starting voltage required with the state of ionization of the discharge me to initiate an arc discharge between the electrodes and to reduce or completely eliminate personnel Further features and advantages of our invenshock hazard incident to the presence of starting tion will appear from the following description strips 1, l on the exterior surface of the enveof species thereof. For a better understanding of lopes. These separate or individual impedance our invention reference may be had to the follow- 8, 8' may be resistances ranging in values of from ing description taken in connection with the acone to ten megohms and preferably from two to companying drawings and its scope will be pointed eight megohms for application to watt size flu- Ol t in e pp d cla ms- Fig. 1 is a diagram- 4.3 crescent lamps. The starting strip and associated matic view of an electric discharge device and impedance is a starting aid and is not required a starting and operating circuit therefor incorwith all types of lamps for the successful operporating our invention. Fig. 2 illustrates vecation of our invention. torially starting characteristics of the circuit 11- The lamps and connected circuits forming a lustrated in Fig. 1. Fig. 3 illustrates vectorially 5o lagging power factor load circuit 9, l0 and a operating characteristics of the circuit illustrated in Fig. 1. Fig. 4 is a diagrammatic representation of a transformer embodying certain features of our invention.
Referring to Fig. 1, electric discharge devices :2-
leading power factor load circuit H], H, are connected across a suitable source of potential, preferably a voltage step-up auto-transformer l2 in which a pair of secondary windings I 3 and I4 serving as ballasts for devices I, l, respectively,
are coupled loosely to the power source or primary winding l by means of leakage reactance. The auto-transformer primary winding [5 in turn is connected across a source of power l6 which, for example, may be 115 volt, 60 cycle supply circuit. The usual capacitor I! is added to the lead circuit to effect phase correction in the two lamp circuit.
In accordance with our invention starting and operating voltages may be impressed across the filamentary electrodes of an electric discharge device by three sources of voltage having one predetermined phase position to provide a resultant voltage of predetermined magnitude to assist in the starting operation of an electric discharge device or lamp, and which vary in phase, or vary in phase and magnitude to produce a substantial reduction the voltage upon and after establishment of an arc discharge in the lamp. For example we may employ three windings producing voltages at least one of which differs in phase from the voltage of the others. This potential source, for example, may be an autotransformer with the primary winding section serving as one source of voltage, and a pair of secondary winding sections serving as the other two sources of voltage. The phase relationships of these winding sections vary with the state of ionization of the medium in the lamps as hereinafter explained. Thus, by using induced voltages from three different sources of voltage or flux varying in phase relationship in accordance with the ionization of the discharge medium, or the current incident thereto, selective control of electrode energization can take place in the heating circuits by proper proportioning and phasing between the three induced voltages. By control of the relative magnitudes and phases of these induced voltages, we can reduce the resultant electrode voltages to a very low value, or to substantially zero, in response to the state of ionization of the medium through which the arc discharge takes place or in response to an electrical condition such as the current conducted by the lamps. This reduction in voltage or bucking action may be accomplished by using a means responsive to the flow of current, such as a means responsive to the lamp current. Therefore, we provide a plurality of tertiary coils or windings l8, I9, 26 and 2| on the core of auto-transformer l2 and inductively coupled to the transformers primary winding section [5; coils or windings 2 2, 23, 24 and on the core of auto-transformer i2 are inductively coupled to the transformer's secondary winding section l3; and coils or windings 26 21, 28 and 29 on the core of auto-transformer 12 are inductively coupled to the transformers secondary winding section [4. The filamentary electrodes, in this case, are each connected in series with windings inductively coupled to the primary winding section l5 of the auto-transformer l2, and secondary winding sections l3 and I4. Thus, electrodes 3, 4, 5 and 6 are connected in series with inductively coupled auto-transformer windings 22, I8 and 26; 23, I9 and 21; 24, 20 and 28; and 25, 2| and 29; respectively, and comprise the starting and electrode control or heating circuits 9-3ll, l03'l, |0-.-32 and -33, respectively.
