US2498893A - Parallel operation of vibrator systems - Google Patents

Parallel operation of vibrator systems Download PDF

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US2498893A
US2498893A US54491344A US2498893A US 2498893 A US2498893 A US 2498893A US 54491344 A US54491344 A US 54491344A US 2498893 A US2498893 A US 2498893A
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contact
vibrating
contacts
winding
transformer
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Jose A Mas
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Cornell Dubilier Electronics Inc
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Cornell Dubilier Electronics Inc
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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
    • H02M7/00Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
    • H02M7/42Conversion of dc power input into ac power output without possibility of reversal
    • H02M7/54Conversion of dc power input into ac power output without possibility of reversal by dynamic converters
    • H02M7/58Conversion of dc power input into ac power output without possibility of reversal by dynamic converters using mechanical contact-making and -breaking parts to interrupt a single potential
    • H02M7/62Conversion of dc power input into ac power output without possibility of reversal by dynamic converters using mechanical contact-making and -breaking parts to interrupt a single potential with electromagnetically-operated vibrating contacts, e.g. chopper

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  • the present invention relates to vibrator interrupter systems and more particularly to vibrator interrupter systems having at least two vibrator interrupters.
  • One of the objects of my invention is to provide a vibrator interrupter system having at least two vibrating interrupters operatin substantially in synchronous frequency and in phase.
  • Another object of my invention is the provision of a vibrating interrupter system having at least two vibrating interrupters with means for insuring the operation of the interrupters in phase by imposing on the interrupters a voltage proportional to the amount of phase deviation so as to bring the lagging interrupter up in phase and slowing down the leading interrupter until the interrupters are in phase.
  • Fig. l is a diagrammatic view of a vibrating interrupter system embodying my invention.
  • Fig. 2 is ,a diagrammatic view showing an equivalent circuit of each vibrator coil insofar as their potentials are concerned.
  • the vibrating interrupter system comprises a first vibrating interrupter circuit A and a second vibrator interrupter circuit B. Each of these circuits is connected to a transformer i having a split primary winding comprising two sections 2 and 3 and a secondary winding 4.
  • the primary winding is provided with a center tap connected with one side of a battery 5 which provides a direct current source and while I have illustrated the source as being a battery, it will be understood that any source of unidirectional current may be provided.
  • the opposite side of the battery 5 is connected to the vibrating reed or contact 8 of the interrupter A and likewise'to the vibrating reed or contact 1 of the vibrating interrupter B.
  • the vibrating contact member 5 vibrates between a pair of oppositely disposed relatively stationary contacts 9 and I0 and the vibrating reed or contact 1 vibrates between a pair of relatively stationary contacts I i and I2.
  • I For driving the contact member 6, I provide a driving magnet having a coil i3 and for driving a member 1, I provide a driving magnet having a coil II.
  • I provide a deviation transformer I 5 having a split secondary winding comprising the sections i6 and I1.
  • the center tap of this winding is connected by a conductor II with one side of the battery 5.
  • the outer terminal of the winding I1 is connected by a conductor I! with the driving magnet winding II, the opposite terminal of which is connected to a relatively stationary contact 20 in engagement with the vibrating contact 6, when the vibrating contact 6 is in neutral position.
  • the outer terminal of the winding I6 is connected by a conductor 2i with one terminal of the driving magnet winding H for the vibrating contact I, the opposite terminal of this winding it being connected to a relatively stationary contact 22 in engagement, when the vibrating contact 1 is in neutral position, with the vibrating contact I.
  • contacts ill and i2 are disposed on the same side of the vibrating contact members 9 and I and may be referred to as the magnet-side contacts.
  • Contacts 9 and ii are likewise disposed on the same side of contacts 6 and 'l and may be referred to as rebound contacts.
  • the deviation transformer is provided with a pair of primary winding sections C and D.
  • the primary C is a split primary windin having the two sections 23 and 24 and similarly the primary winding D is a split winding having the two sections 25 and 26.
  • the center tap of the primary winding C is connected by a conductor 21 with the outer terminal of the primary winding 2 and similarly the center tap of the winding D is connected to the outer terminal of the primary winding section 3;
  • the outer terminals of sections 23 and 24 of the winding C are respectively connected by conductors 28 and 29 with the rebound contacts ii and 9 and the outer terminals of the winding D are respectively connected by the conductors 30 and iii with the magnet-side contacts i2 and i0.
  • windings 23 and 24 are so constituted that when the interrupter contacts 6 and l are in phase the net flux in the core of the transformer I5 is zero.
  • the voltage induced in windings l6 and H is, therefore, also zero.
  • the driving magnet coils l4 and I3 are receiving the same voltage, namely the voltage of the source of continuous power.
  • Fig. 2 shows the equivalent circuit of each vibrator coil insofar as the A. C. components are concerned.
  • the driving coil receives an injection of A. C. from the deviation transformer suflicient to synchronize it, and an added pulse, correctly phased from the deviating transformer.
  • the A. C. components of the injection are in phase.
  • the pulses are not. They are 180 out of phase.
  • the voltage of each driving coil is therefore:
  • E1 Edc+Edic (deviation voltage)
  • E2 Edc-Ediv (deviation voltage) I! the vibrators are in phase, the net deviation flux in the driving coil is zero. The moment that one vibrator tries to lag or lead, a deviation voltage proportional to the phase shift is developed and this voltage is such that it gives a momentary kick to the lagg n vibrator and lowere momentarily the voltage at the other.
  • a vibratory interrupt ng system comprising, in combination, at least two vibratory interrupters each having a vibratory contact, a relativelystationary magnet side contact and a relatively stationary rebound side contact between which the vibratory contact operates, a separate driving magnet for each vibratory'contact including a coil, and a synchronizing transformer for maintaining the vibratory members of the interrupters in phase comprising a secondary winding having a center tap adapted to be connected to one side of a direct current source of supply, an outer terminal connected to one terminal of one of said driving magnets and a second outer terminal connected to one terminal of the other driving magnet, each interrupter having also a pair of driving contacts, one carried on the moving element of the interrupter and the other stationary and connected to the second terminal of the driving magnet, both of the interrupters adapted to be connected to the other side of said direct current source, and a primary winding for said transformer havin a center tap for connection to a direct current source of supply, the outer terminals of said primary winding being respectively connected to the respective rebound contacts of the interrupters.
  • an electrical system for converting current from a direct current source into alternating current and supplying same to a load
  • said system comprising transformer having a primary winding with two ends and a center tap and a secondary winding supplying alternating current to a load, the center tap of said primary winding being connected to one side of a direct current source of supply, at least two vibratory interrupters each having a vibratory contact, a relatively stationary magnet side contact and a relatively stationary rebound side contact between which the vibratory contact operates, a separate drive magnet for each vibratory contact including a coil, a synchronizing transformer for maintaining the vibratory members of the interrupters in phase comprising a secondary winding having a center tap adapted to be connected to one side of a direct current source of supply, an outer terminal connected to one terminal of one of said driving magnets and a second outer terminal connected to one terminal of the other driving magnet, each inter-- rupter having also a pair of driver contacts, one carried on the moving element of the interrupter and the other stationary and connected to the second terminal of the driving magnet

