US2153291A - Electromagnetic relay - Google Patents
Electromagnetic relay Download PDFInfo
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- US2153291A US2153291A US79637A US7963736A US2153291A US 2153291 A US2153291 A US 2153291A US 79637 A US79637 A US 79637A US 7963736 A US7963736 A US 7963736A US 2153291 A US2153291 A US 2153291A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01H—ELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
- H01H47/00—Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current
- H01H47/02—Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current for modifying the operation of the relay
- H01H47/04—Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current for modifying the operation of the relay for holding armature in attracted position, e.g. when initial energising circuit is interrupted; for maintaining armature in attracted position, e.g. with reduced energising current
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- the present invention relates to electro-magnetic relays, and has for its object the production of a new and improved electro-magnetic relay which is reliable in operation and which will actuate and maintain actuated a relatively large number of contact springs.
- the line or operating winding of the relay is of necessity ren) moved from the circuit upon the operation of the relay, leaving only the polarizing winding energized to maintain the relay actuated until such time as it is desired to permit the relay to restore.
- the non-holding tendency is greater when, with a heavy spring load, the stroke or armature travel distance is reduced in order to favor speedy oper ation, for then the polarizing yoke is adjusted to cause the armature in its restored position to stand close to the end of the core. Therefore, the armature does not move very far from the polarizing yoke upon operating, and a large amount of flux is shunted from the armature end of the core to the armature by way of the yoke.
- the shunted flux not only fails to assist in maintaining the armature attracted against the spring load, but also operates to apply an additional restoring urge to the armature.
- the difliculties above discussed are remedied by placing a third or holding winding on the relay around that portion of the core which lies between its intermediate pole shoe and the armature, around which portion the operating winding is also wound. It has been found that a winding placed on this portion of the core is more efficient in maintaining the relay operated than is one on the heel end, because magnetic energy generated in this portion of the core is not so subject to leakage diversion (principally through the polarizing yoke).
- Figs. 1-8 show related views in orthographic projection of the Pye relay modifled in accordance with the present invention
- Fig. 6 is a schematic drawing of the improved relay
- Figs. 7 and 8 show two typical circuit arrangements employed in the use of the relay.
- Figs. 1-3 show a front view, a side view, and a rear view, respectively, of the improved relay;
- Fig. 4 shows a top view; and
- Fig. shows a bottom view of the relay.
- the relay shown in Figs. 1-5 is composed essentially of the coil assembly I, the heel piece 2, armature I, and the polarizing yoke l.
- Armature I is provided with spring-actuating arms I! and II, each of which actuates one of the spring assemblies II and II, secured to heel piece 2 as indicated, the contact springs in assemblies II and II being insulated from each other.
- the coil assembly I includes the central magnetic core I, over which core spool-heads
- the intermediate pole shoe 8 is a piece of magnetic material having a hole therein through which the core 6 is passed, and it is provided with suitable tapped holes to enable the polarizing yoke l to be adiustably mounted therein.
- suitably provided with a protective covering, is wound in the winding space lying between spool heads I and II. The ends of the polarizing winding are secured to terminals 24 and II, carried by spool head II.
- Holding winding 2I and operating winding is are wound in the winding space between spool heads I and I, being separated from each other by the winding separator II.
- the ends of the windings are secured to terminals 25 and 26 in spool head It, terminal 25 serving as a common terminal for one end of each of the windings 2. and 2
- pass through holes in the rear corners of spool heads I and II and thence to the base of terminals 25 and II beneath the covering of winding 2
- Terminal 22 is connected by means of strap wire 28 to coil terminal 21 of spool II, as may be seen best in Figs. 1 and 3, while terminal 2I is connected by means of strap wire 2! to terminal I2 mounted in the spring assembly II.
- These two strap wires, 22 and 29, are provided in order to provide terminals of the operating winding which are accessible from the terminal end of the relay, on the back side of the mounting plate (not shown) to which the relay is mounted by means of screws which pass through tapped holes in heel piece 2, as may be seen in Fig. 5.
- armature I is provided with a pair of lugs through which it is hinged to corresponding lugs on armature bracket II by means of a bearing pin.