By considering each filamentary electrode heating circuit as a single unit, proper initial and substantially instantaneous heating current is supplied by'the windings in series therewith during starting, and is automatically removed by the bucking or neutralizing action of these windings upon initiation of an arc discharge and during operation of the lamps. In order to control the energization of the electrodes, proper phase relationship is necessary. For example, a ballast or auto-transformer [2 may be constructed wherein four electrode heating windings, consisting of the same total number of turns, supply the necessary voltages. Each heating section, for example, may have a total of 173 turns of wire on the transformer core of which 41 may be wound over the secondary winding section [3, 76 turns of wire wound over the auto-transformer primary Winding section i5, and 56 turns of wire wound over the secondary winding section I l. The coils or windings serving electrode 3 and electrode 5 may be wound in the following manner: the windings 22 and 24 are wound over the secondary winding section [3 of the auto-transformer [2 in the opposite direction to that of secondary winding section 13; the winding sections it and 29 are wound over the primary winding section l5 of the auto-transformer 12 in the same direction as the auto-transformers primary winding section l5; and the winding sections 26 and 28 for the above electrodes 3 and 5 are wound over the secondary winding section M of the auto-transformer i2 wound the reverse direction to the secondary winding section id. The secondary winding section l3 of the auto-transformer 12, however, is wound in the reverse direction to the primary winding section 55 and the secondary winding section I l of the auto-transformer [2. The heating sections serving electrodes 6 and 4 may be wound on the transformer core exactly in reverse to that of the above mentioned electrode windings for electrodes 3 and 5.
When switch 3 is closed, power is supplied to the auto-transformer i2, and its associated in- 'fductively coupled windings are energized. Cathode heating current, sufficient for raising the temperature of the electrodes of each discharge device to produce electron emission and to facilitate breakdown of the positive column therebetween is supplied thereto. A proper voltage for starting an arc discharge between the filamentary electrodes is also provided therebetween. Before an arc discharge occurs in lamps or devices l and I the induced voltages in each inductively coupled winding of a particular heating circuit, for example, control or heating circuit lfi--3H, is either in phase or out of phase with the voltages of the other inductively coupled windings of that heating circuit. Fig. 2
illustrates vectorially the phase relationship and magnitudes of the induced starting voltages in the windings of heating circuit Iii-3|. V10 represents the. induced voltage of winding l9; V21 represents the induced voltage of winding 2?; and V22 represents the induced voltage of winding 23. Thus, the resultant voltage Va is that voltage supplied to the control or heating circuit Iii-3| for impressing across the filamentary electrode a voltage for raising the electrode temperature to facilitate breakdown of the positive column in the lamp and for starting an arc discharge between the electrodes. For example, the induced voltage V19=11.9 volts; V27=7.l volts; V23=5 volts and in the phase relationship indicated in Fig. 2. The resulting voltage VR=9.8 which is applied across the filamentary electrode 4 for heating purposes.
After the arc discharge has been established the magnitudes and phase relationship between the induced voltages of the control or heating circuit Ill-31 change. As indicated in Fig. 3, the resultant voltage Va may be substantially reduced to a predetermined operating value by proper proportionlng and phasing of the three induced voltages of the control or heating circuit ili--3l. Perfect bucking or neutralization is difficult to obtain because of the potential drop caused in the lamp filamentary electrode by the phase and magnitude of its arc current. The resultant voltage Va, however, is small enough to be negligible. Perfect correlation between the voltages of the windings to obtain substantially zero operating voltage during lamp conduction is not necessary for the successful operation of the circuit. In fact, a small amount of additional-cathode heat is sometimes desirable during operation of the lamp to lower cathode voltage or arc drop.
It is'possible that the heating of one of the electrodes of each lamp may be dispensed with. In that event, one heating circuit may be elimihated and the electrode associated therewith short-circuited.
Fig. 4 is a diagrammatic representation of a transformer described in application Serial No. 690,855 of Charles W. Kronmiller, filed August 16, 1946, which is assigned to the assignee of this application and which may embody the heating and bucking windings comprising our invention.
