US1942535A - Voltage regulation system - Google Patents

Voltage regulation system Download PDF

Info

Publication number
US1942535A
US1942535A US272495A US27249528A US1942535A US 1942535 A US1942535 A US 1942535A US 272495 A US272495 A US 272495A US 27249528 A US27249528 A US 27249528A US 1942535 A US1942535 A US 1942535A
Authority
US
United States
Prior art keywords
voltage
primary
core
transformer
load
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
US272495A
Inventor
Cairns Mae Lewis
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.)
Individual
Original Assignee
Individual
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 Individual filed Critical Individual
Priority to US272495A priority Critical patent/US1942535A/en
Application granted granted Critical
Publication of US1942535A publication Critical patent/US1942535A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05FSYSTEMS FOR REGULATING ELECTRIC OR MAGNETIC VARIABLES
    • G05F3/00Non-retroactive systems for regulating electric variables by using an uncontrolled element, or an uncontrolled combination of elements, such element or such combination having self-regulating properties
    • G05F3/02Regulating voltage or current
    • G05F3/04Regulating voltage or current wherein the variable is ac
    • G05F3/06Regulating voltage or current wherein the variable is ac using combinations of saturated and unsaturated inductive devices, e.g. combined with resonant circuit

Definitions

  • the object of the present invention is to provide a system whereby a practically constant voltage may be obtained from a source of alternating current, such as a commercial power disl tribution system, which is subject to voltage fiuctuations due to load variations and other causes.
  • my invention comprises essentially two transformers having their primaries connected in series with an alternating l current source and their secondaries connected in series with each other and with a load circuit, such connection being in opposition or in conjunction, depending on the relative direction of the windings of said transformers, as hereinafter l more fully explained.
  • the transformers are so designed that the primary inductance of one remains substantially constant with respect to voltage changes across its terminals, and the inductance of the other varies rapidly and inversely with voltage changes across its terminals.
  • Means are provided for automatically shifting the phase of eachof the primary voltages with respect toa fluctuating line voltage and in response to changes in such line voltage.
  • a condenser may be employed and is connected across the terminals of the primary having the variable. inductance, or preferably across the terminals of a winding inductively associated with said primary, so that the voltage across the terminals of said primary will lag behind the line voltage, while the voltage across the primary having the substantially constant inductance leads the line voltage.
  • the transformer windings are so related and arranged that the vector sum of the primary voltages varies with fluctuations of line voltage and the resultant of their secondary voltages is substantially lconstant from no load to full load.
  • each transformer core is provided with an air gap to eliminate upper harmonics where a A simple harmonic voltage is desired, e. g., when the system is to be used in connection with radio receiving sets.
  • FIG. 1 is a diagram of a voltage regulator embodying my invention.
  • Fig. 2 is a vector diagram employed for more fully explaining the principle thereof.
  • 10 is a transformer core whose length is great compared to its Width so as to provide a relatively long magnetic circuit 0f comparatively high reluctance, and 11 represents a relatively short air gap which is employed in cases where it is desirable to eliminate l the upper harmonics in the voltage delivered to the load circuit.
  • l2 is a second transformer core 70 having substantially the characteristics of the core y10 and provided with an air gap 11 which lpreferably is somewhat larger than the air gap 11.
  • the primaries 13, 14 are connected in series ,with the line 15, 15 and in order to shift the phase of the ⁇ voltage V1 across the primary 13 on the core 10, and the phase of the voltage V2 across the primary 14 on the core 12 with respect and in response to the fluctuating line voltage VL, a condenser 16 connected in series with the secondary v17 maybe employed.
  • said condenser By means of said condenser the phases of the voltages V1 and V2 are automatically shifted with respect and in response to the line voltage Vr.. because, by virtue of the capacitance of said condenser, the voltage V1 always lags behind the line voltage While the voltage V2 always leads the line voltage, as shown by the diagram in Fig. 2.
  • the ratio of the turns in the secondary 17 tov those of the primary 13 is greater than unity and may be as high as 10 to 1.
