US2478906A - Electric system - Google Patents

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US2478906A
US2478906A US700639A US70063946A US2478906A US 2478906 A US2478906 A US 2478906A US 700639 A US700639 A US 700639A US 70063946 A US70063946 A US 70063946A US 2478906 A US2478906 A US 2478906A
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condenser
flash
discharge
spark gap
electrodes
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Harold E Edgerton
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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
    • H05B41/30Circuit arrangements in which the lamp is fed by pulses, e.g. flash lamp
    • H05B41/32Circuit arrangements in which the lamp is fed by pulses, e.g. flash lamp for single flash operation

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  • the present invention though having fields of more general usefulness in electric systems, is particularly related to electric-energy flash-producing or other pulse-producing systems in which the discharge of a condenser is employed for such purposes as to produce a single light flash or a single electric-energy pulse or a repetition of light flashes or electric-energy pulses of short duration and high intensity.
  • the present application is filed in response to a requirement for division in application, Serial No. 685,501, flied August 16, 1933.
  • An object of the preesnt invention is to provide a new and improved electric system of the above-described character that shall overcome these difficulties.
  • An object of the present invention is to provide a new and improved electric system or the above-described character for producing light flashes or other pulses of electric energy.
  • a further object of the present invention is to provide a new and improved system of the above-described character in which a three-electrode gaseous-conductor device may serve as a control for a load, disclosed specifically as a two-terminal flash-producing device.
  • Fig. 1 is a diagrammatic view of circuits and apparatus illustrating one embodiment of the invention according to which the flash is provided by a three-electrode spark ap to the exclusion of any additional flash device; and Fig. 2 is a similar view illustrating a preferred embodiment of the invention, according to which the flash, provided chiefly by a flash device, is augmented by the flash of a three-electrode spark gap.
  • a three-electrode spark gap or other gaseousdischarge device comprising two principal electrodes l and i and a starting triggering or control electrode III disposed substantially between .the principal electrodes 4 and t.
  • the principal electrodes 4 and 6 are connected by wire conductors l and II to a source of direct current, in parallel with a flash condenser or capacitor 26.
  • the source of direct current is shown in Fig. 2 as constituted of a battery I02. As shown in Fig. 1, however, the direct current may be supplied from any desired source of aiternating energy of suitable voltage and frequency through a transformer Ill.
  • the primary winding I of the transformer I48 is connected to the alternating-current source, and the secondary winding in, through a thermionic or gaseous-discharge rectifier II, to the condenser 28.
  • a current-llmitin-g charging impedance 35 may be series-connected in the charging circuit of the condenser 20, either in the wire conductor in, as illustrated in Fig. l, or the wire conductor 8, as shown in Fig. 2.
  • the condenser 26 may be charged to a volta e of from 200 to 2000 volts.
  • the principal electrodes 4 and G of the threeelectrode spark gap are series-connected in the discharge circuit of the condenser 26. The flashes are produced by discharging the condenser 26, after it has become charged, through the air between the principal electrodes 4 and 8 of the spark gap.
  • a simple inexpensive triggering three-electrode spark gap is thus procided for efllciently handling the necessarily high-peak-discharge currents.
  • the noise of operation may be reduced by enclosing the spark gap in a noise-proof chamber.
  • the direct-current source will charge the condenser 16 through the impedance ll without any of itsenergy traversing that space.
  • a diflerence of potential will therefore be established between the spark-gap electrodes 4 and 8 during the charging of the condenser 26 before each flash.
  • the impedance 35 should, however, be small. enough to permit of the condenser 26 becomin recharged with energy from the d rect-current source in time for the next flash.
  • the series-connected discharge circuit comprising the condenser 26 and the'spark gap may include also an additional flash device I52, shown in Fig. 2 as a small fine two-terminal conducting wire.
  • the flash device I52 may provide the principal or chief light of the flash, of substantial illumination intensity but the light from the three-electrode spark gap may itself be quite substantial to augment the flash of the flash device I52.
  • the quantity of light in the flash is determined by the amount of energy in the condenser 26 and by circuit conditions.
  • a conductor is shown connecting theprlncipal electrode 6 to one of the terminals of the additional flash device I52.
  • the conductor I connects the other terminal of the additional flash device I52 to one side of the battery I02.
  • the conductor 8 connects the principal electrode 4 to the other side of the battery I02.
  • the invention is not, 01' course, restricted to use with the two-terminal conductive wire I52.
  • This two-terminal conductive wire I52 is quite emcient for the production of light flashes, but the invention is equally applicable to the production of other electric-energy pulses than light.
  • the additional flash device I52 is therefore merely representative of a suitable load device that may be employed in accordance with the present invention under the control of the three-electrode gaseous-conductor device 4, 8, I50.
  • the secondary winding 29 of the transformer 30 is connected to the starting electrode I50.
  • the trip condenser 28 is shown charged from a-second battery I III, through the impedance 3
  • the thyratron I40 and the primary winding 36 of the transformer 34 are connected in the discharge circuit of the trip condenser 28.
