US2571803A - Electromagnet control mechanism with two armatures - Google Patents

Electromagnet control mechanism with two armatures Download PDF

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US2571803A
US2571803A US71536A US7153649A US2571803A US 2571803 A US2571803 A US 2571803A US 71536 A US71536 A US 71536A US 7153649 A US7153649 A US 7153649A US 2571803 A US2571803 A US 2571803A
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armature
flux
auxiliary
main
coil
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US71536A
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Fred H Winter
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General Electric Co
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General Electric Co
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H51/00Electromagnetic relays
    • H01H51/02Non-polarised relays
    • H01H51/20Non-polarised relays with two or more independent armatures

Definitions

  • the function of the pickup coil is to draw the movable armature into such a position with respect to the core and return circuit of the device as to form the best conductive path for a flux set up by electrical currents applied to the device. This position is called the closed position of the armature.
  • the holding coil has considerably less ampere turns than the pickup coil and draws less electrical energy.
  • the holding 0011 when energized produces a flux which adds to the flux produced by the pickup coil and thus aids in bringing the armature to its closed position
  • the energy required to be imparted to the holding coil is only the energy suflicient to produce a flux which will hold the armature in its closed position once that position is attained. For this reason it is desirable to conserve the amount of energy supplied to the device by disconnecting the pickup coil once the armature is closed and maintaining only the smaller energy supply to the holding coil.
  • auxiliary contacts in series with the control power supply of that coil.
  • One of these contacts is stationary and is secured to some part of the relay structure.
  • the other contact is movable and is operated when the armature strikes .on arm controlling the auxiliary contact operation.
  • Another object oi my invention is to provide an improved pickup coil control mechanism which requires no readjustment during the life of the relay.
  • my invention comprises an auxiliary contact means in series with the control power supply to the pickup coil of an electrical device and mechanically connected to an auxiliary contact armature which is responsive, when the main armature of the device is closed, to a leakage flux produced adjacent to the auxiliary contact armature and tends to rotate the latterinsuchamannerastoopentheauxiliary contact means, thereby disconnecting the pickup coil from the control power circuit.
  • Fig. 1 is an elevational view of a conventional direct current relay showing the application of my invention thereto
  • Fig. 2 is a plan view of an auxiliary contact armature forming a part of my invention
  • Fig. 3 is a partial side elevational view of the relay of Fig. 1 showing the main armature in closed position and the auxiliary armature contacts in open position.
  • Fig. 4 is a diagrammatic circuit of the control wiring of the relay shown in Fig. 1.
  • I provide an auxiliary contact means 9 electrically connected in series with the pickup coil 1 of a conventional direct current relay l, a spring biased auxiliary contact armature l3 pivotally supported on the relay I, a movable contact member ll secured to the auxiliary contact armature l3 and forming a part of the auxiliary contact means 9, and a means for providing a leakage flux adjacent to the auxiliary contact armature I: when the main armature 2 of the relay l is in its closed position, whereby the leakage flux thereby produced rotates the auxiliary contact armature is in the direction of the leakage ilux thereby opening contact means 9 and disconnecting the pickup coil 1.
  • a conventional direct current relay l of the hinged armature type As shown in Fig. l, I have used for the purpose of illustrating my invention a conventional direct current relay l of the hinged armature type.
  • a relay comprises, as shown in Fig. l, a main armature 2, a pole 3, a core 4, an L -shaped flux conducive member 5, a holding coil 6 and a pickup coil I.
  • the member 5 and the core I and the pole 3 together constitute a magnetizable frame which, together with the main armature 2, define a, main air gap between the pole 3 and the armature 2 in its unattracted position.
  • Coils 6 and I are both wound about the core 4 which in conjunction with pole 3, main armature 2, and L-shaped member 5, form a low reluctance magnetic circuit for a flux which is produced by passing an electrical current through either or both of coils t and I.
