US2284621A - Electromagnetic relay - Google Patents

Electromagnetic relay Download PDF

Info

Publication number
US2284621A
US2284621A US271730A US27173039A US2284621A US 2284621 A US2284621 A US 2284621A US 271730 A US271730 A US 271730A US 27173039 A US27173039 A US 27173039A US 2284621 A US2284621 A US 2284621A
Authority
US
United States
Prior art keywords
armature
post
sleeve
core
carrier
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
US271730A
Inventor
Clarence W Kuhn
Theodore F Rosing
William C Stevens
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.)
Cutler Hammer Inc
Original Assignee
Cutler Hammer Inc
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 Cutler Hammer Inc filed Critical Cutler Hammer Inc
Priority to US271730A priority Critical patent/US2284621A/en
Application granted granted Critical
Publication of US2284621A publication Critical patent/US2284621A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H50/00Details of electromagnetic relays
    • H01H50/64Driving arrangements between movable part of magnetic circuit and contact
    • H01H50/645Driving arrangements between movable part of magnetic circuit and contact intermediate part making a resilient or flexible connection

Definitions

  • This invention relates to electromagnetic relays and while not limited thereto is particularly adapted to alternating current relays which are to be operated with a minimum of electrical energy for their energizing circuit.
  • An object of the invention is to provide an improved relay which is reliable and positive in operation.
  • Another object is to provide a relay which When deenergized positively releases its armature.
  • Another object is to provide a novel method of securing the energizing coil of a relay so as to be rigidly held in place without any additional special parts for its securement.
  • Another object is to provide a simple and reliable bearing having a minimum of friction for the armature of a relay.
  • Another object is to provide a relay which may be easily adapted for the commutation of a variety of circuits.
  • Another object is to provide a simple guide for the rectilinear movement of the movable contacts of a relay, while the same are actuated by a pivoted rotating armature.
  • Another object is to provide a relay which is simple in construction and operation and easily assembled and adjusted and with a minimum of skill.
  • Figure 1 is a front view of the relay.
  • Fig. 2 is a section along 2-2 of Fig. 1.
  • Fig. 3 is a section along 3--3 of Fig. 1.
  • Fig. 4 is a bottom view of a device similar to Fig. 1, but including a modified contact arrangement and including a magnet to adapt the device for use with direct current, and
  • Fig. 5 is a section along 5-5 of Fig. 4.
  • i represents a moulded base of insulation which is suitably shaped to receive the various parts of the relay and insulate them from each other where required and also to permit their assembly with the base into a unitary structure.
  • a magnet frame 2 fashioned of a strip of magnetic material and having two limbs 3 and 4 arranged at right angles to each other, the limb 3 lying flat against the upper face of the base I.
  • a magnet core 5 held in place by a cap screw 6 which is threaded into the lower end of the core 5 and which passes through alined clearance holes 1 and 8 in the limb 3 and the base I respectively, so as to also fasten the frame 2 to the base I.
  • which penetrates alined openings in base I and limb 3 of the frame and has the shank end thereof upset, as shown in Fig. 3.
  • the upper end of the core 5 is provided with a transverse slot 9 which divides said end into two areas one of which is embraced by a number of like shading coils ill.
  • the shading coils are assembled with the core into a unitary structure by soldering the parts together.
  • the sectors of the shading coils outside of the slot 9 form a head for the core 5 which is adapted to secure an energizing coil H to said core and tr prevent it from sliding on said core in a longitudinal direction, while the coil II is securec' against rotation on the core by an end flange H which is integral with the coil at the inner fact thereof and which abuts the inside of the liml 4 of the frame 2.
  • the limb 4 is provided near its outer end at it: lateral edges with upstanding brackets or ears it each having a slot therein which provides a1 open pivotal bearing for the armature M of thi I elay.
  • a non-magnetic gap is interposed by making th armature ll of a fiat strip of composite material the outer side thereof being ferromagnetic, whil' ⁇ the inside is a thin layer of non-magnetic ma terial such as certain alloys of stainless or bronz steel. The two layers are welded together durin; the rolling of the strip or sheet from which th armature is made.
  • the non-magnetic layer i of such thickness that it interposes the lowes possible reluctance into the magnetic circui which will assure reliable release of the armaturt
  • This thickness is of the order of three thou sandths of an inch and is too thick to be pro prised economically and with uniformity b electroplating and too thin to be molded o soldered to the ferromagnetic layer.
  • the arma ture comprises two limbs l5 and IE which ar bent at a substantially right angle to each othe:
  • a pin I1 is welded or otherwise fastened to th limb l6 near the bend of the armature to ion a trunnion for the armature adapted to engag the bearings in the ears l3.
  • a stud I8 is rivete to the limb 4 of the magnet frame intermediate the ears l3 and the bend of the frame 2.
  • Th stud l8 passes through a hole in the armatui and is threaded at its outer end to receive an ad justing nut 9.
  • a spring 20 is interposed between the nut I9 and the armature to normally bias the latter away from the core -a bushing or washer 42 being preferably employed to provide an abutment for the upper end of spring 20 and to provide a proper bearing surface for engagement with the bosses or extrusions 43 formed on limb
  • the armature is adapted to actuate a bridging conductor or contact bar 2