  • the condenser 16 which reacts through the magnetic field to shift the phase of the voltage V1 may be very much smaller than if it were connected directly across the primary 13, the effect of such condenser depending upon the square of the ratio of transformation, for example, if such ratio is 10 to 1, a condenser of one microfarad connected across the-secondary will have the same effect as a condenser of 100 microfarads connected across the primary.
  • Wound on the cores 10and 12 are secondaries 18, 19, respectively, which as shown, in the present instance, are connected in opposition and in series with the load circuit 20, 20.
  • the secondaries are connected reversely, or in opposition so that their resultant voltage is equal to the vector difference of their voltages; but the same ultimate result would obviously be obtained if the primary oi each transformer were wound in the same sense as its own secondary, so that each secondary voltage would be substantially 180 out of phase with its primary voltage, and the secondaries connected, as before, in opposition. Also, the same ultimate result would be obtained if the primary of one transformer, say 10, were wound in the opposite sense to its own secondary, and the primary and secondary of the other transformer 12 were both wound in the same sense, and the secondaries connected directly, instead of reversely as shown in Fig. 2, that is to say, the lower (outside) terminal of secondary 18 connected to the upper (inside) terminal of secondary 19.
  • the vector sum. of the primary voltages V1 and V2 is equal. at all times to the line voltage V1..
  • the resultant or, in the present instance, tlie vector diierence of the voltages V1 and V5 is' the load voltage Vs.
  • the primary voltages will increase to the values V1 and V2', respectively, and the secondary voltages will increase to the values V4 and V5', respectively.
  • the resultant, or, in the present instance, the vector difference of the voltages V4 and V5 is V3 which is always substantially equal to Vs, for wide variations in V1..
  • t is desirable to use high magnetizations in the core 10, and preferably to work on the flat portion of the B-H curve which represents magnetic saturation, e. g. to use flux densities of the order 13,000-16,000, because at such flux densities the permeability of transformer iron changes rapidly with the flux density and hence the inductance of the primary winding, which is proportional to permeability, also changes rapidly with the flux density, and I-prei'er, as above stated, to use a core having its length great compared to its Width so as to increase the reluctance of the magnetic circuit, for, by so doing, I may obtain the same results with a lower degree of magnetization as would be effected if the core nihis means, of course, that the primary had less reluctance and a higher degree of magnetization were used.
  • substantially constant voltage may be obtained across the terminals of the load circuit when the line voltage is subjected to so large a variation as 35%, for example, when it varies between and 130.
  • a simple harmonic electromotive force in the output circuit is necessary or is more desirable than an absolutely constant voltage, as for instance, where the system is to be employed for supplying the several voltages for radio receiving sets employing alternating current tubes, I provide core 10 with a gap such as 11, to eliminate the upper harmonics and thereby prevent the radio set from giving oif an audible hum, and in such case, I have found that the load voltage remains constant within about 2%.
  • the inductance of the primary 13 will not vary sufiiciently with variations in the voltage V1 to accomplish my object, because such inductance is an inverse function of the sum of the length of the air gap and the ratio of the length of the iron circuit to the permeability thereof. I have found, however, that if said gap 11 be made relatively short, the inductance of the primary 13 will vary with sufficient rapidity with changes in the voltage V' to effect the desired result.
  • the air gap 11 is made somewhat longer than the gap 1l so that the length thereof is much greater than the ratio of the length of the iron circuit to the permeability thereof, and therefore such ratio has but little effect in determining the value of the inductance.
  • the flux densities employed in this core are more nearly normal, 10,000 to 13,000 lines, i. e., said core is unsaturated.
  • the regulation obtained by means of my invention is independent of load from no-load to full load of the particular rating.
  • the eiliciency of my improved regulator is relatively high, a.
  • E30-watt system having an efficiency of 60% at 130 volts input, and 80% at 90 volts input. Inasmuch as the usual (S0-watt transformer has an efiiciency of 85%, the energy loss to get the desired result is not prohibitive.
  • Radio receiving sets of the type known as electrical that is, those which require no batteries and are connected directly to a light socket, are provided with means whereby the proper voltages are delivered to the lamp laments, plates, grids, etc., and in such case, the load circuit of my system will simply be connected to the terminals of such sets which heretofore are connected to the lighting circuit.