- Armature bracket II is mounted on heel piece 2 by means of a mounting screw which passes through lug washer II and through a vertical slot (not shown) in bracket iI.
- a guide lug on washer l4 passes into hole
- one pole of the current source is connected preferably to terminal 25, which serves as a common terminal for one end of the polarizing winding 2
- the other pole of the current source is connected to terminal 24, to which the other end of winding 2
- Winding I9 is connected in the operating circuit through terminals 22 and 22, by way of strap wires 28 and 29, extending to coil terminal 21 and to spring-assembly terminal I2, respectively, the conductors of the operating circuit being attached to terminals 21 and I2.
- the holding winding 20 may be connected in circuit upon the operation of the relay by applying the other pole of the current source through contacts of the relay to coil terminal 26, the first pole of the current source having been connected to one terminal of winding 20 by way of coil terminal 20, as previously noted.
- Winding 20 may be wound so as to produce a relatively powerful flux through the portion of the core encircled thereby, which flux is driven through the upper end of core 0 to the armature 3, returning for the most part through the heel piece 2 to the lower end of core 0. Being located on the inside of the path through the polarizing yoke 4, the winding 20 is relatively efllcient in holding armature 2 operated. compared to the expenditure of similar power in polarizing winding 20, due to the somewhat adverse location previously noted of winding 2
- one pole of the current source may be disconnected from terminals 24 and 26, de-energizing both the polarizing winding 2i and the holding winding 20.
- the controlled pole of the current source may be disconnected from terminal 24 upon the operation of the relay, leaving only winding 20 energized (through terminals 26 and 25) to maintain the relay operated. Under this condition, it is merely riecessary to disconnect terminal 26 to thereby deenergize winding 20 to permit the relay to restore.
- Circuit operation of the improved relay The circuit operation of the improved relay will be understood more fuliy upon reference to the following description of the typical circuits illustrated in Figs. 7 and 8.
- Fig. '7 shows a circuit arrangement in which the improved relay is held up, when once op erated, by cooperation of the holding winding and the polarizing winding.
- Fig. 8 a circuit arrangement is shown whereby the relay is held up, when once operated, by the holding winding alone.
- Key 20I is closed to energize polarizing winding 2
- the circuit of winding I9 is held open at key 202 and the circuit of winding 20 is held open at contact 200 so that the relay does not operate.
- key 202 is momentarily closed winding I9 is energized to assist winding 2
- contact 203 is closed to complete the circuit for the holding winding 20 which energizes, and contact 204 is opened to effect the deenergization of windings I0 and 2
- windings l9 and 20 may be placed on the armature end of the core 6 in the form of concentric windings instead of segregating windings as illustrated.
- An electro-polarlzed relay having a core and an armature actuatable when the core is sufliciently energized, contact springs actuatable by said armature when it is attracted to the core, a polarizing winding, an operating winding, and a holding winding, all on said core, said armature being non-responsive to energization of said polarizing winding alone, but responsive to simultaneous energization of the polarizing winding and the operating winding to actuate said contact springs, and circuit connections rendered effective upon the actuation of said contact springs for energizing the holding winding in a direction to aid in holding the armature actuated.
- an electro-polarized relay having a core and an armature attractable to said core when the core is sufiiciently energized, contact springs actuatable by said armature when it is attracted by the core, a polarizing winding, an operating winding, and a holding winding, all on said core, said armature being non-responsive to energization of said polarizing winding alone to actuate said contact springs, but responsive to simultaneous energization of polarizing winding and operating winding to actuate said contact springs, circuit connections rendered eifective upon the actuation of said contact springs for deenergizing said operating winding, and additional circuit connections rendered eflective upon the actuation of said contact springs for energizing said holding winding in the same direction as the operating winding was energized and sufliciently to maintain the relay actuated after the operating winding is deenergized.
- an electro-polarized relay having a core and an armature attractable to the core when the core is sumciently energized, contact springs actuatable by said armature when it is attracted by the core, a polarizing winding, an operating winding, and a holding winding, all on said core, said armature being non-responsive to energization of said polarizing winding alone, but responsive to simultaneous energization oi the polarizing winding and the operating winding to actuate said contact springs, and circuit connections rendered efiective upon the actuation or said contact springs for deenergizing said polarizing and operating windings and for energizing said holding windings to maintain the relay operated after the polarizing and operating windings have become deenergized.