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Apparatuses For Generation Of Mechanical Vibrations (AREA)

Description

Feb. 28, 1950 J. A. MAS 2,498,893
PARALLEL OPERATION OF VIBRATOR SYSTEMS Filed July 14, 1944' Coil Edizr fly. 2 Y
I NVENTOR. JOSE 14. N/LS ATTORNEY.
Patented Feb. 28, 1950 PARALLEL OPERATION OF VIBRATO SYSTEMS J os A. Mas, Indianapolis, Ind., assignor, by mesne assignments, to Cornell-Dubilier Electric Corporation, South Plainileld, N. 1., a corporation of Delaware Application July 14, 1944, Serial No. 544,918
' 2 Claims. I
The present invention relates to vibrator interrupter systems and more particularly to vibrator interrupter systems having at least two vibrator interrupters.
One of the objects of my invention is to provide a vibrator interrupter system having at least two vibrating interrupters operatin substantially in synchronous frequency and in phase.
Another object of my invention is the provision of a vibrating interrupter system having at least two vibrating interrupters with means for insuring the operation of the interrupters in phase by imposing on the interrupters a voltage proportional to the amount of phase deviation so as to bring the lagging interrupter up in phase and slowing down the leading interrupter until the interrupters are in phase.
For the purpose of disclosing my invention 1 have illustrated an embodiment thereof in the accompanying drawing, in which:
Fig. l is a diagrammatic view of a vibrating interrupter system embodying my invention; and
Fig. 2 is ,a diagrammatic view showing an equivalent circuit of each vibrator coil insofar as their potentials are concerned.
Referring to the diagrammatic illustration shown in Fig. l, the vibrating interrupter system comprises a first vibrating interrupter circuit A and a second vibrator interrupter circuit B. Each of these circuits is connected to a transformer i having a split primary winding comprising two sections 2 and 3 and a secondary winding 4. The
primary winding is provided with a center tap connected with one side of a battery 5 which provides a direct current source and while I have illustrated the source as being a battery, it will be understood that any source of unidirectional current may be provided. The opposite side of the battery 5 is connected to the vibrating reed or contact 8 of the interrupter A and likewise'to the vibrating reed or contact 1 of the vibrating interrupter B. The vibrating contact member 5 vibrates between a pair of oppositely disposed relatively stationary contacts 9 and I0 and the vibrating reed or contact 1 vibrates between a pair of relatively stationary contacts I i and I2.
For driving the contact member 6, I provide a driving magnet having a coil i3 and for driving a member 1, I provide a driving magnet having a coil II.
In addition to the load transformer I, I provide a deviation transformer I 5 having a split secondary winding comprising the sections i6 and I1. The center tap of this winding is connected by a conductor II with one side of the battery 5. The outer terminal of the winding I1 is connected by a conductor I! with the driving magnet winding II, the opposite terminal of which is connected to a relatively stationary contact 20 in engagement with the vibrating contact 6, when the vibrating contact 6 is in neutral position. The outer terminal of the winding I6 is connected by a conductor 2i with one terminal of the driving magnet winding H for the vibrating contact I, the opposite terminal of this winding it being connected to a relatively stationary contact 22 in engagement, when the vibrating contact 1 is in neutral position, with the vibrating contact I.
For the purpose of identification, contacts ill and i2 are disposed on the same side of the vibrating contact members 9 and I and may be referred to as the magnet-side contacts. Contacts 9 and ii are likewise disposed on the same side of contacts 6 and 'l and may be referred to as rebound contacts.
The deviation transformer is provided with a pair of primary winding sections C and D. The primary C is a split primary windin having the two sections 23 and 24 and similarly the primary winding D is a split winding having the two sections 25 and 26. The center tap of the primary winding C is connected by a conductor 21 with the outer terminal of the primary winding 2 and similarly the center tap of the winding D is connected to the outer terminal of the primary winding section 3; The outer terminals of sections 23 and 24 of the winding C are respectively connected by conductors 28 and 29 with the rebound contacts ii and 9 and the outer terminals of the winding D are respectively connected by the conductors 30 and iii with the magnet-side contacts i2 and i0.
windings 23 and 24 are so constituted that when the interrupter contacts 6 and l are in phase the net flux in the core of the transformer I5 is zero. The voltage induced in windings l6 and H is, therefore, also zero. The driving magnet coils l4 and I3 are receiving the same voltage, namely the voltage of the source of continuous power.