  • a voltage regulation system comprising in combination two transformers each having an iron core provided with an air gap, one 'of said cores being magnetically saturated,-and the other core being magnetically unsaturated, means connecting the primaries of said transformers in series with each other and with a sourceof altery voltage, and secondary windings nating current; means for automatically shifting the phase of the primary voltage of each of said transformers with respect and in response to a fluctuating line voltage; secondaries for said transformers, respectively, and means connecting said .secondaries in series with each other and with a load circuit, said secondaries being so connected and related that their resultant voltage is substantially constant from no load to full load for wide uctuations in line voltage.
  • a voltage regulator comprising in combination two windings connected in series with each other and with a sourceof alternating current, an iron core for each of said windings, one of said cores being magnetically saturated and having a relatively short air gap, and the other core being magnetically unsaturated; means for automatically shifting' the phase of the voltage across each of said windings with respect and in response 'to a fluctuating line voltage, and secondary wind-f ings inductively associated with the first mentioned windings, respectively, and connected in series with each other and with a load circuit, said secondaryJ windings being so connected and related that the resultant voltage is substantially constant from no load to full load for wide fluctuations in line voltage.
  • a voltage regulator comprising in comb ation two windings connected in series witheach other and with a source of alternating current, an iron core-for each of said windings, one of said cores'being magnetically saturated and having a relatively short air gap, and the other core being magnetically unsaturated and having a relatively long air gap, means for automatically shifting the phase of the voltage across each of said windings with respect and in response to a fluctuating line uctively associated with-the first mentioned windings, respectively, and connected in series with each other and with a load circuit, lsaidfsecondarv' windings being so connected and related that their resultant voltage is substantially constant from no load to full load for wide fluctuations in line voltage.
  • a system for obtaining substantially constant output voltage across a varying load from a source of fluctuating input voltage comprising two transformers whose primaries are connected in series and whose cores are excited at different ilux densities, the transformer whose core has the higher flux density being a step-up transformer and the transformer whose core has the lower ux density being a step-down transformer, means connecting the secondaries of said transformers in series with each other and with a load circuit, and a condenser inductively connected to the ⁇ primary of the transformer, the
  • a system for obtaining substantially constant output voltage across a varying load from a source of fluctuating input voltage comprising two transformers whose primaries are connected in series and whose cores are excited at different ux densities, the transformer whose core has the higher flux density being a step-up transformer and the transformer whose core has the lower flux density being a step-down transformer, means connecting the secondaries of said transformers in series with each other and with a load circuit, a winding nductively related to the primary of the transformer having the higher flux density, said winding Yhaving a greater number of turns than the primary with which it is related, and a condenser connected to the terminals of vsaid Winding.
  • a system for obtaining substantially' constant output voltage across a varying. load from a source of fluctuating input voltage comprising two transformers whose primaries are connected in series and whose cores are excited at different flux densities, the ratio of the secondary voltage of the transformer whose core has the higher flux density to ,the secondary voltage of the transformer whose core has the lower flux density being greater than unity, means connecting the secondaries of said transformers in series with each other and with a load circuit, and a 'condenser inductively connected to the primary Vcomprising two transformers whose primaries are connected in series and whose cores are excited at different ux densities, the ratio of the secondary voltage of the transformer whose core has the higher flux density to thesecondary voltage of the transformer whose core has the lower ux density being substantially flve'to one, means connecting the secondaries of said transformers in series with each other and with a load circuit, and a condenser inductively connected to the primary of the transformewith the higher iiux density