One aspect of our invention relates to a further improvement of devices of this nature wherein additional means or windings are provided to furnish variable magnitude and variable phase voltages which may be utilized to control selectively the energization of associated load cirnew and improved means for impressing a starting and operating voltage across the filamentary electrodes of an electric discharge device which will vary in phase and magnitude in accordance with the state of ionization of the discharge medium, or which may vary in accordance with or response to an electrical quantity such as lamp current. Accordingly, we provide a means for heating the filamentary electrodes and, after an 'arc discharge-occurs in the lamp, reduce electrode energization by bucking or neutralization.
Generally speaking, we effect these desired results by providing windings inductively coupled "to three potential sources differing in phase one from the other. By this means neutralization can take place in the heating circuits by proper proportioning between the three induced voltages.
7 What we claim as new and desire to secure by Letters Patent of the United States is:
1. In combination, an alternating current supply circuit, a laggingpower factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections, one of said secondary winding sections connected to said lagging power 2. In combination, an alternating current supply circuit, a lagging power factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections loosely coupled to said primary winding section, one of said secondary winding sections connected to said lagging power factor load circuit and the other connected to said leading power factor load circuit, a control circuit, and means comprising three serially connected windings inductively coupled with said primary and secondary winding sections, respectively, for supplying to said control circuit a voltage of predetermined magnitude under no load conditions of the load circuits and for reducing said voltage in magnitude upon flow of current in said load circuits.
3. In combination, an alternating current supply circuit, a lagging power factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and. the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections loosely coupled to said primary winding section, one of said secondary winding sections connected to said lagging power factor load circuit and the other connected to said leading power factor load circuit, a plurality of control circuits, and means including sets of three serially connected windings inductively coupled with said primary and secondary winding sections, respectively, for supplying to each of said control circuits a resultant voltage the magnitude of which is reduced to substantially zero upon the flow of current in the load circuits.
4. In combination, an alternating current supply circuit, a lagging power factor load circuit, a leading power factor load circuit, transforming means connected between said supply circuit and the load circuits and comprising a core member, a primary winding section and a pair of secondary winding sections, one of said secondary winding sections connected to said lagging power factor lead circuit and the other connected to said leading power factor load circuit, a pair of control circuits, and means including three serially connected windings inductively coupled with said primary and secondary winding sections, respectively, for supplying to said control circuits a resultant voltage the magnitude of which varies in accordance with a predetermined electrical condition Of said load circuits.
5. In combination, an alternating current supply circuit, a pair of .electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium, and an electric transforming means connected to said supply circuit and comprising a primary windin section and a pair of secondary winding sections, the primary winding section and one of .said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected in circuit with a leading power factor means for supplying to the second mentioned discharge device a start-- ing and operating voltage, said electric transforming means comprising three serially connected windings each inductively coupled with said primary winding section and secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance with the state of ionization of said medium.
6. In combination, an alternating current supply circuit, a pair of electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium, and an electric transforming means connected to said supply circuit and comprising a primary winding section and a pair of secondary winding sections,
the primer winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected in circuit with a leading power factor means for supplying to the second mentioned discharge device a starting and operating voltage, said electric transforming means comprising a winding inductively coupled to the primary winding section for producing a voltage of substantially constant magnitude and phase, and a pair of windings serially connected therewith each inductively coupled with said secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance cuit and comprising a primary winding section and a pair of secondary winding sections loosely coupled to said primary winding section, the primary winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected in circuit with a leading power factor means for supplying to the second mentioned discharge device a starting and operating voltage, said electric transforming means comprising three serially connected windings providing voltages two of which are variable in phase and which are inductively coupled with said primary winding section and secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in magnitude in accordance with the current conducted by said electric discharge devices.