  • the upper end of the bushing 22 is provided with a flange which limits the upward movement of the bar relative thereto, while the bar is loosely fitted to the bushing so as to permit a limited rocking motion of the bar, to facilitate adjustment of the cooperating contacts relative to each other and equalization of the contact pressure.
  • the limb l6 has its outer end forked and preferably provided with a cylindrical surface which engages the lower surface of the bar 2
  • the bushing 22 is s idable on a pin 23 riveted to the magnet frame limb 4 so as to provide for a rectilinear movement of the bar 2
  • a second bushing 24 is slidably mounted on the first bushing 22.
  • the bushing 24 is provided with a collar 25 which engages the lower face of the armature lever opposite the engagement thereof by the bar 2
  • the bushing 22 has its outer end threaded to receive an adjusting nut 26 for the adjustment of a spring 21 interposed between said nut and the collar 25.
  • the spring 21 cooperates with the spring 20 to bias the armature and to provide contact pressure for the bar 2
  • is prevented from substantial rotary displacement with reference to bushing 22 and pin 2
  • the nuts l9 and 26 may be permanently secured to the respective studs by soldering after adjustment of the relay.
  • the relay is provided with two sets of stationary contacts 29 and 30, respectively.
  • the contacts 29 are bridged by the bar 2
  • the pressure of the spring 20 biases the bar 2
  • the stationary contacts are each mounted on an angle shaped strip 31 which is screw-fastened to the base and which is provided with a terminal screw 32 for the connection of circuit conductors.
  • the contact buttons 38 are connected, through plates 39 carricd on insulating cross bar 40, with stationary terminals 34 by means of flexible leads 35each having one end welded or otherwise attached to a terminal plate 34 and the other end similarly attached to a plate 39, to thereby provide for completion of a circuit between the sets of terminals 34 and 31 when the relay is energized and the contact buttons 38 engage the buttons 30.
  • a horseshoe type permanent magnet 36 may be mounted at right angles to the base and intermediate of the contacts 30, as shown in Fig. 4, so that the poles of said magnet are located adjacent the contacts.
  • a contact carrier a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction
  • an operating member comprising an armature associated with said electromagnet and engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said op crating member, and a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction.
  • a contact carrier comprising an armature associated with said electromagnet and engaging said carrier and adapted to move it in said 40 one direction, a second sleeve, surrounding said first sleeve and adapted to engage said operating member, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, an open pivotal bearing and 5 a cooperating pivot pin for said operating member, and associated means to insure contact between said bearing and said pin.
  • a inagnet core an energizing coil surrounding said core, an L-shaped magnet frame partially surrounding said coil and affording a support for said core and forming therewith a magnetic circuit having an air gap, an armature bridging said air gap, said armature comprising a rolled bimetallic strip including a layer of ferromagnetic material and a layer of non-magnetic material welded integrally to the former and facing said core, a downwardly opening pivotal bearing for said armature attached to the lower surface of the horizontal portion of said frame and providing for oscillation of said armature relatively to said frame, biasing means including a coiled compression spring acting to bias said armature away from said core and to maintain contact between said armature and said bearing, a stationary contact, a movable contact adapted to engage said stationary contact, a stationary post rigidly attached to and depending from the hori' zontal portion of said frame upon which said movable contact is slidably mounted, means providing a positive driving connection between said movable contact and
  • an electromagnetic relay in combination, a magnet core, an energizing coil surrounding "said core, an L-shaped magnet frame partially surrounding said coil and forming with said core a magnetic circuit having an air gap, an armature for bridging said air gap, said armature comprising a rolled bimetallic strip including a layer of ferromagnetic material and a layer of nonmagnetic material welded integrally to the former and facing said core, a downwardly opening pivotal bearing mounted upon the lower surface of the horizontal portion of said frame and a cooperating pivot pin on said armature adapted to permit oscillation of the latter in response to changes in excitation of said magnetic circuit, cooperating stationary and movable contacts, a carrier for said movable contact, a stationary post attached to and depending from the horizontal portion of said frame and a sleeve slidable on said post affording sliding support for said carrier and adapted to limit its movement thereon in one direction, a connection between said armature and said carrier affording operation of the latter by the former in said
  • a contact carrier in combination, a contact carrier, a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said operating member, and a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction.
  • a contact carrier in combination, a contact carrier, a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said operating member, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, an open pivotal bearing and a cooperating pivot pin for said operating member, and associated means to insure contact between said pin and said bearing 8.
  • a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said operating member, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, an open pivotal bearing and a cooperating pivot pin for said operating member, a second post arranged intermediate of said bearing and said first post and an adjustable spring interposed between saiC operating member and said second post and affording contact between said pivot pin and saic bearing.