  • the flux necessary to move armature 2 to a closed position against the pole 3 in opposition to the bias of spring I onarmature 2 is considerably greater than the flux necessary to hold armature 2 in its closed position once that position is attained. Therefore, to close armature 2 both the holding coil 8 and the pickup coil 1 must be energizedto provide the necessary closing energy.
  • both the holding coil 8 and the pickup coil 1 must be energizedto provide the necessary closing energy.
  • I provide a contact means 9 comprising two stationary contacts Ill secured to relay I, as shown in Figs. 1 and 2, and a U-shaped movable contact member II made of any suitable conducting material and carrying two movable contacts I2. Contacts I and I2 form two pair of aligned contacts and are in series in the electrical supply circuit to the pickup coil 1, as shown in.
  • Movable contact member II is secured, as by rivets or other suitable means, to an auxiliary contact armature I3 pivotally supported on relay I and spring biased as by sprin I4 in the contact closing direction of contacts In and I2. Interposed in the magnetic circuit on the opposite side of auxiliary contact armature I3 from pole 3 I provide a flux resistant member I5 which may be in the form of a shim, as shown in Fig. 1.
  • Figs. 1, 4 and 3 To assist in understanding the operation of my invention, attention is directed to Figs. 1, 4 and 3 in order.
  • Fig. 1 when no current is applied to relay I, main armature 2 is biased open by the force of spring 8 and con- 1 tacts I0 and I2 are biased closed by the force of spring I4.
  • control switch I6 As shown in Fig. 4, is'closed current is supplied to pickup coil 6, which is electrically connected across two control power lines I1 and I8. Closing switch I6 also supplies current to holding coil I, which is also electrically connected to control power lines I1 and I8 and is in series with contacts I0 and I2 and movable contact member II.
  • the leakage flux 2I passes into one side and out of the other side of the auxiliary armature I3, so that the flux in a first leakage gap FI between pole 3 and armature I3 tends to hold the armature I3 in its dropped out position, while the flux in a second leakage gap F2 between the frame 5 and the armature I3 tends to pick up the armature I3. So long as the main armature 2 is dropped out these opposing forces on the auxiliary armature neutralize each other, and the spring I4 ensures that the armature I3 remains dropped out. However, when the main armature 2 picks up, as at Fig.
  • the leakage gap FI is shunted by the main armature, so that magnetic holding or restraining force on the auxiliary armature I3 is removed.
  • the leakage flux in the gap F2 then picks up the auxiliary armature to open the contacts I0, I2.
  • pickup coil 1 is disconnected from control power line H and only the holding coil 6 remains energized.
  • An advantage of the pickup control above described lies in the fact that the auxiliary contact control is not subject to damage resulting from the striking of the control means by the Another advantage of my pickup control is that the control is not dependent upon a spaced adjustment of the auxiliary control with respect to the motion of the main armature, which adjustment, if not correct, will cause improper closing of the main armature or improper opening of the pickup control power supply; but rather is dependent upon the elimination or production of a leakage flux inherent in the design of the control mechanism and for which no mechanical adjustment is necessary. Therefore, the necessity of repeated adjustments as a result of continued operation of the device is avoided and the proper control operation made more dependable.
  • this device may also be adapted to alternating current devices employing the use of pickup coils.
  • An electromagnetic device comprising a U- shaped magnetizable frame and a movable magnetizable main armature pivotally mounted upon one leg of said frame to bridge the open end of said frame, means normally maintaining said main armature in an unattracted position spaced from the other leg of said frame thereby to define a main flux gap, said frame and armature and main gap defining a main flux path, an energizing coil mounted upon said frame and adapted to be energized to attract said main armature to close said gap, an auxiliary armature pivotally mounted upon said frame and positioned to shunt" leakage flux from said main gap through a first part of said auxiliary armature and a first leakage gap when said main armature is in said unattracted position, the flux in said first leakage gap holding said auxiliary armature in a predetermined normal position, and a shim of high reluctance material positioned in another part of said main flux path adjacent said auxiliary armature to shunt leakage flux through a-

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  • Electromagnetism (AREA)
  • Electromagnets (AREA)

