US2060235A - Relay - Google Patents

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Publication number
US2060235A
US2060235A US27954A US2795435A US2060235A US 2060235 A US2060235 A US 2060235A US 27954 A US27954 A US 27954A US 2795435 A US2795435 A US 2795435A US 2060235 A US2060235 A US 2060235A
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United States
Prior art keywords
armature
relay
contacts
casing
contact
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Expired - Lifetime
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US27954A
Inventor
Daniel D Miller
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AT&T Corp
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Bell Telephone Laboratories Inc
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Filing date
Publication date
Application filed by Bell Telephone Laboratories Inc filed Critical Bell Telephone Laboratories Inc
Priority to US27954A priority Critical patent/US2060235A/en
Priority to DEI55262D priority patent/DE738062C/en
Application granted granted Critical
Publication of US2060235A publication Critical patent/US2060235A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H51/00Electromagnetic relays
    • H01H51/28Relays having both armature and contacts within a sealed casing outside which the operating coil is located, e.g. contact carried by a magnetic leaf spring or reed
    • H01H51/284Polarised relays

Definitions

  • This invention relates to relays and more particularly to sensitive polarized telegraph relays.
  • the length of telegraph lines and the speed of transmission of telegraph signal impulses over 5 them is largely dependent upon the speed and sensitivity of the receiving relays used with these lines.
  • This relay requires frequent adjusting and cleaning to compensate for contact wear and to remove dirt from the contacts and pole-pieces. Since the adjustments are critical, considerable time and expense are required to maintain these relays.
  • the object of this invention is to provide an improved relay structure in which the contacts are enclosed and maintained in a non-corrosive atmosphere or in a vacuum without greatly reducing the sensitivity of the relay. This reduces the contact wear and erosion and also keeps dust and dirt away from these parts of the relay so that the relay does not have to be adjusted very often.
  • a further object of the invention is to reduce the expense of maintenance required. This is accomplished by incorporating the armature, armature hinge, contacts and in some cases the pole-pieces in a small readily detachable and replaceable structure or unit. Then when the contacts become wornv and require adjustment, this entire structure may be replaced with a new or rebuilt structure at a small expense.
  • Fig. 1 shows a relay equipped with a contact structure made in accordance with this invention.
  • Fig. 2 shows details of the contact structure or unit.
  • Fig. 3 shows a modified form of the unit in which the casing is made of glass and metal.
  • Fig. 4 shows another modification in which the pole-pieces extend through the casing.
  • Figs. 5, 6, and 'l are sectional views taken along 1935, Serial N0. 27,954
  • Fig. 8 shows another view of the end of the armature and illustrates one method of mounting the armature and unit.
  • I represents the base or supporting member of the relay.
  • Terminal block I I is mounted on base I0 and carries mounting lugs I2 and contacts I3 which serve to support and connect the relay to its associated circuit.
  • the permanent mag-- net I4 which is connected through members I1 to yokes I5 and Iii of the relay.
  • a relay coil 25 mounted within yokes I and I6 is a relay coil 25 through the windings of which the energizing current of the relay flows.
  • armature I0 Supported at the rear end of the yokes is armature I0 which extends through the coil 25 between adjustable pole-pieces Iii and forms the lportion of the contact making means of the unit 20.
  • Unit 20 is shown in greater detail in Figs. 2 and 5. As shown in Fig. 2 this unit comprises a glass envelope through which armature 28 extends. The glass is hermetically sealed or soldered to armature 28 at 30.
  • the glass is iirst metallized such as by sputtering under reduced pressures, spraying or in some other suitable manner after which it may be electroplated when necessary or desirable and then soldered to make a gas-tight joint.
  • Armature 28 is provided with a reduced or hinged portion 24 so that the contact end 23 may move freely between contacts 22.
  • This hinge is shown as a reduced and flexible portion of the armature but it is to be understood that any suitable hinge may be employed which will permit the end 23 of armature 28 to move freely between contacts 22 without creating any undue strain on the soldered joint 30 or supporting end I9 of armature 28.
  • Rods 3G are sealed into the upper end of the glass tube and support contacts 22 which are made of suitable contact metal and provide connections through the glass to these contacts (see Figs. 2 and 5).
  • the component parts are rst fabricated and then assembled.
  • the armature 28 is soldered to the tubes at 3U.