Description

jan- 9, 1934 c. F. cAlRNs VOLTAGE REGULATION SYSTEM Filed April 24, 1928 ATTDFNEL:
Patented Jan. 9', 1934 UNITED STATES PATENT OFFICE Cairns executrix of said deceased Claude F. Cairns,
Application April 24, 1928. Serial No. 272,495
7 claims'.
The object of the present invention is to provide a system whereby a practically constant voltage may be obtained from a source of alternating current, such as a commercial power disl tribution system, which is subject to voltage fiuctuations due to load variations and other causes.
With this object in view, my invention comprises essentially two transformers having their primaries connected in series with an alternating l current source and their secondaries connected in series with each other and with a load circuit, such connection being in opposition or in conjunction, depending on the relative direction of the windings of said transformers, as hereinafter l more fully explained. The transformers are so designed that the primary inductance of one remains substantially constant with respect to voltage changes across its terminals, and the inductance of the other varies rapidly and inversely with voltage changes across its terminals. Means are provided for automatically shifting the phase of eachof the primary voltages with respect toa fluctuating line voltage and in response to changes in such line voltage. For this purpose, a condenser may be employed and is connected across the terminals of the primary having the variable. inductance, or preferably across the terminals of a winding inductively associated with said primary, so that the voltage across the terminals of said primary will lag behind the line voltage, while the voltage across the primary having the substantially constant inductance leads the line voltage. A
The transformer windings are so related and arranged that the vector sum of the primary voltages varies with fluctuations of line voltage and the resultant of their secondary voltages is substantially lconstant from no load to full load.
4o The voltages across said primaries vary with the line voltage, butk their phase difference varies inverselv with the line voltageY because of the changes in theinductance of the variable inductance primary. I-t is desirable though not necessary that the magnetic circuits of the transformers belong compared to those of the usual transformen-in other words, I prefer to employ a transformer core whose length is great compared to its width, the ratio of the length to the width being, for example, as large as 6 to 1 in contradistinction to Athe usual rtransformer in which such ratio is ordinarily about 3 to 1. Preferably each transformer core is provided with an air gap to eliminate upper harmonics where a A simple harmonic voltage is desired, e. g., when the system is to be used in connection with radio receiving sets.
In the accompanying drawing:-
Figure 1 is a diagram of a voltage regulator embodying my invention; and
Fig. 2 is a vector diagram employed for more fully explaining the principle thereof.
In the drawing, 10 is a transformer core whose length is great compared to its Width so as to provide a relatively long magnetic circuit 0f comparatively high reluctance, and 11 represents a relatively short air gap which is employed in cases where it is desirable to eliminate l the upper harmonics in the voltage delivered to the load circuit. l2 is a second transformer core 70 having substantially the characteristics of the core y10 and provided with an air gap 11 which lpreferably is somewhat larger than the air gap 11.
The primaries 13, 14 are connected in series ,with the line 15, 15 and in order to shift the phase of the `voltage V1 across the primary 13 on the core 10, and the phase of the voltage V2 across the primary 14 on the core 12 with respect and in response to the fluctuating line voltage VL, a condenser 16 connected in series with the secondary v17 maybe employed. By means of said condenser the phases of the voltages V1 and V2 are automatically shifted with respect and in response to the line voltage Vr.. because, by virtue of the capacitance of said condenser, the voltage V1 always lags behind the line voltage While the voltage V2 always leads the line voltage, as shown by the diagram in Fig. 2. 'Ihis relation is true for all fiuctuations of line voltage and for all variations of load from no load to full load. The ratio of the turns in the secondary 17 tov those of the primary 13 is greater than unity and may be as high as 10 to 1. By this arrangement the condenser 16 which reacts through the magnetic field to shift the phase of the voltage V1 may be very much smaller than if it were connected directly across the primary 13, the effect of such condenser depending upon the square of the ratio of transformation, for example, if such ratio is 10 to 1, a condenser of one microfarad connected across the-secondary will have the same effect as a condenser of 100 microfarads connected across the primary. Wound on the cores 10and 12 are secondaries 18, 19, respectively, which as shown, in the present instance, are connected in opposition and in series with the load circuit 20, 20.
