US3387188A - Magnetically latchable relay - Google Patents

Magnetically latchable relay Download PDF

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US3387188A
US3387188A US418727A US41872764A US3387188A US 3387188 A US3387188 A US 3387188A US 418727 A US418727 A US 418727A US 41872764 A US41872764 A US 41872764A US 3387188 A US3387188 A US 3387188A
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armature
core
coil
latching
energization
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George M Euler
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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
    • H01H47/00Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current
    • H01H47/22Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current for supplying energising current for relay coil
    • H01H47/226Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current for supplying energising current for relay coil for bistable relays

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  • ABSTRACT OF THE DISCLOSURE A magnetically latchable relay which is latched by energization of a circuit which provides a large inrush current to a latching coil and is unlatched by energization of an unlatching coil.
  • the large inrush current is provided by connecting a capacitor in series with the latching coil and a diode for energization from an AC or a DC source.
  • This invention relates to electromagnetically operated relays and has particular relation to magnetically latchable relays.
  • Relays of the magnetically latchable type have been proposed heretofore and generally include a magnetic core 'and a movable magnetic armature with a coil surrounding the core, the core being formed of a special material which exhibits a very high magnetic retentivity and a high permeability.
  • the coil When the coil is energized, the armature is attracted to the core and suflicient residual flux is established so that when the coil is deenergized, the armature remains attracted to the core.
  • a magnetically latchable relay including a core and an armature mounted for movement relative to the core.
  • a switch is arranged for operation in response to movement of the armature, and restoring means is provided to urge the armature out of engagement with the core.
  • Coil means surrounds the core and is connected to latching 'and unlatching circuits adapted for energization from a source of voltage.
  • the core is formed of conventional high silicon electrical steel containing approximately I /2% silicon, whereas the armature is formed of a material exhibiting a moderately high residual flux density of from 5000 to 6000 gauss 'and a moderately high coer- 3,337,188 Patented June 4, 1968
  • the latching circuit includes a device such as a capacitor which supplies a high inrush current to the coil means which quickly reduces to a low steady state value.
  • Each of the latching and unlatching circuits includes switch means for controlling energization of the respective circuits.
  • FIG. 1 is a diagrammatic representation of a magnetically latchable relay constructed in accordance with the present invention.
  • the relay shown is capable of energization from either a direct voltage or an alternating voltage source and includes a laminated generally U-shaped core 10 formed of a suitable magnetizable material such as conventional high silicon electrical steel.
  • the relay also includes a magnetic armature 12 which is mounted for movement in any suitable manner relative to the core 10. As illustrated, the armature 12 is mounted for pivotal movement at the upper end of the right-hand leg of the core 10. The material of the armature is described hereinafter.
  • the present invention is applicable to the relay disclosed in application S.N. 352,005, now Patent No. 3,236,969, filed Mar. 16, 1964, by G. M. Euler entitled Electromagnetically Operated Relays and assigned to the assignee of the present invention.
  • a suitable switch 16 is operated in accord with movements of the armature 12 and as diagrammatically shown, the armature supports a movable contact 18 for movement with respect to a fixed contact 20. In the normal position of the armature 12 as illustrated, the armature is spaced from the core 19 whereas the contacts 18 and 20 are likewise spaced from each other. Suitable restoring means in the form of a spring 22 is associated with the armature 12 to maintain the armature in its normal position spaced from the core. In order to magnetize the core 10 to attract the armature 12 to the core 10, there is provided coil means surrounding the core 10 and adapted for energ'mation from a suitable source of voltage.
  • the coil means is energized from a direct voltage source represented by the conductors 30 and 32 having the polarity shown by the associated plus and minus signs.
  • the coil means preferably comprises a pair of separate coils 46 and 50 oppositely wound on the core 10.
  • a pair of electrically separate latching and unlatching circuits 44 and 48 respectively include the coils 46 and 50 and are connected across the source of voltage represented by conductors 30 and 32. The provision of separate latching and unlatching circuits avoids undesired sneak circuits therebetween.
  • the material of the core 10 is conventional high silicon electrical steel which typically contains 08% carbon, .5% manganese, .05% phosphoms, .045% sulphur, l.52% silicon, .45-.55% aluminum and the remainder iron.