  • the resistor 33 shown shunted across the trip condenser 28, allows a small current to flow, in order to maintain upon the control-grid electrode 50 of the thyratron I40 a voltage bias suitably negative with respect to the thyratron cathode 48.
  • the gas pressure or the thyratron I40 is such that the-control electrode "30 loses control over a discharge already passing through the t ratron.
  • the trip circuit functions to discharge the trip condenser 28 through the mercury of the thyratron I 40 when rendered effective and the primary winding 38 0f the flashtransformer 30.
  • the direct-current energy of the second battery IIII becomes thus converted into sudden voltage d pulses in the primary winding.
  • This discharge of the trip condenser 20 is effected at selected intervals, whenever it is desired to produce the flash, under the control of the thyratron grid 50.
  • the potential on the grid 50 is controlled by a switch 32. The instant when the flash occurs is thus accurately timed, without the aid of 7 any switches in the high-voltage circuit.
  • the grid 55 is shown connected to one side of the switch 32 through a small trip condenser 50, which may be as small as 0.00025 microfarad.
  • the other side of the switch 32 is shown connected to the anode 52 of the thyratron 8 30.
  • the grid 50 is connected also to the negative end of the resistor 3! in series with a resistor M2.
  • the resistor M2 serves to limit any current that may tend to flow when the grid 50 becomes positive. I
  • the voltage pulses produced in the primary winding 36 in response tothe discharge of the trip condenser 28 are conveyed, through the sec-- ondary winding 29 of the transformer 30, to the starting electrode I50 of the spark gap to impress a high-potential stimulus thereon.
  • the air in the vicinity of the starting electrode H50, between the principal spark-gap electrodes 4 and B, becoming thereby ionized, the flash condenser 26 discharges suddenly through its discharge circuit.
  • the initiation of the spark or discharge between the principal electrodes 4 and 6 is thus controlled by the control electrode 550 of the trigger circuit.
  • the duration of the flash is of the order of microseconds, as determined by the size of the capacity 26, the voltage towhich it is charged, the dimensions of the spark gap, the impedance of the leads 8 and i0 connecting the condenser 20, and other factors. the flash is less than one microsecond.
  • the energy of the discharging condenser 26, in addition to creating a flash across the triggering spark gap between the principal electrodes 4 and 6, serves also to vaporize the fine wire I52.
  • An additional arc discharge therefore takes place through the metal vapor, the time of occurrence of which is controlled by the spark gap.
  • metals for the wire such as aluminum or magnesium, the are through the vaporized metal may be caused to give considerably more light than can be obtained from the spark gap.
  • Fig. 2 has the further advantage that the wire I52 is isolated by the spark gap from the high direct-current potentials of the condenser 26 and the spark gap except at the instant of flashing. As these high-potential elements may be completely enclosed at some distance from the wire 952, the operator is protected from these high potentials, except at the moment of discharge.
  • a spark gap means connecting the spark gap into the electric circuit, a normally unenergized gaseous-discharge device in series with the spark gap, and means comprising a grid-controlled, gaseous-discharge rectifier tor energizing the gaseous-discharge device.
  • An electric system having, in combination, a condenser, means for charging the condenser, a load, a three-electrode spark gap, a discharge circuit for the condenser including the load and two of the electrodes of the spark ap. and means comprising a grid-controlled rectifier for impressing a voltage upon the third electrode of the spark gap to produce a spark between the said two electrodes, thereby to cause the condenser to discharge through the discharge circuit including the load and the said two electrodes.
  • a flash-producing system having, in combination, a condenser, means for charging the condenser, a flash device, a three-electrode spark gap, a discharge circuit for the condenser including the flash device and two of the electrodes of the spark gap, and means comprising a grid-controlled rectifier for impressing a voltage upon the third electrode oithe spark gap to produce a spark between the said two electrodes, thereby to cause the condenser to discharge through the discharge circuit including the flash device and the said two electrodes.
  • An electric system having, in combination, a normally deionized spark gap, means for normally impressing across the spark gap a voltage insuflicient to produce a spark across the spark gap when the spark gap is deionized but sufiicient to produce a spark across the spark gap when the spark gap is ionized, a normally ineffective gaseous-discharge rectifier having a control electrode and operable when effective to ionize the spark gap, and means for controlling the control electrode to render the rectifier effective to ionize the spark gap in order to enable the impressed voltage to produce a spark across the spark gap.
  • An electric system having, in combination, a normally deionized spark gap, means for normally impressing across the spark gap a voltage insufiicient to produce a spark across the spark gap when the spark gap is deionized but suflicient to product a spark across the spark gap when the spark gap is ionized, a normally ineflective gaseous-discharge rectifier having a control electrode and operable when effective to ionize the spark gap, and means for controlling the control electrode to render the rectifier effective to ionize the spark gap in order to enable the impressed voltage to produce a spark across the spark gap, the gas pressure of the rectifier being such that the control electrode loses control over a discharge already passing through the rectifier.
