US2056376A - Voltage multiplier - Google Patents

Voltage multiplier Download PDF

Info

Publication number
US2056376A
US2056376A US668102A US66810233A US2056376A US 2056376 A US2056376 A US 2056376A US 668102 A US668102 A US 668102A US 66810233 A US66810233 A US 66810233A US 2056376 A US2056376 A US 2056376A
Authority
US
United States
Prior art keywords
rectifiers
load
source
circuit
alternating current
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US668102A
Inventor
Travis Charles
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
RCA Corp
Original Assignee
RCA Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by RCA Corp filed Critical RCA Corp
Priority to US668102A priority Critical patent/US2056376A/en
Application granted granted Critical
Publication of US2056376A publication Critical patent/US2056376A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • 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
    • H02M7/00Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
    • H02M7/02Conversion of ac power input into dc power output without possibility of reversal
    • H02M7/04Conversion of ac power input into dc power output without possibility of reversal by static converters
    • H02M7/06Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes without control electrode or semiconductor devices without control electrode
    • H02M7/10Conversion of ac power input into dc power output without possibility of reversal by static converters using discharge tubes without control electrode or semiconductor devices without control electrode arranged for operation in series, e.g. for multiplication of voltage
    • H02M7/103Containing passive elements (capacitively coupled) which are ordered in cascade on one source

