US3311784A - Preignition prevention in ignitrons by delayed application to the auxiliary anode - Google Patents

Preignition prevention in ignitrons by delayed application to the auxiliary anode Download PDF

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US3311784A
US3311784A US323719A US32371963A US3311784A US 3311784 A US3311784 A US 3311784A US 323719 A US323719 A US 323719A US 32371963 A US32371963 A US 32371963A US 3311784 A US3311784 A US 3311784A
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cathode
ignitor
circuit
anode
potential
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Louis A Casanova
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CBS Corp
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Westinghouse Electric Corp
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M1/00Details of apparatus for conversion
    • H02M1/02Circuits specially adapted for the generation of grid-control or igniter-control voltages for discharge tubes incorporated in static converters

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  • a preignition breakdown may be an are from some element of the ignitron tube, such as grids, shields or auxiliary anode, to some other surface within the tube, such as the tube wall, prior to ignition of the cathode spot by the ignitor.
  • Preign-ition breakdown in addition to causing loss of control of the ignitron tube, also materially aids deterioration of the tube due to sputtering of the surface to which the breakdown are occurs, causing the surface to vaporize and deposit the ingredients of the vapor on the tube elements.
  • Preignition breakdown causes further problems when utilizing control circuits in which the ignitron grid means are released or made positive by coupling a signal into the grid circuit from one of the other tube elements, such as an auxiliary anode, when said other tube element conducts.
  • a signal into the grid circuit from one of the other tube elements, such as an auxiliary anode
  • conduction of the auxiliary anode prior to the ignition of the cathode spot would prematurely release the ignitron grids.
  • Another object of this invention is to provide a new and improved control circuit for ignitron rectifiers which precludes release of the ignitron grids prior to initiation of the cathode spot or electron emission from the cathode.
  • Another object of this invention is to provide a new and improved control circuit for ignitron rectifiers in which the application of voltage to one element of the ignitron is dependent upon current flow through the ignitor plus the collapsing voltage characteristic of the ignitor circuit.
  • control or switching means such as a thyratron or silicon controlled rectifier, connected in series circuit relation with the element of the rectifier tube which is not to be energized until after establishment of a cathode spot on the pool cathode.
  • the switching means receives its switching signal from current flow through the ignitorv circuit, with an overriding signal responsive to the voltage characteristic of the ignitor circuit preventing application of the switching signals to the switching means until the ignitor has initiated a cathode spot, More specifically, when a current pulse is applied to the ignitor circuit, the voltage of the ignitor circuit increases until a cathode spot is initiated, at which time the voltage of the ignitor circuit collapses or is reduced to the voltage drop across the are.
  • the rising voltage characteristic of the ignitor circuit is utilized, in combination with saturable core means, to prevent the current flow through theignitor circuit from producing a switching signal.
  • the ignitor When the ignitor establishes a cathode spot, the ignitor voltage collapses, and the ignitor current flow is then allowed to produce 'a signal which switches the switching means from its nonconducting state to a conducting state, which allows a potential to be applied to the series connected tube element. Current flow through the series connected tube element may then be used to release the grids or overcome the negative bias applied to the grids, thus allowing the tubes to conduct electrons from its pool cathode to the main anode.
  • the single figure illustrates an ignitiontype mercury-arc rectifier It) and an associated control circuit 12, which incorporates the teachings of this invention.
  • a source of alternating potential, represented by conductors 26 and 27, and a load circuit 28, are shown connected in series circuit relation in the anode 14- cathode 16 circuit of the ignitron 10. 27 is illustrated for purposes of simplicity as being a single phase circuit.
  • this invention is, in general, applicable to all of them.
  • a cathode spot is initiated on the mercury pool cathode 16 by means of an ignitor 18, at a predetermined time during the positive voltage half cycle.
  • a current pulse or signal is applied to the ignitor 18', a high voltage gradient is established at the point where the ignitor 18 enters the pool cathode 16, initiating electron emission and estab- 1 lishing a cathode spot.
  • the cathode spot is usually established in 10 to microseconds after the current pulse enters the pool cathode.
  • an auxiliary or holding anode such as auxiliary anode 20, may be used to maintain the cathode spot after the ignitor current peak has subsided, for the remaining portion of the positive voltage half cycle.
  • the auxiliary anode 20 will maintain the cathode spot for low values of anode current and when the voltage magnitude of the alternating supply potential from conductors 26 and 27 is less than the back voltage of the vapor are.
  • the ignitron grids 22 and 24 keep the anode 14 from conducting prematurely, by setting up a negative potential around it which precludes electrons from the cathode 16 or other surfaces within the ignitron, from being attracted to the anode 14. In order to initiate conduction of the ignitron 10, the grids 22 and 24 must be made sufiiciently positive to allow electrons from the cathode 16 to flow to the anode 14 upon initiation of the cathode spot.
  • the negative bias or unidirectional potential may be developed by first obtaining the proper magnitude of alternating potential through a secondary winding 21 of a control transformer 23, which has a primary winding 31 connected to alternating potential conductors 2 6 and 27. This alternating potential may then be rectified in a bridge rectifier 29, with the negative bias being applied through an adjustable resistor 30 to the grids 22 and 24, through limiting resistors 32 and 34, respectively. In order to overcome the negative bias applied to grids 22 and 24 at the proper time, a voltage responsive to current flow through the auxiliary anode 20 may 'be produced across resistor 36.
  • Resistor 36 is connected in circuit relation with secondary winding 40 of control transformer 23, which provides an alternating potential of the desired magnitude having the instantaneous polarity shown in the figure.
  • a coupling transformer 42 having a winding 44 connected across resistor 36, and a winding 46 connected in series circuit relation with resistor 30 and grids 22 and 24, may be used.
  • the potential produced in winding 46 of coupling transformer 42 overcomes the negative bias applied to grids 22 and 24, making the grids 22 and 24 sufficiently positive to allow conduction between the cathode 16 and anode 14.