  • An electric system having, in combination, a normally deionized spark gap, a condenser, a discharge circuit for the condenser connected to the spark gap to produce a spark across the spark gap in response to the discharge of the condenser through the discharge circuit, means for normally charging the condenser in order normally to impress across the spark gap a.
  • a normally lnefiective gaseous-discharge rectifier having a control electrode and operable when effective to ionize the spark gap, and means for controlling the control electrode to render the ram rectifier eflective to ionize the spark gap in order to enable the charged condenser to discharge through the discharge circuit to produce a spark across the spark gap.
  • An electric system having, in combination, a normally deionized spark gap, means for normally impressing across the spark gap a voltage insuii'icient-to produce a spark across the spark gap when the spark gap is deionized but sumcient to produce a spark across the spark gap when the spark gap is ionized, and a trigger circuit comprising a triggering transformer having a primary winding and a normally inefiective secondary winding connected to the spark gap to ionize the spark gap when effective and a gaseous-discharge device having a normally ineflective control electrode, and means for rendering the control electrode effective to produce an electricalimpulse upon the primary winding in order to render the secondary winding efiective to ionize the spark gap in order to enable the impressed voltage to produce a spark across the spark gap.
  • a light-flash producer having, in combination, a normally deionized flash device comprising a three-electrode spark gap between two of the electrodes of which, when the spark gap is ionized, a spark may be produced to produce a flash of light of substantial illumination intensity, the third electrode of the spark gap being disposed substantially between the said two electrodes, a condenser, a discharge circuit for the condenser connected to the said two electrodes to produce the said spark between the said two electrodes in response to the discharge of the condenser through the discharge circuit, means for charging the condenser, and means for impressing a voltage upon the third electrode to ionize the spark gap in order to enable the charged condenser to discharge through the discharge circuit to produce the said spark between the said two electrodes.
  • a light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, a spark gap having two principal electrodes between which the condenser may discharge to produce a light flash of substantial illumination intensity and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the flash device, and means for applying a condenser-discharge-initiating stimulus to the control electrode to effect a sudden discharge of the condenser through the condenser-discharging circuit and the principal electrodes and the flash device to produce a flash of light of substantial illumination intensity between the principal electrodes and a flash of light of substantial illumination intensity through the flash device.
  • a light-flash producer having, in combination, a condenser, a first flash device through which the condensermay discharge to produce a light flash of substantial illumination intensity, a second flash device having two principal electrodes between which the condenser may discharge to produce a light flash of substantial illumination intensity and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the first flash device, and means avenue for applying a condenser-discharge-initiating condenser-discharging circuit and the principal electrodes and the first flash device to produce a flash of light of substantial illumination intensity between the principal electrodes and a flash of light of substantial illumination intensity through the first flash device.
  • 'A light-flash producer having, in combination, a normally deionized flash device comprising a three-electrode spark gap between two of the electrodes ofwvhich, when the spark gap is ionized, a spark may be produced to produce a flash of light of substantial illumination intensity, the third electrode of the spark gap being disposed substantially between'the said two electrodes, a condenser, a discharge circuit for the condenser connected to the said two electrodes to produce the said spark between the said.
  • a triggering transformer having a primary winding and a secondary winding connected to the third electrode, and means for exciting the primary winding in order to impress a voltage upon the third electrode to ionize the spark gap, thereby to enable the charged condenser to discharge through the discharge circuit toproduce the said spark between'the said two electrodes.
  • a light-flash producer having, in combination, a; condenser, a first flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, a second flash device having two principal electrodes between which the condenser may discharge to produce a light flash of substantial illumination intensity and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the first flash device, a triggering transformer having a primary winding and a secondary winding connected to the control electrode, and means for exciting the primary winding in order to apply a condenser-dischargeinitiating stimulus to the control electrode to effect a sudden discharge of the condenser through the condenser-discharging circuit and the printhe principal electrodes and through the load between the load terminalsto produce a pulse of electricenergy in the load when the gaseousconductor device is conductive, and a trip circuit comprising
  • a light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity
  • flash device having two terminals, a normally cipal electrodes and the first flash device to pro- I prise a flash of light of substantial illumination intensity between the principal electrodes and a flash of light of substantial illumination intensity through the first flash device.
  • An electric system having, in combination, a condenser, a load through which the condenser may discharge to produce a pulse of electric energy therein, the load having two terminals, a normally non-conductive gaseous-conductor device having two principal electrodes and a control electrode, a conductor connecting one of the principal electrodes to one of the load terminals, conductors connecting the other principal electrode and the other load terminal to the condenser, a circuit having a source of direct current for charging the condenser to a voltage of magnitude insuflicient to effect a discharge of the condenser through the gaseous-conductor device between the principal electrodes and through the load between the load terminals when the gaseous-conductor device is non-conductive but sufflcient to eflect a discharge of the condenser through the gaseous-conductor device between non-conductive gaseous-conductor device having two principal electrodes and a control electrode, a conductor connecting one of the principal electrodes to one of
  • An electric system having, in combination, a condenser, a load through which the condenser may discharge to produce a pulse of electric energy therein, the load having two terminals, a normally non-conductive gaseous-conductor device having two electrodes, a conductor connecting one of the electrodes to one of the load terminals, conductors connecting the other electrode and the other load terminal to the condenser, a circuit having a source of direct current for charging the condenser, means whereby the condenser is charged by the condenser-charging circuit from the source without producing a substantial pulse in the load during the charging of the condenser, and means for applying a con- 9 through the gaseous-conductor device between the electrodes and through the load between the load terminals to produce a pulse of electric energy in the load.