Definitions

  • the present invention relates generally to voltage multipliers and more particularly to so-called transformerless voltage multipliers and rectifiers.
  • the present invention is primarily directed toward devising a circuit arrangement and method of feeding the A. C. into the rectifiers in such a way that the A. C. does not come across the load with the result that conventional filter circuits may be utilized.
  • Fig. 1 is a schematic diagram utilized to explain certain features of the invention in connection with an odd number of rectifiers in series;
  • FIG. 2 is a more complete diagram of the system shown in Fig. 1;
  • Fig- 3 illustrates the invention applied to a system utilizing an even number of rectifiers
  • Fig. 4 shows in diagrammatic form a voltage quadrupler connected in accordance with the in- Vention
  • Fig. 5 illustrates a voltage quadrupler utilizing a particular type of rectifier tube.
  • a load L is shown connected in a circuit with seven rectifiers R1R7.
  • the two phases are herein designated for convenience as phase a and phase I).
  • the two ends of the load are designated to be at phase a.
  • the rectifiers must, of course, form a series chain with the load, and the problem is then to find how the rectifiers may be excited while observing the foregoing condition, namely, having both ends of the load at the same phase. With an odd number of rectifiers as shown in Figs.
  • each rectifier R1R7 is fed through a condenser feed branch the condensers of which are preferably of the electrolytic type and are indicated as C1-C7 in the drawing.
  • FIG. 3 For the case where an even number of rectifiers are employed reference to Fig. 3 is made.
  • an even' number of rectifiers RIR6 are connected in series with a load L.
  • the A. C. line or source cannot be in series with the chain of rectifiers and fulfill the aforementioned conditions, namely, the avoidance of the A. C. line across the load.
  • the A. C. source in the case of an even number of rectifiers is shunted through condensers across each rectifier while the I). C. path does not include the source.
  • the A. C. the A. C.
  • the D. C. path comprises rectifiers R1'R6 and load L.
  • condenser C4 may be omitted and a direct connection made to the b line without interfering with the operation of the system, however, for evident reasons such as undetermined grounded lines in the A. C. system it is best to provide the condenser C4.
  • path may include the A. C. source while for an even number of rectifiers the D. C. path does not include the A. C. source.
  • A. C. is never connected across the load directly and furthermore a filter of the usual condenser first type may be employed.
  • a voltage quadrupler' is shown as comprising four rectifiers R1R4 forming a D ...C. chain with a load L. Since there are an even number of rectifiers the A. C. source cannot be connected in the D. C. chain, hence, the A. C. source is connected across the various rectifiers through condenser branch circuits. It should be noted that the terminal a of the A. C. line is connected directly to the rectifier-load chain at the point P. It is to be understood, however, that connection through a condenser is the better practice for the reasons pointed out previously in connection with the description of condenser C4 of Fig. 3.
  • a filter condenser C may be inserted directly across the load without danger of short circuiting the A. C. source.
  • a source of alternating current a load circuit, a rectifier assembly comprising an even number of rectifiers, said number being greater than two, said load and rectifiers being connected so as to form a series circuit, means for exciting each of said rectifiers with alternating current comprising capacitive branch circuits for connecting each rectifier across said source of alternating current, said branch circuits being connected with respect to the load so that both ends of the load are, in effect, connected to the same terminal of the alternating current source whereby both ends of the load are maintained at substantially the same alternating current potential with respect to the alternating current source.
  • a voltage multiplier circuit comprising a direct current closed path including an even number of rectifiers greater than two and a load cirrent potential and capacitive paths for connecting each of said rectifiers across the source of alternating current.
  • a uni-directional direct current closed circuit comprising an even number of rectifiers greater than two and said source in series, means for connecting each of said rectifiers across said source of alternating current including at least one capacitive element and means for maintaining both ends of said load at the same alternating current potential comprising connections from both ends of the load to only one terminal of the alternating current source.
  • a voltage multiplier circuit of the type comprising a plurality of rectifiers, the number thereof being an .even number greater than two forming a closed D. C. series circuit including the load, the method of energizing the rectifiers with alternating current which comprises impressing the alternating current across each rectifier separately while maintaining both ends of the load at the same A. C. source voltage.
  • a voltage quadrupler circuit comprising four rectifiers connected in series with a load circuit, said rectifiers and load forming a closed unidirectional direct-current path, a source of alternating current, means for connecting each of said rectifiers across said source, said means including at least one condenser, means for connecting both ends of said load circuit to only one side of said alternating current source, the connection of said source side to each end of the load including at least one condenser, and a filter condenser shunted directly across the load circuit.
  • an alternating. current source including two line conductors, a load circuit, a rectifier assembly comprising a plurality of rectifiers connected in series with the load, means for separately exciting each of said rectifiers comprising aplurality of circuits each including at least one capacitive element for connecting each of the rectifiers across the source, the capacitive elements of all of said means being arranged in two sets, the elements in each set being inmultiple, one of said sets .being cone nected to one of said conductors while the other set is connected to the other conductor.
  • a rectifier assembly comprising an even number of rectifiers greater than two and a load, said rectifiers and load forming a series closed circuit, a source of exciting current for said rectifiers including two line conductors, capacitive connections between 76 one of said line conductors and alternate junction points of successive rectifiers in said series circuit, capacitive connections between the other line conductor and the junction points in said series circuit of successive rectifiers not connected to the first named line conductor, the capacitive connection between the line conductor and the junction point of the two successive rectifiers having the load circuit between them, including capacitive connections from said line conductor to both sides of the load.
  • a rectifier assembly comprising an even number of rectifiers greater than two and a load circuit, said rectifiers and load circuit being connected so as to form a series closed circuit, a source of exciting current for said rectifiers including two line conductors, connections between one of said line conductors and alternate junction points of successive rectifiers in said series circuit, connections between the other line conductor and the junction points in said series circuit of successive rectifiers not already connected to the first named line conductor, at least all but one of said connections being made through a capacitive element, the connection between the line conductor and the junction point of those two successive rectifiers having the load circuit between them, including connections from said line conductor to both sides of the load.
  • a rectifier assembly comprising an even number of rectifiers, said number being greater than two, and a load circuit, said rectifiers and the load circuit being connected together so as to form a series closed circuit
  • a source of alternating current for exciting said rectifiers including two line conductors, connections between one of said line conductors and alternate junction points of successive rectifiers in said series circuit, connections between the other line conductor and the junction points of successive rectifiers in said series circuit not already connected to the first named line conductor, at least all but one of said connections being made through a capacitive element, the connection between the line conductor and the junction point of those two successive rectifiers having the load circuit connected between them comprising capacitive connections from said line conductor to both sides of the load circuit whereby both ends of the load circuit are maintained at the same alternating current potential.
  • a voltage quadrupler circuit comprising four rectifiers connected in series with a load circuit, said rectifiers and load circuit forming a closed uni-directional direct current path, a source of alternating current, means for connecting each of said rectifiers across the source of alternating current, said means including at least one condenser, means for connecting both ends of said load circuit to only one side of said alternating current source to thereby maintain both ends of the load at the same alternating current potential, the connection of said source side to each end of the load including at least one condenser.