  • Capacitors 48 and may be connected from the grids 22 and 24, respectively, to the cathode 16 in order to insure that the potential of the grids 22 and 24 follows the cathode potential during sudden changes.
  • auxiliary anode 20 an alternating potential from winding 40 of transformer 23 is appliedto auxiliary anode 20. If the alternating potential is applied to the auxiliary anode 20 during the complete positive half cycle, however, serious problems may be encountered. In certain applications or conditions, the auxiliary anode 20 may establish an arc to some surface within the ignitron tube prior to initiation of the cathode spot on the cathode. 16. An are from the auxiliary anode to the casing or wall of the ignitron 10, or other elements within the ignitron 10, causes sputtering and release of undesirable vapors which coat the anode 14 and other elements, causing deterioration of the ignitron tube 10.
  • the grids 22 and 24 are released upon current flow in the auxiliary anode circuit, as illustrated in the figure, they will be released or made positive prior to the firing of the ignitron, causing precise control over conduction of the ignitron 10 to be lost.
  • a control or switching means having two main electrodes and a control electrode, such as a thyratron or, as illustrated, a controlled rectifier 50, may be utilized.
  • A-controlled rectifier 50 such as a solid state, semiconductor silicon controlled rectifier, having an anode electrode a, a cathode electrode c, and gate or control electrode g, is connected between the auxiliary anode 20 and the alternating potential from winding of transformer 23, with its cathode 0 being connected to auxiliary anode 20 and its anode a being connected to resistor 36.
  • silicon controlled rectifiers have the characteristic of blocking current in their forward direction until a certain voltage magnitude is reached. This voltage magnitude may be sharply reduced by applying a positive current pulse to its gate electrode -g.
  • the controlled rectifier may be utilized as a switch, with the switch being normally open and a gate signal being applied to close it. When the alternating current applied to the controlled rectifier reaches zero or voltage reversal, the controlled rectifier will turn off and another gate signal is required during the next positive voltage half cycle to turn on, or close the switch again.
  • Firing circuit 60 A firing current pulse for firing or initiating the cathode spot on cathode 16 may be applied to the ignitor 18 from firing means or firing circuit 60.
  • Firing circuit 60 is described in detail in US. Patent 3,030,550, issued Apr. 17, 1962 to G. Smeltzer and assigned to the same assignee as the present invention. However, it is obvious that any conventional firing circuit may be utilized.
  • Firing circuit 60 comprises an energy device, illustrated in this instance as a capacitor 61. The capacitor 61 is charged to a predetermined value in the direction indicated by the plus sign in the figure through a charging circuit which may be a secondary winding 63 on control transformer 23.
  • the secondary winding 63 of transformer 23 is connected in series circuit relation with a charging resistor 65, a diode 67, and the capacitor 61.
  • the diode 67 is poled to charge the capacitor 61 to a predetermined value in the direction indicated by the plus mark in the figure.
  • the capacitor 61 is connected through a pulse shaping inductance 69, a switching means 71, and the ignitor 18-cathode 16 0f the ignitron 10.
  • the cathode 16 of the ignitron '10 is connected back to capacitor 61 through conductor 73.
  • the semiconductor device 71 may be a controlled rectifier or any other three element semiconductor device which may be switched to a conducting state or a nonconducting state.
  • the device 71 may be switched to its conducting state by some suitable switching source, which has been indicated generally at 77. It is to be understood that any suitable switching device such as a thyratron or other device may be substituted for the semiconductor switching device 71.
  • the switching source 77 is a timed switching source which may be a conventional sawtooth generator, and it serves to switch the device 71 on in timed relationship with respect to the phase of the alternating current of the supply energy at the proper time to cause the capacitor 61 to discharge through the ignitor 18-cathode 16 circuit of the ignitron 10.
  • Switching sources such as 77 are conventional in the art.
  • the device 71 is switched to its nonconducting state when the total current through the ignitor 18-cathode 16 becomes Zero.
  • a resistor 79 is connected across the ignitor 18- cathode 16 circuit.
  • a semiconductor rectifier 81 is connected across the capacitor 61. It can be seen that the rectifier 81 is poled in the opposite direction to the charg ing rectifier 67.
  • capacitor 61 is charged to a predetermined value from the alternating current supply lines 26 and 27 through the secondary winding 63 of transformer 23, the charging resistor 65, and the rectifier 67.
  • the switching device 71 is in its nonconducting or open state.
  • the switching source 77 applies a switching potential to the semiconductor device 71 to switch the device 71 to its conducting state.
  • the capacitor 61 then discharges through the pulse shaping inductance 69, the switching device 71, the ignitor 18-cathode 16 circuit, and the conductor 73.
  • the current builds up an opposite charge on capacitor 61.
  • the capacitor 61 discharges through the diode 81 and the pulse shaping inductance 69 and starts building up a positive charge on the capacitor 61 in the direction necessary to provide the next pulse for firing the ignitron. Consequently, it is only necessary for the charging circuit to provide the additional energy which is lost in the ignitor IS-cathode 16 circuit to build up a positive charge on the capacitor 61 to the predetermined magnitude in the proper direction to provide the next pulse.
  • the rectifier 67 is poled to prevent capacitor 61 from discharging back to the charging circuit before the ignitor 18-cathode cirf Cult fires.
  • the resistor 79 which shunts the ignitor 18- cathode 16 circuit and also shunts the capacitor 21 is a stabilizing resistor and enables capacitor 61 to discharge in case the ignitor 14 misfires.
  • a firing current pulse from firing circuit 60 may be utilized to develop a gate signal for controlled rectifier 50 which will turn controlled rectifier 50 on, or change it from its high impedance state to a very low impedance state.