  • a light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, the flash device having two terminals, a normally non-conductive gaseous-conductor device having two electrodes, a conductor connecting one of the electrodes to one of the flash-device terminals, conductors connecting the other electrode and the other flash-device terminal to the condenser, a circuit having a source of direct current for charging the condenser, and means for applying a condenser-discharge-initiating stimulus to the gaseous-conductor device to render the gaseousconductor device suddenly conductive in order to eilect a sudden discharge of the condenser through the gaseous-conductor device between the electrodes and through the flash device between the flash-device terminals to produce a flash of light of substantial illumination intensity.
  • An electric system having, in combination, a condenser, a load through which the condenser may discharge to produce a pulse of electric energy therein, a spark gap having two principal electrodes and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the load, and means for applying a condenser-discharge-initiating stimulus to the control electrode to effect a sudden discharge of the condenser through the condenser-discharging circuit and the principal electrodes and the load to produce a pulse of electric energy in the load.
  • a light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, a spark gap having two principal electrodes and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes.

Description

Aug. 1949- H. E. EDGERTON 2,478,906
ELECTRIC SYSTEM Original Filed Aug. 16, 1933 INVENTOR.
HAROLD E. EDGERTON ATTORNEY Patented Aug. 16, 1949 UNITED STATES PATENT OFFICE arias memo srs'rsm Harold E. Edger-ton, Belmont, Mass.
Original application August 10, 193:. Serial No. 885,501. Divided and this applloation octobes- 2, 1946, Serial No. 700.639
19 Claims. (Cl. m-n' The present invention, though having fields of more general usefulness in electric systems, is particularly related to electric-energy flash-producing or other pulse-producing systems in which the discharge of a condenser is employed for such purposes as to produce a single light flash or a single electric-energy pulse or a repetition of light flashes or electric-energy pulses of short duration and high intensity. The present application is filed in response to a requirement for division in application, Serial No. 685,501, flied August 16, 1933.
It has heretofore been proposed to initiate the discharge of the condenser by sending a spark through a two-electrode spark gap connected in series with the condenser and the light-flash device. A system of this character would ofler the advantage that it would do away with the necessity for employing the large flash devices that are complicated by the presence of high-voltage triggering or starting electrodes. To send a spark through the two-electrode spark gap, however, has involved difficulties that have rendered the system impracticable.
An object of the preesnt invention, therefore, is to provide a new and improved electric system of the above-described character that shall overcome these difficulties.
In the said application, there is disclosed a new and improved electric system for producing strong and intense substantially uniform pulses of electric energy by discharging a condenser quickly, reliably and accurately at high frequency through a gaseous-conductor device. This system is simple and rugged in construction, light in weight, portable and self contained, easily operable, without moving parts (except, in some cases, for a contactor), and thoroughly effective and reliable in operation. v
An object of the present invention is to provide a new and improved electric system or the above-described character for producing light flashes or other pulses of electric energy.
In the said application, Serial No. 685,501, the source of the light flashes is disclosed as a threeelectrode gaseous-conductor device. A further object of the present invention, on the other hand, is to provide a new and improved system of the above-described character in which a three-electrode gaseous-conductor device may serve as a control for a load, disclosed specifically as a two-terminal flash-producing device.
Other and further objects will be explained hereinafter and will be particularly pointed out in the appended claims.
The invention will now be more fully explained in connection with the accompanying drawings, in which Fig. 1 is a diagrammatic view of circuits and apparatus illustrating one embodiment of the invention according to which the flash is provided by a three-electrode spark ap to the exclusion of any additional flash device; and Fig. 2 is a similar view illustrating a preferred embodiment of the invention, according to which the flash, provided chiefly by a flash device, is augmented by the flash of a three-electrode spark gap.
A three-electrode spark gap or other gaseousdischarge device is shown comprising two principal electrodes l and i and a starting triggering or control electrode III disposed substantially between .the principal electrodes 4 and t. The principal electrodes 4 and 6 are connected by wire conductors l and II to a source of direct current, in parallel with a flash condenser or capacitor 26. The source of direct current is shown in Fig. 2 as constituted of a battery I02. As shown in Fig. 1, however, the direct current may be supplied from any desired source of aiternating energy of suitable voltage and frequency through a transformer Ill. The primary winding I of the transformer I48 is connected to the alternating-current source, and the secondary winding in, through a thermionic or gaseous-discharge rectifier II, to the condenser 28.
