US3273024A - Impulse relay - Google Patents

Impulse relay Download PDF

Info

Publication number
US3273024A
US3273024A US329725A US32972563A US3273024A US 3273024 A US3273024 A US 3273024A US 329725 A US329725 A US 329725A US 32972563 A US32972563 A US 32972563A US 3273024 A US3273024 A US 3273024A
Authority
US
United States
Prior art keywords
switch
coil
capacitor
relay
reed
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
US329725A
Inventor
Charles A Sherman
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.)
Weyerhaeuser Co
Original Assignee
Weyerhaeuser Co
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 Weyerhaeuser Co filed Critical Weyerhaeuser Co
Priority to US329725A priority Critical patent/US3273024A/en
Application granted granted Critical
Publication of US3273024A publication Critical patent/US3273024A/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
    • H01H47/00Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current

Definitions

  • This invention relates to electrical control apparatus and particularly, to an improved-impulse relay apparatus for actuating a control relay.
  • the machine control apparatus be simple, inexpensive, reliable and durable. Whenever possible it is desirable to cycle the machine by pushing one button which, when pushed, will actuate the electrical controls to one operating condition which condition will be maintained until the button is again pushed. Such a control is termed an impulse relay.
  • impulse relays have been used which are of mechanical construction; however, such relays have not provided satisfactory service over extended periods of usage. Often the mechanical parts of the relays become unreliable after repeated use due to dirt, wear and breakage.
  • I provide an impulse relay which comprises; a capacitor which is alternatively charged positively and negatively, a .pair of diode rectifiers which are alternatively connected to the capacitor, 9. reed switch which is opened or closed by changes in direction of current flow through a coil surrounding the reed switch and which is held closed by the magnetic force of a permanent magnet which is placed in the vicinity of the reed switch, a relay which changes the connection between the capacitor and the rectifiers and which is energized by the closing of the reed switch, and a pulse switch which when closed makes contact between the capacitor and the reed coil to discharge the capacitor through the reed coil.
  • I provide a reed switch which is open in the normal condition, which is biased to an open or closed position by the magnetic force caused by the direction of current flow through a coil surrounding the reed switch, and which is held in the closed position by the magnetic force of another magnet which is of a magnitude sufiicient to hold the reed switch closed but insufiicient to actuate the switch from an open to a closed condition.
  • the figure shows a schematic diagram of the control circuit of the impulse relay apparatus.
  • the figure shows an impulse relay 1 which actuates a control relay 3 which is shown within the dashed lines.
  • the control relay 3 is connected by means of negative relay lead 5 to negative charging diode rectifier 7, and likewise, control relay 3 is connected by means of positive relay lead 9 to positive charging diode rectifier 11.
  • the specific polarity of the diode rectifiers 7 and 11 is given by way of example only and of course is dependent upon the direction of wrapping of the wires in the coil 33 and the polarity of the permanent magnet 49.
  • Rectifiers 7 and 11 have a common connection at junction 12 with rectifier lead 13 which includes resistor R1 and is connected to junction 15. From junction 15, capacitor lead 17 which includes capacitor 19 is connected to junction 21. Also from junction 15, switch lead 23 which includes resistor R2 and pulse switch 25 is connected to junction 27. Between junctions 21 and 27 is lead 29 which includes resistor R3.
  • first coil lead 31 which is connected to reed coil 33.
  • a second coil lead 35 connects reed coil 33 at junction 37 with lead 39 which at the other end is connected to junction 21.
