US2351730A - Relay - Google Patents

Relay Download PDF

Info

Publication number
US2351730A
US2351730A US459391A US45939142A US2351730A US 2351730 A US2351730 A US 2351730A US 459391 A US459391 A US 459391A US 45939142 A US45939142 A US 45939142A US 2351730 A US2351730 A US 2351730A
Authority
US
United States
Prior art keywords
armature
core
relay
sections
secured
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
US459391A
Inventor
Frank A Zupa
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.)
AT&T Corp
Original Assignee
Bell Telephone Laboratories 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 Bell Telephone Laboratories Inc filed Critical Bell Telephone Laboratories Inc
Priority to US459391A priority Critical patent/US2351730A/en
Priority claimed from US459390A external-priority patent/US2327549A/en
Application granted granted Critical
Publication of US2351730A publication Critical patent/US2351730A/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
    • H01H51/00Electromagnetic relays
    • H01H51/02Non-polarised relays
    • H01H51/04Non-polarised relays with single armature; with single set of ganged armatures
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H51/00Electromagnetic relays
    • H01H51/30Electromagnetic relays specially adapted for actuation by ac

Definitions

  • This invention relates to relays and more particularly to relays for use in the circuits of telephone systems.
  • a relay of the direct current type such as is disclosed in Patent No. 2,294,327 granted to me on August 25, 3,942, does have adquate contact pressures and twin contacts but cannot be operated effectively in response to alternating current.
  • This object is attained by dividing the forward cross reach of the armature into two magnetically separated but nonmagnetically joined sections, one of which is surrounded by a short-circuited coil or copper sleeve to provide a phase displacement of the flux in one section of the armature with respect to the other section.
  • Fig. 1 is a top plan view of a relay of the direct current type her'einbefore referred to, modified in accordance with the present invention
  • Fig. 2 is an enlarged front end view of the relay shown in Fig. 2;
  • Fig. 3 is a detail view of the armature of the relay showing the manner in which the armature is divided into magnetically separated sections and the manner in which a phase displacement of the flux in one section of the armature with respect to the other section is secured;
  • Fig. 4 is a sectional view of the front end of the armature as viewed along section line 4-4 of Fig. 3.
  • the relay disclosed in the drawing is of the general type disclosed in Patent No. 2,294,327, granted to me, and consists of a core I secured at its rear end to a mounting bracket 2, an energizing coil 3 surrounding the core having front and rear spoolheads 4 and 5 of insulating material, an armature 6 the forward cross reach of which cooperates with the enlarged pole face I of the forward end of the core I and the rear ends of the legs 8 and 9 of which are pivoted by pivot pins in to the forwardly extending arms of the mounting bracket 2, reed springs ll, coil terminal lugs l2, a spring pile-up on each side of the relay coil 3 each comprising suitable contact springs such as l3, l4, l5, l6, etc., and a back-stop structure comprising the screw l'l secured to the forward end of the core I and the back-stop nut I8 threaded thereon.
  • the reed springs II, coil terminal lugs l2 and the springs of the spring pile-ups are suitably clamped to the mounting bracket 2 by screws l9 and 20 which pass through holes in the clamping plates 2!, insulating strips 22, the bracket 2, the reed springs ll, insulating strips 23 and the springs of the spring pile-ups into threaded holes in the clamping plates 24.
  • Terminal lugs I2 and the springs of the spring pile-ups are insulated from each other and from the bracket 2 by the interposed insulating strips 22 and 23 and the screws l9 and 20 are surrounded by the usual sleeves of insulating material (not shown) where they pass through the holes in the terminal lugs and the springs of the spring pile-ups.
  • studs of insulating material such as studs 25 and 26, are ring-staked to certain of the movable springs with the outer ends of the studs 26 engaged against the legs of the armature 6.
  • the forward cross reach 21 of the armature 6 is severed by a slot 28 and the two severed sections are reunited by a plate 29 of non-magnetic material riveted or otherwise secured to both sections whereby the two sections are firmly secured together but magnetically separated by an intervening narrow air-gap.
  • the leg 8 of the armature is surrounded by a sleeve 30 of good electrically conductive material, such as copper, which, in effect, is a short-circuited. winding. In place of the sleeve, a low resistance winding short-circuited upon itself could be used.
  • the pole face of the armature at the point of engagement with the pole face I of the core i is provided with an embossment II.
  • the embossed portion Il may be an integral part of the armature and formed when the armature is stamped out or may be a separate insert either magnetic or non-magnetic material.
  • the embossment may be formed instead on the pole face I of the core I.
  • the division oi the armature into two malnetioally separated sections in effect provides two separate armatures which mechanically function as a single armature since they are rigidly united by the plate 29 but which magnetically function as separate armatures.
  • the copper sleeve Ill surrounding the leg I or one of the sections serves to produce a phase displacement oi the flux in that section or the armature with respect to the other section.
  • a heel-piece a core secured thereto, a coil surrounding said core, an armature hinged to said heel-piece with its free end attractable toward said core upon the energization of said coil, said armature being divided into two magnetically separated sections and a short-circuited coil surrounding one 01 said sections whereby a phase displacement or the flux in that section with respect to the other section is secured to render said device eilectively operable by alternating current.
  • a heel-piece a core secured thereto, a coil surrounding said core, a U-shaped armature having its forward cross reach positioned for attraction toward the pole face oi the iorward end of said core upon the energization or said coil and having the ends of its legs hinged to said heel-piece, said am ture having its cross reach severed by a slot to divide said armature into two magnetically separated sections, a plate of non-magnetic material secured to the two sections of the cross reach to non-magnetically Join said sections, and a copper sleeve surrounding the leg of one of said sections whereby a phase displacement of the flux in that section with respect to the other section is secured to render said device eflectively operable by alternating current.
  • armature having its forward cross reach positioned for attraction toward the pole iace oi! the iorward tree and of said core upon the energization of said coil and having the ends of its legs hinged to said heel-piece, said armature having an embossed portion on its pole lace opposite the pole lace of said core and having its cross reach severed by a slot forming an air-gap to divide said armature into two mag netically separated sections, a plate of non-ma?- netic material secured to the two sections of said cross reach to non-magnetically join said sections, and a copper sleeve surrounding the leg of one of said sections whereby a phase displace ment of flux in that section with respect to the other section is secured to render said device atiectively operable by alternating current.
  • a heel--piece In an electromagnetic device, a heel--piece, a core secured thereto, a coii surrounding said cor-c, an L-shaped annaturo hinged to said heeluiece at one side oi said core, a second L-shoped armature, surrounded by a copper sleeve, hinged to said heelmiece at th other side oi" said core, the short legs of said armatures joined by a plate of non-magnetic material, whereby said arms tures are forced to move at the same time in response to energization oi said coil, the sleeve on said second armature causing a phase displacement of the flux in that armature with re spect to the flux in the other armature, to render said device effectively operable by alternating current.
  • a heel-piece In an electromagnetic device, a. heel-piece, a core secured thereto, a coil surrounding said core, an L-shaped armature hinged to said hee1- piece at one side of said core, a second L-shaped armature hinged to said heel-piece at the other side of said core, said second armature surrounded by a copper sleeve and carrying an.
  • embossed lug ior controlling the extent of motion of said armature, the short legs of said armatures joined by a plate oi non-magnetic material, whereby said armatures are forced to move at the same time in response to energization of said coil, the sleeve on said second armature causing a phase displacement oi the flux in that armature with respect to the flux in the other armature, to render said device effectively operable by alternating current.