Landscapes

  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Electromagnets (AREA)

Description

u 1942- c. w. KUHN ETAL 2,234,521
ELECTROMAGNETIC RELAY Filed May 4. 1939 STATES UNITED PATENT OFFICE ELECTROMAGNETIC RELAY Clarence W. Kuhn, Wauwatosa, Theodore F. Rosing, Whitefish Bay, and William 0. Stevens, Milwaukee, Wis., assignors to Cutler-Hammer, Inc., Milwaukee, Wis., a corporation of Delaware Applicatimi May 4, 1939, Serial No. 271,730
8 Claims.
This invention relates to electromagnetic relays and while not limited thereto is particularly adapted to alternating current relays which are to be operated with a minimum of electrical energy for their energizing circuit.
An object of the invention is to provide an improved relay which is reliable and positive in operation.
Another object is to provide a relay which When deenergized positively releases its armature.
Another object is to provide a novel method of securing the energizing coil of a relay so as to be rigidly held in place without any additional special parts for its securement.
Another object is to provide a simple and reliable bearing having a minimum of friction for the armature of a relay.
Another object is to provide a relay which may be easily adapted for the commutation of a variety of circuits.
Another object is to provide a simple guide for the rectilinear movement of the movable contacts of a relay, while the same are actuated by a pivoted rotating armature.
Another object is to provide a relay which is simple in construction and operation and easily assembled and adjusted and with a minimum of skill.
Other objects and advantages will hereinafter The accompanying drawing is illustrative of a relay embodying the invention.
In the drawing,
Figure 1 is a front view of the relay.
Fig. 2 is a section along 2-2 of Fig. 1.
Fig. 3 is a section along 3--3 of Fig. 1.
Fig. 4 is a bottom view of a device similar to Fig. 1, but including a modified contact arrangement and including a magnet to adapt the device for use with direct current, and
Fig. 5 is a section along 5-5 of Fig. 4.
Referring to the drawing, i represents a moulded base of insulation which is suitably shaped to receive the various parts of the relay and insulate them from each other where required and also to permit their assembly with the base into a unitary structure. Mounted on the base is a magnet frame 2 fashioned of a strip of magnetic material and having two limbs 3 and 4 arranged at right angles to each other, the limb 3 lying flat against the upper face of the base I. Mounted on the limb 3 and perpendicular thereto is a magnet core 5 held in place by a cap screw 6 which is threaded into the lower end of the core 5 and which passes through alined clearance holes 1 and 8 in the limb 3 and the base I respectively, so as to also fasten the frame 2 to the base I. To insure against any possible movement of frame 2 relative to base I, I prefer to provide a hollow eyelet 4| which penetrates alined openings in base I and limb 3 of the frame and has the shank end thereof upset, as shown in Fig. 3. The upper end of the core 5 is provided with a transverse slot 9 which divides said end into two areas one of which is embraced by a number of like shading coils ill. The shading coils are assembled with the core into a unitary structure by soldering the parts together. Thus the sectors of the shading coils outside of the slot 9 form a head for the core 5 which is adapted to secure an energizing coil H to said core and tr prevent it from sliding on said core in a longitudinal direction, while the coil II is securec' against rotation on the core by an end flange H which is integral with the coil at the inner fact thereof and which abuts the inside of the liml 4 of the frame 2.
The limb 4 is provided near its outer end at it: lateral edges with upstanding brackets or ears it each having a slot therein which provides a1 open pivotal bearing for the armature M of thi I elay. To prevent retention of the armature ii fits attracted position due to residual magnetism 30; a non-magnetic gap is interposed by making th armature ll of a fiat strip of composite material the outer side thereof being ferromagnetic, whil' {the inside is a thin layer of non-magnetic ma terial such as certain alloys of stainless or bronz steel. The two layers are welded together durin; the rolling of the strip or sheet from which th armature is made. The non-magnetic layer i of such thickness that it interposes the lowes possible reluctance into the magnetic circui which will assure reliable release of the armaturt This thickness is of the order of three thou sandths of an inch and is too thick to be pro duced economically and with uniformity b electroplating and too thin to be molded o soldered to the ferromagnetic layer. The arma ture comprises two limbs l5 and IE which ar bent at a substantially right angle to each othe: A pin I1 is welded or otherwise fastened to th limb l6 near the bend of the armature to ion a trunnion for the armature adapted to engag the bearings in the ears l3. A stud I8 is rivete to the limb 4 of the magnet frame intermediate the ears l3 and the bend of the frame 2. Th stud l8 passes through a hole in the armatui and is threaded at its outer end to receive an ad justing nut 9. A spring 20 is interposed between the nut I9 and the armature to normally bias the latter away from the core -a bushing or washer 42 being preferably employed to provide an abutment for the upper end of spring 20 and to provide a proper bearing surface for engagement with the bosses or extrusions 43 formed on limb |6 of said armature. By adjusting the nut l9 and thus the tension of the spring 20 the biasing force can be varied.