- a relay having three windings, means for first energizing the first winding in a given direction to polarize the relay, means for energizing the second winding in the same direction to operate the relay, and means for thereafter energizing the third winding in the same direction to hold the relay operated.
- an electro-polarized relay comprising a core, a magnetic return heel piece secured to one end of the core, an armature mounted for operation in a magnetic circuit between the iree end of the heel piece and the free end of the core when the core is sufiiciently energized, an intermediate pole shoe of magnetic material mounted on an intermediate portion of the core, a polarizing yoke mounted on said intermediate pole shoe and being of such a configuration as to normally contact the armature and serve as a backstop therefor, a polarizing winding wound on the end of the core which lies on the side of the intermediate polarizing yoke away from the armature, and operating winding wound on said core on the end thereon lying between the armature and the intermediate pole shoe, a holding winding also wound on the portion or the core lying between the armature and the intermediate pole shoe, means for energizing the polarizing winding to polarize the relay by the passage oi magnetic that through the polarizing yoke, whereby the
- an electro-polarized relay having three windings, means for energizing the first winding to polarlze the relay, means ior energizing the second winding to actuate the relay by the combined influence otthe first and second windings, means responsive to the actuation of the relay for energizing the third winding to hold the relay operated, and ior deenergizing the operating winding, and means for deenergizing the holding and polarizing windings to bring about a restoration of the relay,
- an electro-polarized relay having three windings, means for energizing one winding to polarize the relay, means for energizing the second winding to operate the relay in conjunction with the energization oi the first winding, means responsive to the energization of the relay for energizing the third winding in the same direction as the first two were energized to hold the relay operated, and means also responsive to the operation of the relay for deenergizing the polarizing and operating windings, said holding winding being effective to hold the relay operated indefinitely after the other two windings are deenergized, and means for subsequently deenergizing the holding winding to permit the relay to restore.
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Description
April 1939- P. BAKKER 2,153,291
ELECTROMAGNETI C RELAY Filed May 14, 1936 2 Sheets-Sheet l INVENTOR. Pl E R BA KKER 'JZ W ATTORNEY.
Patented Apr. 4, 1939 UNITED STATES PATENT OFFICE 2,153,291 ELECTROMAGNETIC RELAY Application May 14,
7 Claims.
The present invention relates to electro-magnetic relays, and has for its object the production of a new and improved electro-magnetic relay which is reliable in operation and which will actuate and maintain actuated a relatively large number of contact springs.
General description It has been chosen to illustrate the invention 10 as applied to a relay of the general type disclosed in Patent 1,673,884 granted June 19, 1928, to
Harold C. Pye. The Pye relay-has been widely used in automatic telephone systems and in similar systems employing testing and switching relays when a relay is required which is fast to operate and which will at the same time actuate a number of contact springs. In many circum- :;tances under which this relay is used, the line or operating winding of the relay is of necessity ren) moved from the circuit upon the operation of the relay, leaving only the polarizing winding energized to maintain the relay actuated until such time as it is desired to permit the relay to restore.
It has been often found, however, that the polariz- ==5 ing winding of the relay does not afford suflicient energization of the relay to maintain it operated after the operating winding has been removed from the circuit in the event that the relay is carrying an excessively heavy spring load, such :0 as may obtain when a large number of spring contacts are arranged to be actuated by the relay and the contact springs are somewhat heavily tensioned, or are stamped from relatively thick material. This difliculty may be partially overcome in practice by giving each relay a special adjustment under current after assembly, but such procedure is somewhat costly in a manufacturing operation; moreover, the desired contact pressure or the operating speed must often be sacrificed somewhat in order to enable the relay to remain operated from the polarizing winding alone.