Landscapes

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

Description

F. A. ZUPA June 20, 1944;
RELAY Filed. Sept. 25, 1942 Patented June 20, 1944 RELAY Frank A. Zupa, New York, N. Y., assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation 01 New York Application September 23, 1942, Serial No. 459,391
Claims.
This invention relates to relays and more particularly to relays for use in the circuits of telephone systems.
It is often necessary that certain relays of a telephone system be responsive to alternating current, as for example, a relay which responds to ringing current incoming over a trunk for signaling the presence of an incoming call on the trunk. Relays which have been used heretofore for this purpose, in order to secure adequate sensitivity, have been especially designed with relatively low contact pressures and with single contact springs.
It has been found desirable to provide a relay having as great sensitivity as those previously used but with greater contact pressures and with contact springs having twin contacts of the type generally provided in standard direct current relays employed in telephone circuits whereby more reliable circuit controls may be secured. A relay of the direct current type, such as is disclosed in Patent No. 2,294,327 granted to me on August 25, 3,942, does have adquate contact pressures and twin contacts but cannot be operated effectively in response to alternating current.
It is the object of the present invention to so modify a relay of this direct current type that it may be responsive to alternating current to maintain its contacts firmly engaged without any tendency to' chatter. This object is attained by dividing the forward cross reach of the armature into two magnetically separated but nonmagnetically joined sections, one of which is surrounded by a short-circuited coil or copper sleeve to provide a phase displacement of the flux in one section of the armature with respect to the other section.
The invention will be more readily understood from the following detailed description taken in connection with the accompanying drawing in which:
Fig. 1 is a top plan view of a relay of the direct current type her'einbefore referred to, modified in accordance with the present invention;
' Fig. 2 is an enlarged front end view of the relay shown in Fig. 2;
Fig. 3 is a detail view of the armature of the relay showing the manner in which the armature is divided into magnetically separated sections and the manner in which a phase displacement of the flux in one section of the armature with respect to the other section is secured; and
Fig. 4 is a sectional view of the front end of the armature as viewed along section line 4-4 of Fig. 3.
As hereinbefore stated the relay disclosed in the drawing is of the general type disclosed in Patent No. 2,294,327, granted to me, and consists of a core I secured at its rear end to a mounting bracket 2, an energizing coil 3 surrounding the core having front and rear spoolheads 4 and 5 of insulating material, an armature 6 the forward cross reach of which cooperates with the enlarged pole face I of the forward end of the core I and the rear ends of the legs 8 and 9 of which are pivoted by pivot pins in to the forwardly extending arms of the mounting bracket 2, reed springs ll, coil terminal lugs l2, a spring pile-up on each side of the relay coil 3 each comprising suitable contact springs such as l3, l4, l5, l6, etc., and a back-stop structure comprising the screw l'l secured to the forward end of the core I and the back-stop nut I8 threaded thereon.
The reed springs II, coil terminal lugs l2 and the springs of the spring pile-ups are suitably clamped to the mounting bracket 2 by screws l9 and 20 which pass through holes in the clamping plates 2!, insulating strips 22, the bracket 2, the reed springs ll, insulating strips 23 and the springs of the spring pile-ups into threaded holes in the clamping plates 24. Terminal lugs I2 and the springs of the spring pile-ups are insulated from each other and from the bracket 2 by the interposed insulating strips 22 and 23 and the screws l9 and 20 are surrounded by the usual sleeves of insulating material (not shown) where they pass through the holes in the terminal lugs and the springs of the spring pile-ups. For enabling the movable springs of the spring pile-ups to be moved with respect to the fixed springs, studs of insulating material, such as studs 25 and 26, are ring-staked to certain of the movable springs with the outer ends of the studs 26 engaged against the legs of the armature 6.
In accordance with the present invention, the forward cross reach 21 of the armature 6 is severed by a slot 28 and the two severed sections are reunited by a plate 29 of non-magnetic material riveted or otherwise secured to both sections whereby the two sections are firmly secured together but magnetically separated by an intervening narrow air-gap. The leg 8 of the armature is surrounded by a sleeve 30 of good electrically conductive material, such as copper, which, in effect, is a short-circuited. winding. In place of the sleeve, a low resistance winding short-circuited upon itself could be used. To minimize chatter or vibration on the alternating current operation of the relay the pole face of the armature at the point of engagement with the pole face I of the core i is provided with an embossment II. The embossed portion Il may be an integral part of the armature and formed when the armature is stamped out or may be a separate insert either magnetic or non-magnetic material. The embossment may be formed instead on the pole face I of the core I.