The armature is adapted to actuate a bridging conductor or contact bar 2| which has its center supported by a bushing 22. The upper end of the bushing 22 is provided with a flange which limits the upward movement of the bar relative thereto, while the bar is loosely fitted to the bushing so as to permit a limited rocking motion of the bar, to facilitate adjustment of the cooperating contacts relative to each other and equalization of the contact pressure. The limb l6 has its outer end forked and preferably provided with a cylindrical surface which engages the lower surface of the bar 2|. The bushing 22 is s idable on a pin 23 riveted to the magnet frame limb 4 so as to provide for a rectilinear movement of the bar 2|. A second bushing 24 is slidably mounted on the first bushing 22. The bushing 24 is provided with a collar 25 which engages the lower face of the armature lever opposite the engagement thereof by the bar 2|. The bushing 22 has its outer end threaded to receive an adjusting nut 26 for the adjustment of a spring 21 interposed between said nut and the collar 25. The spring 21 cooperates with the spring 20 to bias the armature and to provide contact pressure for the bar 2|. Bar 2| is prevented from substantial rotary displacement with reference to bushing 22 and pin 2| by the provision of two ribs or ridges 28 on the insulating base as best illustrated in Fig. 3. The nuts l9 and 26 may be permanently secured to the respective studs by soldering after adjustment of the relay.
As shown in Figs. 1 and 2 the relay is provided with two sets of stationary contacts 29 and 30, respectively. The contacts 29 are bridged by the bar 2| which is provided with cooperating contact buttons 3|, when the relay is deenergized and the armature is biased away from the core 5, while the bar bridges the contacts 30 when the armature is in the attracted position. In this manner the pressure of the spring 20 biases the bar 2| against the flange of the bushing 22 and when the contacts 3| engage the contacts 30 the degree of compression of the spring 21 is increased (due to downward movement of bushing 24 relatively to bushing 22) to thereby produce the necessary contact pressure between the stationary and movable contacts 30 and 3| and also to amplify the bias acting on limb l6 of the armature as a result of the pressure of the spring 20. The stationary contacts are each mounted on an angle shaped strip 31 which is screw-fastened to the base and which is provided with a terminal screw 32 for the connection of circuit conductors.
In the modification shown in Figs. 4 and 5, the normally closed contacts 29 and their associated terminal plates 31 are omitted. In this modification adjustment of the air gap between the armature l4 and the core 5 is provided for by washers 33 shown in Fig. 3, which may be interposed between the bushing 22 and the limb 4 of frame 2. Furthermore, as shown in Figs. 4
and 5, if the contacts 29 are omitted, the contact buttons 38 are connected, through plates 39 carricd on insulating cross bar 40, with stationary terminals 34 by means of flexible leads 35each having one end welded or otherwise attached to a terminal plate 34 and the other end similarly attached to a plate 39, to thereby provide for completion of a circuit between the sets of terminals 34 and 31 when the relay is energized and the contact buttons 38 engage the buttons 30.
If the relay is employed to control a direct our- JO rent circuit it is frequently desirable to provide for a magnetic field at the contacts to facilitate the extinguishment of an are which may form upon opening of the circuit. In this case a horseshoe type permanent magnet 36 may be mounted at right angles to the base and intermediate of the contacts 30, as shown in Fig. 4, so that the poles of said magnet are located adjacent the contacts.
What we claim as new and desire to secure by Letters Patent is:
1. In an electromagnetic relay, a contact carrier, a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member comprising an armature associated with said electromagnet and engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said op crating member, and a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction.
2. In an electromagnetic relay, a contact carrier, a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member comprising an armature associated with said electromagnet and engaging said carrier and adapted to move it in said 40 one direction, a second sleeve, surrounding said first sleeve and adapted to engage said operating member, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, an open pivotal bearing and 5 a cooperating pivot pin for said operating member, and associated means to insure contact between said bearing and said pin.