  • the coercive force of this material is about one oersted.
  • the armature 12 is formed of a readily available comparatively low cost material which exhibits a moderately high residual flux density, a moderately high coercive force and a fairly high permeability.
  • the material preferably employed for the armature 12 is a chrome magnet 3 steel known as Sparta steel AISI-AZ.
  • Such material typically contains 1.00% carbon, .65% manganese, 5.25% chromium, 30% silicon, 25% vanadium, 1.10% molybdenum with the remainder iron.
  • Such steel has particularly advantageous magnetic properties for purposes of the invention when heated at 1700 F. for twenty minutes, quenched in oil, and tempered at 300 F. for two hours.
  • a maximum magnetizing force of about 300 oersteds
  • a saturation induction of approximately 10,800 'gauss is obtained.
  • the maximum residual flux density realized when the magnetizing force is reduced to zero is of the order of 5,400 gauss.
  • this material exhibits a coercive force of about 57 oersteds and the permeability is approximately 80.
  • the armature 12 is the high coercive force portion of the magnetic circuit and exhibits a coercive force which is about fifty times that of the core 10.
  • the latching circuit 44 includes in series with the coil 46, a diode 52, a capacitor 54, and a switch 56.
  • a resistor 58 is connected in parallel with capacitor 54.
  • the switch 56 may be controlled in any suitable manner and when the switch 56 is closed, a pulse of direct current traverses the coil 46 to effect magnetization of the core to an extent sufficient to attract the armature 12 to the core against the bias of spring 22.
  • the capacitor 54 provides a high inrush current to the coil 46 to produce a strong magnetizing force with a small number of turns of the coil 46.
  • Resistor 58 operates to discharge thecapacitor 54 when switch 56 is opened to permit repeated operation of the device.
  • the high inrush current is quickly reduced to a low steady state value resulting in low power applied to the coil 46 it the switch 56 is kept closed for an extended period as required in certain applications.
  • the unlatching circuit 48 includes in series the coil 50, a diode 60, a resistor 62, and a switch 64.
  • switch 64 When switch 64 is closed, direct current flows through coil 50 to establish a magnetizing force effective to reduce the residual flux to a level below that sufficient to overcome the force of the spring 22 and maintain engagement of the armature with the core. As a result, the spring 22 returns the armature to its normal illustrated position.
  • the coercive force of the magnetic circuit is less than that of the armature material and does not require excessive magnetizing force to unlatch the armature.
  • the diodes 52 and 60 are poled in the same direction and are effective to prevent undesired current fiow in the associated circuit in response to voltage induced in the associated coil as a result of current flow in the other circuit.
  • the diodes also permit energization of the device from an alternating voltage source rather than from a direct voltage source.
  • the capacitor 54 can be replaced by a miniature incandescent lamp which also iS capable of providing a high inrush current and low steady state current.
  • a magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of magnetizable material, and an armature formed of magnetizable material, means mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, coil means surrounding said core, a latching circuit adapted for energization from a source of voltage, said latching circuit including in series said coil means, a rectifier, and an inrush current producing device,
  • a magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of magnetizable material, and an armature formed of a magnetizable material, rneans mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, coil means surrounding said core, a latching circuit adapted for energization from a source of voltage, said latching circuit including in series said coil means, a rectifier, and a capacitor, a resistor in parallel with said capacitor, means controlling energization of said latching circuit to effect energization of said coil means through said capacitor and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual flux having a value sufficient to maintain engagement of said armature and core when said latching circuit is deenergized, an unlatching circuit connected to said coil means for energization from a source of voltage
  • a magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of magnetizable material, and an armature formed of a magnetizable material, means mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, a latching circuit for energization from a source of voltage including a latching coil surrounding said core, a first rectifier in series with said latching coil, a capacitor in series with said first rectifier, and a resistor in parallel with said capacitor; means controlling energization of said latching circuit to effect energization of said latching coil and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual flux having a value sufiicient to maintain engagement of said armature and core when said latching circuit is deenerized, and unlatching circuit for energization from a source of
  • a magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of a silicon steel with at least one and one-half percent silicon, an armature formed of a chrome magnet steel With at least five percent chromium, means mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, a latching circuit for energization from a source of direct current voltage including a latching coil surrounding said core, a first rectifier in series with said latching coil, and an inrush current producing device in series with said first rectifier, means controlling energizat-ion of said latching circuit to effect energization of said latching coil and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual fiux having a value sufiicient to maintain engagement of said armature and core when said latching circuit is deenergized, an unlatching circuit

Description

June 4, 1968 G. M. EULER 3,387,188
MAGNETICALLY LATCHABLE RELAY Filed -Dec. 16, 1964 INVENTOR.