The division oi the armature into two malnetioally separated sections in effect provides two separate armatures which mechanically function as a single armature since they are rigidly united by the plate 29 but which magnetically function as separate armatures. The copper sleeve Ill surrounding the leg I or one of the sections serves to produce a phase displacement oi the flux in that section or the armature with respect to the other section. For example, assuming the coil 3 to be energized in response to one polarity of the alternating current and the armature I to be in its attracted position and the energizing current changes polarity, then when the current passes through the zero point in its change irom one polarity to the other, the flux in one section of the armature having the leg 5, will decay rapidly but due to the short-circuited sleeve 30 the flux in the section oi the armature having the leg B will be retarded in its decay sufficiently to hold the armature attracted until a flow of flux is again established in the opposite direction in both sections of the armature upon the reenergization oi the coil 3 in response to the opposite polarity of the energizing current. At this time flux flow in the unsleeved section of the armature will build up rapidly and beiorc a reversal of flux flow is produced in th sleeved section 01' the armature.
It is thus apparent that by a very simple modiflcation of the armature or an eiilcient direct current type relay, such a relay may be converted for alternating current operation and that since the direct current relay has adequate spring pressures and twin contacts on all or its springs, a very reliable and eflicient alternating current relay is mad available.
What is claimed is:
1. In an electromagnetic device, a heel-piece, a core secured thereto, a coil surrounding said core, an armature hinged to said heel-piece with its free end attractable toward said core upon the energization of said coil, said armature being divided into two magnetically separated sections and a short-circuited coil surrounding one 01 said sections whereby a phase displacement or the flux in that section with respect to the other section is secured to render said device eilectively operable by alternating current.
2. In an electromagnetic device, a heel-piece, a core secured thereto, a coil surrounding said core, a U-shaped armature having its forward cross reach positioned for attraction toward the pole face oi the iorward end of said core upon the energization or said coil and having the ends of its legs hinged to said heel-piece, said am ture having its cross reach severed by a slot to divide said armature into two magnetically separated sections, a plate of non-magnetic material secured to the two sections of the cross reach to non-magnetically Join said sections, and a copper sleeve surrounding the leg of one of said sections whereby a phase displacement of the flux in that section with respect to the other section is secured to render said device eflectively operable by alternating current.
3. In an electromagnetic device, a heel-piece, a core secured thereto, a coil surrounding said core, a U-shaped armature having its forward cross reach positioned for attraction toward the pole iace oi! the iorward tree and of said core upon the energization of said coil and having the ends of its legs hinged to said heel-piece, said armature having an embossed portion on its pole lace opposite the pole lace of said core and having its cross reach severed by a slot forming an air-gap to divide said armature into two mag netically separated sections, a plate of non-ma?- netic material secured to the two sections of said cross reach to non-magnetically join said sections, and a copper sleeve surrounding the leg of one of said sections whereby a phase displace ment of flux in that section with respect to the other section is secured to render said device atiectively operable by alternating current.
a. In an electromagnetic device, a heel--piece, a core secured thereto, a coii surrounding said cor-c, an L-shaped annaturo hinged to said heeluiece at one side oi said core, a second L-shoped armature, surrounded by a copper sleeve, hinged to said heelmiece at th other side oi" said core, the short legs of said armatures joined by a plate of non-magnetic material, whereby said arms tures are forced to move at the same time in response to energization oi said coil, the sleeve on said second armature causing a phase displacement of the flux in that armature with re spect to the flux in the other armature, to render said device effectively operable by alternating current.
In an electromagnetic device, a. heel-piece, a core secured thereto, a coil surrounding said core, an L-shaped armature hinged to said hee1- piece at one side of said core, a second L-shaped armature hinged to said heel-piece at the other side of said core, said second armature surrounded by a copper sleeve and carrying an. embossed lug ior controlling the extent of motion of said armature, the short legs of said armatures joined by a plate oi non-magnetic material, whereby said armatures are forced to move at the same time in response to energization of said coil, the sleeve on said second armature causing a phase displacement oi the flux in that armature with respect to the flux in the other armature, to render said device effectively operable by alternating current.
FRANK A. ZUPA.
US459391A 1942-09-23 1942-09-23 Relay Expired - Lifetime US2351730A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US459391A US2351730A (en) 1942-09-23 1942-09-23 Relay

