US1911133A - Self-biasing relay circuit - Google Patents

Self-biasing relay circuit Download PDF

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Publication number
US1911133A
US1911133A US474857A US47485730A US1911133A US 1911133 A US1911133 A US 1911133A US 474857 A US474857 A US 474857A US 47485730 A US47485730 A US 47485730A US 1911133 A US1911133 A US 1911133A
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relay
circuit
signal
condenser
plate
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US474857A
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Leon G Pollard
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Western Union Telegraph Co
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Western Union Telegraph Co
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L27/00Modulated-carrier systems
    • H04L27/02Amplitude-modulated carrier systems, e.g. using on-off keying; Single sideband or vestigial sideband modulation
    • H04L27/08Amplitude regulation arrangements

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  • This invention relates to a receiving circuit, and more particularly to a circuit in which a polarized relay may be operated by a unipolar interrupted signal wave of varyl u 1 ing intensity, or ot varying speed, or ooth.
  • My relay circuit may be employed for the detection of signals ot varying intensity sucn as high frequency radio signals subject to lading. lt may also be employed 'for the de tection of signals transmitted over wires by carrier currents.
  • V1 and V2 are two three-electrode vacuum tubes whose input circuits are connected in push-pull relation to the secondary of an input transformer T.
  • the signals to be detected are supplied to the primary of transformer T.
  • the common portion of the input circuit or the two vacuum tubes includes a biasing battery B1 arranged to normally maintain the grids at a negative potential with respect to the cathodes.
  • a second Winding HJ of the polar relay is connected in shunt to resistance R with a condenser C inserted in series therewith.
  • the tongue t ot the polar relay is arranged to operate between the marking and spacing contacts M and S, respectively, which are connected to opposite terminals of a battery B3.
  • the tongue t and the midpoint of battery B3 are connected respectively to the operating terminals of any suitable recording apparatus P.
  • a condenser K is connected between the plate and lilament elements of the tubes to bly-pass the high frequency component around the polar relay.
  • the value of the negative biasing voltage supplied by battery B1 is such that normally when no signal is being received no plate current flows through the plate circuit.
  • the two coils of the polar relay are so connected that the charging current taken by condenser C and flowing through coil HJ normally assists the plate current lowiiig through coil TPG to move the armature t to the mai-hing position.
  • the plate current flowing through the relay drops to zero, and the condenser C is allowed to discharge through resistance R. Since the discharge current flows in a direction opposite to the charging current, the tongue t of the relay will be actuated to the spacing contact S, thereby causing a spacing signal to be recorded. This cycle of operation takes place for each signal wav-e received.
  • lVhile I have shown two vacuum tubes arranged in push-pull relation with respect to the incoming signal circuit, it is obvious that the invention is not limited to the push-pull arrangement, but a single tube may be employed if desired. It is also obvious that a polar relay having a single winding may be operated by my circuit arrangement in which the winding is connected in the same position as winding I-IJ in the diagram. In this modification, the two plate elements would be connected directly to the upper terminal of the resistance R. In the operation of this modification, the charging current for condenser C flowing through the Winding HJ operates the tongue to the marking contact M, and the discharging current which occurs V at the end of the signal, operates the tongue to the spacing contact.
  • my invention may be employed for the detection of interrupted pulsating signal waves as well as modulated carrier waves.
  • a relay circuit the combination of a polar relay having two operating windings, a vacuum tube relay, a plate circuit for said vacuum tube relay including one of said windings and a resistance element, a shunt circuit around said resistance including said second Winding and a condenser in series, said windings being arranged to exert a cumulative action upon the tongue of said relay While said condenser is being charged.
  • a relay circuit the combination of a polar relay having an operating Winding, a Vacuum tube relay, a plate circuit for said vacuum tube relay including a resistance element, a shunt circuit around said resistance element including said operating winding and al condenser in series, a source of signaling current connected to the input circuit of said vacuum tube relay, means for normally biasing the input circuit of said relay to prevent the iow of plate current While no signal is being received.
  • a relay circuit the combination of a source of signaling Waves, a pair of vacuum tube relays having their input circuits connected to said source in pushpull relation, and the output circuits connected in parallel relation, a resistance element connected in said plate circuit, a polar relay having an operating Winding and a condenser in series therewith, said operating winding and condenser being connected in shunt to said resistance element, and means for normally biasing the input circuits of said vacuum tube relays to prevent the flow of plate current when no signal is received.
  • a relay circuit the combination of a source of signaling waves, a pair of vacuum tube relays having their input circuits connected to said source in push-pull relation, a polar relay having two operating windings, the plate elements of said vacuum tubes being connected together to a common plate circuit including one winding of said relay and a resistance element, and a path in shunt to said resistance element including the other Winding of said relay and a condenser in series relation.
  • a relay circuit In a relay circuit, the combination of an input transformer, a pair of vacuum tube relays having their input circuits connected to the secondary of said transformer in pushpull relation, a polar relay having two operating windings, the plate elements of said vacuum tube relays being connected together to a common plate circuit including one operating Winding and a resistance element, a path in shunt to said resistance element including the other operating winding and a condenser connected in series relation, and a source of potential for normally biasing the the input circuits of said vacuum tube relays to prevent the flow of plate current when no signal is received.