Giana: M. 01.52 By 9 M /aan ATTORNEY United States Patent Oflice 3,387,188 MAGNETICALLY LATCHABLE RELAY George M. Euler, Normal, EL, assignor to General Electric Company, a corporation of New York Filed Dec. 16, 1964, Ser. No. 418,727 7 Claims. (Cl. 317-1555) ABSTRACT OF THE DISCLOSURE A magnetically latchable relay which is latched by energization of a circuit which provides a large inrush current to a latching coil and is unlatched by energization of an unlatching coil. The large inrush current is provided by connecting a capacitor in series with the latching coil and a diode for energization from an AC or a DC source.
This invention relates to electromagnetically operated relays and has particular relation to magnetically latchable relays.
Relays of the magnetically latchable type have been proposed heretofore and generally include a magnetic core 'and a movable magnetic armature with a coil surrounding the core, the core being formed of a special material which exhibits a very high magnetic retentivity and a high permeability. When the coil is energized, the armature is attracted to the core and suflicient residual flux is established so that when the coil is deenergized, the armature remains attracted to the core.
Previous designs of magnetically latchable relays have suffered from several disadvantages. Among these is the high cost of the special core material employed. Further, previous designs have included a latching coil with a large number of turns and have employed high currents to obtain the necessary magnetizing force to assure sufiicient residual flux to maintain the armature in engagement with the core when the coil is deenergized. Such designs require that the coil be capable of dissipating large amounts of power especially in applications wherein the latching circuit is energized for relatively long periods of time. An example of a previous design of magnetically latchable relay is found in US. Patent 3,128,418.
It is therefore an object of the present invention to provide a novel and improved magnetically latchable relay having a latching coil with means for supplying a large inrush current to the coil which thereafter decreases to a relatively low steady state value.
It is another object of the invention to provide a novel and improved magnetically latchable relay of inexpensive design including a core formed of conventional electrical steel and an armature formed of material exhibiting both a moderately high residual flux density and a moderately high coercive force.
It is a further object of the invention to provide a novel and improved magnetically latchable relay of inexpensive and efiicient design utilizing readily available and low cost components and magnetic materials.
In carrying out the invention in one form a magnetically latchable relay is provided including a core and an armature mounted for movement relative to the core. A switch is arranged for operation in response to movement of the armature, and restoring means is provided to urge the armature out of engagement with the core. Coil means surrounds the core and is connected to latching 'and unlatching circuits adapted for energization from a source of voltage. The core is formed of conventional high silicon electrical steel containing approximately I /2% silicon, whereas the armature is formed of a material exhibiting a moderately high residual flux density of from 5000 to 6000 gauss 'and a moderately high coer- 3,337,188 Patented June 4, 1968 The latching circuit includes a device such as a capacitor which supplies a high inrush current to the coil means which quickly reduces to a low steady state value. Each of the latching and unlatching circuits includes switch means for controlling energization of the respective circuits.
Other objects and advantages of the invention will become apparent from the following description taken in conjunction with the accompanying drawing in which The figure is a diagrammatic representation of a magnetically latchable relay constructed in accordance with the present invention.