8. In combination, an alternating current supply circuit, a pair of electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium, an electric transforming means connected to said supply circuit and comprising a primary winding section and a pair of secondary winding sections, the primary winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary winding section and the other secondary winding section connected in circuit with aleading power factor means for supplying to the second mentioned discharge device a starting and operating voltage, said secondary winding sections being loosely coupled to said primary winding section and serving as ballast inductances for said devices, and said electric transforming means comprising three serially connected windings each inductively coupled with said primary winding section and secondary winding sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance with the state of ionization of said medium.
9. In combination, an alternating current supply circuit, a pair of electric discharge devices each comprising at least one filamentary electrode and employing an ionizable medium, means facilitating the starting of an arc discharge between said electrodes comprising a strip on each of said devices extending an appreciable distance between associated electrodes and connected to one of said electrodes, and an electric transforming means connected to said supply circuit and comprising a primary winding section and a pair of secondary winding sections, the primary winding section and one of said secondary winding sections constituting a lagging power factor circuit connected to the electrodes of one of said discharge devices for supplying thereto a starting and operating voltage, said primary Winding section and the othersecondary winding section connected in circuit with a leading power factor means for supplying to the second mentioned discharge device a starting and operating voltage, said electric transforming means comprising three serially connected windings each inductively coupled with said primary winding section and secondary windin sections, respectively, for supplying to said filamentary electrode of one of said devices a resultant voltage variable in accordance with the state of ionization of said medium.
10. In an inductive device, the combination comprising a magnetic core structure having wound thereon primary winding means for connection to an alternating current supply circuit and a pair of secondary winding means, and a plurality of tertiary winding means for producing a resultant voltage the magnitude of which varies in accordance with the current conducted by said secondary winding means and comprising a tertiary winding inductively associated with said primary winding means for producing a reference voltage of substantially constant magnitude, a second tertiary winding inductively associated with one of said secondary winding means for producing a component of voltage variable in magnitude and phase in response to the current conducted by said one secondary winding means, and a third tertiary winding inductively associated with the other of said secondary winding means for producing a second component of voltage variable in magnitude and phase in response to the current conducted by said second secondary winding means, the sum of said reference voltage and said components being reduced upon the flow of current through said secondary winding means.
11. In a voltage transforming means of the auto-transformer type, the combination comprising a magnetic structure having wound thereon primary winding means for connection to an alternating current supply circuit and a pair of secondary winding means and three serially connected tertiary winding means for producing a resultant voltage the magnitude of which varies in accordance with the current conducted by said secondary winding means and comprising a tertiary winding inductively associated with said primary winding means for producing a refer-,-
ence voltage of substantially constant magnitude, a second tertiary winding inductively associated with one of said secondary winding means for producing a component of voltage variable in response to the current conducted by said one secondary winding means, and a third tertiary winding inductively associated with the other of said secondary winding means for producing a second component of voltage variable in response to the current conducted by said secondary winding means, the sum of said reference voltage and said components being reduced upon the flow of current through said secondary winding means.
12. In an inductive device, the combination comprising a magnetic core structure having thereon primary winding means for connection to an alternating current supply circuit and a pair of secondary winding means, the primary winding means and one of said secondary winding means constituting a lagging power factor circuit and the primary winding means and the other secondary winding means connected in circuit with a leading power factor means, and a plurality of tertiary winding means for producing a resultant voltage the magnitude of which varies in accordance with the current conducted by said secondary winding means and comprising a tertiary winding inductively associated with said primary winding means for producing a reference voltage of substantially constant magnitude, a second tertiary winding inductively associated with one of said secondary winding means for producing a component of voltage variable in magnitude and phase in response to the current conducted by said one secondary K winding means, and a third tertiary winding inductively associated with the other of said secondary winding means for producing a second component of voltage variable in magnitude and phase in response to the magnitude and phase of the current conducted by said second secondary winding means, the sum of said reference voltage and said components being reduced upon the flow of current through said secondary winding means.