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Relay Circuits (AREA)

Description

May 23, 1933. L. G. POLLARD 1,911,133
SELF BIASING RELAY CIRCUIT Filed Aug. l2, 1950 Rico/roe@ p lleve/1Km' Jew: f Polla/a Patented May 23, 1933 UNE STATES PATE.
. LEON G. YOLLARD, OF SOUTHAMPTON, NEW YORK, ASSIGNOR TO THE WESTERN UNION TELEGRAPH COMPANY, OF NEW YORK, N. Y., A CORPORATION OF NEW YORK SELF-BIASING RELAY CIRCUIT Application led August 12, 1930. Serial No. 474,857.
This invention relates to a receiving circuit, and more particularly to a circuit in which a polarized relay may be operated by a unipolar interrupted signal wave of varyl u 1 ing intensity, or ot varying speed, or ooth.
" the cessation of the incoming signal.
My relay circuit may be employed for the detection of signals ot varying intensity sucn as high frequency radio signals subject to lading. lt may also be employed 'for the de tection of signals transmitted over wires by carrier currents.
My invention is illustrated in the accompanying drawing in which is shown a circuit Y diagram ot one forni of the relay circuit.
Referring to the drawing V1 and V2 are two three-electrode vacuum tubes whose input circuits are connected in push-pull relation to the secondary of an input transformer T.
The signals to be detected are supplied to the primary of transformer T. The common portion of the input circuit or the two vacuum tubes includes a biasing battery B1 arranged to normally maintain the grids at a negative potential with respect to the cathodes. The
two plate elements are connected in parallel, and a common plate circuit is completed through a winding` FG of a polar relay, through resist-ance R and through battery B2 to the filaments connected in parallel. A second Winding HJ of the polar relay is connected in shunt to resistance R with a condenser C inserted in series therewith. The tongue t ot the polar relay is arranged to operate between the marking and spacing contacts M and S, respectively, which are connected to opposite terminals of a battery B3. The tongue t and the midpoint of battery B3 are connected respectively to the operating terminals of any suitable recording apparatus P. A condenser K is connected between the plate and lilament elements of the tubes to bly-pass the high frequency component around the polar relay.
The value of the negative biasing voltage supplied by battery B1 is such that normally when no signal is being received no plate current flows through the plate circuit. The two coils of the polar relay are so connected that the charging current taken by condenser C and flowing through coil HJ normally assists the plate current lowiiig through coil TPG to move the armature t to the mai-hing position.
peration ot the relay circuit is as follows:
Vhen no signal is being received, no current flows in the plate circuit and, therefore, there is no drop in potential across resistance R. Under this condition, condenser C is in a state of discharge. Upon the receipt of a signal wave, unidirectional current is caused to flow in the plate circuit through resistance R and polar relay coil FG. Due to the difference in potential developedacross resistance R a. current is caused to llow through coil HJ to charge condenser C. The two currents flowing in the two coils ot the relay act in a cumulative manner to move the tongue t to the marking Contact M, thereby causing a marking signal to be recorded.
At the end of the signal, the plate current flowing through the relay drops to zero, and the condenser C is allowed to discharge through resistance R. Since the discharge current flows in a direction opposite to the charging current, the tongue t of the relay will be actuated to the spacing contact S, thereby causing a spacing signal to be recorded. This cycle of operation takes place for each signal wav-e received.
From the foregoing it will be ob-served that normally the tongue ot the polarized relay is not biased to either position, but the biasing force tending to move the tongue of the relay to the spacing position is brought into play only after the signals have ceased. Tn other words, the circuit provides `for the seltbiasing oie the relay, and the strength of the biasing force varies in accordance with the strength of the signal being received. This oiers a considerable advantage overv relays of the type in which the tongue is normally biased to the spacing position by a biasing force of constant magnitude, and in which the tongue is moved to the spacing position as soon as the signal strength drops below the force tending to bias the relay to the spacing position. In my arrangement, by the inclusion of one coil of the relay directly in the plate circuit, the armature is caused to remain on the marking contact as long as the signal is of sutiicient strength to exert the slightest force on the armature.