  • the positive current pulse necessary to gate the controlled rectifier 50 may be developed by utilizing a saturable current transformer 70, having a winding 72 responsive to the flow of current in the ignitor circuit, and 'a winding 74, having the instantaneous polarity shown, connected from the gate electrode g to the cathode electrode c of controlled rectifier 50, which develops a potential which will make the gate electrode g more posi tive than the cathode electrode c.
  • the windings 72 and 74 are inductively disposed on a saturable magnetic core 75.
  • Resistor 76 holds the voltage across Winding 74 within the desired range; unidirectional device, such as a semiconductor diode 78, ensures that current will flow in the proper direction in the gate circuit; and, capacitor 80 prevents damaging surge voltages from being applied to the gate-cathode junction.
  • the cathode spot is not immediately produced upon flow of ignitor current, with its initiation usually varying in the range of 10 to 150 microseconds after start of the ignitor current.
  • the controlled rectifier 50 were to be turned on as soon as the ignitor current pulse is applied to the ignitor 18, the controlled rectifier 50 would be prematurely triggered, and voltage would be applied to auxiliary anode 20 before initiation of the cathode spot.
  • the ignitor voltage increases until a cathode spot is initiated, at which time the voltage collapses or falls to the arc value.
  • the drop in ignitor voltage which signifies the beginning of the cathode spot, is precisely the time when it is desired that potential be applied to the auxiliary anode 20.
  • This voltage characteristic of the ignitor circuit may be utilized by placing the winding or coil 82 on core 75 of saturable current transformer 70, with winding 82 being connected from the ignitor 18 to the cathode 16 through current limiting resistor 84.
  • winding 82 keeps core 75 saturated, and winding 74 is unable to apply a gating signal to the gate g of controlled rectifier 50.
  • the ignitor voltage rapidly drops to the arc voltage and core 75 drops out of saturation, allowing winding 74 to produce a signal which renders controlled rectifier 50 conductive.
  • Resistor 90 from the cathode electrode of controlled rectifier 50 provides a keep alive path to conductor 73 to maintain controlled rectifier 50 in its conducting state until an arc is established from auxiliary anode 20 to cathode 16.
  • Capacitor 102 suppresses voltage spikes and transients.
  • controlled rectifier 50 When the cathode spot on cathode 16 is initiated, controlled rectifier 50 is rendered conductive, applying a potential to auxiliary anode 20. Auxiliary anode 20 then establishes an arc to the cathode spot on the cathode 16.
  • the current'fiow from secondary winding 40 through controlled rectifier 50 to auxiliary anode 20 produces a voltage drop across the resistor 36, which is coupled into the grid circuit, overcoming the negative bias applied to grids 22 and 24, allowing conduction to be initiated from the cathode 16 to the anode 14 of ignitron 10.
  • the voltage or anode 14 becomes negative and the cathode spot disappears, rendering ignitron 10 nonconductive.
  • the controlled rectifier also becomes nonconductive when the positive voltage half-cycle falls to zero, and the grids 22 and 24 regain control. Sometime during the current starts until the cathode spot is established; winding 74 applies a gating signal to controlled rectifier 50 when the cathode spot is initiated; the auxiliary anode establishes an arc to the cathode 16; and the grids are made positive in response to current flow in the auxiliary anode circuit, allowing conduction to take place through the ignitron 10.
  • preignition of the auxiliary anode it is not possible for preignition of the auxiliary anode to occur, as voltage is not applied to the auxiliary anode 20 until a cathode spot has been initiated on cathode 16.
  • the grids 22 and 24 to prematurely become positive and thus lose control over the anode 14, as the negative bias applied to grids 22 and 24 is not overcome until current flows in the auxiliary anode circuit.
  • the invention disclosed herein precludes preignition of any of the elements of an ignitron rectifier and also prevents premature releasing of the grids.
  • a control circuit constructed and arranged according to the prin ciples of this invention will extend the use of the ignitron to entirely new applications and Widen the range of voltage control, in addition to extending the life of the ignitron used on conventional applications by preventing an occasional preigintion and the tube deterioration which accompanies it.
  • a control circuit for rectifier tubes of the type having a plurality of electrodes including a cathode and an ignitor comprising a source of potential, switching means having two main electrodes and a control electrode, the main electrodes of said switching means being connected in series circuit relation with one of the electrodes of said rectifier tube and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode, and means connected in circuit relation with said ignitor and the control electrode of said switching means for producing a second signal when electron emission from said cathode is initiated, said second signal changing said switching means from its nonconducting to its conducting state and electrically connecting said source of potential with the electrode of said rectifier tube connected to said switching means.
  • a control circuit for rectifier tubes of the type hav: ing a plurality of electrodes including a cathode and ignitor, comprising a source of potential, switching means having two main electrodes and a control electrode, the main electrodes of said switching means being connected in series circuit relation with one of the electrodes of said rectifier tube and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode, and means connected in circuit relation with said ignitor and the control electrode of said switching means for producing a second signal responsive to the current and collapsing voltage characteristic of said ignitor when electron emission from said cathode is established, said second signal changing said switching means trode of said rectifier tube connected to said switching means.
  • a control circuit for rectifier tubes of the type having a plurality of electrodes including a cathode and an ignitor comprising a source of potential, switching means having two main electrodes and a control electrode, the main electrodes of said switching means being connected in series circuit relation with one of the electrodes of said rectifier tubes and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode, and saturable core means comprising first, second, and third windings disposed in inductive relation With a saturable magnetic core, the first winding of said saturable core means being connected in circuit relation with said firing means and said ignitor, the second winding of said saturable core means being connected in circuit relation with the control electrode of said switching means, the third winding of said saturable core means being connected from the ignitor to the cathode of said rectifier tube, said third winding saturating said saturable magnetic core when said firing means applies
  • a rectifier tube of the type having an anode, cathode, ignitor, auxiliary anode, and grid means; a source of negative unidirectional potential connected in circuit relation with said grid means; a source of alternating potential; a load circuit; said source of alternating potential, load circuit, anode, and cathode being connected in series circuit relation; switching means having two main electrodes and a control electrode; the main electrodes of said switching means being connected in series circuit relation with the auxiliary anode of said rectifier tube and said source of alternating potential; firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode; means connected in circuit relation with said ignitor and the control electrode of said switching.