  • the contacts 22 are next-adjusted by inserting suitable gauges through the end 33, which has not yet been sealed off, between the contacts and the armature member.
  • the glass surrounding these contacts is then heated and these contacts adjusted in this manner to provide the required contact gap.
  • the unit is then connected onto a gaseous pumping system which may either pump all the air out or flush the structure with some suitable gas or both pump it out of the structure and then flush a suitable gas through the entire structure. While the unit is thus connected to the pumping system it may be heated if desirable to drive out some or all of the occluded or adsorbed gases after which a suitable atmosphere is introduced. and the unit sealed oil! at 3l.
  • This atmosphere may be of any suitable gas such as the inert gases like helium, argon or neon, etc. or may be of some non-corrosive gas such as nitrogen, hydrogen, CO or CO: etc. Furthermore the pressure of these gases is ad- Justed in accordance with the operating conditions such as, for example, the associated circuit, contact metals, contact gaps, etc. as to give the best operation and least wear.
  • are loosened and the end I9 of the armature 2l is inserted between them. The screws pass in the slot 34 of end I9 of armature 29. (See Fig. 8.) After the armature is inserted these screws are tightened to securely hold the entire unit.
  • Rods 36 are clamped or fastenedin any suitable man ner to leads from contact pins I3. The relay may then be adjusted by controlling or moving the positions of the pole-pieces I8. s
  • this structure does not greatly increase the length of the air-gap since the glass may be quite close to armature 28 and also rather thin.
  • the lower portion oi' the tube or envelope may be made of metal as shown in Fig. 3.
  • themetal tube 2B is formed preferably of a highly resistive material or alloy such as a copper-manganese alloy so as not to appreciably delay the change of ilux in the armature when the current through coil 25 changes.
  • Armature 24 is then inserted in tube 26 and soldered at 30 as before.
  • a glass cap 20 is provided which fits over the end of this tube and is treated so that it may be soldered to the metal tube at Il.
  • the contacts 22 are then inserted and sealed in the glass cap in such a manner as to provide suitable contact gaps.
  • Fig. 6 is the section of the unit along line 8 8 of Fig. 3 which is in the plane of the pole-pieces. It is to be noted that in this case the air-gap between the armature and pole-pieces may be quite small.
  • This arrangement has the further advantage that it is more rugged and able to withstand shocks and jars better than the unit having the entire casing or tube made of glass.
  • the atmosphere within the unit may be controlled by rst pumping all the air out and then admitting a suitable gas at such a pressure as may be desired.
  • the metal tube used ln the arrangement shown in Fig. 3 is provided with sui'- iicient resilience to permit more accurate adjustment of the po1e-pieces o! the relay and secure closer operating limits.
  • this may be accomplished by inserting the pole-pieces through the casing as shown in Fig. 4.
  • 'I'hese pole-pieces may be soldered or brazed to the casing 28 as shown at 35.
  • armature 2l is provided with a shoulder or cap 3
  • Pole-pieces 21 are nsoldered, brazed or welded in the casing 26 which is provided with suiicient resilience to permit the air-gaps between these pole-pieces and the armatures to be adjusted.
  • the contacts are supported on threaded rods 36 which iit through caps 32 which in turn are soldered to the glass cap 20. Glass cap 2l is soldered to the tube 26 at-ll.
  • nuts J2 may be soldered both to cap 32 and the contact supporting rod 3B as shown at 33 in Fig'. 3.
  • a sensitivepolarized telegraph relay having a readily detachable armature and contact structure comprising a exible armature, a metallic casing of highly resistive material surrounding a portion of said armature, said annature extending through said casing and soldered thereto, a glass cap surrounding the contactend of said armature soldered'to said metallic casing. a contact member extending through and soidered to said glass cap and non-corrosive atmosphere sealed within said cap and casing.
  • a sensitive polarized relay having .a small readily detachable and replaceable structure comprising a gas-tight casing, a flexible armature member extending therethrough, pole-pieces extending through said casing and contact members supported on and insulated trom said casing which cooperate with said armature member.
  • a sensitive polarized relay and a contact structure therefor comprising an armature member a metallic casing oi material of high electrical resistance surrounding a portion of said armature hermetically sealed to said armature, pole-pieces for said armature extending through and resiliently supported by said casing, a glass cap hermetically sealed to the end of said casing, contact members extending through said cap and hermetically sealed therethrough, and a non-corrosive atmosphere sealed within said casing.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Manufacture Of Switches (AREA)
  • Contacts (AREA)