Referring now to the drawing there is diagrammatically illustrated a magnetically latchable relay constructed in accord with the present invention. The relay shown is capable of energization from either a direct voltage or an alternating voltage source and includes a laminated generally U-shaped core 10 formed of a suitable magnetizable material such as conventional high silicon electrical steel. The relay also includes a magnetic armature 12 which is mounted for movement in any suitable manner relative to the core 10. As illustrated, the armature 12 is mounted for pivotal movement at the upper end of the right-hand leg of the core 10. The material of the armature is described hereinafter. The present invention is applicable to the relay disclosed in application S.N. 352,005, now Patent No. 3,236,969, filed Mar. 16, 1964, by G. M. Euler entitled Electromagnetically Operated Relays and assigned to the assignee of the present invention.
A suitable switch 16 is operated in accord with movements of the armature 12 and as diagrammatically shown, the armature supports a movable contact 18 for movement with respect to a fixed contact 20. In the normal position of the armature 12 as illustrated, the armature is spaced from the core 19 whereas the contacts 18 and 20 are likewise spaced from each other. Suitable restoring means in the form of a spring 22 is associated with the armature 12 to maintain the armature in its normal position spaced from the core. In order to magnetize the core 10 to attract the armature 12 to the core 10, there is provided coil means surrounding the core 10 and adapted for energ'mation from a suitable source of voltage. In the embodiment illustrated the coil means is energized from a direct voltage source represented by the conductors 30 and 32 having the polarity shown by the associated plus and minus signs. The coil means preferably comprises a pair of separate coils 46 and 50 oppositely wound on the core 10. In order to control energization of the coils 46 and 50 a pair of electrically separate latching and unlatching circuits 44 and 48 respectively include the coils 46 and 50 and are connected across the source of voltage represented by conductors 30 and 32. The provision of separate latching and unlatching circuits avoids undesired sneak circuits therebetween.
As previously stated, the material of the core 10 is conventional high silicon electrical steel which typically contains 08% carbon, .5% manganese, .05% phosphoms, .045% sulphur, l.52% silicon, .45-.55% aluminum and the remainder iron. The coercive force of this material is about one oersted. In accord with the invention the armature 12 is formed of a readily available comparatively low cost material Which exhibits a moderately high residual flux density, a moderately high coercive force and a fairly high permeability. The material preferably employed for the armature 12 is a chrome magnet 3 steel known as Sparta steel AISI-AZ. Such material typically contains 1.00% carbon, .65% manganese, 5.25% chromium, 30% silicon, 25% vanadium, 1.10% molybdenum with the remainder iron. Such steel has particularly advantageous magnetic properties for purposes of the invention when heated at 1700 F. for twenty minutes, quenched in oil, and tempered at 300 F. for two hours. Upon the application of a maximum magnetizing force of about 300 oersteds, a saturation induction of approximately 10,800 'gauss is obtained. The maximum residual flux density realized when the magnetizing force is reduced to zero is of the order of 5,400 gauss. Also, this material exhibits a coercive force of about 57 oersteds and the permeability is approximately 80. The armature 12 is the high coercive force portion of the magnetic circuit and exhibits a coercive force which is about fifty times that of the core 10.
The latching circuit 44 includes in series with the coil 46, a diode 52, a capacitor 54, and a switch 56. A resistor 58 is connected in parallel with capacitor 54. The switch 56 may be controlled in any suitable manner and when the switch 56 is closed, a pulse of direct current traverses the coil 46 to effect magnetization of the core to an extent sufficient to attract the armature 12 to the core against the bias of spring 22. The capacitor 54 provides a high inrush current to the coil 46 to produce a strong magnetizing force with a small number of turns of the coil 46. When the switch 56 is opened, a residual flux is established in the magnetic circuit which results from the fairly high coercive force of armature 12 and which is effective to hold the armature in engagement with the core. Resistor 58 operates to discharge thecapacitor 54 when switch 56 is opened to permit repeated operation of the device. The high inrush current is quickly reduced to a low steady state value resulting in low power applied to the coil 46 it the switch 56 is kept closed for an extended period as required in certain applications.
The unlatching circuit 48 includes in series the coil 50, a diode 60, a resistor 62, and a switch 64. When switch 64 is closed, direct current flows through coil 50 to establish a magnetizing force effective to reduce the residual flux to a level below that sufficient to overcome the force of the spring 22 and maintain engagement of the armature with the core. As a result, the spring 22 returns the armature to its normal illustrated position. The coercive force of the magnetic circuit is less than that of the armature material and does not require excessive magnetizing force to unlatch the armature.