  • first alternating current power lead 43 Also joined at junction 37 is first alternating current power lead 43 and first reed contact 45.
  • the first reed contact 45 is at one end of reed switch 47 which as shown is glass enclosed.
  • permanent magnet 49 Above the reed switch 47 is permanent magnet 49 which has suflicient magnetic strength to hold first reed contact 45 in physical contact with second reed contact 51, once physical contact between the two reed contacts 45 and 51 has been made by the energization of the reed coil 33.
  • the permanent magnet 49 does not have sufficient strength however to pull contacts 45 and 51 together when reed coil 33 is not energized. It should be noted that reed switch 47 is a normally open switch. Although the magnet 49 is shown as a permanent magnet it is possible to use an electric magnet in its place if it has a constant direction and magnitude of current flow through it.
  • the second reed switch contact 51 is connected to the control relay coil 53 in control relay 3.
  • the other end of the control relay coil 53 is connected at junction 55 with the second alternating current power lead 57.
  • Energizing relay coil 53 causes the relay yoke 59 to move from the normal right-hand position to the energized left-hand position.
  • Attached to the control relay yoke 59 is left switch arm 61 which is connected by means of power lead 63 to junction 55.
  • Also attached to control relay yoke 59 is right switch arm 65 which is connected electrically to the apparatus being controlled by the control relay 3.
  • the right switch arm 65 makes contact with the normal control contact 67, and in the energized condition of the control relay 3, the right switch arm 65 makes contact with the energized control con-tact 69.
  • left switch arm 61 makes contact with negative relay lead 5 in the normal condition and makes contact with positive relay lead 9 in the energized condition.
  • the control relay 3 is connected to diode rectifiers 7 and 11 in the manner shown to charge the capacitor 19 either positively or negatively, depending upon the position of the left switch arm 61.
  • the resistor R1 is placed in the circuit between the diode rectifiers 7 and 11 and the capacitor 19 to limit the charging current of the capacitor 19 and to eliminate surge currents,
  • the resistor RZ serves to prolong the discharge of the capacitor 19 through the reed coil 33.
  • the resistor R3 stabilizes the reed switch circuit.
  • the control relay coil 53 is energized or de-energized by the closing or opening of the reed switch contacts 45 and 51.
  • the magnet 49 In the vicinity of the reed switch 47 is the magnet 49, having suflicien-t strength to bias or hold the contacts 45 and 51 closed, but insufiicient strength to cause the closure of the contacts 45 and 51.
  • the negative diode rectifier 7 is connected to the capacitor 19 and impresses a negative charge on the capacitor 19.
  • the capacitor 19 discharges through the reed coil 33 causing the reed switch contacts 45 and 51 to close.
  • the pulse switch 2 can then be released without effect since the magnetic field of the magnet 49 is sulficiently strong to hold the contacts 45 and 51 together. Since the reed switch 47 is closed the control relay coil 53 is energized pulling yoke 59 and left switch arm 61 to the left-hand position to connect positive diode rectifier 11 with capacitor 19 impressing a positive charge on the capacitor 19.
  • An impulse relay apparatus which comprises in combination:
  • first switch means having an opened and a closed condi-tion
  • relay means responsive to said conditions of said first switch means for switching contact between. said capacitor means and said first charging means and between said capacitor means and said second charging means,
  • said holding means is a permanent magnet having sufficient strength to hold said first switch means in said closed condition but having insufiicient strength to bias said first switch means from said open condition to said closed condition.
  • said first and said second charging means include diodes and a power source.