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US459391A US2351730A (en) 1942-09-23 1942-09-23 Relay
US459390A US2327549A (en) 1942-09-23 1942-09-23 Two-step relay

Publications (1)

Publication Number Publication Date
US2351730A true US2351730A (en) 1944-06-20

Family

ID=27039330

Family Applications (1)

Application Number Title Priority Date Filing Date
US459391A Expired - Lifetime US2351730A (en) 1942-09-23 1942-09-23 Relay

Country Status (1)

Country Link
US (1) US2351730A (en)

Similar Documents

Publication Publication Date Title
US3001049A (en) Magnetic latch
USRE24209E (en) bernstein
US2378986A (en) Polarized relay
US1763003A (en) Electromagnetic device
US3470510A (en) Magnetic latch relay
US2741728A (en) Polarized electromagnetic devices
US2327549A (en) Two-step relay
GB1239930A (en) Electromagnetic relays
US2275531A (en) Relay
US2351730A (en) Relay
US3340487A (en) Armature structure for an electromagnetic device
US1139956A (en) Electromagnetic device.
US2295390A (en) Electromagnetic device
US3239727A (en) Electromagnetic switching device
US2274013A (en) Time delay relay
GB1271389A (en) Improvements in electromagnetic relays
US2611012A (en) Armature mounting for plural electromagnetic relays
US2761929A (en) Polarised electromagnetic relays
US3771083A (en) Magnetically operable multiple reed contact
US3182232A (en) Electromagnetic relays
GB1257698A (en)
US2393784A (en) Circuit controlling device
US2542835A (en) Electromagnetic contactor
US2270966A (en) Electromagnetic relay
US3255328A (en) Electromagnetic relay