The diodes 52 and 60 are poled in the same direction and are effective to prevent undesired current fiow in the associated circuit in response to voltage induced in the associated coil as a result of current flow in the other circuit. The diodes also permit energization of the device from an alternating voltage source rather than from a direct voltage source. If desired, the capacitor 54 can be replaced by a miniature incandescent lamp which also iS capable of providing a high inrush current and low steady state current.
Although the invention has been described with reference to certain specific embodiments thereof, numerous modifications are possible and it is intended to cover all modifications falling within the spirit and scope of the invention.
Iclaim:
1. A magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of magnetizable material, and an armature formed of magnetizable material, means mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, coil means surrounding said core, a latching circuit adapted for energization from a source of voltage, said latching circuit including in series said coil means, a rectifier, and an inrush current producing device,
means controlling energization of said latching circuit to effect energization of said coil means through said inrush current producing device and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual flux having a value sufficient to maintain engagement of said armature and core when said latching circuit is deenergized, an unlatching circuit connected to said coil means for energization from a source of voltage, and means controlling energization of said unlatching circuit to effect energization of said coil means so as to reduce said residual flux to a value which permits said restoring means to move the armature out of engagement with said core.
2. A relay as defined in claim 1 wherein the armature is formed of a chrome magnet steel with at least five percent chromium, and the core is formed of high silicon electrical steel.
3. A magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of magnetizable material, and an armature formed of a magnetizable material, rneans mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, coil means surrounding said core, a latching circuit adapted for energization from a source of voltage, said latching circuit including in series said coil means, a rectifier, and a capacitor, a resistor in parallel with said capacitor, means controlling energization of said latching circuit to effect energization of said coil means through said capacitor and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual flux having a value sufficient to maintain engagement of said armature and core when said latching circuit is deenergized, an unlatching circuit connected to said coil means for energization from a source of voltage, and means controlling energization of said unlatching circuit to effect energization of said coil means so as to reduce said residual flux to a value which permits said restoring means to move the armature out of engagement with said core said capacitor being discharged through said resistor when said latching circuit is deenergized, such that subsequent reenergization of said latching circuit and said coil means will move said armature into engagement with said core.
4. A relay as defined in claim 3 wherein the armature is formed of a chrome magnet steel with at least five percent chromium and exhibiting a coercive force of from fifty to sixty oersteds.
'5. A magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of magnetizable material, and an armature formed of a magnetizable material, means mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, a latching circuit for energization from a source of voltage including a latching coil surrounding said core, a first rectifier in series with said latching coil, a capacitor in series with said first rectifier, and a resistor in parallel with said capacitor; means controlling energization of said latching circuit to effect energization of said latching coil and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual flux having a value sufiicient to maintain engagement of said armature and core when said latching circuit is deenerized, and unlatching circuit for energization from a source of voltage including an unlatching coil separate from said latching coil and wound on said core in opposition to said latching coil, and a second rectifier in series with said unlatching coil and poled in the same direction as said first rectifier; and means controlling energization of said unlatching circuit to efiect energization of said unlatching coil so as to reduce said residual flux to a value which permits said restoring means to move the armature out of engagement with said core.
6. A relay as defined in claim 5 wherein the armature is formed of a chrome magnet steel with at least five percent chromium and exhibiting a coercive force of from fifty to sixty oersteds, and the core is formed of high silicon electrical steel.