A current-llmitin-g charging impedance 35 may be series-connected in the charging circuit of the condenser 20, either in the wire conductor in, as illustrated in Fig. l, or the wire conductor 8, as shown in Fig. 2. The condenser 26 may be charged to a volta e of from 200 to 2000 volts. The principal electrodes 4 and G of the threeelectrode spark gap are series-connected in the discharge circuit of the condenser 26. The flashes are produced by discharging the condenser 26, after it has become charged, through the air between the principal electrodes 4 and 8 of the spark gap.
A simple inexpensive triggering three-electrode spark gap is thus procided for efllciently handling the necessarily high-peak-discharge currents. The noise of operation may be reduced by enclosing the spark gap in a noise-proof chamber.
Because of the dielectric properties of the normally deionized air in the space between the spark-gap electrodes I and i, the direct-current source will charge the condenser 16 through the impedance ll without any of itsenergy traversing that space. A diflerence of potential will therefore be established between the spark-gap electrodes 4 and 8 during the charging of the condenser 26 before each flash. The impedance 35 should be designed suiflciently large so that, after the creation of the spark between the principal electrodes 4 and 5, further current flow be= tween them will be prevented until after the air of this gap shall have again become deionized. The impedance 35 should, however, be small. enough to permit of the condenser 26 becomin recharged with energy from the d rect-current source in time for the next flash.
The series-connected discharge circuit comprising the condenser 26 and the'spark gap may include also an additional flash device I52, shown in Fig. 2 as a small fine two-terminal conducting wire. The flash device I52 may provide the principal or chief light of the flash, of substantial illumination intensity but the light from the three-electrode spark gap may itself be quite substantial to augment the flash of the flash device I52. The quantity of light in the flash is determined by the amount of energy in the condenser 26 and by circuit conditions.
A conductor is shown connecting theprlncipal electrode 6 to one of the terminals of the additional flash device I52. The conductor I connects the other terminal of the additional flash device I52 to one side of the battery I02. The conductor 8 connects the principal electrode 4 to the other side of the battery I02.
The invention is not, 01' course, restricted to use with the two-terminal conductive wire I52. This two-terminal conductive wire I52 is quite emcient for the production of light flashes, but the invention is equally applicable to the production of other electric-energy pulses than light. The additional flash device I52 is therefore merely representative of a suitable load device that may be employed in accordance with the present invention under the control of the three-electrode gaseous-conductor device 4, 8, I50.
I40, two impedances 3| and 33, shown as resistors, and a small trip condenser 23. The secondary winding 29 of the transformer 30 is connected to the starting electrode I50. The trip condenser 28 is shown charged from a-second battery I III, through the impedance 3|, which may perform a function similar to that of the impedance 35. The thyratron I40 and the primary winding 36 of the transformer 34 are connected in the discharge circuit of the trip condenser 28. The resistor 33, shown shunted across the trip condenser 28, allows a small current to flow, in order to maintain upon the control-grid electrode 50 of the thyratron I40 a voltage bias suitably negative with respect to the thyratron cathode 48. The gas pressure or the thyratron I40 is such that the-control electrode "30 loses control over a discharge already passing through the t ratron.
The trip circuit functions to discharge the trip condenser 28 through the mercury of the thyratron I 40 when rendered effective and the primary winding 38 0f the flashtransformer 30. The direct-current energy of the second battery IIII becomes thus converted into sudden voltage d pulses in the primary winding. This discharge of the trip condenser 20 is effected at selected intervals, whenever it is desired to produce the flash, under the control of the thyratron grid 50. The potential on the grid 50, in turn, is controlled by a switch 32. The instant when the flash occurs is thus accurately timed, without the aid of 7 any switches in the high-voltage circuit.
The grid 55 is shown connected to one side of the switch 32 through a small trip condenser 50, which may be as small as 0.00025 microfarad. The other side of the switch 32 is shown connected to the anode 52 of the thyratron 8 30. The grid 50 is connected also to the negative end of the resistor 3! in series with a resistor M2. The resistor M2 serves to limit any current that may tend to flow when the grid 50 becomes positive. I
The voltage pulses produced in the primary winding 36 in response tothe discharge of the trip condenser 28 are conveyed, through the sec-- ondary winding 29 of the transformer 30, to the starting electrode I50 of the spark gap to impress a high-potential stimulus thereon. The air in the vicinity of the starting electrode H50, between the principal spark-gap electrodes 4 and B, becoming thereby ionized, the flash condenser 26 discharges suddenly through its discharge circuit. The initiation of the spark or discharge between the principal electrodes 4 and 6 is thus controlled by the control electrode 550 of the trigger circuit. A very large current, over one thousand amperes, thereupon surges through between the principal electrodes 4 and 6 of the spark gap, producing a verybrilliant quick flash of light of substantial illumination intensity, concentrated in a small space. The duration of the flash is of the order of microseconds, as determined by the size of the capacity 26, the voltage towhich it is charged, the dimensions of the spark gap, the impedance of the leads 8 and i0 connecting the condenser 20, and other factors. the flash is less than one microsecond.