13. In a transforming system, the combination comprising primary winding means for connection to an alternating supply circuit and a secondary winding means for energizing a pair of load circuits having diiferent power factors, a
control circuit, and three serially connected control windings for energizing said control circuit and for supplying thereto a resultant voltage the magnitude of which varies in accordance with the currents conducted by said load circuits, one
i ii
1 primary winding on said core, a secondary winding on said core, said windings being loosely coupled by means of a leakage flux path therebetween on said core, said windings being connected in auto-transformer relation for providing a relatively high open circuit voltage and a relatively low operating voltage when load current flows therein by reason of the phase displacement of their voltages which is caused by their leakage fluxes, and separate auxiliary windings mounted on said core and closely coupled respectively with said primary and secondary windings, said auxiliary windings being serially connected in a circuit having a predetermined resultant voltage of substantial value when no load current flows in said primary and secondary windings and having a minimum resultant voltage when a load current flows in said primary and secondary windings, said minimum voltage being produced by the phase displacement between the voltages of said auxiliary windings which is caused by the leakage fluxes of said primary and secondary windings.
15. A transformer for the quick starting and eflicient stable operation of an arc discharge lamp of the type having two electrodes at least one of which has a heating coil comprising, in combination, a magnetic core having a primary winding section and a secondary winding section, a magnetic shunt on said core between said sections which provides a leakage flux path therebetween, a primary winding on said primary core section, a secondary winding on said secondary core section, said primary and secondary windings being serially connected in auto-transformer relation for providing a relatively high open circuit starting voltage across the electrodes of a lamp of the above-mentioned type and for providing a substantially lower operating voltage for such a lamp when load current flows through said windings by reason of the leakage reactance of said transformer which is produced by said magnetic shunt, a pair of auxiliary electrode heater supply windings mounted respectively on said primary and secondary core sections, said auxiliary windings being serially connected with each other to supply a relatively high resultant starting voltage to a lamp electrode heater coil and to supply a substantially low resultant operating voltage to such a coil when load current flows through said primary and secondary windings by reason of the phase displacement of the voltages of said auxiliary windings which is caused by the primary winding and secondary winding leakage fluxes.
EUGENE LEMMERS. RAYMOND L. KEIFFER.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 1,485,727 Sindeband Mar. 4, 1924 2,094,680 Schouwstra Oct. 5, 1937
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Cited By (22)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2644107A (en) * 1949-11-23 1953-06-30 Gen Electric Preheat neutralizing circuit for fluorescent lamps
US2683241A (en) * 1951-02-23 1954-07-06 Thorn Electric Ind Ltd Electric lamp circuits
US2685662A (en) * 1950-05-05 1954-08-03 Advance Transformer Co Apparatus for igniting and operating gaseous discharge devices
US2694787A (en) * 1948-10-26 1954-11-16 Gen Electric Starting circuit for electric lamps
US2716205A (en) * 1950-04-05 1955-08-23 Advance Transformer Co Apparatus for operating gaseous discharge devices
US2719937A (en) * 1949-11-23 1955-10-04 Gen Electric Cathode preheat conversion unit for fluorescent lamps
US2767349A (en) * 1953-07-14 1956-10-16 Albert E Feinberg Fluorescent lamp socket and lighting system
US2774010A (en) * 1951-10-13 1956-12-11 Advance Transformer Co Apparatus for starting and operating gaseous discharge devices