Description

D.` D. M|LLER Nav. l0, 1936.
RELAY Filed June 22, 1935 ATTORNEY Patented Nov. 1), 1936 PATENT OFFICE RELAY Daniel D. Miller, New
Bell Telephone Laboratories,
York, N. Y., assigner to Incorporated,
New York, N. Y., a corporation of New York Application June 22,
3 Claims.
This invention relates to relays and more particularly to sensitive polarized telegraph relays. The length of telegraph lines and the speed of transmission of telegraph signal impulses over 5 them is largely dependent upon the speed and sensitivity of the receiving relays used with these lines. About the only relay available to meet the severe requirements of commercial telegraph systems, is a sensitive polarized relay.
This relay, however, requires frequent adjusting and cleaning to compensate for contact wear and to remove dirt from the contacts and pole-pieces. Since the adjustments are critical, considerable time and expense are required to maintain these relays.
Various relay structures have been proposed from time to time in which the contact wear and erosion are greatly reduced and in which dirt and soot are not allowed to reach the contacts or pole-pieces. These structures, however, greatly reduce the sensitivity of the relays so that they will no longer meet the requirements of the commercial telegraph systems.
The object of this invention is to provide an improved relay structure in which the contacts are enclosed and maintained in a non-corrosive atmosphere or in a vacuum without greatly reducing the sensitivity of the relay. This reduces the contact wear and erosion and also keeps dust and dirt away from these parts of the relay so that the relay does not have to be adjusted very often. v
A further object of the invention is to reduce the expense of maintenance required. This is accomplished by incorporating the armature, armature hinge, contacts and in some cases the pole-pieces in a small readily detachable and replaceable structure or unit. Then when the contacts become wornv and require adjustment, this entire structure may be replaced with a new or rebuilt structure at a small expense.
These and other objects and features of this invention may be more fully understood from the following description when read with reference to the attached drawing in which:
Fig. 1 shows a relay equipped with a contact structure made in accordance with this invention.
Fig. 2 shows details of the contact structure or unit.
Fig. 3 shows a modified form of the unit in which the casing is made of glass and metal.
Fig. 4 shows another modification in which the pole-pieces extend through the casing.
Figs. 5, 6, and 'l are sectional views taken along 1935, Serial N0. 27,954
lines 5-5, 6 6, and 'I--1 of Figs. 2, 3, and 4, respectively; and
Fig. 8 shows another view of the end of the armature and illustrates one method of mounting the armature and unit.
Similar parts of the various gures have been designated by the same numbers.
Referring now to Fig. l, I represents the base or supporting member of the relay. Terminal block I I is mounted on base I0 and carries mounting lugs I2 and contacts I3 which serve to support and connect the relay to its associated circuit. Also supported on base I0 is the permanent mag-- net I4 which is connected through members I1 to yokes I5 and Iii of the relay. Mounted within yokes I and I6 is a relay coil 25 through the windings of which the energizing current of the relay flows. Supported at the rear end of the yokes is armature I0 which extends through the coil 25 between adjustable pole-pieces Iii and forms the lportion of the contact making means of the unit 20.
Unit 20 is shown in greater detail in Figs. 2 and 5. As shown in Fig. 2 this unit comprises a glass envelope through which armature 28 extends. The glass is hermetically sealed or soldered to armature 28 at 30.
In order that the armature may be soldered to the glass, the glass is iirst metallized such as by sputtering under reduced pressures, spraying or in some other suitable manner after which it may be electroplated when necessary or desirable and then soldered to make a gas-tight joint.
Armature 28 is provided with a reduced or hinged portion 24 so that the contact end 23 may move freely between contacts 22. This hinge is shown as a reduced and flexible portion of the armature but it is to be understood that any suitable hinge may be employed which will permit the end 23 of armature 28 to move freely between contacts 22 without creating any undue strain on the soldered joint 30 or supporting end I9 of armature 28.
Rods 3G are sealed into the upper end of the glass tube and support contacts 22 which are made of suitable contact metal and provide connections through the glass to these contacts (see Figs. 2 and 5).
In making these units, the component parts are rst fabricated and then assembled. The armature 28 is soldered to the tubes at 3U. The contacts 22 are next-adjusted by inserting suitable gauges through the end 33, which has not yet been sealed off, between the contacts and the armature member. The glass surrounding these contacts is then heated and these contacts adjusted in this manner to provide the required contact gap. The unit is then connected onto a gaseous pumping system which may either pump all the air out or flush the structure with some suitable gas or both pump it out of the structure and then flush a suitable gas through the entire structure. While the unit is thus connected to the pumping system it may be heated if desirable to drive out some or all of the occluded or adsorbed gases after which a suitable atmosphere is introduced. and the unit sealed oil! at 3l.