Description

Oct. 6, 1936. c TRAVIS 2,056,376
VOLTAGE MULTIPLIER Filed April 26, 1933 INVENTOR 09649455 7/2/1145 BY /Y ATTORNEY Patented Oct. 6, 1936 UNITED STATES PATENT OFFICE VOLTAGE MULTIPLIER Charles Travis, Philadelphia, Pa., assignor to Radio Corporation of America, a corporation of Delaware The present invention relates generally to voltage multipliers and more particularly to so-called transformerless voltage multipliers and rectifiers.
It is an object of the present invention to disclose a broad method of setting up voltage multiplier circuits especially for use in power supply circuits of radio receivers and the like possessing certain desirable heretofore unattained characteristics.
Specific objects of the present invention will unfold themselves in the following detailed specification when read in conjunction with the accompanying drawing.
It is well known in the art that any number of diodes may be connected in series with a load and separately excited with alternating current. The resulting direct current load voltage will be the sum of the individual voltages generated by the several rectifiers, and the same direct current will flow through all. the rectifiers. Tests have indicated that the particular D. C. voltage developed across any particular rectifier or diode is to a large extent dependent upon the size of the condenser through which the alternating current is fed to the rectifier. For systems such as now known to the art reference is made to the publication Electronics of February 1932, pages 50 and 51. In particular attention is called to Fig. 5, page 51 of said publication wherein there is shown what is known as a voltage quadrupler. It is obvious at once that in the system shown by said Fig. 5 the load has the 110 A. C. across it through a pair of condensers C3, C4 in series. Thus if a large smoothing condenser is placed across the load, the line is more or less short-circuited as are likewise the rectifiers R1 and R4, hence, the filter would have to be of the choke first type as shown in said figure which is not a desirable arrangement.
The present invention is primarily directed toward devising a circuit arrangement and method of feeding the A. C. into the rectifiers in such a way that the A. C. does not come across the load with the result that conventional filter circuits may be utilized.
Reference is now directed to the appended drawing whereinz- Fig. 1 is a schematic diagram utilized to explain certain features of the invention in connection with an odd number of rectifiers in series;
Fig. 2 is a more complete diagram of the system shown in Fig. 1;
Fig- 3 illustrates the invention applied to a system utilizing an even number of rectifiers;
Fig. 4 shows in diagrammatic form a voltage quadrupler connected in accordance with the in- Vention; and,
Fig. 5 illustrates a voltage quadrupler utilizing a particular type of rectifier tube.
Reference will now be had to Fig. 1 wherein a load L is shown connected in a circuit with seven rectifiers R1R7. In order to prevent the load being connected across the A. C. source both sides of the load must be at the. same phase. The two phases are herein designated for convenience as phase a and phase I). For example, the two ends of the load are designated to be at phase a. The rectifiers must, of course, form a series chain with the load, and the problem is then to find how the rectifiers may be excited while observing the foregoing condition, namely, having both ends of the load at the same phase. With an odd number of rectifiers as shown in Figs. 1 and 2, and starting with the two ends of the load at phase a it is seen that poling the rectifiers alternately since the A. C. source must be connected across each rectifier R1R7 it is found that somewhere in the chain an a pole comes immediately adjacent to a b pole owing to the fact that there are an odd number of rectifiers. In Fig. 1 this is shown as occurring at point x and the A. C. source is inserted here to preserve the proper alternation of polarities as shown in Fig. 2. It follows then that with an odd number of rectifiers the A. C. source on line must be in series with the rectifiers and load and the D. C. must flow through the line if A. C. across the load is to be avoided. In Fig. 2 each rectifier R1R7 is fed through a condenser feed branch the condensers of which are preferably of the electrolytic type and are indicated as C1-C7 in the drawing.
For the case where an even number of rectifiers are employed reference to Fig. 3 is made. In said figure an even' number of rectifiers RIR6 are connected in series with a load L. Starting as before with the two ends of the load L in the same phase (a for convenience) it is seen that the a and b poles alternate completely around the chain, hence, the A. C. line or source cannot be in series with the chain of rectifiers and fulfill the aforementioned conditions, namely, the avoidance of the A. C. line across the load. In accord ance with the invention the A. C. source in the case of an even number of rectifiers is shunted through condensers across each rectifier while the I). C. path does not include the source. In Fig. 3 the A. C. source is connected across R1 through condensers C2 and C1; rectifier R2 through C3 and C2; R3 through C3 and C4; R4 through C4 and C5; R5 through C5, Cs; and, R6 through Cs and C7- The D. C. path comprises rectifiers R1'R6 and load L.