As above stated-the secondaries 18 and 19 are so connected and related to the other ele- 110 Cil ments of the system that their resultant voltage which, in the present instance, is the vector difference of their voltages V1 and V5 is always substantially constant, irrespective of variations in the line voltage and irrespective of variations in load from no load to full load, and the direction of each of said secondary windings is so related to that of its primary that in the present instance each secondary voltage is substantially in phase with its primary voltage, as indicated in Fig. 2. winding of each transformer is wound in the opposite sense to its own secondary, and as shown in Fig. 2, the secondaries are connected reversely, or in opposition so that their resultant voltage is equal to the vector difference of their voltages; but the same ultimate result would obviously be obtained if the primary oi each transformer were wound in the same sense as its own secondary, so that each secondary voltage would be substantially 180 out of phase with its primary voltage, and the secondaries connected, as before, in opposition. Also, the same ultimate result would be obtained if the primary of one transformer, say 10, were wound in the opposite sense to its own secondary, and the primary and secondary of the other transformer 12 were both wound in the same sense, and the secondaries connected directly, instead of reversely as shown in Fig. 2, that is to say, the lower (outside) terminal of secondary 18 connected to the upper (inside) terminal of secondary 19. This is so, because in such case the secondary voltage V4 of the first transformer will be substantially in phase with its primary voltage V1 and the secondary voltage V5 of the second transformer substantially 180 out of phase with its own primary voltage V2. When I use the expression the secondaries being so connected and related that their resultant voltage is substantially constant in the appended claims, I desire to be understood as defining the foregoing and other obvious equivalent arrangements, and any and all other permutations of direction or sense of the transformer windings with the modes of connecting the secundarios in series.
The vector sum. of the primary voltages V1 and V2 is equal. at all times to the line voltage V1.. The resultant or, in the present instance, tlie vector diierence of the voltages V1 and V5 is' the load voltage Vs. As the line voltage increases, for example, to the value V11', the primary voltages will increase to the values V1 and V2', respectively, and the secondary voltages will increase to the values V4 and V5', respectively. The resultant, or, in the present instance, the vector difference of the voltages V4 and V5 is V3 which is always substantially equal to Vs, for wide variations in V1..
t is desirable to use high magnetizations in the core 10, and preferably to work on the flat portion of the B-H curve which represents magnetic saturation, e. g. to use flux densities of the order 13,000-16,000, because at such flux densities the permeability of transformer iron changes rapidly with the flux density and hence the inductance of the primary winding, which is proportional to permeability, also changes rapidly with the flux density, and I-prei'er, as above stated, to use a core having its length great compared to its Width so as to increase the reluctance of the magnetic circuit, for, by so doing, I may obtain the same results with a lower degree of magnetization as would be effected if the core nihis means, of course, that the primary had less reluctance and a higher degree of magnetization were used.
have found in practice that by means of my invention substantially constant voltage may be obtained across the terminals of the load circuit when the line voltage is subjected to so large a variation as 35%, for example, when it varies between and 130. Where a simple harmonic electromotive force in the output circuit is necessary or is more desirable than an absolutely constant voltage, as for instance, where the system is to be employed for supplying the several voltages for radio receiving sets employing alternating current tubes, I provide core 10 with a gap such as 11, to eliminate the upper harmonics and thereby prevent the radio set from giving oif an audible hum, and in such case, I have found that the load voltage remains constant within about 2%.
If the air gap 11 is too long, the inductance of the primary 13 will not vary sufiiciently with variations in the voltage V1 to accomplish my object, because such inductance is an inverse function of the sum of the length of the air gap and the ratio of the length of the iron circuit to the permeability thereof. I have found, however, that if said gap 11 be made relatively short, the inductance of the primary 13 will vary with sufficient rapidity with changes in the voltage V' to effect the desired result.
Inasmuch as the inductance of the primary 14 should remain substantially constant irrespective of variations in the voltage V2, the air gap 11 is made somewhat longer than the gap 1l so that the length thereof is much greater than the ratio of the length of the iron circuit to the permeability thereof, and therefore such ratio has but little effect in determining the value of the inductance. Furthermore, the flux densities employed in this core are more nearly normal, 10,000 to 13,000 lines, i. e., said core is unsaturated.
Without limiting myself thereto, I append a list of the constants of a voltage regulation systern constructed in accordance with my invention to deliver 110 volts and current not exceeding .6 ampere with a variation in line voltage of from 90 to 130 volts:
Primary 13 270 turns of No. 19 wire.
Primary 14 400 turns of No. 19 wire.
Secondary 1'7 2800 turns of No. 27 wire.
Secondary 18 510 turns of No. 24 wire.
Secondary 19 160 turns of No. 24 wire.
Condenser 16, 1 m. f.
Cross section of core l0, 1 square inch.
Length of air gap 11, .020 inch.
Crossvsection of core i2, 1 square inch.
Length of air gap 11', .040 inch.
The regulation obtained by means of my invention is independent of load from no-load to full load of the particular rating. The eiliciency of my improved regulator is relatively high, a.
E30-watt system having an efficiency of 60% at 130 volts input, and 80% at 90 volts input. Inasmuch as the usual (S0-watt transformer has an efiiciency of 85%, the energy loss to get the desired result is not prohibitive.
Radio receiving sets of the type known as electrical, that is, those which require no batteries and are connected directly to a light socket, are provided with means whereby the proper voltages are delivered to the lamp laments, plates, grids, etc., and in such case, the load circuit of my system will simply be connected to the terminals of auch sets which heretofore are connected to the lighting circuit. K