Landscapes

  • Relay Circuits (AREA)

Description

Sept. 13, 1966 c. A. SHERMAN IMPULSE RELAY Filed Dec. 11, 1963 INVENTOR. CIMRZES A. sum/-14 W ATTORNEYS United States Patent 3,273,024 IMPULSE RELAY Charles A. Sherman, Tacoma, Wash., assignors to Weyerhaeuser Company, Tacoma, Wash, a corporation of Washington Filed Dec. 11, 1963, Ser. No. 329,725 4 Claims. (Cl. 317157) This invention relates to electrical control apparatus and particularly, to an improved-impulse relay apparatus for actuating a control relay.
In electrically operated machines, which are cycled by an operator, it is desirable that the machine control apparatus be simple, inexpensive, reliable and durable. Whenever possible it is desirable to cycle the machine by pushing one button which, when pushed, will actuate the electrical controls to one operating condition which condition will be maintained until the button is again pushed. Such a control is termed an impulse relay.
In the past, impulse relays have been used which are of mechanical construction; however, such relays have not provided satisfactory service over extended periods of usage. Often the mechanical parts of the relays become unreliable after repeated use due to dirt, wear and breakage.
It is a principal object of this invention to provide an impulse relay which is not adversely vaffected by dirt and prolonged usage.
It is a further object of this invention to provide an electrical impulse relay which is made up of simple, inexpensive, electrical components which are reliable and effective in continuous operation.
In the practice of this invention I provide an impulse relay which comprises; a capacitor which is alternatively charged positively and negatively, a .pair of diode rectifiers which are alternatively connected to the capacitor, 9. reed switch which is opened or closed by changes in direction of current flow through a coil surrounding the reed switch and which is held closed by the magnetic force of a permanent magnet which is placed in the vicinity of the reed switch, a relay which changes the connection between the capacitor and the rectifiers and which is energized by the closing of the reed switch, and a pulse switch which when closed makes contact between the capacitor and the reed coil to discharge the capacitor through the reed coil.
Also in the practice of the invention I provide a reed switch which is open in the normal condition, which is biased to an open or closed position by the magnetic force caused by the direction of current flow through a coil surrounding the reed switch, and which is held in the closed position by the magnetic force of another magnet which is of a magnitude sufiicient to hold the reed switch closed but insufiicient to actuate the switch from an open to a closed condition.
How the foregoing objects, together with such other objects as may appear hereafter or are incident to my invention are attained, is illustrated in the preferred form in the accompanying drawing. Various changes may be made, however, in the construction and arrangements of parts in the apparatus and certain features may be used without the use of other features. All such modifications are intended to be within the scope of the appended claims.
The figure shows a schematic diagram of the control circuit of the impulse relay apparatus.
In detail, the figure shows an impulse relay 1 which actuates a control relay 3 which is shown within the dashed lines. The control relay 3 is connected by means of negative relay lead 5 to negative charging diode rectifier 7, and likewise, control relay 3 is connected by means of positive relay lead 9 to positive charging diode rectifier 11. The specific polarity of the diode rectifiers 7 and 11 is given by way of example only and of course is dependent upon the direction of wrapping of the wires in the coil 33 and the polarity of the permanent magnet 49. Rectifiers 7 and 11 have a common connection at junction 12 with rectifier lead 13 which includes resistor R1 and is connected to junction 15. From junction 15, capacitor lead 17 which includes capacitor 19 is connected to junction 21. Also from junction 15, switch lead 23 which includes resistor R2 and pulse switch 25 is connected to junction 27. Between junctions 21 and 27 is lead 29 which includes resistor R3.
Continuing past junction 27 is first coil lead 31 which is connected to reed coil 33. A second coil lead 35 connects reed coil 33 at junction 37 with lead 39 which at the other end is connected to junction 21. Also joined at junction 37 is first alternating current power lead 43 and first reed contact 45. The first reed contact 45 is at one end of reed switch 47 which as shown is glass enclosed. Above the reed switch 47 is permanent magnet 49 which has suflicient magnetic strength to hold first reed contact 45 in physical contact with second reed contact 51, once physical contact between the two reed contacts 45 and 51 has been made by the energization of the reed coil 33. The permanent magnet 49 does not have sufficient strength however to pull contacts 45 and 51 together when reed coil 33 is not energized. It should be noted that reed switch 47 is a normally open switch. Although the magnet 49 is shown as a permanent magnet it is possible to use an electric magnet in its place if it has a constant direction and magnitude of current flow through it.