  • grid means allowing electrons to flow from said cathode to said anode through said load circuit.
  • a rectifier tube of the type having an anode, pool cathode, ignitor, auxiliary anode, and grid means; a source of negative unidirectional potential connected in circuit relation With said grid means; a
  • saturable core means comprising first, second, and third windings disposed in inductive relation with a saturable magnetic core; the first Winding of said saturable core means being connected in circuit relation with said firing means and said ignitor; the second winding of saturable core means being connected in circuit relation with the control electrode of said switching means; the third winding of said saturable core means being connected from the ignitor to the cathode of said rectifier tube; said third winding saturating said saturable magnetic core when said firing means applies the first signal to
  • a control circuit for rectifier tubes of the type having a plurality of electrodes including a cathode and ignitor comprising a source of potential, a silicon controlled rectifier having two main electrodes and a control electrode, the main electrodes of said silicon controlled rectifier being connected in series circuit relation with one of the electrodes of said rectifier tube and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating a cathode spot on said cathode, and means connected in circuit relation with said ignitor and the control electrode of said silicon control rectifier for producing a second signal responsive to the current and collapsing voltage characteristic of said ignitor when electron emission from said cathode is established, said second signal changing said silicon controlled rectifier from its nonconducting to its conducting state and electrically connecting'said source of potential With the electrode of said rectifier connected to said switching means.

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Description

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March 28, 1967 L. A. CASANOVA PREIGNITION PREVENTION IN IGNITRONS BY DELAYE APPLICATION TO THE AUXILIARY ANODE Filed Nov. 14, 1965 SWITCHING SOURCE INVENTOR ouis A. Casanova ZwLJXW y A TORNEY WITNESSES United States Patent 3,311,784 PREIGNiTlON PREVENTION IN IGNITRONS BY DELAYED APPLECATHON T0 vTHIE AUXILIARY ANODE Louis A. Casanova, Willrinsburg, Pa., assignor to Westinghouse Electric Corporation, East Pittsburgh, Pa., a corporation of Pennsylvania Filed Nov. 14, 1963, Ser. No. 323,719 6 Claims. (Cl. 315-262) This invent-ion relates in general to electrical control circuits and more particularly to electrical control circuits for mercury-arc type rectifiers.
Mercury-arc type rectifier tubes, of the type having a single main anode, a pool-type cathode, and an ignitor to initiate a cathode spot or electron emission prior to each conducting period, commonly called ignitrons, have not been utilized on certain applications requiring a wide range of voltage control due to an excessive rate of preignition breakdowns. A preignition breakdown may be an are from some element of the ignitron tube, such as grids, shields or auxiliary anode, to some other surface within the tube, such as the tube wall, prior to ignition of the cathode spot by the ignitor. Preign-ition breakdown, in addition to causing loss of control of the ignitron tube, also materially aids deterioration of the tube due to sputtering of the surface to which the breakdown are occurs, causing the surface to vaporize and deposit the ingredients of the vapor on the tube elements.
Preignition breakdown causes further problems when utilizing control circuits in which the ignitron grid means are released or made positive by coupling a signal into the grid circuit from one of the other tube elements, such as an auxiliary anode, when said other tube element conducts. Thus, if the ignitron grids are released by a signal coupled into the grid circuit when the auxiliary anode conducts, conduction of the auxiliary anode prior to the ignition of the cathode spot would prematurely release the ignitron grids.
Accordingly, it is an object of this invention to provide a new and improved control circuit for mercury arc rectifiers.
Another object of this invention is to provide a new and improved control circuit for ignitron rectifiers which precludes release of the ignitron grids prior to initiation of the cathode spot or electron emission from the cathode.
A further object of this invention is to provide a new and improved control circuit for ignitron rectifiers which eliminates preignition of any of the elements of the ignitron.
Another object of this invention is to provide a new and improved control circuit for ignitron rectifiers in which the application of voltage to one element of the ignitron is dependent upon current flow through the ignitor plus the collapsing voltage characteristic of the ignitor circuit.
Briefly, the present invention accomplishes the above cited objects by providing control or switching means, such as a thyratron or silicon controlled rectifier, connected in series circuit relation with the element of the rectifier tube which is not to be energized until after establishment of a cathode spot on the pool cathode. The switching means receives its switching signal from current flow through the ignitorv circuit, with an overriding signal responsive to the voltage characteristic of the ignitor circuit preventing application of the switching signals to the switching means until the ignitor has initiated a cathode spot, More specifically, when a current pulse is applied to the ignitor circuit, the voltage of the ignitor circuit increases until a cathode spot is initiated, at which time the voltage of the ignitor circuit collapses or is reduced to the voltage drop across the are. The rising voltage characteristic of the ignitor circuit is utilized, in combination with saturable core means, to prevent the current flow through theignitor circuit from producing a switching signal. When the ignitor establishes a cathode spot, the ignitor voltage collapses, and the ignitor current flow is then allowed to produce 'a signal which switches the switching means from its nonconducting state to a conducting state, which allows a potential to be applied to the series connected tube element. Current flow through the series connected tube element may then be used to release the grids or overcome the negative bias applied to the grids, thus allowing the tubes to conduct electrons from its pool cathode to the main anode.
Further objects and advantages of the invention will become apparent as the following description proceeds and features of novelty which characterize the invention will be pointed out in particularity in the claims annexed to. and forming a part of this specification.
For a better understanding of the invention, reference may be had to the accompanying drawing in which the single figure is a schematic diagram illustrating a control circuit incorporating the teachings of this invention.