It will, however. be a merely obvious extension of the system shownand described herein to provide each of the cores 10, 12 with a plurality of sets of secondaries 18, 19 designed to deliver constant potential of the proper values for the various elements of the radio receiving set, for
example, one pair of secondaries which will de-` liver five volts fo'r tube filaments, another pair for 1.5 volts for other tube filaments, another pair which will deliver 600 volts tothe plates of rectiiler tubes, etc. i
HavingV thus described an illustrativeembodb ment of my invention, without however limiting the same thereto. what I claim and desire to secure by Letters Patent isz- 1. A voltage regulation system comprising in combination two transformers each having an iron core provided with an air gap, one 'of said cores being magnetically saturated,-and the other core being magnetically unsaturated, means connecting the primaries of said transformers in series with each other and with a sourceof altery voltage, and secondary windings nating current; means for automatically shifting the phase of the primary voltage of each of said transformers with respect and in response to a fluctuating line voltage; secondaries for said transformers, respectively, and means connecting said .secondaries in series with each other and with a load circuit, said secondaries being so connected and related that their resultant voltage is substantially constant from no load to full load for wide uctuations in line voltage.
2. A voltage regulator comprising in combination two windings connected in series with each other and with a sourceof alternating current, an iron core for each of said windings, one of said cores being magnetically saturated and having a relatively short air gap, and the other core being magnetically unsaturated; means for automatically shifting' the phase of the voltage across each of said windings with respect and in response 'to a fluctuating line voltage, and secondary wind-f ings inductively associated with the first mentioned windings, respectively, and connected in series with each other and with a load circuit, said secondaryJ windings being so connected and related that the resultant voltage is substantially constant from no load to full load for wide fluctuations in line voltage.
3. A voltage regulator comprising in comb ation two windings connected in series witheach other and with a source of alternating current, an iron core-for each of said windings, one of said cores'being magnetically saturated and having a relatively short air gap, and the other core being magnetically unsaturated and having a relatively long air gap, means for automatically shifting the phase of the voltage across each of said windings with respect and in response to a fluctuating line uctively associated with-the first mentioned windings, respectively, and connected in series with each other and with a load circuit, lsaidfsecondarv' windings being so connected and related that their resultant voltage is substantially constant from no load to full load for wide fluctuations in line voltage. i
4. A system for obtaining substantially constant output voltage across a varying load from a source of fluctuating input voltage, such system comprising two transformers whose primaries are connected in series and whose cores are excited at different ilux densities, the transformer whose core has the higher flux density being a step-up transformer and the transformer whose core has the lower ux density being a step-down transformer, means connecting the secondaries of said transformers in series with each other and with a load circuit, and a condenser inductively connected to the `primary of the transformer, the
core of which has the higher flux density.
5. A system for obtaining substantially constant output voltage across a varying load from a source of fluctuating input voltage, such system comprising two transformers whose primaries are connected in series and whose cores are excited at different ux densities, the transformer whose core has the higher flux density being a step-up transformer and the transformer whose core has the lower flux density being a step-down transformer, means connecting the secondaries of said transformers in series with each other and with a load circuit, a winding nductively related to the primary of the transformer having the higher flux density, said winding Yhaving a greater number of turns than the primary with which it is related, and a condenser connected to the terminals of vsaid Winding.
6. A system for obtaining substantially' constant output voltage across a varying. load from a source of fluctuating input voltage, such system comprising two transformers whose primaries are connected in series and whose cores are excited at different flux densities, the ratio of the secondary voltage of the transformer whose core has the higher flux density to ,the secondary voltage of the transformer whose core has the lower flux density being greater than unity, means connecting the secondaries of said transformers in series with each other and with a load circuit, and a 'condenser inductively connected to the primary Vcomprising two transformers whose primaries are connected in series and whose cores are excited at different ux densities, the ratio of the secondary voltage of the transformer whose core has the higher flux density to thesecondary voltage of the transformer whose core has the lower ux density being substantially flve'to one, means connecting the secondaries of said transformers in series with each other and with a load circuit, and a condenser inductively connected to the primary of the transformewith the higher iiux density. i f CLAUDE F. CAIRNS.
US272495A 1928-04-24 1928-04-24 Voltage regulation system Expired - Lifetime US1942535A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US272495A US1942535A (en) 1928-04-24 1928-04-24 Voltage regulation system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US272495A US1942535A (en) 1928-04-24 1928-04-24 Voltage regulation system