3. In an electromagnetic relay, a contact carrier, a stationary post, a sleeve slidable on said post afiording a sliding support for said carrier m cooperating pivot pin for said operating member,
a second post arranged intermediate of said bearing and said first post, and an adjustable spring interposed between said operatingmember and saidsecond post and affording contact between sa' bearing and said pin.
4. In an electromagnetic relay, in combination,
a inagnet core, an energizing coil surrounding said core, an L-shaped magnet frame partially surrounding said coil and affording a support for said core and forming therewith a magnetic circuit having an air gap, an armature bridging said air gap, said armature comprising a rolled bimetallic strip including a layer of ferromagnetic material and a layer of non-magnetic material welded integrally to the former and facing said core, a downwardly opening pivotal bearing for said armature attached to the lower surface of the horizontal portion of said frame and providing for oscillation of said armature relatively to said frame, biasing means including a coiled compression spring acting to bias said armature away from said core and to maintain contact between said armature and said bearing, a stationary contact, a movable contact adapted to engage said stationary contact, a stationary post rigidly attached to and depending from the hori' zontal portion of said frame upon which said movable contact is slidably mounted, means providing a positive driving connection between said movable contact and said armature in one direction of movement of the latter, and means providing a resilient driving connection between said parts in the opposite direction of movement of said armature, said last mentioned means including a coiled compression spring underlying said armature and said movable contact.
5. In an electromagnetic relay, in combination, a magnet core, an energizing coil surrounding "said core, an L-shaped magnet frame partially surrounding said coil and forming with said core a magnetic circuit having an air gap, an armature for bridging said air gap, said armature comprising a rolled bimetallic strip including a layer of ferromagnetic material and a layer of nonmagnetic material welded integrally to the former and facing said core, a downwardly opening pivotal bearing mounted upon the lower surface of the horizontal portion of said frame and a cooperating pivot pin on said armature adapted to permit oscillation of the latter in response to changes in excitation of said magnetic circuit, cooperating stationary and movable contacts, a carrier for said movable contact, a stationary post attached to and depending from the horizontal portion of said frame and a sleeve slidable on said post affording sliding support for said carrier and adapted to limit its movement thereon in one direction, a connection between said armature and said carrier affording operation of the latter by the former in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said armature, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, a second post attached to and depending from said horizontal portion of the frame intermediate of said bearing and said first post, and an adjustable spring interposed between said armature and said second post and normally insuring contill tact between said pivot pin and said bearing and biasing of said armature away from said core, said first mentioned spring providing a resilient driving connection between said armature and said carrier during movement of the armature to its attracted position.
6. In a device of the character described, in combination, a contact carrier, a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said operating member, and a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction.
7. In a device of the character described, in combination, a contact carrier, a stationary post, a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said operating member, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, an open pivotal bearing and a cooperating pivot pin for said operating member, and associated means to insure contact between said pin and said bearing 8. In a device of the character described, in
combination, a contact carrier, a stationary post,
a sleeve slidable on said post affording a sliding support for said carrier and limiting its movement thereon in one direction, an operating member engaging said carrier and adapted to move it in said one direction, a second sleeve surrounding said first sleeve and adapted to engage said operating member, a biasing spring interposed between said sleeves and adapted to bias said second sleeve in said one direction, an open pivotal bearing and a cooperating pivot pin for said operating member, a second post arranged intermediate of said bearing and said first post and an adjustable spring interposed between saiC operating member and said second post and affording contact between said pivot pin and saic bearing.
CLARENCE W. KUHN.
THEODORE F. ROSING.
WILLIAM C. STEVENS.
US271730A 1939-05-04 1939-05-04 Electromagnetic relay Expired - Lifetime US2284621A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US271730A US2284621A (en) 1939-05-04 1939-05-04 Electromagnetic relay