Referring now to the drawing, the single figure illustrates an ignitiontype mercury-arc rectifier It) and an associated control circuit 12, which incorporates the teachings of this invention. trates an ignitron type mercury-arc rectifier 10 and an ignitor 13, auxiliary anode 20, 'and grid means including grids 22 and 24, all disposed within a casing 25. A source of alternating potential, represented by conductors 26 and 27, and a load circuit 28, are shown connected in series circuit relation in the anode 14- cathode 16 circuit of the ignitron 10. 27 is illustrated for purposes of simplicity as being a single phase circuit. However, it is well known in the art that there are many other possible connect-ions in which ignitrons may be used, and this invention is, in general, applicable to all of them.
In the operation of an ignitron, a cathode spot is initiated on the mercury pool cathode 16 by means of an ignitor 18, at a predetermined time during the positive voltage half cycle. When a current pulse or signal is applied to the ignitor 18', a high voltage gradient is established at the point where the ignitor 18 enters the pool cathode 16, initiating electron emission and estab- 1 lishing a cathode spot. The cathode spot is usually established in 10 to microseconds after the current pulse enters the pool cathode. Once the cathode spot is initiated, an auxiliary or holding anode such as auxiliary anode 20, may be used to maintain the cathode spot after the ignitor current peak has subsided, for the remaining portion of the positive voltage half cycle. The auxiliary anode 20 will maintain the cathode spot for low values of anode current and when the voltage magnitude of the alternating supply potential from conductors 26 and 27 is less than the back voltage of the vapor are.
When the cathode spot is initiated on cathode 16, if the auxiliary anode 20 has a positive potential applied to it, an arc will be established from the auxiliary anode 20 to the cathode 16, with electrons flowing from the cathode 16 to the auxiliary anode 20.
The ignitron grids 22 and 24 keep the anode 14 from conducting prematurely, by setting up a negative potential around it which precludes electrons from the cathode 16 or other surfaces within the ignitron, from being attracted to the anode 14. In order to initiate conduction of the ignitron 10, the grids 22 and 24 must be made sufiiciently positive to allow electrons from the cathode 16 to flow to the anode 14 upon initiation of the cathode spot. When the cathode spot is initiated, current will fiow through the auxiliary anode circuit, and this current The ignitron 16, as illus- The alternating current circuit 26 and flow may be used to develop a potential which will overcome the negative bias applied to the grids 22 and 24 and allow electrons from the cathode 16 to flow to the main anode 14.
More specifically, the negative bias or unidirectional potential, may be developed by first obtaining the proper magnitude of alternating potential through a secondary winding 21 of a control transformer 23, which has a primary winding 31 connected to alternating potential conductors 2 6 and 27. This alternating potential may then be rectified in a bridge rectifier 29, with the negative bias being applied through an adjustable resistor 30 to the grids 22 and 24, through limiting resistors 32 and 34, respectively. In order to overcome the negative bias applied to grids 22 and 24 at the proper time, a voltage responsive to current flow through the auxiliary anode 20 may 'be produced across resistor 36. Resistor 36 is connected in circuit relation with secondary winding 40 of control transformer 23, which provides an alternating potential of the desired magnitude having the instantaneous polarity shown in the figure. In order to reflect the potential produced across resistor 36 by current fiow therethrough, a coupling transformer 42 having a winding 44 connected across resistor 36, and a winding 46 connected in series circuit relation with resistor 30 and grids 22 and 24, may be used. The potential produced in winding 46 of coupling transformer 42 overcomes the negative bias applied to grids 22 and 24, making the grids 22 and 24 sufficiently positive to allow conduction between the cathode 16 and anode 14. Capacitors 48 and may be connected from the grids 22 and 24, respectively, to the cathode 16 in order to insure that the potential of the grids 22 and 24 follows the cathode potential during sudden changes.
As hereinbefore stated, an alternating potential from winding 40 of transformer 23 is appliedto auxiliary anode 20. If the alternating potential is applied to the auxiliary anode 20 during the complete positive half cycle, however, serious problems may be encountered. In certain applications or conditions, the auxiliary anode 20 may establish an arc to some surface within the ignitron tube prior to initiation of the cathode spot on the cathode. 16. An are from the auxiliary anode to the casing or wall of the ignitron 10, or other elements within the ignitron 10, causes sputtering and release of undesirable vapors which coat the anode 14 and other elements, causing deterioration of the ignitron tube 10. Further, if the grids 22 and 24 are released upon current flow in the auxiliary anode circuit, as illustrated in the figure, they will be released or made positive prior to the firing of the ignitron, causing precise control over conduction of the ignitron 10 to be lost.
In order to prevent preignition of the auxiliary anode 20, with the accompanying sputtering and pre-release of the grids 22 and 24, a control or switching means having two main electrodes and a control electrode, such as a thyratron or, as illustrated, a controlled rectifier 50, may be utilized. A-controlled rectifier 50, such as a solid state, semiconductor silicon controlled rectifier, having an anode electrode a, a cathode electrode c, and gate or control electrode g, is connected between the auxiliary anode 20 and the alternating potential from winding of transformer 23, with its cathode 0 being connected to auxiliary anode 20 and its anode a being connected to resistor 36. As is well known in the art, silicon controlled rectifiers have the characteristic of blocking current in their forward direction until a certain voltage magnitude is reached. This voltage magnitude may be sharply reduced by applying a positive current pulse to its gate electrode -g. Thus, the controlled rectifier may be utilized as a switch, with the switch being normally open and a gate signal being applied to close it. When the alternating current applied to the controlled rectifier reaches zero or voltage reversal, the controlled rectifier will turn off and another gate signal is required during the next positive voltage half cycle to turn on, or close the switch again.