Publications (1)

Publication Number Publication Date
US1942535A true US1942535A (en) 1934-01-09

Family

ID=23040044

Family Applications (1)

Application Number Title Priority Date Filing Date
US272495A Expired - Lifetime US1942535A (en) 1928-04-24 1928-04-24 Voltage regulation system

Country Status (1)

Country Link
US (1) US1942535A (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2553591A (en) * 1946-08-16 1951-05-22 Gen Electric Electric induction apparatus
US2673323A (en) * 1948-01-22 1954-03-23 Westinghouse Brake & Signal Voltage regulating apparatus for alternating electric current circuits

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2553591A (en) * 1946-08-16 1951-05-22 Gen Electric Electric induction apparatus
US2673323A (en) * 1948-01-22 1954-03-23 Westinghouse Brake & Signal Voltage regulating apparatus for alternating electric current circuits

Similar Documents

Publication Publication Date Title
US2169093A (en) Electrical control system
US2143745A (en) Constant potential transformer
US2561329A (en) Electric energy control system
US2395881A (en) Controlled peaking trasformer
US2207234A (en) Voltage regulating device
US2086120A (en) Control system
US2666178A (en) Frequency multiplier
US1985634A (en) Regulating system
US1942535A (en) Voltage regulation system
US2358394A (en) Electric regulating circuit
US2709776A (en) Voltage regulators
US1434346A (en) Apparatus for regulating the voltage of metal vapor-rectifier installations
US2588155A (en) Rectifier connection
US2461957A (en) Transformer
US1870093A (en) Electrical regulator
US2916685A (en) Direct current motor speed control system
US2442960A (en) Regulated rectifying system
US1839869A (en) Voltage regulator for radiotransmitters
US3099784A (en) Frequency multiplier
US3710233A (en) Polyphase saturable power modulator
US3611116A (en) Ferroresonant voltage regulator with saturable and unsaturable transformers
GB1106309A (en) Improvements in or relating to rectifying circuits
US2894195A (en) Frequency tripler
US2892142A (en) Frequency multiplier
US2911582A (en) Static magnetic frequency multiplier