The moment that one vibrator tries to lag or lead, a deviating voltage from the deviation transformer, proportional to the phase shift, is developed which is so phased that it gives a momentary kick to the lagging vibrator and lowers momentarily the voltage to the other, thus the vibrators are brought back in phase and the deviation time is kept at a minimum. For the purpose of example, we will assume that vibrator contact becomes a lagging contact. Under these circumstances vibrator I will complete a circuit through section 28 of the primary winding C, inducing a voltage in the deviation transformer secondary windings which will be added to the voltage of the battery to impress upon th winding ll of the lagging contact an additional voltage which will give it a momentary kick. At the same time an opposing voltage will be imposed on the circuit of the coil M through the secondary section ll, thus lowering the voltage of the coil It to bring the two vibrating contacts back into phase. It is apparent, therefore, that through the deviation transformer I am enabled to, in event the vibrating contacts operate out of phase, boost the voltage of one driving magnet and lower the voltage of the other until the two vibrating contacts are brought into phase relation. The circuit including the coils 25 and 26 is for dividing the load current on the contacts of the two vibrators.
Fig. 2 shows the equivalent circuit of each vibrator coil insofar as the A. C. components are concerned. The driving coil receives an injection of A. C. from the deviation transformer suflicient to synchronize it, and an added pulse, correctly phased from the deviating transformer. The A. C. components of the injection are in phase. The pulses are not. They are 180 out of phase. The voltage of each driving coil is therefore:
E1=Edc+Edic (deviation voltage) E2=Edc-Ediv (deviation voltage) I! the vibrators are in phase, the net deviation flux in the driving coil is zero. The moment that one vibrator tries to lag or lead, a deviation voltage proportional to the phase shift is developed and this voltage is such that it gives a momentary kick to the lagg n vibrator and lowere momentarily the voltage at the other.
I claim as my invention:
1. A vibratory interrupt ng system comprising, in combination, at least two vibratory interrupters each having a vibratory contact, a relativelystationary magnet side contact and a relatively stationary rebound side contact between which the vibratory contact operates, a separate driving magnet for each vibratory'contact including a coil, and a synchronizing transformer for maintaining the vibratory members of the interrupters in phase comprising a secondary winding having a center tap adapted to be connected to one side of a direct current source of supply, an outer terminal connected to one terminal of one of said driving magnets and a second outer terminal connected to one terminal of the other driving magnet, each interrupter having also a pair of driving contacts, one carried on the moving element of the interrupter and the other stationary and connected to the second terminal of the driving magnet, both of the interrupters adapted to be connected to the other side of said direct current source, and a primary winding for said transformer havin a center tap for connection to a direct current source of supply, the outer terminals of said primary winding being respectively connected to the respective rebound contacts of the interrupters.
2. In an electrical system for converting current from a direct current source into alternating current and supplying same to a load, said system comprising transformer having a primary winding with two ends and a center tap and a secondary winding supplying alternating current to a load, the center tap of said primary winding being connected to one side of a direct current source of supply, at least two vibratory interrupters each having a vibratory contact, a relatively stationary magnet side contact and a relatively stationary rebound side contact between which the vibratory contact operates, a separate drive magnet for each vibratory contact including a coil, a synchronizing transformer for maintaining the vibratory members of the interrupters in phase comprising a secondary winding having a center tap adapted to be connected to one side of a direct current source of supply, an outer terminal connected to one terminal of one of said driving magnets and a second outer terminal connected to one terminal of the other driving magnet, each inter-- rupter having also a pair of driver contacts, one carried on the moving element of the interrupter and the other stationary and connected to the second terminal of the driving magnet, both of the interrupters adapted to be connected to the other side of the direct current source and a primary winding for said transformer havin a center tap connected to one terminal of the primary winding of said first mentioned transformer, the outer terminals of said synchronizing transformer primary winding being respectively connected to the respective rebound contacts of the interrupters and a second primary winding for said synchronizing transformer having a center tap connected to the other outer terminal of the primary winding of said first mentioned transformer and its respective outer terminals connected to the respective magnet side contacts of the respective interrupters.
JOSE A. MAS.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number Name Date 2,113,762 James Apr. 12, 1938 2,209,806 Bedford July 30, 1940 2,265,717 Bedford Dec. 9, 1941 2,327,577 Brown Aug. 24, 1943 2,337,207 Nicholson Dec. 21, 1943 FOREIGN PATENTS Number Country Date 119,081 Great Britain 1919 181,070 Great Britain May 25, 1922
US54491344 1944-07-14 1944-07-14 Parallel operation of vibrator systems Expired - Lifetime US2498893A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2875397A (en) * 1954-09-02 1959-02-24 Rca Corp Synchronized vibrator system