US2774918A (en) * 1951-10-06 1956-12-18 Gen Electric Electric discharge device
US2796554A (en) * 1952-07-25 1957-06-18 Gen Electric Electrical transformer ballast
US2797366A (en) * 1952-01-22 1957-06-25 Westinghouse Electric Corp Apparatus for operating gaseous discharge devices
US2823337A (en) * 1952-10-02 1958-02-11 Gen Electric Apparatus for starting and operating electric discharge lamp
US2829311A (en) * 1952-05-15 1958-04-01 Philips Corp Low-pressure arc discharge tube arrangement
US2838714A (en) * 1953-09-28 1958-06-10 Philips Corp Igniting and operating circuit for discharge tubes
US2849656A (en) * 1953-09-15 1958-08-26 Gen Electric Switch-start discharge lamp circuit
US2861219A (en) * 1954-01-07 1958-11-18 Knobel Fritz Lighting installation
US2861217A (en) * 1954-08-17 1958-11-18 Advance Transformer Co Apparatus for igniting and operating gaseous discharge devices
US2864035A (en) * 1955-12-23 1958-12-09 Ariel R Davis Fluorescent light dimming
US2877382A (en) * 1953-09-23 1959-03-10 Westinghouse Electric Corp Apparatus for operating gaseous discharge devices
US2900577A (en) * 1955-11-03 1959-08-18 Albert E Feinberg Ballast and lighting system for fluorescent lamps
US3176187A (en) * 1953-09-29 1965-03-30 Basic Products Corp Safety system for fluorescent lamp ballasts
US4663566A (en) * 1984-02-03 1987-05-05 Sharp Kabushiki Kaisha Fluorescent tube ignitor

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1485727A (en) * 1920-09-20 1924-03-04 Gen Electric Voltage boosting or bucking system
US2094680A (en) * 1935-12-21 1937-10-05 Gen Electric Gaseous electric discharge device

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1485727A (en) * 1920-09-20 1924-03-04 Gen Electric Voltage boosting or bucking system
US2094680A (en) * 1935-12-21 1937-10-05 Gen Electric Gaseous electric discharge device

Cited By (22)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2694787A (en) * 1948-10-26 1954-11-16 Gen Electric Starting circuit for electric lamps
US2719937A (en) * 1949-11-23 1955-10-04 Gen Electric Cathode preheat conversion unit for fluorescent lamps
US2644107A (en) * 1949-11-23 1953-06-30 Gen Electric Preheat neutralizing circuit for fluorescent lamps
US2716205A (en) * 1950-04-05 1955-08-23 Advance Transformer Co Apparatus for operating gaseous discharge devices
US2685662A (en) * 1950-05-05 1954-08-03 Advance Transformer Co Apparatus for igniting and operating gaseous discharge devices
US2683241A (en) * 1951-02-23 1954-07-06 Thorn Electric Ind Ltd Electric lamp circuits
US2774918A (en) * 1951-10-06 1956-12-18 Gen Electric Electric discharge device
US2774010A (en) * 1951-10-13 1956-12-11 Advance Transformer Co Apparatus for starting and operating gaseous discharge devices
US2797366A (en) * 1952-01-22 1957-06-25 Westinghouse Electric Corp Apparatus for operating gaseous discharge devices
US2829311A (en) * 1952-05-15 1958-04-01 Philips Corp Low-pressure arc discharge tube arrangement
US2796554A (en) * 1952-07-25 1957-06-18 Gen Electric Electrical transformer ballast
US2823337A (en) * 1952-10-02 1958-02-11 Gen Electric Apparatus for starting and operating electric discharge lamp
US2767349A (en) * 1953-07-14 1956-10-16 Albert E Feinberg Fluorescent lamp socket and lighting system
US2849656A (en) * 1953-09-15 1958-08-26 Gen Electric Switch-start discharge lamp circuit
US2877382A (en) * 1953-09-23 1959-03-10 Westinghouse Electric Corp Apparatus for operating gaseous discharge devices
US2838714A (en) * 1953-09-28 1958-06-10 Philips Corp Igniting and operating circuit for discharge tubes
US3176187A (en) * 1953-09-29 1965-03-30 Basic Products Corp Safety system for fluorescent lamp ballasts
US2861219A (en) * 1954-01-07 1958-11-18 Knobel Fritz Lighting installation
US2861217A (en) * 1954-08-17 1958-11-18 Advance Transformer Co Apparatus for igniting and operating gaseous discharge devices
US2900577A (en) * 1955-11-03 1959-08-18 Albert E Feinberg Ballast and lighting system for fluorescent lamps
US2864035A (en) * 1955-12-23 1958-12-09 Ariel R Davis Fluorescent light dimming
US4663566A (en) * 1984-02-03 1987-05-05 Sharp Kabushiki Kaisha Fluorescent tube ignitor

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