A firing current pulse for firing or initiating the cathode spot on cathode 16 may be applied to the ignitor 18 from firing means or firing circuit 60. Firing circuit 60 is described in detail in US. Patent 3,030,550, issued Apr. 17, 1962 to G. Smeltzer and assigned to the same assignee as the present invention. However, it is obvious that any conventional firing circuit may be utilized. Firing circuit 60 comprises an energy device, illustrated in this instance as a capacitor 61. The capacitor 61 is charged to a predetermined value in the direction indicated by the plus sign in the figure through a charging circuit which may be a secondary winding 63 on control transformer 23. It can be seen from the figure that the secondary winding 63 of transformer 23 is connected in series circuit relation with a charging resistor 65, a diode 67, and the capacitor 61. The diode 67 is poled to charge the capacitor 61 to a predetermined value in the direction indicated by the plus mark in the figure. The capacitor 61 is connected through a pulse shaping inductance 69, a switching means 71, and the ignitor 18-cathode 16 0f the ignitron 10. The cathode 16 of the ignitron '10 is connected back to capacitor 61 through conductor 73.
The semiconductor device 71 may be a controlled rectifier or any other three element semiconductor device which may be switched to a conducting state or a nonconducting state. The device 71 may be switched to its conducting state by some suitable switching source, which has been indicated generally at 77. It is to be understood that any suitable switching device such as a thyratron or other device may be substituted for the semiconductor switching device 71. The switching source 77 is a timed switching source which may be a conventional sawtooth generator, and it serves to switch the device 71 on in timed relationship with respect to the phase of the alternating current of the supply energy at the proper time to cause the capacitor 61 to discharge through the ignitor 18-cathode 16 circuit of the ignitron 10. Switching sources such as 77 are conventional in the art. The device 71 is switched to its nonconducting state when the total current through the ignitor 18-cathode 16 becomes Zero. A resistor 79 is connected across the ignitor 18- cathode 16 circuit. A semiconductor rectifier 81 is connected across the capacitor 61. It can be seen that the rectifier 81 is poled in the opposite direction to the charg ing rectifier 67.
In the operation of firing circuit 60, capacitor 61 is charged to a predetermined value from the alternating current supply lines 26 and 27 through the secondary winding 63 of transformer 23, the charging resistor 65, and the rectifier 67. During the charging of the capacitor 61 to the predetermined value, the switching device 71 is in its nonconducting or open state. After the capacitor 61 has been charged to its predetermined value in the positive direction as indicated by the plus mark in the figure, the switching source 77 applies a switching potential to the semiconductor device 71 to switch the device 71 to its conducting state. The capacitor 61 then discharges through the pulse shaping inductance 69, the switching device 71, the ignitor 18-cathode 16 circuit, and the conductor 73. Thus, the current builds up an opposite charge on capacitor 61. As soon as the total current in the igniter IS-cathode 16 circuit becomes zero,v the capacitor 61 discharges through the diode 81 and the pulse shaping inductance 69 and starts building up a positive charge on the capacitor 61 in the direction necessary to provide the next pulse for firing the ignitron. Consequently, it is only necessary for the charging circuit to provide the additional energy which is lost in the ignitor IS-cathode 16 circuit to build up a positive charge on the capacitor 61 to the predetermined magnitude in the proper direction to provide the next pulse. The rectifier 67 is poled to prevent capacitor 61 from discharging back to the charging circuit before the ignitor 18-cathode cirf Cult fires. The resistor 79 which shunts the ignitor 18- cathode 16 circuit and also shunts the capacitor 21 is a stabilizing resistor and enables capacitor 61 to discharge in case the ignitor 14 misfires.
A firing current pulse from firing circuit 60 may be utilized to develop a gate signal for controlled rectifier 50 which will turn controlled rectifier 50 on, or change it from its high impedance state to a very low impedance state. The positive current pulse necessary to gate the controlled rectifier 50 may be developed by utilizing a saturable current transformer 70, having a winding 72 responsive to the flow of current in the ignitor circuit, and 'a winding 74, having the instantaneous polarity shown, connected from the gate electrode g to the cathode electrode c of controlled rectifier 50, which develops a potential which will make the gate electrode g more posi tive than the cathode electrode c. The windings 72 and 74 are inductively disposed on a saturable magnetic core 75. Resistor 76 holds the voltage across Winding 74 within the desired range; unidirectional device, such as a semiconductor diode 78, ensures that current will flow in the proper direction in the gate circuit; and, capacitor 80 prevents damaging surge voltages from being applied to the gate-cathode junction.
However, as hereinbeforestated, the cathode spot is not immediately produced upon flow of ignitor current, with its initiation usually varying in the range of 10 to 150 microseconds after start of the ignitor current. Thus, if the controlled rectifier 50 were to be turned on as soon as the ignitor current pulse is applied to the ignitor 18, the controlled rectifier 50 would be prematurely triggered, and voltage would be applied to auxiliary anode 20 before initiation of the cathode spot. In order to eliminate the possibility of this premature appearance of potential on auxiliary anode 20, use is made of the voltage characteristic of the ignitor circuit. When a current pulse is applied to the ignitor 18, the ignitor voltage increases until a cathode spot is initiated, at which time the voltage collapses or falls to the arc value. The drop in ignitor voltage, which signifies the beginning of the cathode spot, is precisely the time when it is desired that potential be applied to the auxiliary anode 20. This voltage characteristic of the ignitor circuit may be utilized by placing the winding or coil 82 on core 75 of saturable current transformer 70, with winding 82 being connected from the ignitor 18 to the cathode 16 through current limiting resistor 84. As long as the ignitor 18 has a rising voltage characteristic, winding 82 keeps core 75 saturated, and winding 74 is unable to apply a gating signal to the gate g of controlled rectifier 50. Once a cathode spot has been initiated, the ignitor voltage rapidly drops to the arc voltage and core 75 drops out of saturation, allowing winding 74 to produce a signal which renders controlled rectifier 50 conductive. Resistor 90 from the cathode electrode of controlled rectifier 50 provides a keep alive path to conductor 73 to maintain controlled rectifier 50 in its conducting state until an arc is established from auxiliary anode 20 to cathode 16. Capacitor 102 suppresses voltage spikes and transients.