According to the embodiment of the invention illustrated by Fig. 2, the energy of the discharging condenser 26, in addition to creating a flash across the triggering spark gap between the principal electrodes 4 and 6, serves also to vaporize the fine wire I52. An additional arc discharge therefore takes place through the metal vapor, the time of occurrence of which is controlled by the spark gap. With suitable choice of metals for the wire, such as aluminum or magnesium, the are through the vaporized metal may be caused to give considerably more light than can be obtained from the spark gap.
The arrangement of Fig. 2 has the further advantage that the wire I52 is isolated by the spark gap from the high direct-current potentials of the condenser 26 and the spark gap except at the instant of flashing. As these high-potential elements may be completely enclosed at some distance from the wire 952, the operator is protected from these high potentials, except at the moment of discharge.
Further modifications will occur to persons Iskilled in the art, and all such are considered Under some conditions, the duration of 2. In an electric circuit, a spark gap, means connecting the spark gap into the electric circuit, a normally unenergized gaseous-discharge device in series with the spark gap, and means comprising a grid-controlled, gaseous-discharge rectifier tor energizing the gaseous-discharge device.
3. An electric system having, in combination, a condenser, means for charging the condenser, a load, a three-electrode spark gap, a discharge circuit for the condenser including the load and two of the electrodes of the spark ap. and means comprising a grid-controlled rectifier for impressing a voltage upon the third electrode of the spark gap to produce a spark between the said two electrodes, thereby to cause the condenser to discharge through the discharge circuit including the load and the said two electrodes.
4. A flash-producing system having, in combination, a condenser, means for charging the condenser, a flash device, a three-electrode spark gap, a discharge circuit for the condenser including the flash device and two of the electrodes of the spark gap, and means comprising a grid-controlled rectifier for impressing a voltage upon the third electrode oithe spark gap to produce a spark between the said two electrodes, thereby to cause the condenser to discharge through the discharge circuit including the flash device and the said two electrodes.
5. An electric system having, in combination, a normally deionized spark gap, means for normally impressing across the spark gap a voltage insuflicient to produce a spark across the spark gap when the spark gap is deionized but sufiicient to produce a spark across the spark gap when the spark gap is ionized, a normally ineffective gaseous-discharge rectifier having a control electrode and operable when effective to ionize the spark gap, and means for controlling the control electrode to render the rectifier effective to ionize the spark gap in order to enable the impressed voltage to produce a spark across the spark gap.
'6. An electric system having, in combination, a normally deionized spark gap, means for normally impressing across the spark gap a voltage insufiicient to produce a spark across the spark gap when the spark gap is deionized but suflicient to product a spark across the spark gap when the spark gap is ionized, a normally ineflective gaseous-discharge rectifier having a control electrode and operable when effective to ionize the spark gap, and means for controlling the control electrode to render the rectifier effective to ionize the spark gap in order to enable the impressed voltage to produce a spark across the spark gap, the gas pressure of the rectifier being such that the control electrode loses control over a discharge already passing through the rectifier.
7. An electric system having, in combination, a normally deionized spark gap, a condenser, a discharge circuit for the condenser connected to the spark gap to produce a spark across the spark gap in response to the discharge of the condenser through the discharge circuit, means for normally charging the condenser in order normally to impress across the spark gap a. voltage insuflicient to eflect its discharge through the discharge circuit when the spark gap is deionized but suflficient to effect its discharge through the discharge circuit when the spark gap is ionized, a normally lnefiective gaseous-discharge rectifier having a control electrode and operable when effective to ionize the spark gap, and means for controlling the control electrode to render the ram rectifier eflective to ionize the spark gap in order to enable the charged condenser to discharge through the discharge circuit to produce a spark across the spark gap.
8. An electric system having, in combination, a normally deionized spark gap, means for normally impressing across the spark gap a voltage insuii'icient-to produce a spark across the spark gap when the spark gap is deionized but sumcient to produce a spark across the spark gap when the spark gap is ionized, and a trigger circuit comprising a triggering transformer having a primary winding and a normally inefiective secondary winding connected to the spark gap to ionize the spark gap when effective and a gaseous-discharge device having a normally ineflective control electrode, and means for rendering the control electrode effective to produce an electrical impuse upon the primary winding in order to render the secondary winding efiective to ionize the spark gap in order to enable the impressed voltage to produce a spark across the spark gap.
9. A light-flash producer having, in combination, a normally deionized flash device comprising a three-electrode spark gap between two of the electrodes of which, when the spark gap is ionized, a spark may be produced to produce a flash of light of substantial illumination intensity, the third electrode of the spark gap being disposed substantially between the said two electrodes, a condenser, a discharge circuit for the condenser connected to the said two electrodes to produce the said spark between the said two electrodes in response to the discharge of the condenser through the discharge circuit, means for charging the condenser, and means for impressing a voltage upon the third electrode to ionize the spark gap in order to enable the charged condenser to discharge through the discharge circuit to produce the said spark between the said two electrodes.