The second reed switch contact 51 is connected to the control relay coil 53 in control relay 3. The other end of the control relay coil 53 is connected at junction 55 with the second alternating current power lead 57. Energizing relay coil 53 causes the relay yoke 59 to move from the normal right-hand position to the energized left-hand position. Attached to the control relay yoke 59 is left switch arm 61 which is connected by means of power lead 63 to junction 55. Also attached to control relay yoke 59 is right switch arm 65 which is connected electrically to the apparatus being controlled by the control relay 3. In the normal condition of the control relay coil 3, the right switch arm 65 makes contact with the normal control contact 67, and in the energized condition of the control relay 3, the right switch arm 65 makes contact with the energized control con-tact 69. Similarly left switch arm 61 makes contact with negative relay lead 5 in the normal condition and makes contact with positive relay lead 9 in the energized condition.
OPERATION The control relay 3 is connected to diode rectifiers 7 and 11 in the manner shown to charge the capacitor 19 either positively or negatively, depending upon the position of the left switch arm 61. The resistor R1 is placed in the circuit between the diode rectifiers 7 and 11 and the capacitor 19 to limit the charging current of the capacitor 19 and to eliminate surge currents, The resistor RZ serves to prolong the discharge of the capacitor 19 through the reed coil 33. The resistor R3 stabilizes the reed switch circuit.
The control relay coil 53 is energized or de-energized by the closing or opening of the reed switch contacts 45 and 51. In the vicinity of the reed switch 47 is the magnet 49, having suflicien-t strength to bias or hold the contacts 45 and 51 closed, but insufiicient strength to cause the closure of the contacts 45 and 51.
With the impulse relay 1 in the condition shown in the figure, the negative diode rectifier 7 is connected to the capacitor 19 and impresses a negative charge on the capacitor 19. Once the pulse switch 25 is closed the capacitor 19 discharges through the reed coil 33 causing the reed switch contacts 45 and 51 to close. The pulse switch 2 can then be released without effect since the magnetic field of the magnet 49 is sulficiently strong to hold the contacts 45 and 51 together. Since the reed switch 47 is closed the control relay coil 53 is energized pulling yoke 59 and left switch arm 61 to the left-hand position to connect positive diode rectifier 11 with capacitor 19 impressing a positive charge on the capacitor 19. Whenever the pulse switch 25 is again closed the positively charged capacitor 19 discharges through the reed coil 33 causing an opposing magnetic field to that of the magnet 49 which in turn breaks the connection between the reed switch contacts 45 and 51 de-energizing the control relay coil 53 returning the control relay 3 to the normal condition.
Having now described my invention and in what manner the same may be used, what I claim as new and desire to protect by Letters Patent is:
1. An impulse relay apparatus which comprises in combination:
capacitor means,
first means for charging said capacitor means with a charge of one polarity,
second means for charging said capacitor means with a charge of a polarity opposite to said one polarity, first switch means having an opened and a closed condi-tion,
holding means for holding said first switch in said closed condition,
coil means for biasing said first switch means to said closed position responsive to current flow through said coil means of a first direction and for opposing the force of said holding means for biasing said first switch means to said open position responsive to current flow through said coil means of a direction opposite to said first direction,
relay means responsive to said conditions of said first switch means for switching contact between. said capacitor means and said first charging means and between said capacitor means and said second charging means,
second switch means for connecting said coil means to said capacitor means whereby said capacitor means discharges said charges through said coil means to actuate said first switch means to either of said conditions.
2. The appanatus of claim 1 wherein said first switch means is a reed switch.
3. The apparatus of claim 1 wherein said holding means is a permanent magnet having sufficient strength to hold said first switch means in said closed condition but having insufiicient strength to bias said first switch means from said open condition to said closed condition.
4. The apparatus of claim 1 wherein said first and said second charging means include diodes and a power source.
References Cited by the Examiner UNITED STATES PATENTS 2,789,256 4/1957 Stenerson 317-l39 3,002,067 9/ 1961 Baldwin 317--123 OTHER REFERENCES Hovgaard: Development of Reed Switches and Relays, Bell System Technical Journal, vol. 34, March 1955, pp. 326-328.
MILTON O. HIRSHFIELD, Primary Examiner.
SAMUEL BERNSTEIN, Examiner. J. A. SILVERMAN, Assistant Examiner.