Attempts have been made to overcome the difficulty by increasing the magnetizing power of the polarizing winding by the well-known process of winding it with wire of a larger diameter, but a new difliculty is then experienced in that the relay tends to operate from the polarizing winding alone before the operating winding is energized. This tendency results largely from saturation of the armature at its point of contact with the polarizing yoke serving as a backstop. Also energization of the polarizing winding beyond a critical value results in excessive power consumption and consequent inability of the winding to dissipate heat at a rate sufficient to prevent 1936, Serial No. 79,637
damage to the winding insulation when the relay is energized for a considerable time.
Other attempts have been made to overcome the non-holding difliculty by connecting the operating winding in the holding circuit when the operating circuit is opened, so asto cause the operating winding to aid the polarizing winding in holding the relay operated. This procedure, although successful, is somewhat involved in that it often requires switching both terminals of the operating winding from one circuit to the other, which switching operation must be performed through make-before-break contacts in order to avoid momentarily interrupting the holding circuit. Several additional contact springs are thus required, still further loading the relay.
The non-holding tendency is greater when, with a heavy spring load, the stroke or armature travel distance is reduced in order to favor speedy oper ation, for then the polarizing yoke is adjusted to cause the armature in its restored position to stand close to the end of the core. Therefore, the armature does not move very far from the polarizing yoke upon operating, and a large amount of flux is shunted from the armature end of the core to the armature by way of the yoke. The shunted flux, not only fails to assist in maintaining the armature attracted against the spring load, but also operates to apply an additional restoring urge to the armature.
By the present invention, the difliculties above discussed are remedied by placing a third or holding winding on the relay around that portion of the core which lies between its intermediate pole shoe and the armature, around which portion the operating winding is also wound. It has been found that a winding placed on this portion of the core is more efficient in maintaining the relay operated than is one on the heel end, because magnetic energy generated in this portion of the core is not so subject to leakage diversion (principally through the polarizing yoke).
In addition to the main object previously set forth, it is an object of the invention to provide suitable circuits incorporating the new three winding relay. Two typical circuit arrangements are disclosed. In one, the third winding and the polarizing winding are energized together to hold the relay operated after operation thereof responsive to current-flow in the operating winding, while, in the other typical circuit arrangement, current-flow is discontinued through the polarizing winding and through the operating winding after the relay is operated, and the holding'of the relay is accomplished solely by the current flow through the third or holding winding. A further disclosure employing the elementary circuits shown herein or variations of them in a telephone system is made in the United States patent application of Voss and Crocker, 40,686, September 16, 1935.
Description drawings Referring now to the accompanying drawings comprising Figs. 1-8, Figs. 1-5 show related views in orthographic projection of the Pye relay modifled in accordance with the present invention, Fig. 6 is a schematic drawing of the improved relay, and Figs. 7 and 8 show two typical circuit arrangements employed in the use of the relay.
Referring now particularly to Figs. 1-5, Figs. 1-3 show a front view, a side view, and a rear view, respectively, of the improved relay; Fig. 4 shows a top view; and Fig. shows a bottom view of the relay.
structurally, the relay shown in Figs. 1-5 is composed essentially of the coil assembly I, the heel piece 2, armature I, and the polarizing yoke l. Armature I is provided with spring-actuating arms I! and II, each of which actuates one of the spring assemblies II and II, secured to heel piece 2 as indicated, the contact springs in assemblies II and II being insulated from each other.
The coil assembly I includes the central magnetic core I, over which core spool-heads |.|ll are forced. The intermediate pole shoe 8 is a piece of magnetic material having a hole therein through which the core 6 is passed, and it is provided with suitable tapped holes to enable the polarizing yoke l to be adiustably mounted therein. The polarizing winding 2| suitably provided with a protective covering, is wound in the winding space lying between spool heads I and II. The ends of the polarizing winding are secured to terminals 24 and II, carried by spool head II.
Holding winding 2I and operating winding is are wound in the winding space between spool heads I and I, being separated from each other by the winding separator II. The ends of the windings are secured to terminals 25 and 26 in spool head It, terminal 25 serving as a common terminal for one end of each of the windings 2. and 2|. The leads from winding 2| pass through holes in the rear corners of spool heads I and II and thence to the base of terminals 25 and II beneath the covering of winding 2| Terminals 22 and II, as may be seen in Figures 2, 3. and 5, are fastened into the coil separator.