10. A light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, a spark gap having two principal electrodes between which the condenser may discharge to produce a light flash of substantial illumination intensity and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the flash device, and means for applying a condenser-discharge-initiating stimulus to the control electrode to effect a sudden discharge of the condenser through the condenser-discharging circuit and the principal electrodes and the flash device to produce a flash of light of substantial illumination intensity between the principal electrodes and a flash of light of substantial illumination intensity through the flash device.
11. A light-flash producer having, in combination, a condenser, a first flash device through which the condensermay discharge to produce a light flash of substantial illumination intensity, a second flash device having two principal electrodes between which the condenser may discharge to produce a light flash of substantial illumination intensity and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the first flash device, and means avenue for applying a condenser-discharge-initiating condenser-discharging circuit and the principal electrodes and the first flash device to produce a flash of light of substantial illumination intensity between the principal electrodes and a flash of light of substantial illumination intensity through the first flash device.
12. 'A light-flash producer having, in combination, a normally deionized flash device comprising a three-electrode spark gap between two of the electrodes ofwvhich, when the spark gap is ionized, a spark may be produced to produce a flash of light of substantial illumination intensity, the third electrode of the spark gap being disposed substantially between'the said two electrodes, a condenser, a discharge circuit for the condenser connected to the said two electrodes to produce the said spark between the said. two
electrodes in response to the discharge of the condenser through the discharge circuit, means for charging the condenser, a triggering transformer having a primary winding and a secondary winding connected to the third electrode, and means for exciting the primary winding in order to impress a voltage upon the third electrode to ionize the spark gap, thereby to enable the charged condenser to discharge through the discharge circuit toproduce the said spark between'the said two electrodes.
13. A light-flash producer having, in combination, a; condenser, a first flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, a second flash device having two principal electrodes between which the condenser may discharge to produce a light flash of substantial illumination intensity and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the first flash device, a triggering transformer having a primary winding and a secondary winding connected to the control electrode, and means for exciting the primary winding in order to apply a condenser-dischargeinitiating stimulus to the control electrode to effect a sudden discharge of the condenser through the condenser-discharging circuit and the printhe principal electrodes and through the load between the load terminalsto produce a pulse of electricenergy in the load when the gaseousconductor device is conductive, and a trip circuit comprising a discharge device, means for con-' necting the discharge device to the control electrode, means for impressing an impulse upon the discharge device, meanscontrolled by the discharge device in response to the impulse for producing a sudden violent electrical transient impulse, and means for transmitting the transient impulse to .the control electrode to render the gaseous-conductor device suddenly conductive in order to efiect a discharge of the condenser through the gaseous-conductor device between the principal electrodes and through the load between the load terminals to produce a pulse of electric energy in the load.
15. A light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, the
, flash device having two terminals, a normally cipal electrodes and the first flash device to pro- I duce a flash of light of substantial illumination intensity between the principal electrodes and a flash of light of substantial illumination intensity through the first flash device.
14. An electric system having, in combination, a condenser, a load through which the condenser may discharge to produce a pulse of electric energy therein, the load having two terminals, a normally non-conductive gaseous-conductor device having two principal electrodes and a control electrode, a conductor connecting one of the principal electrodes to one of the load terminals, conductors connecting the other principal electrode and the other load terminal to the condenser, a circuit having a source of direct current for charging the condenser to a voltage of magnitude insuflicient to effect a discharge of the condenser through the gaseous-conductor device between the principal electrodes and through the load between the load terminals when the gaseous-conductor device is non-conductive but sufflcient to eflect a discharge of the condenser through the gaseous-conductor device between non-conductive gaseous-conductor device having two principal electrodes and a control electrode, a conductor connecting one of the principal electrodes to one of the flash-device terminals, conductors connecting the other principal electrode and the other flash-device terminal to the condenser a circuit having a source of direct current for charging the condenser to a voltage of magni tude insufficient to effect a discharge of the condenser through the gaseous-conductor device between the principal electrodes and through the flash device between the flash-device terminals when the gaseous-conductor device is non-conductive but suflicient to effect a discharge of the condenser through the-gaseous-conductor device between the principal electrodes and through the flash device between the flash-device terminals to produce a light flash when the gaseous-conductor device is conductive and a trip circuit comprising a discharge device, means connecting the discharge device to the control electrode, means for impressing an impulse upon the discharge device, means controlled by the discharge device in response to the impulse for producing a sudden violent electrical transient impulse, and means for transmitting the transient impulse to the control electrode to render the gaseous-conductor device suddenly conductive in order to eiTect a discharge of the condenser through the gaseous-conductor device between the principal electrodes and through the flash device between the flash-device terminals to produce a light flash of substantial illumination intensity.
16. An electric system having, in combination, a condenser, a load through which the condenser may discharge to produce a pulse of electric energy therein, the load having two terminals, a normally non-conductive gaseous-conductor device having two electrodes, a conductor connecting one of the electrodes to one of the load terminals, conductors connecting the other electrode and the other load terminal to the condenser, a circuit having a source of direct current for charging the condenser, means whereby the condenser is charged by the condenser-charging circuit from the source without producing a substantial pulse in the load during the charging of the condenser, and means for applying a con- 9 through the gaseous-conductor device between the electrodes and through the load between the load terminals to produce a pulse of electric energy in the load.