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US271730A US2284621A (en) 1939-05-04 1939-05-04 Electromagnetic relay

Publications (1)

Publication Number Publication Date
US2284621A true US2284621A (en) 1942-06-02

Family

ID=23036825

Family Applications (1)

Application Number Title Priority Date Filing Date
US271730A Expired - Lifetime US2284621A (en) 1939-05-04 1939-05-04 Electromagnetic relay

Country Status (1)

Country Link
US (1) US2284621A (en)

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2441137A (en) * 1943-10-05 1948-05-11 Anthony Robert P De Automatically locking relay
US2510028A (en) * 1945-11-01 1950-05-30 Yale & Towne Mfg Co Motor control apparatus
US2839631A (en) * 1954-07-28 1958-06-17 Gen Electric Electromagnetic device
US3242285A (en) * 1963-03-21 1966-03-22 Guardian Electric Mfg Co Relay with unitary field piece construction
US3479627A (en) * 1966-09-15 1969-11-18 Cornell Dubilier Electric Electromagnetic relay and method of manufacture thereof
US4225838A (en) * 1977-07-29 1980-09-30 Societe D'appareillage Electrique Saparel Electro-magnetic relay with first and second spring biasing means
US4344055A (en) * 1979-04-24 1982-08-10 Mitsubishi Denki Kabushiki Kaisha Automatic trip device for circuit interrupter
US20190082148A1 (en) * 2017-09-14 2019-03-14 Jeffrey Overall Drone Stabilizing Handgrip

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2441137A (en) * 1943-10-05 1948-05-11 Anthony Robert P De Automatically locking relay
US2510028A (en) * 1945-11-01 1950-05-30 Yale & Towne Mfg Co Motor control apparatus
US2839631A (en) * 1954-07-28 1958-06-17 Gen Electric Electromagnetic device
US3242285A (en) * 1963-03-21 1966-03-22 Guardian Electric Mfg Co Relay with unitary field piece construction
US3479627A (en) * 1966-09-15 1969-11-18 Cornell Dubilier Electric Electromagnetic relay and method of manufacture thereof
US4225838A (en) * 1977-07-29 1980-09-30 Societe D'appareillage Electrique Saparel Electro-magnetic relay with first and second spring biasing means
US4344055A (en) * 1979-04-24 1982-08-10 Mitsubishi Denki Kabushiki Kaisha Automatic trip device for circuit interrupter
US20190082148A1 (en) * 2017-09-14 2019-03-14 Jeffrey Overall Drone Stabilizing Handgrip

Similar Documents

Publication Publication Date Title
US2539547A (en) Relay
US2321834A (en) Relay
US2569281A (en) Contact mechanism for automatic circuit breakers and similar electrical switchgear
US2273545A (en) Electric switch
US2266536A (en) Electric relay
US2436224A (en) Differential electromagnet having snap action
US2284621A (en) Electromagnetic relay
US2447632A (en) Magnetic lock relay
US2735967A (en) Electromagnetic relays
US3848206A (en) Electromagnetic solenoid with improved contact antibounce means
US2257900A (en) Tube switch
US3727157A (en) Electric control device
US1839629A (en) Push button switch for elevators
US2881365A (en) Neutral relay
US2299671A (en) Electromagnetic motor switch
US2235861A (en) Electromagnetic relay
US3110789A (en) Thermally actuated cycling switch
US3588765A (en) Electromagnetic relays
US2915683A (en) Electromagnetic relays
US2524874A (en) Electromagnetic relay construction
US3825865A (en) Electromagnetic relay
US1996606A (en) Repulsion relay
US2463333A (en) Electric switch
US2545587A (en) Electromagnetic relay
US1904847A (en) Electromagnetic device