Description

F. H. WINTER Oct. 16, 1951 ELECTROMAGNET CONTROL MECHAN ISM WITH TWO ARMATURES Filed Jan. 18, 1949 IhvehtoT" FYed H. Winter Zuni-M. Hls Attor-Twey.
Patented 0a.,1c, 1951 ELECTROMAGNET CONTROL MECHANISM WITH TWO ABMATUBES Fred H. Winter, Schenectady, N .Y., assignor to General Electric Company, a corporation of New York Application January 18, 1949, Serial No. 71,536
1 Claim. (Cl. "Han This invention relates to electrical devices employing pickup coils, such as direct current relays and contactors and more particularly' to a control mechanism for operation of the pickup coil of such a device.
In electrical devices of the type comprising a pickup coil, a holding coil, a flux conductive core and return circuit, and a spring biased movable armature, the function of the pickup coil is to draw the movable armature into such a position with respect to the core and return circuit of the device as to form the best conductive path for a flux set up by electrical currents applied to the device. This position is called the closed position of the armature. The holding coil has considerably less ampere turns than the pickup coil and draws less electrical energy. Although the holding 0011 when energized produces a flux which adds to the flux produced by the pickup coil and thus aids in bringing the armature to its closed position, the energy required to be imparted to the holding coil is only the energy suflicient to produce a flux which will hold the armature in its closed position once that position is attained. For this reason it is desirable to conserve the amount of energy supplied to the device by disconnecting the pickup coil once the armature is closed and maintaining only the smaller energy supply to the holding coil.
To disconnect the pickup coil in such a device it is conventional to provide a pair of normally closed auxiliary contacts in series with the control power supply of that coil. One of these contacts is stationary and is secured to some part of the relay structure. The other contact is movable and is operated when the armature strikes .on arm controlling the auxiliary contact operation.
However, the hammer blow of the armature, after a time, does mechanical damage to the auxiliary control. Moreover, a small deviation in the proper spaced relationship of the armature and the control arm results in opening of the auxiliary contacts before the armature is completely closed and therefore the armature fails to close properly.
It is an object of my invention to provide an improved pickup coil mechanism which is simple in construction and reliable.
Another object oi my invention is to provide an improved pickup coil control mechanism which requires no readjustment during the life of the relay.
In general, my invention comprises an auxiliary contact means in series with the control power supply to the pickup coil of an electrical device and mechanically connected to an auxiliary contact armature which is responsive, when the main armature of the device is closed, to a leakage flux produced adjacent to the auxiliary contact armature and tends to rotate the latterinsuchamannerastoopentheauxiliary contact means, thereby disconnecting the pickup coil from the control power circuit.
' For a complete understanding of my invention, reference should be had to the following specification and accompanying drawing wherein Fig. 1 is an elevational view of a conventional direct current relay showing the application of my invention thereto, Fig. 2 is a plan view of an auxiliary contact armature forming a part of my invention, Fig. 3 is a partial side elevational view of the relay of Fig. 1 showing the main armature in closed position and the auxiliary armature contacts in open position. and Fig. 4 is a diagrammatic circuit of the control wiring of the relay shown in Fig. 1.
In carrying out my invention in one form, I provide an auxiliary contact means 9 electrically connected in series with the pickup coil 1 of a conventional direct current relay l, a spring biased auxiliary contact armature l3 pivotally supported on the relay I, a movable contact member ll secured to the auxiliary contact armature l3 and forming a part of the auxiliary contact means 9, and a means for providing a leakage flux adjacent to the auxiliary contact armature I: when the main armature 2 of the relay l is in its closed position, whereby the leakage flux thereby produced rotates the auxiliary contact armature is in the direction of the leakage ilux thereby opening contact means 9 and disconnecting the pickup coil 1.
For a complete understanding of my invention, attention is directed to Figs. 1, 2, and 4 in order. As shown in Fig. l, I have used for the purpose of illustrating my invention a conventional direct current relay l of the hinged armature type. Such a relay comprises, as shown in Fig. l, a main armature 2, a pole 3, a core 4, an L -shaped flux conducive member 5, a holding coil 6 and a pickup coil I. The member 5 and the core I and the pole 3 together constitute a magnetizable frame which, together with the main armature 2, define a, main air gap between the pole 3 and the armature 2 in its unattracted position. Coils 6 and I are both wound about the core 4 which in conjunction with pole 3, main armature 2, and L-shaped member 5, form a low reluctance magnetic circuit for a flux which is produced by passing an electrical current through either or both of coils t and I. The flux necessary to move armature 2 to a closed position against the pole 3 in opposition to the bias of spring I onarmature 2 is considerably greater than the flux necessary to hold armature 2 in its closed position once that position is attained. Therefore, to close armature 2 both the holding coil 8 and the pickup coil 1 must be energizedto provide the necessary closing energy. However,-
once armature 2 is closed, energy may be conserved by maintaining current in holding coil 6 only and disconnecting the power supply to the pickup coil 1.
To accomplish the disconnecting of pickup coil 1 when armature 2 is closed, in accordance with my invention, I provide a contact means 9 comprising two stationary contacts Ill secured to relay I, as shown in Figs. 1 and 2, and a U-shaped movable contact member II made of any suitable conducting material and carrying two movable contacts I2. Contacts I and I2 form two pair of aligned contacts and are in series in the electrical supply circuit to the pickup coil 1, as shown in.