17. A light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, the flash device having two terminals, a normally non-conductive gaseous-conductor device having two electrodes, a conductor connecting one of the electrodes to one of the flash-device terminals, conductors connecting the other electrode and the other flash-device terminal to the condenser, a circuit having a source of direct current for charging the condenser, and means for applying a condenser-discharge-initiating stimulus to the gaseous-conductor device to render the gaseousconductor device suddenly conductive in order to eilect a sudden discharge of the condenser through the gaseous-conductor device between the electrodes and through the flash device between the flash-device terminals to produce a flash of light of substantial illumination intensity.
18. An electric system having, in combination, a condenser, a load through which the condenser may discharge to produce a pulse of electric energy therein, a spark gap having two principal electrodes and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes and the load, and means for applying a condenser-discharge-initiating stimulus to the control electrode to effect a sudden discharge of the condenser through the condenser-discharging circuit and the principal electrodes and the load to produce a pulse of electric energy in the load.
19. A light-flash producer having, in combination, a condenser, a flash device through which the condenser may discharge to produce a light flash of substantial illumination intensity, a spark gap having two principal electrodes and a control electrode disposed substantially between the principal electrodes, a circuit having a source of direct current for charging the condenser, a discharging circuit for the condenser connected to the principal electrodes.
and the flash device, and means for applying a condenser-discharge-initiating stimulus to the control electrode to efiect a sudden discharge of the condenser through the condenser-discharging circuit and the principal electrode and the flash device to produce a flash of light of substantial illumination intensity.
HAROLD E. EDGERTON.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Great Britain July 24, 1938
US700639A 1933-08-16 1946-10-02 Electric system Expired - Lifetime US2478906A (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
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US2689928A (en) * 1949-02-17 1954-09-21 Products & Licensing Corp Process for lighting ionic tubes, particularly tubes with auxiliary priming electrodes
US3151428A (en) * 1961-11-03 1964-10-06 Phillips Petroleum Co Automatic impulse heat sealing
US3166704A (en) * 1961-03-22 1965-01-19 Jansons Arnolds Servo mechanism transient and velocity error compensation means
US3248633A (en) * 1962-11-23 1966-04-26 John J Guarrera Circuit for controlling electromechanical load
US3281719A (en) * 1964-11-03 1966-10-25 Edgerton Germeshausen & Grier Microwave switching apparatus utilizing breakdown gaps triggered by direct current control pulse and radio frequency power level

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US1586524A (en) * 1916-12-29 1926-06-01 Western Electric Co Constant frequency system
US1684108A (en) * 1921-10-22 1928-09-11 Thomas E Murray Electric welding
US1738464A (en) * 1929-01-26 1929-12-03 Gen Electric Cathode-ray oscillograph control
US1745830A (en) * 1927-04-01 1930-02-04 Bethenod Joseph Method for ignition on combustion engines
US2030228A (en) * 1936-02-11 Spark generating system
GB450939A (en) * 1935-01-24 1936-07-24 Wassily Tarassoff Improvements in and relating to electric welding apparatus
US2147472A (en) * 1937-08-20 1939-02-14 Westinghouse Electric & Mfg Co High current impulse device
US2405069A (en) * 1942-02-23 1946-07-30 Gen Electric Pulse generating system

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Publication number Priority date Publication date Assignee Title
US2030228A (en) * 1936-02-11 Spark generating system
US1586524A (en) * 1916-12-29 1926-06-01 Western Electric Co Constant frequency system
US1684108A (en) * 1921-10-22 1928-09-11 Thomas E Murray Electric welding
US1745830A (en) * 1927-04-01 1930-02-04 Bethenod Joseph Method for ignition on combustion engines
US1738464A (en) * 1929-01-26 1929-12-03 Gen Electric Cathode-ray oscillograph control
GB450939A (en) * 1935-01-24 1936-07-24 Wassily Tarassoff Improvements in and relating to electric welding apparatus
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US2405069A (en) * 1942-02-23 1946-07-30 Gen Electric Pulse generating system

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2689928A (en) * 1949-02-17 1954-09-21 Products & Licensing Corp Process for lighting ionic tubes, particularly tubes with auxiliary priming electrodes
US3166704A (en) * 1961-03-22 1965-01-19 Jansons Arnolds Servo mechanism transient and velocity error compensation means
US3151428A (en) * 1961-11-03 1964-10-06 Phillips Petroleum Co Automatic impulse heat sealing
US3248633A (en) * 1962-11-23 1966-04-26 John J Guarrera Circuit for controlling electromechanical load
US3281719A (en) * 1964-11-03 1966-10-25 Edgerton Germeshausen & Grier Microwave switching apparatus utilizing breakdown gaps triggered by direct current control pulse and radio frequency power level

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