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB119081A (en) * 1917-09-19 1918-09-19 Samuel Alexander Pollock Improvements in or relating to the Rectification of Alternating Currents of Electricity.
GB181070A (en) * 1921-02-25 1922-05-25 Samuel Alexander Pollock Improvements relating to the rectification of alternating currents of electricity
US2113762A (en) * 1933-04-03 1938-04-12 Stephen F James Vibrator transformer and rectifier
US2209806A (en) * 1938-09-29 1940-07-30 Gen Electric Electric translating apparatus
US2265717A (en) * 1940-06-28 1941-12-09 Gen Electric Electric translating apparatus
US2327577A (en) * 1942-01-31 1943-08-24 Harold J Brown Balanced interrupter system
US2337207A (en) * 1941-10-04 1943-12-21 Union Switch & Signal Co Alternating current supply means

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB119081A (en) * 1917-09-19 1918-09-19 Samuel Alexander Pollock Improvements in or relating to the Rectification of Alternating Currents of Electricity.
GB181070A (en) * 1921-02-25 1922-05-25 Samuel Alexander Pollock Improvements relating to the rectification of alternating currents of electricity
US2113762A (en) * 1933-04-03 1938-04-12 Stephen F James Vibrator transformer and rectifier
US2209806A (en) * 1938-09-29 1940-07-30 Gen Electric Electric translating apparatus
US2265717A (en) * 1940-06-28 1941-12-09 Gen Electric Electric translating apparatus
US2337207A (en) * 1941-10-04 1943-12-21 Union Switch & Signal Co Alternating current supply means
US2327577A (en) * 1942-01-31 1943-08-24 Harold J Brown Balanced interrupter system

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2875397A (en) * 1954-09-02 1959-02-24 Rca Corp Synchronized vibrator system

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