Fig. 4. Movable contact member II is secured, as by rivets or other suitable means, to an auxiliary contact armature I3 pivotally supported on relay I and spring biased as by sprin I4 in the contact closing direction of contacts In and I2. Interposed in the magnetic circuit on the opposite side of auxiliary contact armature I3 from pole 3 I provide a flux resistant member I5 which may be in the form of a shim, as shown in Fig. 1.
To assist in understanding the operation of my invention, attention is directed to Figs. 1, 4 and 3 in order. As shown in Fig. 1, when no current is applied to relay I, main armature 2 is biased open by the force of spring 8 and con- 1 tacts I0 and I2 are biased closed by the force of spring I4. When control switch I6, as shown in Fig. 4, is'closed current is supplied to pickup coil 6, which is electrically connected across two control power lines I1 and I8. Closing switch I6 also supplies current to holding coil I, which is also electrically connected to control power lines I1 and I8 and is in series with contacts I0 and I2 and movable contact member II.
Once coils 6 and I are energized a flux is produced in the magnetic circuit comprising pole 3, core 4, L-shaped member 5 and armature 2. However, while the main armature 2 is still open, or dropped out, as shown at Fig. 1, a leakage flux shunting the main gap and the shim I5 passes through the auxiliary armature I3. At Fig. 1 I have indicated the main flux by a broken line 20, and the leakage flux by a broken line 2|. The leakage flux 2I passes into one side and out of the other side of the auxiliary armature I3, so that the flux in a first leakage gap FI between pole 3 and armature I3 tends to hold the armature I3 in its dropped out position, while the flux in a second leakage gap F2 between the frame 5 and the armature I3 tends to pick up the armature I3. So long as the main armature 2 is dropped out these opposing forces on the auxiliary armature neutralize each other, and the spring I4 ensures that the armature I3 remains dropped out. However, when the main armature 2 picks up, as at Fig. 3, the leakage gap FI is shunted by the main armature, so that magnetic holding or restraining force on the auxiliary armature I3 is removed. The leakage flux in the gap F2 then picks up the auxiliary armature to open the contacts I0, I2. Thus pickup coil 1 is disconnected from control power line H and only the holding coil 6 remains energized.
An advantage of the pickup control above described lies in the fact that the auxiliary contact control is not subject to damage resulting from the striking of the control means by the Another advantage of my pickup control is that the control is not dependent upon a spaced adjustment of the auxiliary control with respect to the motion of the main armature, which adjustment, if not correct, will cause improper closing of the main armature or improper opening of the pickup control power supply; but rather is dependent upon the elimination or production of a leakage flux inherent in the design of the control mechanism and for which no mechanical adjustment is necessary. Therefore, the necessity of repeated adjustments as a result of continued operation of the device is avoided and the proper control operation made more dependable.
With modiflcations, this device may also be adapted to alternating current devices employing the use of pickup coils.
While I have shown and described particular embodiments of my invention, it will be obvious to those skilled in the art that various changes and modifications may be made without departing from my invention in its broader aspects and I, therefore, aim in the appended claim to cover all such changes and modifications as fall within the true spirit and scope of my invention.
What I claim as new and desire to secure by Letters Patent of the United States is:
An electromagnetic device comprising a U- shaped magnetizable frame and a movable magnetizable main armature pivotally mounted upon one leg of said frame to bridge the open end of said frame, means normally maintaining said main armature in an unattracted position spaced from the other leg of said frame thereby to define a main flux gap, said frame and armature and main gap defining a main flux path, an energizing coil mounted upon said frame and adapted to be energized to attract said main armature to close said gap, an auxiliary armature pivotally mounted upon said frame and positioned to shunt" leakage flux from said main gap through a first part of said auxiliary armature and a first leakage gap when said main armature is in said unattracted position, the flux in said first leakage gap holding said auxiliary armature in a predetermined normal position, and a shim of high reluctance material positioned in another part of said main flux path adjacent said auxiliary armature to shunt leakage flux through a-second part of said auxiliary armature and a second leakage gap to attract said auxiliary armature from said normal position, whereby movement of said main armature to said attracted position reduces the flux in said first leakage gap' and permits said auxiliary armature to move under the influence of the flux in said second leakage file of this patent:
UNITED STATES PATENTS Number Name Date 890,220 Crane Jan. 29, 1906 1,142,852 Simon June 15, 1915 1,413,691 Slough Apr. 25, 1922 1,664,104- Carichofi Mar. 27, 1928 1,810,306 Trofimov June 16, 1931 1,978,737 Bower Oct. 30, 1931
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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2759130A (en) * 1952-11-14 1956-08-14 Bell Telephone Labor Inc Relay circuits
US2920693A (en) * 1951-12-05 1960-01-12 Baso Inc Flow interrupter for thermoelectrically powered control devices
US2942104A (en) * 1957-09-30 1960-06-21 Gen Motors Corp Low voltage transistorized signal seeking tuner
US2982832A (en) * 1958-07-08 1961-05-02 Square D Co Electrical device
US3018418A (en) * 1958-04-30 1962-01-23 Cannon Electric Co Solenoid
US3104302A (en) * 1960-05-16 1963-09-17 William J Williams Two point switch mechanism