It is obvious from the showing in Fig. 3 that condenser C4 may be omitted and a direct connection made to the b line without interfering with the operation of the system, however, for evident reasons such as undetermined grounded lines in the A. C. system it is best to provide the condenser C4.
It is seen from what has so far been described that with an odd number of rectifiers the D. C.
path may include the A. C. source while for an even number of rectifiers the D. C. path does not include the A. C. source. By following this rule the A. C. is never connected across the load directly and furthermore a filter of the usual condenser first type may be employed.
In Fig. 4. a voltage quadrupler'is shown as comprising four rectifiers R1R4 forming a D ...C. chain with a load L. Since there are an even number of rectifiers the A. C. source cannot be connected in the D. C. chain, hence, the A. C. source is connected across the various rectifiers through condenser branch circuits. It should be noted that the terminal a of the A. C. line is connected directly to the rectifier-load chain at the point P. It is to be understood, however, that connection through a condenser is the better practice for the reasons pointed out previously in connection with the description of condenser C4 of Fig. 3.
In the system of Fig. 4 a filter condenser C may be inserted directly across the load without danger of short circuiting the A. C. source.
In Figure 5 two double space path tubes l and 2 have been substituted for the four rectifiers R1R4 of Fig. 4. The two circuits are otherwise alike except that a well known type or" filter arrangement has been shown interposed between the voltage multiplier and the load. This filter circuit comprises filter capacitiesC and choke 3.
In the various circuits shown I prefer to use electrolytic condensers although other type of condensers may be substituted.
' In the cases where the A. C. source or line is inserted in series with the chain as where an odd number of rectifiers is present it is to be understood that the D. C. passes through the A. C. source. This presupposes a D..C. path through the A. C. lines. If such a path is not present it must of. course be provided by suitable means.
I claim:
1. In a voltage multiplier circuit a source of alternating current, a load circuit, a rectifier assembly comprising an even number of rectifiers, said number being greater than two, said load and rectifiers being connected so as to form a series circuit, means for exciting each of said rectifiers with alternating current comprising capacitive branch circuits for connecting each rectifier across said source of alternating current, said branch circuits being connected with respect to the load so that both ends of the load are, in effect, connected to the same terminal of the alternating current source whereby both ends of the load are maintained at substantially the same alternating current potential with respect to the alternating current source.
2. A voltage multiplier circuit comprising a direct current closed path including an even number of rectifiers greater than two and a load cirrent potential and capacitive paths for connecting each of said rectifiers across the source of alternating current.
3. In a voltage multiplier circuit adapted to be connected between a source of alternating current and a load circuit, a uni-directional direct current closed circuit comprising an even number of rectifiers greater than two and said source in series, means for connecting each of said rectifiers across said source of alternating current including at least one capacitive element and means for maintaining both ends of said load at the same alternating current potential comprising connections from both ends of the load to only one terminal of the alternating current source.
4. In a voltage multiplier circuit of the type comprising a plurality of rectifiers, the number thereof being an .even number greater than two forming a closed D. C. series circuit including the load, the method of energizing the rectifiers with alternating current which comprises impressing the alternating current across each rectifier separately while maintaining both ends of the load at the same A. C. source voltage.
5. A voltage quadrupler circuit comprising four rectifiers connected in series with a load circuit, said rectifiers and load forming a closed unidirectional direct-current path, a source of alternating current, means for connecting each of said rectifiers across said source, said means including at least one condenser, means for connecting both ends of said load circuit to only one side of said alternating current source, the connection of said source side to each end of the load including at least one condenser, and a filter condenser shunted directly across the load circuit.