When the cathode spot on cathode 16 is initiated, controlled rectifier 50 is rendered conductive, applying a potential to auxiliary anode 20. Auxiliary anode 20 then establishes an arc to the cathode spot on the cathode 16. The current'fiow from secondary winding 40 through controlled rectifier 50 to auxiliary anode 20 produces a voltage drop across the resistor 36, which is coupled into the grid circuit, overcoming the negative bias applied to grids 22 and 24, allowing conduction to be initiated from the cathode 16 to the anode 14 of ignitron 10. At the conclusion of the positive voltage half cycle, the voltage or anode 14 becomes negative and the cathode spot disappears, rendering ignitron 10 nonconductive. The controlled rectifier also becomes nonconductive when the positive voltage half-cycle falls to zero, and the grids 22 and 24 regain control. Sometime during the current starts until the cathode spot is established; winding 74 applies a gating signal to controlled rectifier 50 when the cathode spot is initiated; the auxiliary anode establishes an arc to the cathode 16; and the grids are made positive in response to current flow in the auxiliary anode circuit, allowing conduction to take place through the ignitron 10. Thus, it is not possible for preignition of the auxiliary anode to occur, as voltage is not applied to the auxiliary anode 20 until a cathode spot has been initiated on cathode 16. Further, it is not possible for the grids 22 and 24 to prematurely become positive and thus lose control over the anode 14, as the negative bias applied to grids 22 and 24 is not overcome until current flows in the auxiliary anode circuit.
While the illustration used herein shows the application of potential to the auxiliary anode 20 after initiation of the cathode spot, it is obvious that the switching means or controlled rectifier 50 could be placed in series circuit relation with any element of the ignitron where it is not desirable to have voltage appear until after the cathode spot has been established.
The invention disclosed herein precludes preignition of any of the elements of an ignitron rectifier and also prevents premature releasing of the grids. Thus, a control circuit constructed and arranged according to the prin ciples of this invention will extend the use of the ignitron to entirely new applications and Widen the range of voltage control, in addition to extending the life of the ignitron used on conventional applications by preventing an occasional preigintion and the tube deterioration which accompanies it.
Since numerous changes may be made in the abovedescribed apparatus and different embodiments of the invention may be made without departing from. the spirit thereof, it is intended that all matter contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative, and not in a limiting sense.
I claim as my invention:
1. A control circuit for rectifier tubes of the type having a plurality of electrodes including a cathode and an ignitor, comprising a source of potential, switching means having two main electrodes and a control electrode, the main electrodes of said switching means being connected in series circuit relation with one of the electrodes of said rectifier tube and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode, and means connected in circuit relation with said ignitor and the control electrode of said switching means for producing a second signal when electron emission from said cathode is initiated, said second signal changing said switching means from its nonconducting to its conducting state and electrically connecting said source of potential with the electrode of said rectifier tube connected to said switching means.
2. A control circuit for rectifier tubes of the type hav: ing a plurality of electrodes including a cathode and ignitor, comprising a source of potential, switching means having two main electrodes and a control electrode, the main electrodes of said switching means being connected in series circuit relation with one of the electrodes of said rectifier tube and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode, and means connected in circuit relation with said ignitor and the control electrode of said switching means for producing a second signal responsive to the current and collapsing voltage characteristic of said ignitor when electron emission from said cathode is established, said second signal changing said switching means trode of said rectifier tube connected to said switching means.
1 3. A control circuit for rectifier tubes of the type having a plurality of electrodes including a cathode and an ignitor, comprising a source of potential, switching means having two main electrodes and a control electrode, the main electrodes of said switching means being connected in series circuit relation with one of the electrodes of said rectifier tubes and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode, and saturable core means comprising first, second, and third windings disposed in inductive relation With a saturable magnetic core, the first winding of said saturable core means being connected in circuit relation with said firing means and said ignitor, the second winding of said saturable core means being connected in circuit relation with the control electrode of said switching means, the third winding of said saturable core means being connected from the ignitor to the cathode of said rectifier tube, said third winding saturating said saturable magnetic core when said firing means applies the first signal to said ignitor until electron emission from said cathode is initiated, said second winding producing a second signal in response to the current flow produced in said first winding by said first signal when said saturable magnetic core drops out of saturation, said second signal changing said switching means from its nonconducting to its conducting state and electrically connecting said source of potential with the electrode of said rectifier tube connected to said switching means.
4. I11 combination, a rectifier tube of the type having an anode, cathode, ignitor, auxiliary anode, and grid means; a source of negative unidirectional potential connected in circuit relation with said grid means; a source of alternating potential; a load circuit; said source of alternating potential, load circuit, anode, and cathode being connected in series circuit relation; switching means having two main electrodes and a control electrode; the main electrodes of said switching means being connected in series circuit relation with the auxiliary anode of said rectifier tube and said source of alternating potential; firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode; means connected in circuit relation with said ignitor and the control electrode of said switching. means for producing a second signal responsive to the current and collapsing voltage characteristic of said ignitor when electron emission from said cathode is established; said second signal changing said switching means from its nonconducting to its conducting state and electrically connecting said source of alternating potential with the auxiliary anode of said rectifier tube, causing electrons to flow from said cathode to said auxiliary anode; and means responsive to electron flow from said cathode to said auxiliary anode connected in circuit relation with said grid means producing a positive potential overcoming the negative potential applied to said.
grid means allowing electrons to flow from said cathode to said anode through said load circuit.