This atmosphere may be of any suitable gas such as the inert gases like helium, argon or neon, etc. or may be of some non-corrosive gas such as nitrogen, hydrogen, CO or CO: etc. Furthermore the pressure of these gases is ad- Justed in accordance with the operating conditions such as, for example, the associated circuit, contact metals, contact gaps, etc. as to give the best operation and least wear. In inserting the unit in the relay screws 2| are loosened and the end I9 of the armature 2l is inserted between them. The screws pass in the slot 34 of end I9 of armature 29. (See Fig. 8.) After the armature is inserted these screws are tightened to securely hold the entire unit. Rods 36 are clamped or fastenedin any suitable man ner to leads from contact pins I3. The relay may then be adjusted by controlling or moving the positions of the pole-pieces I8. s
It is to be noted that this structure does not greatly increase the length of the air-gap since the glass may be quite close to armature 28 and also rather thin. i
However, in case it is desired to more nearly approach the air-gap now in use in relays not equipped with this unit, the lower portion oi' the tube or envelope may be made of metal as shown in Fig. 3. Here themetal tube 2B is formed preferably of a highly resistive material or alloy such as a copper-manganese alloy so as not to appreciably delay the change of ilux in the armature when the current through coil 25 changes. Armature 24 is then inserted in tube 26 and soldered at 30 as before. A glass cap 20 is provided which fits over the end of this tube and is treated so that it may be soldered to the metal tube at Il. Here again the contacts 22 are then inserted and sealed in the glass cap in such a manner as to provide suitable contact gaps. Inv
this case it is easy to provide special indentations 29 to permit the pole-pieces to come very close to armature 28. This is shown more clearly in Fig. 6 which is the section of the unit along line 8 8 of Fig. 3 which is in the plane of the pole-pieces. It is to be noted that in this case the air-gap between the armature and pole-pieces may be quite small.
This arrangement has the further advantage that it is more rugged and able to withstand shocks and jars better than the unit having the entire casing or tube made of glass.
In this case as before the atmosphere within the unit may be controlled by rst pumping all the air out and then admitting a suitable gas at such a pressure as may be desired.
Furthermore the metal tube used ln the arrangement shown in Fig. 3 is provided with sui'- iicient resilience to permit more accurate adjustment of the po1e-pieces o! the relay and secure closer operating limite. However, in case it is necessary to further reduce the air-gap this may be accomplished by inserting the pole-pieces through the casing as shown in Fig. 4. 'I'hese pole-pieces may be soldered or brazed to the casing 28 as shown at 35.
As shown in Fig. 4 armature 2l is provided with a shoulder or cap 3| to which casing 2l is soldered, brazed, or welded at 30. Pole-pieces 21 are nsoldered, brazed or welded in the casing 26 which is provided with suiicient resilience to permit the air-gaps between these pole-pieces and the armatures to be adjusted. As shown in Fig. 4 the contacts are supported on threaded rods 36 which iit through caps 32 which in turn are soldered to the glass cap 20. Glass cap 2l is soldered to the tube 26 at-ll. With this arrangement it is much easier to adjust and readjust contacts 22 since they may be screwed through cap 30 until the required contact gap is obtained after which nuts 32 are tightened to lock the contacts 22 in this position. If it is desired to seal this arrangement nuts J2 may be soldered both to cap 32 and the contact supporting rod 3B as shown at 33 in Fig'. 3.
It is thus apparent that the contacts 22 are protected from all dirt and dust and erosion. Consequently they will need no cleaning and very little if any adjustment. However, when any adjustment is required, all that is necessary is that the two screws 2l be loosened; the old unit 20 removed and the new or rebuilt or readjusted unit inserted and these screws tightened after which the relay may be readily adjusted. Thus both the maintenance and wear of the contacts are greatly reduced.
The foregoing describes several specitlc embodiments of this invention, the novel features of which are set forth in the following claims.
What is claimed is:
l. A sensitivepolarized telegraph relay having a readily detachable armature and contact structure comprising a exible armature, a metallic casing of highly resistive material surrounding a portion of said armature, said annature extending through said casing and soldered thereto, a glass cap surrounding the contactend of said armature soldered'to said metallic casing. a contact member extending through and soidered to said glass cap and non-corrosive atmosphere sealed within said cap and casing.
2. A sensitive polarized relay having .a small readily detachable and replaceable structure comprising a gas-tight casing, a flexible armature member extending therethrough, pole-pieces extending through said casing and contact members supported on and insulated trom said casing which cooperate with said armature member.
3. In combination, a sensitive polarized relay and a contact structure therefor comprising an armature member a metallic casing oi material of high electrical resistance surrounding a portion of said armature hermetically sealed to said armature, pole-pieces for said armature extending through and resiliently supported by said casing, a glass cap hermetically sealed to the end of said casing, contact members extending through said cap and hermetically sealed therethrough, and a non-corrosive atmosphere sealed within said casing.
DANIEL D. BEUTLER.
US27954A 1935-06-22 1935-06-22 Relay Expired - Lifetime US2060235A (en)