II to serve as terminals for the two ends of the operating winding l8. Terminal 22 is connected by means of strap wire 28 to coil terminal 21 of spool II, as may be seen best in Figs. 1 and 3, while terminal 2I is connected by means of strap wire 2! to terminal I2 mounted in the spring assembly II. These two strap wires, 22 and 29, are provided in order to provide terminals of the operating winding which are accessible from the terminal end of the relay, on the back side of the mounting plate (not shown) to which the relay is mounted by means of screws which pass through tapped holes in heel piece 2, as may be seen in Fig. 5.
It is to be observed that armature I is provided with a pair of lugs through which it is hinged to corresponding lugs on armature bracket II by means of a bearing pin. Armature bracket II is mounted on heel piece 2 by means of a mounting screw which passes through lug washer II and through a vertical slot (not shown) in bracket iI. A guide lug on washer l4 passes into hole |I in heel piece 2 to prevent turning of the washer II as the mounting screw is tightened so as to thereby prevent twisting of the armature I out of its desired position upon the tightening of the mounting screw.
Method of operation Referring now to Fig. 6, one pole of the current source is connected preferably to terminal 25, which serves as a common terminal for one end of the polarizing winding 2| and for one end of the holding winding 20, as above noted. When the relay is to be used, the other pole of the current source is connected to terminal 24, to which the other end of winding 2| is connected, thereby energizing the polarizing winding 2|. Winding I9 is connected in the operating circuit through terminals 22 and 22, by way of strap wires 28 and 29, extending to coil terminal 21 and to spring-assembly terminal I2, respectively, the conductors of the operating circuit being attached to terminals 21 and I2.
With the polarizing winding energized alone, the major portion of the flux produced thereby passes through the polarizing yoke l and by way of the back side of armature I to the heel piece 2 by way of which it returns to the bottom end of the magnetic core 8. 1n the event that a current flow is set up in the operating circuit in such a direction as to cause operating winding II to generate flux opposite in direction to that produced by winding 2|, this additional flux passes through the core to the polarizing yoke i, from which point it joins with the flux produced by winding 2| and passes through the yoke 4 to the armature I, from which point it passes across the air gap existing between the armature I and the upper end of core 8 to the upper end of thecore, completing the magnetic circuit. Ar mature I is not attracted as a result of this flux produced in the operating winding, being instead held more firmly against the polarizing yoke 4, serving as a back-stop for the armature.
When the operating winding I9 is energized in such direction that the flux resulting therefrom coincides in direction with the flux produced by the polarizing winding 2|, the net flux passing through polarizing yoke I is correspondingly reduced, and if the energization of the operating winding II is suflicient the flux passing from the upper end of core 0 across the small air gap to armature I is greater than the flux reaching armature I by way of the polarizing yoke I, and the armature is attracted toward the core I. As the armature I moves, an air gap is introduced between it and the polarizing yoke 4, while the air gap between the armature and the core is steadily reduced. As a result, by the time armature I has reached the core 6, the major portion of the flux generated by windings 2| and I! passes serially through the entire core, returning by way of armature I and heel piece 2, and the flux passing through polarizing yoke I is reduced to a low value.
As has been pointed out, it is often necessary to discontinue the flow of current in the operat ing circuit upon the operation of the relay, which is accomplished ordinarily by contacts actuated by the movement of the armature I. Horetoiore, the only means of maintaining the relay operated following the cutting out of winding i9 is the flux generated by the polarizing winding 2|. It is to be noted that, upon the cutting out of the winding I0 and the flux generated by the current passing therethrough, the presence of polarizing yoke 4 constitutes a serious shunt on the flux generated in winding 2|, in that whatever flux passes yoke 4 to armature I and returns by way of heel piece 2 works in direct opposition to the flux that traverses the entire length of core 0 and passes through armature 3 to the heel piece. With the improved structure, however, the holding winding 20 may be connected in circuit upon the operation of the relay by applying the other pole of the current source through contacts of the relay to coil terminal 26, the first pole of the current source having been connected to one terminal of winding 20 by way of coil terminal 20, as previously noted.