5. In combination, a rectifier tube of the type having an anode, pool cathode, ignitor, auxiliary anode, and grid means; a source of negative unidirectional potential connected in circuit relation With said grid means; a
source of alternating potential; a load circuit; said source of alternating potential, load circuit, anode, and cathode being connected in series circuit relation; switching means having two main electrodes and a control electrode; the main electrodes of said switching means being connected in series circuit relation with the auxiliary anode of said rectifier tube and said source of alternating potential; firing means connected in circuit relation with said ignitor providing a first signal for initiating electron emission from said cathode; saturable core means comprising first, second, and third windings disposed in inductive relation with a saturable magnetic core; the first Winding of said saturable core means being connected in circuit relation with said firing means and said ignitor; the second winding of saturable core means being connected in circuit relation with the control electrode of said switching means; the third winding of said saturable core means being connected from the ignitor to the cathode of said rectifier tube; said third winding saturating said saturable magnetic core when said firing means applies the first signal to said ignitor, until electron emission from said cathode is initiated; said second winding producing a second signal in response to the current flow produced in said first winding by said first signal when said saturable magnetic core drops out of saturation; said second signal changing said switching means from its nonconducting to its conducting state and electrically connecting said source of alternating potential with the auxiliary anode of said rectifier tube, causing electrons to flow from said cathode to said auxiliary anode; and means responsive to electron flow from said cathode to said auxiliary anode connected in circuit relation with said grid means, producing a positive potential overcoming the negative potential applied to said grid means, allowing electrons to flow from said cathode to said anode through said load circuit.
6. A control circuit for rectifier tubes of the type having a plurality of electrodes including a cathode and ignitor, comprising a source of potential, a silicon controlled rectifier having two main electrodes and a control electrode, the main electrodes of said silicon controlled rectifier being connected in series circuit relation with one of the electrodes of said rectifier tube and said source of potential, firing means connected in circuit relation with said ignitor providing a first signal for initiating a cathode spot on said cathode, and means connected in circuit relation with said ignitor and the control electrode of said silicon control rectifier for producing a second signal responsive to the current and collapsing voltage characteristic of said ignitor when electron emission from said cathode is established, said second signal changing said silicon controlled rectifier from its nonconducting to its conducting state and electrically connecting'said source of potential With the electrode of said rectifier connected to said switching means.
References Cited by the Examiner UNITED STATES PATENTS Boyer et al. 315-262 X JAMES W. LAWRENCE, Primary Examiner.
C. R. CAMPBELL, Assistant Examiner.

Claims (1)

  1. 4. IN COMBINATION, A RECTIFIER TUBE OF THE TYPE HAVING AN ANODE, CATHODE, IGNITOR, AUXILIARY ANODE, AND GRID MEANS; A SOURCE OF NEGATIVE UNIDIRECTIONAL POTENTIAL CONNECTED IN CIRCUIT RELATION WITH SAID GRID MEANS; A SOURCE OF ALTERNATING POTENTIAL; A LOAD CIRCUIT; SAID SOURCE OF ALTERNATING POTENTIAL, LOAD CIRCUIT, ANODE, AND CATHODE BEING CONNECTED IN SERIES CIRCUIT RELATION; SWITCHING MEANS HAVING TWO MAIN ELECTRODES AND A CONTROL ELECTRODE; THE MAIN ELECTRODES OF SAID SWITCHING MEANS BEING CONNECTED IN SERIES CIRCUIT RELATION WITH THE AUXILIARY ANODE OF SAID RECTIFIER TUBE AND SAID SOURCE OF ALTERNATING POTENTIAL; FIRING MEANS CONNECTED IN CIRCUIT RELATION WITH SAID IGNITOR PROVIDING A FIRST SIGNAL FOR INITIATING ELECTRON EMISSION FROM SAID CATHODE; MEANS CONNECTED IN CIRCUIT RELATION WITH SAID IGNITOR AND THE CONTROL ELECTRODE OF SAID SWITCH-
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3424972A (en) * 1965-09-09 1969-01-28 Asea Ab Device for transmitting control pulses to a rectifier
US4074202A (en) * 1975-10-28 1978-02-14 English Electric Valve Co., Ltd. Biasing circuit for thyratron
US4131826A (en) * 1977-08-03 1978-12-26 General Electric Company Triggering circuit for triggered vacuum gaps
EP3364533A1 (en) * 2017-02-17 2018-08-22 General Electric Technology GmbH Improvements in or relating to gate drivers for gas tubes

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1959201A (en) * 1931-03-25 1934-05-15 Gen Electric Electric discharge apparatus
US2083133A (en) * 1934-11-05 1937-06-08 Allis Chalmers Mfg Co Electric valve system
US2431903A (en) * 1940-12-05 1947-12-02 Gen Electric Electric control circuits
US2441987A (en) * 1944-07-07 1948-05-25 Westinghouse Electric Corp Excitation system for vapor electric valves

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1959201A (en) * 1931-03-25 1934-05-15 Gen Electric Electric discharge apparatus
US2083133A (en) * 1934-11-05 1937-06-08 Allis Chalmers Mfg Co Electric valve system
US2431903A (en) * 1940-12-05 1947-12-02 Gen Electric Electric control circuits
US2441987A (en) * 1944-07-07 1948-05-25 Westinghouse Electric Corp Excitation system for vapor electric valves

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3424972A (en) * 1965-09-09 1969-01-28 Asea Ab Device for transmitting control pulses to a rectifier
US4074202A (en) * 1975-10-28 1978-02-14 English Electric Valve Co., Ltd. Biasing circuit for thyratron
US4131826A (en) * 1977-08-03 1978-12-26 General Electric Company Triggering circuit for triggered vacuum gaps
EP3364533A1 (en) * 2017-02-17 2018-08-22 General Electric Technology GmbH Improvements in or relating to gate drivers for gas tubes
WO2018149629A1 (en) * 2017-02-17 2018-08-23 General Electric Technology Gmbh Improvements in or relating to gate drivers for gas tubes

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