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US890220A (en) * 1906-01-29 1908-06-09 Western Electric Co Electromagnetic signal-controlling device.
US1142852A (en) * 1913-10-10 1915-06-15 Cutler Hammer Mfg Co Electromagnet and solenoid.
US1413691A (en) * 1916-12-07 1922-04-25 Stromberg Carlson Telephone Relay
US1664104A (en) * 1924-02-09 1928-03-27 Gen Electric Electromagnetic device
US1810306A (en) * 1928-04-19 1931-06-16 Electric Controller & Mfg Co Electroresponsive device
US1978737A (en) * 1931-03-23 1934-10-30 Honeywell Regulator Co Solenoid

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US890220A (en) * 1906-01-29 1908-06-09 Western Electric Co Electromagnetic signal-controlling device.
US1142852A (en) * 1913-10-10 1915-06-15 Cutler Hammer Mfg Co Electromagnet and solenoid.
US1413691A (en) * 1916-12-07 1922-04-25 Stromberg Carlson Telephone Relay
US1664104A (en) * 1924-02-09 1928-03-27 Gen Electric Electromagnetic device
US1810306A (en) * 1928-04-19 1931-06-16 Electric Controller & Mfg Co Electroresponsive device
US1978737A (en) * 1931-03-23 1934-10-30 Honeywell Regulator Co Solenoid

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2920693A (en) * 1951-12-05 1960-01-12 Baso Inc Flow interrupter for thermoelectrically powered control devices
US2759130A (en) * 1952-11-14 1956-08-14 Bell Telephone Labor Inc Relay circuits
US2942104A (en) * 1957-09-30 1960-06-21 Gen Motors Corp Low voltage transistorized signal seeking tuner
US3018418A (en) * 1958-04-30 1962-01-23 Cannon Electric Co Solenoid
US2982832A (en) * 1958-07-08 1961-05-02 Square D Co Electrical device
US3104302A (en) * 1960-05-16 1963-09-17 William J Williams Two point switch mechanism

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