6. A circuit arrangement according to claim 5 wherein the rectifiers comprise thermionic paths arranged in pairs, each pair thereof being enclosed within an envelope.
7. In combination, an alternating. current source including two line conductors, a load circuit, a rectifier assembly comprising a plurality of rectifiers connected in series with the load, means for separately exciting each of said rectifiers comprising aplurality of circuits each including at least one capacitive element for connecting each of the rectifiers across the source, the capacitive elements of all of said means being arranged in two sets, the elements in each set being inmultiple, one of said sets .being cone nected to one of said conductors while the other set is connected to the other conductor.
8. The combination with an alternating current source including two terminals of a load circuit'and a rectifier assembly, said rectifier assembly comprising a plurality of rectifiers all connected in series with the load, means for separately exciting eachof said rectifiers comprising a plurality of circuits each thereof including at least one capacitive element for connecting each of said rectifiers across the source, the capacitive elements of all said means being arranged in two sets, one set being connected to one of said terminals and the other set being connected to the other of said terminals, the elements of each set being star connected with respect to their respective terminal.
9. In a voltage multiplier circuit, a rectifier assembly comprising an even number of rectifiers greater than two and a load, said rectifiers and load forming a series closed circuit, a source of exciting current for said rectifiers including two line conductors, capacitive connections between 76 one of said line conductors and alternate junction points of successive rectifiers in said series circuit, capacitive connections between the other line conductor and the junction points in said series circuit of successive rectifiers not connected to the first named line conductor, the capacitive connection between the line conductor and the junction point of the two successive rectifiers having the load circuit between them, including capacitive connections from said line conductor to both sides of the load.
10. In a voltage multiplier circuit, a rectifier assembly comprising an even number of rectifiers greater than two and a load circuit, said rectifiers and load circuit being connected so as to form a series closed circuit, a source of exciting current for said rectifiers including two line conductors, connections between one of said line conductors and alternate junction points of successive rectifiers in said series circuit, connections between the other line conductor and the junction points in said series circuit of successive rectifiers not already connected to the first named line conductor, at least all but one of said connections being made through a capacitive element, the connection between the line conductor and the junction point of those two successive rectifiers having the load circuit between them, including connections from said line conductor to both sides of the load.
11. In a voltage multiplier circuit a rectifier assembly comprising an even number of rectifiers, said number being greater than two, and a load circuit, said rectifiers and the load circuit being connected together so as to form a series closed circuit, a source of alternating current for exciting said rectifiers including two line conductors, connections between one of said line conductors and alternate junction points of successive rectifiers in said series circuit, connections between the other line conductor and the junction points of successive rectifiers in said series circuit not already connected to the first named line conductor, at least all but one of said connections being made through a capacitive element, the connection between the line conductor and the junction point of those two successive rectifiers having the load circuit connected between them comprising capacitive connections from said line conductor to both sides of the load circuit whereby both ends of the load circuit are maintained at the same alternating current potential.
12. A voltage quadrupler circuit comprising four rectifiers connected in series with a load circuit, said rectifiers and load circuit forming a closed uni-directional direct current path, a source of alternating current, means for connecting each of said rectifiers across the source of alternating current, said means including at least one condenser, means for connecting both ends of said load circuit to only one side of said alternating current source to thereby maintain both ends of the load at the same alternating current potential, the connection of said source side to each end of the load including at least one condenser.
CHARLES TRAVIS.
US668102A 1933-04-26 1933-04-26 Voltage multiplier Expired - Lifetime US2056376A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US668102A US2056376A (en) 1933-04-26 1933-04-26 Voltage multiplier