Winding 20 may be wound so as to produce a relatively powerful flux through the portion of the core encircled thereby, which flux is driven through the upper end of core 0 to the armature 3, returning for the most part through the heel piece 2 to the lower end of core 0. Being located on the inside of the path through the polarizing yoke 4, the winding 20 is relatively efllcient in holding armature 2 operated. compared to the expenditure of similar power in polarizing winding 20, due to the somewhat adverse location previously noted of winding 2| with respect to holding the relay operated.
When it is desired that the relay be restored, one pole of the current source may be disconnected from terminals 24 and 26, de-energizing both the polarizing winding 2i and the holding winding 20. Alternatively, the controlled pole of the current source may be disconnected from terminal 24 upon the operation of the relay, leaving only winding 20 energized (through terminals 26 and 25) to maintain the relay operated. Under this condition, it is merely riecessary to disconnect terminal 26 to thereby deenergize winding 20 to permit the relay to restore.
Circuit operation of the improved relay The circuit operation of the improved relay will be understood more fuliy upon reference to the following description of the typical circuits illustrated in Figs. 7 and 8.
Fig. '7 shows a circuit arrangement in which the improved relay is held up, when once op erated, by cooperation of the holding winding and the polarizing winding. When key I0! is closed, polarizing winding 2| is energized and circuits are prepared for the energization of windings I9 and 20. The circuit for winding i0 is held open at key I02 and the circuit for winding 20 is held open at contact I02, so that the relay does not operate at this point but merely becomes polarized as hereinbefore mentioned. Now, by closing key I02 the circuit is completed for energizing the operating winding I! in the same direction as winding 2| and the armature of the relay is immediately attracted to close contacts I03, I04 and I05. The closure of contact I03 completes the circuit to energize the holding winding 20,and the closure of contact I04 short circuits winding I! which deenergizes; it will be seen, therefore, that the relay is now held up by windings 20 and 2| and may be released by opening key IOI. It will also be observed that any associated relays, whose windings are shown as element I06 in Fig. 7, which may have been operated at the same time winding I9 was energized or alternatively, when winding l9 was short circuited, will also be released by opening key IOI. he relay is prepared for subsequent operation by opening key I02 which restores the shown circuits to their original state.
In Fig. 8 a circuit arrangement is shown whereby the relay is held up, when once operated, by the holding winding alone. Key 20I is closed to energize polarizing winding 2| and to prepare circuits for the energization of windings I0 and 20. The circuit of winding I9 is held open at key 202 and the circuit of winding 20 is held open at contact 200 so that the relay does not operate. When key 202 is momentarily closed winding I9 is energized to assist winding 2| and the relay operates. In operating, contact 203 is closed to complete the circuit for the holding winding 20 which energizes, and contact 204 is opened to effect the deenergization of windings I0 and 2|.
The reiay, now being held up by winding 20 alone, may be released by opening key 20L It will be understood that the disclosed circuit arrangements are merely exemplary, and that the improved relay may be utilized in numerous other arrangements which will be suggested to the mind of a person versed in the art. The functions performed manually by keys in these examples will, in the automatic telephone art, ordinarily be performed at the contacts of associated relay equipment; contacts of associated relays may also, of course, be given the circuit control assigned to contacts I03, I04, 203 and 204 of these examples.
It will be understood further that the exact details of construction illustrated in Figures 1 to 5 need not be followed. For example, windings l9 and 20 may be placed on the armature end of the core 6 in the form of concentric windings instead of segregating windings as illustrated.
What is claimed is:
1. An electro-polarlzed relay having a core and an armature actuatable when the core is sufliciently energized, contact springs actuatable by said armature when it is attracted to the core, a polarizing winding, an operating winding, and a holding winding, all on said core, said armature being non-responsive to energization of said polarizing winding alone, but responsive to simultaneous energization of the polarizing winding and the operating winding to actuate said contact springs, and circuit connections rendered effective upon the actuation of said contact springs for energizing the holding winding in a direction to aid in holding the armature actuated.