Claims (1)

1. AN IMPULSE RELAY APPARATUS WHICH COMPRISES IN COMBINATION: CAPACITOR MEANS, FIRST MEANS FOR CHANGING SAID CAPACITOR MEANS WITH A CHARGE OF ONE POLARITY, SECOND MMEANS FOR CHARGING SAID CAPACITOR MEANS WITH A CHARGE OF A POLARITY OPPOSITE TO SAID ONE POLARITY, FIRST SWITCH MEANS HAVING AN OPENED AND A CLOSED CONDITION, HOLDING MEANS FOR HOLDING SAID FIRST SWITCH IN SAID CLOSED CONDITION, COIL MEANS FOR BIASING SAID FIRST SWITCH IN SAID CLOSED POSITION RESPONSIVE TO CURRENT FLOW THROUGH SAID COIL MEANS OF A FIRST DIRECTION AND FOR OPPOSING THE FORCE OF SAID HOLDING MEANS FIR BIASING SAID FIRST SWITCH MEANS TO SAID OPEN POSITION RESPONSIVE TO CURRENT FLOW THROUGH SAID COIL MEANS OF A DIRECTION OPPOSITE TO SAID FIRST DIRECTION, RELAY MEANS RESPONSIVE TO SAID CONDITIONS OF SAID FIRST SWITCH MEANS FOR SWITCHING CONTACT BETWEEN SAID CAPACITOR MEANS AND SAID FIRST CHARGING MEANS AND BETWEEN SAID CAPACITOR MEANS AND SAID SECOND CHARGING MEANS, SECOND SWITCH MEANS FOR CONNECTING SAID COIL MEANS TO SAID CAPACITOR MEANS FOR CONNECTING SAID COIL MEANS MEANS DISCHARGES SAID CHARGES THROUGH SAID COIL MEANS TO ACTUATE SAID FIRST SWITCH MEANS TO EITHER OF SAID CONDITIONS.
US329725A 1963-12-11 1963-12-11 Impulse relay Expired - Lifetime US3273024A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US329725A US3273024A (en) 1963-12-11 1963-12-11 Impulse relay

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US329725A US3273024A (en) 1963-12-11 1963-12-11 Impulse relay

Publications (1)

Publication Number Publication Date
US3273024A true US3273024A (en) 1966-09-13

Family

ID=23286732

Family Applications (1)

Application Number Title Priority Date Filing Date
US329725A Expired - Lifetime US3273024A (en) 1963-12-11 1963-12-11 Impulse relay

Country Status (1)

Country Link
US (1) US3273024A (en)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3544851A (en) * 1967-11-16 1970-12-01 B & R Relays Ltd Electric stepping switches
US3794888A (en) * 1971-10-01 1974-02-26 Matsushita Electric Works Ltd Remote control switch circuit

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2789256A (en) * 1953-11-18 1957-04-16 Motorola Inc Timing circuit
US3002067A (en) * 1959-07-01 1961-09-26 Bell Telephone Labor Inc Magnetically biased switch

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2789256A (en) * 1953-11-18 1957-04-16 Motorola Inc Timing circuit
US3002067A (en) * 1959-07-01 1961-09-26 Bell Telephone Labor Inc Magnetically biased switch

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3544851A (en) * 1967-11-16 1970-12-01 B & R Relays Ltd Electric stepping switches
US3794888A (en) * 1971-10-01 1974-02-26 Matsushita Electric Works Ltd Remote control switch circuit

Similar Documents

Publication Publication Date Title
GB1402490A (en) Hybrid switching devices for alternating currents
US2317888A (en) Operating circuit for electrical devices
US1606164A (en) Circuit-controlling device
US3273024A (en) Impulse relay
US2260810A (en) Control system
US3912941A (en) Isolation circuit for arc reduction in a dc circuit
US2427719A (en) Polarized direct-current contactor
US2331697A (en) Control system
US5469350A (en) Voltage boosting power failure protected power supply device
US2456541A (en) Differential relay
US3535593A (en) Power flow direction responsive means for alternating current circuit
US3407306A (en) Cranking motor solenoid lockout circuit
US3462647A (en) Cdr self-actuating voltage level protective circuit for vehicular electrical systems
US2425570A (en) Switch system to prevent arcing of contacts
US2845580A (en) Electric protective equipment
US3706087A (en) Alarm latching circuit
GB972673A (en) Supply system for feeding a direct-current magnet system
US3188529A (en) System for controlling electroresponsive means
US3379949A (en) Electronic braking circuit for electric motor
US3529221A (en) Solid state starting circuit for electric motors
US4095124A (en) Transformer/switch device
US2449224A (en) Electrical circuit control
US2419276A (en) Remote control means for electrical circuits
US2353392A (en) Electrical relay
US938501A (en) Adding machine.