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US668102A US2056376A (en) 1933-04-26 1933-04-26 Voltage multiplier

Publications (1)

Publication Number Publication Date
US2056376A true US2056376A (en) 1936-10-06

Family

ID=24681016

Family Applications (1)

Application Number Title Priority Date Filing Date
US668102A Expired - Lifetime US2056376A (en) 1933-04-26 1933-04-26 Voltage multiplier

Country Status (1)

Country Link
US (1) US2056376A (en)

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2621302A (en) * 1949-08-31 1952-12-09 Rca Corp Band pass voltage multiplier network for pulsed power supplies
US2975353A (en) * 1955-10-11 1961-03-14 Telefunken Gmbh D. c. -d. c. converter
US3147390A (en) * 1960-11-25 1964-09-01 Benjamin H Beam Thermo-electrostatic generator
DE1203875B (en) * 1960-03-04 1965-10-28 Husqvarna Vapenfabriks Ab Device for dielectric heating, in particular of food
US3748492A (en) * 1972-05-25 1973-07-24 Massachusetts Inst Technology Light-triggered electric power source
US3849717A (en) * 1970-08-13 1974-11-19 R Ostreicher Circuit for operation of gas discharge lamps
US3909666A (en) * 1973-12-26 1975-09-30 Stanley N Tenen Ballast circuit for gaseous discharge lamps
US4812961A (en) * 1987-05-15 1989-03-14 Linear Technology, Inc. Charge pump circuitry having low saturation voltage and current-limited switch

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2621302A (en) * 1949-08-31 1952-12-09 Rca Corp Band pass voltage multiplier network for pulsed power supplies
US2975353A (en) * 1955-10-11 1961-03-14 Telefunken Gmbh D. c. -d. c. converter
DE1203875B (en) * 1960-03-04 1965-10-28 Husqvarna Vapenfabriks Ab Device for dielectric heating, in particular of food
US3147390A (en) * 1960-11-25 1964-09-01 Benjamin H Beam Thermo-electrostatic generator
US3849717A (en) * 1970-08-13 1974-11-19 R Ostreicher Circuit for operation of gas discharge lamps
US3748492A (en) * 1972-05-25 1973-07-24 Massachusetts Inst Technology Light-triggered electric power source
US3909666A (en) * 1973-12-26 1975-09-30 Stanley N Tenen Ballast circuit for gaseous discharge lamps
US4812961A (en) * 1987-05-15 1989-03-14 Linear Technology, Inc. Charge pump circuitry having low saturation voltage and current-limited switch

Similar Documents

Publication Publication Date Title
US2072278A (en) Voltage multiplier circuit
US2056376A (en) Voltage multiplier
US2619602A (en) Apparatus for the supply of highvoltage unidirectional currents from a relatively low-voltage alternating current source
US1885728A (en) Harmonic generating and selecting system
US1976391A (en) Thermionic system
US2510075A (en) Modulator of the dry type
US3432738A (en) Current driven voltage multiplication circuit
US1932589A (en) Frequency translating device
US2682002A (en) Transformerless voltage multiplier circuits
US1867503A (en) Rectifier
US1666473A (en) High-voltage direct-current system
US1898366A (en) Frequency transformation system
US3337788A (en) Cyclo-converter circuits
US2438831A (en) Voltage regulating rectifying circuits
US1834889A (en) Power transmitting apparatus
US2017708A (en) Polyphase oscillator
US4270166A (en) Circuit arrangement for producing a regulated high DC voltage from a three-phase current
US3258673A (en) System for converting single phase
US2439223A (en) Rectifier system
US2357418A (en) Rectifier and circuit
US1712677A (en) Electric-current-rectifying apparatus
US1642526A (en) Means for supplying power to thermionic valves
US1957229A (en) Electric valve converting apparatus
US2000986A (en) Rectifier and filter circuit
US2037267A (en) Power supply network for thermionic tubes