2. In combination, an electro-polarized relay having a core and an armature attractable to said core when the core is sufiiciently energized, contact springs actuatable by said armature when it is attracted by the core, a polarizing winding, an operating winding, and a holding winding, all on said core, said armature being non-responsive to energization of said polarizing winding alone to actuate said contact springs, but responsive to simultaneous energization of polarizing winding and operating winding to actuate said contact springs, circuit connections rendered eifective upon the actuation of said contact springs for deenergizing said operating winding, and additional circuit connections rendered eflective upon the actuation of said contact springs for energizing said holding winding in the same direction as the operating winding was energized and sufliciently to maintain the relay actuated after the operating winding is deenergized.
3. In combination, an electro-polarized relay having a core and an armature attractable to the core when the core is sumciently energized, contact springs actuatable by said armature when it is attracted by the core, a polarizing winding, an operating winding, and a holding winding, all on said core, said armature being non-responsive to energization of said polarizing winding alone, but responsive to simultaneous energization oi the polarizing winding and the operating winding to actuate said contact springs, and circuit connections rendered efiective upon the actuation or said contact springs for deenergizing said polarizing and operating windings and for energizing said holding windings to maintain the relay operated after the polarizing and operating windings have become deenergized.
4. In combination, a relay having three windings, means for first energizing the first winding in a given direction to polarize the relay, means for energizing the second winding in the same direction to operate the relay, and means for thereafter energizing the third winding in the same direction to hold the relay operated.
5- In combination, an electro-polarized relay comprising a core, a magnetic return heel piece secured to one end of the core, an armature mounted for operation in a magnetic circuit between the iree end of the heel piece and the free end of the core when the core is sufiiciently energized, an intermediate pole shoe of magnetic material mounted on an intermediate portion of the core, a polarizing yoke mounted on said intermediate pole shoe and being of such a configuration as to normally contact the armature and serve as a backstop therefor, a polarizing winding wound on the end of the core which lies on the side of the intermediate polarizing yoke away from the armature, and operating winding wound on said core on the end thereon lying between the armature and the intermediate pole shoe, a holding winding also wound on the portion or the core lying between the armature and the intermediate pole shoe, means for energizing the polarizing winding to polarize the relay by the passage oi magnetic that through the polarizing yoke, whereby the relay-is not operated, means for energizing the operating winding in a direction to generate flux longitudinally through the core agreeing in direction with the fiux generated by the polarizing winding, whereby the armature oi the relay is attracted away from the back stop and in association with the free end 0! the core, and means responsive to the movement of said armature when it is attracted Ior energizing the holding winding in a direction agreeing with the energization of the operating winding.
6. In combination, an electro-polarized relay having three windings, means for energizing the first winding to polarlze the relay, means ior energizing the second winding to actuate the relay by the combined influence otthe first and second windings, means responsive to the actuation of the relay for energizing the third winding to hold the relay operated, and ior deenergizing the operating winding, and means for deenergizing the holding and polarizing windings to bring about a restoration of the relay,
7. In combination, an electro-polarized relay having three windings, means for energizing one winding to polarize the relay, means for energizing the second winding to operate the relay in conjunction with the energization oi the first winding, means responsive to the energization of the relay for energizing the third winding in the same direction as the first two were energized to hold the relay operated, and means also responsive to the operation of the relay for deenergizing the polarizing and operating windings, said holding winding being effective to hold the relay operated indefinitely after the other two windings are deenergized, and means for subsequently deenergizing the holding winding to permit the relay to restore.
PIER BAKKER.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US79637A US2153291A (en) | 1936-05-14 | 1936-05-14 | Electromagnetic relay |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US79637A US2153291A (en) | 1936-05-14 | 1936-05-14 | Electromagnetic relay |
Publications (1)
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US2153291A true US2153291A (en) | 1939-04-04 |
Family
ID=22151814
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US79637A Expired - Lifetime US2153291A (en) | 1936-05-14 | 1936-05-14 | Electromagnetic relay |
Country Status (1)
Country | Link |
---|---|
US (1) | US2153291A (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2449224A (en) * | 1944-07-15 | 1948-09-14 | Western Electric Co | Electrical circuit control |
-
1936
- 1936-05-14 US US79637A patent/US2153291A/en not_active Expired - Lifetime
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2449224A (en) * | 1944-07-15 | 1948-09-14 | Western Electric Co | Electrical circuit control |
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