7. A magnetically latchable relay comprising in combination, a magnetic circuit including a core formed of a silicon steel with at least one and one-half percent silicon, an armature formed of a chrome magnet steel With at least five percent chromium, means mounting said armature for movement into and out of engagement with said core, a switch operable in response to movement of said armature, restoring means urging said armature out of engagement with said core, a latching circuit for energization from a source of direct current voltage including a latching coil surrounding said core, a first rectifier in series with said latching coil, and an inrush current producing device in series with said first rectifier, means controlling energizat-ion of said latching circuit to effect energization of said latching coil and move said armature into engagement with said core, said magnetic circuit when said armature and core are engaged providing a residual fiux having a value sufiicient to maintain engagement of said armature and core when said latching circuit is deenergized, an unlatching circuit for energization from said source of direct current voltage including an unlatching coil separate from said latching coil and Wound on said core in opposition to said latching coil, and a second rectifier in series with said unlatching coil and poled in the same direction as said first rectifier; and means controlling energization of said unlatching circuit to effect energization of said unlatching coil so as to reduce said residual flux to a value which permits said restoring means to move the armature out of engagement with said core, said armature material exhibiting a coercive force of from fifty to sixty oersteds and a residual flux density of from five thousand to six thousand gauss.
References Cited UNITED STATES PATENTS 2,427,750 9/ 1947 Snyder 317-151 2,441,984 5/1948 Armstrong 317-1555 X 2,928,027 3/ 1960 Dennison 317-154 3,010,053 11/1961 Schubert 317155.5
LEE T. HIX, Primary Examiner.
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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3896639A (en) * 1973-01-09 1975-07-29 Hayes Albion Corp Knitting machine actuators
US4409552A (en) * 1981-04-16 1983-10-11 Honeywell Inc. Cyclic means with magnetic latch for checking switch integrity
EP0111016A1 (en) * 1981-10-14 1984-06-20 Oded E. Sturman Integrated latching actuators
US4733212A (en) * 1987-04-29 1988-03-22 Wright Components, Inc. Pulse latching solenoid
US4758918A (en) * 1986-12-12 1988-07-19 Syndergeneral Corporation Advanced latching circuit
US5128826A (en) * 1989-01-27 1992-07-07 Aisan Kogyo Kabushiki Kaisha D.C. solenoid
US6295192B1 (en) * 1996-04-03 2001-09-25 Mitsubishi Denki Kabushiki Kaisha Switchgear
US8978313B1 (en) * 2014-04-04 2015-03-17 Antonio Pilla Precipitation deflector

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE2532558C2 (en) * 1975-07-21 1983-03-03 Siemens AG, 1000 Berlin und 8000 München Circuit arrangement for a remanence relay

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2427750A (en) * 1945-03-29 1947-09-23 Westinghouse Electric Corp Capacitor closed relay having retentive magnetic circuit
US2441984A (en) * 1944-10-12 1948-05-25 Westinghouse Electric Corp Electric circuit for electromagnets
US2928027A (en) * 1956-08-10 1960-03-08 Cutler Hammer Inc Electric circuit for direct current electromagnetic contactors
US3010053A (en) * 1957-09-13 1961-11-21 Westinghouse Electric Corp Triggered relay circuit

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2441984A (en) * 1944-10-12 1948-05-25 Westinghouse Electric Corp Electric circuit for electromagnets
US2427750A (en) * 1945-03-29 1947-09-23 Westinghouse Electric Corp Capacitor closed relay having retentive magnetic circuit
US2928027A (en) * 1956-08-10 1960-03-08 Cutler Hammer Inc Electric circuit for direct current electromagnetic contactors
US3010053A (en) * 1957-09-13 1961-11-21 Westinghouse Electric Corp Triggered relay circuit

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3896639A (en) * 1973-01-09 1975-07-29 Hayes Albion Corp Knitting machine actuators
US4409552A (en) * 1981-04-16 1983-10-11 Honeywell Inc. Cyclic means with magnetic latch for checking switch integrity
EP0111016A1 (en) * 1981-10-14 1984-06-20 Oded E. Sturman Integrated latching actuators
US4758918A (en) * 1986-12-12 1988-07-19 Syndergeneral Corporation Advanced latching circuit
US4733212A (en) * 1987-04-29 1988-03-22 Wright Components, Inc. Pulse latching solenoid
US5128826A (en) * 1989-01-27 1992-07-07 Aisan Kogyo Kabushiki Kaisha D.C. solenoid
US6295192B1 (en) * 1996-04-03 2001-09-25 Mitsubishi Denki Kabushiki Kaisha Switchgear
US8978313B1 (en) * 2014-04-04 2015-03-17 Antonio Pilla Precipitation deflector

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