lVhile I have shown two vacuum tubes arranged in push-pull relation with respect to the incoming signal circuit, it is obvious that the invention is not limited to the push-pull arrangement, but a single tube may be employed if desired. It is also obvious that a polar relay having a single winding may be operated by my circuit arrangement in which the winding is connected in the same position as winding I-IJ in the diagram. In this modification, the two plate elements would be connected directly to the upper terminal of the resistance R. In the operation of this modification, the charging current for condenser C flowing through the Winding HJ operates the tongue to the marking contact M, and the discharging current which occurs V at the end of the signal, operates the tongue to the spacing contact.
It is obvious that my invention may be employed for the detection of interrupted pulsating signal waves as well as modulated carrier waves.
I claim:
l. In a relay circuit, the combination of a polar relay having two operating windings, a vacuum tube relay, a plate circuit for said vacuum tube relay including one of said windings and a resistance element, a shunt circuit around said resistance including said second Winding and a condenser in series, said windings being arranged to exert a cumulative action upon the tongue of said relay While said condenser is being charged.
2. In a relay circuit, the combination of a polar relay having an operating Winding, a Vacuum tube relay, a plate circuit for said vacuum tube relay including a resistance element, a shunt circuit around said resistance element including said operating winding and al condenser in series, a source of signaling current connected to the input circuit of said vacuum tube relay, means for normally biasing the input circuit of said relay to prevent the iow of plate current While no signal is being received.
3. In a relay circuit, the combination of a source of signaling Waves, a pair of vacuum tube relays having their input circuits connected to said source in pushpull relation, and the output circuits connected in parallel relation, a resistance element connected in said plate circuit, a polar relay having an operating Winding and a condenser in series therewith, said operating winding and condenser being connected in shunt to said resistance element, and means for normally biasing the input circuits of said vacuum tube relays to prevent the flow of plate current when no signal is received.
4. In a relay circuit, the combination of a source of signaling waves, a pair of vacuum tube relays having their input circuits connected to said source in push-pull relation, a polar relay having two operating windings, the plate elements of said vacuum tubes being connected together to a common plate circuit including one winding of said relay and a resistance element, and a path in shunt to said resistance element including the other Winding of said relay and a condenser in series relation. 5. In a relay circuit, the combination of an input transformer, a pair of vacuum tube relays having their input circuits connected to the secondary of said transformer in pushpull relation, a polar relay having two operating windings, the plate elements of said vacuum tube relays being connected together to a common plate circuit including one operating Winding and a resistance element, a path in shunt to said resistance element including the other operating winding and a condenser connected in series relation, and a source of potential for normally biasing the the input circuits of said vacuum tube relays to prevent the flow of plate current when no signal is received.
In testimony whereof I afx my signature.
LEON G. POLLARD.
US474857A 1930-08-12 1930-08-12 Self-biasing relay circuit Expired - Lifetime US1911133A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2731551A (en) * 1950-06-30 1956-01-17 Gen Railway Signal Co Cab signalling system for railroads

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2731551A (en) * 1950-06-30 1956-01-17 Gen Railway Signal Co Cab signalling system for railroads

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