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US27954A US2060235A (en) 1935-06-22 1935-06-22 Relay
DEI55262D DE738062C (en) 1935-06-22 1936-06-16 Polarized telegraph relay

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Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2425038A (en) * 1943-09-27 1947-08-05 Lear Inc Safety switch device
US2485024A (en) * 1945-03-21 1949-10-18 Amalgamated Wireless Australas Electromagnetically operated vacuum sealed relay
US2508508A (en) * 1946-08-10 1950-05-23 Bell Telephone Labor Inc Mercury contact for electrical switches
US2523366A (en) * 1946-09-28 1950-09-26 Bell Telephone Labor Inc Mercury type relay
US2563831A (en) * 1945-11-07 1951-08-14 Monitor Controller Co Vacuum relay
US2577602A (en) * 1947-10-01 1951-12-04 Bell Telephone Labor Inc Method for adjusting the sensitivity of contact devices
US2606981A (en) * 1946-07-05 1952-08-12 F K G Fritz Kesselring Gerateb Magnetic switching device of the cartridge or plug-type
US2797329A (en) * 1954-11-04 1957-06-25 Research Corp Mercury contact switch impulse generator
US2866028A (en) * 1955-06-14 1958-12-23 Bristol Company Electrically actuated contactor
US3059074A (en) * 1957-04-09 1962-10-16 Int Standard Electric Corp Electrical switching device and method for making
US3243541A (en) * 1963-10-04 1966-03-29 Falco Angelo De Reed switch with magnwetically responsive reed elements
DE1248161B (en) * 1962-09-07 1967-08-24 Siemens Ag Polarized toggle relay with hermetically sealed contact arrangement
US4114127A (en) * 1976-09-30 1978-09-12 Texas Instruments Incorporated Current interrupting apparatus

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2425038A (en) * 1943-09-27 1947-08-05 Lear Inc Safety switch device
US2485024A (en) * 1945-03-21 1949-10-18 Amalgamated Wireless Australas Electromagnetically operated vacuum sealed relay
US2563831A (en) * 1945-11-07 1951-08-14 Monitor Controller Co Vacuum relay
US2606981A (en) * 1946-07-05 1952-08-12 F K G Fritz Kesselring Gerateb Magnetic switching device of the cartridge or plug-type
US2508508A (en) * 1946-08-10 1950-05-23 Bell Telephone Labor Inc Mercury contact for electrical switches
US2523366A (en) * 1946-09-28 1950-09-26 Bell Telephone Labor Inc Mercury type relay
US2577602A (en) * 1947-10-01 1951-12-04 Bell Telephone Labor Inc Method for adjusting the sensitivity of contact devices
US2797329A (en) * 1954-11-04 1957-06-25 Research Corp Mercury contact switch impulse generator
US2866028A (en) * 1955-06-14 1958-12-23 Bristol Company Electrically actuated contactor
US3059074A (en) * 1957-04-09 1962-10-16 Int Standard Electric Corp Electrical switching device and method for making
DE1248161B (en) * 1962-09-07 1967-08-24 Siemens Ag Polarized toggle relay with hermetically sealed contact arrangement
US3243541A (en) * 1963-10-04 1966-03-29 Falco Angelo De Reed switch with magnwetically responsive reed elements
US4114127A (en) * 1976-09-30 1978-09-12 Texas Instruments Incorporated Current interrupting apparatus

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Publication number Publication date
DE738062C (en) 1943-08-02

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