US2918609A - Electronically controlled relay - Google Patents

Electronically controlled relay Download PDF

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US2918609A
US2918609A US569844A US56984456A US2918609A US 2918609 A US2918609 A US 2918609A US 569844 A US569844 A US 569844A US 56984456 A US56984456 A US 56984456A US 2918609 A US2918609 A US 2918609A
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base
emitter
relay
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Elliott George
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General Dynamics Corp
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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03KPULSE TECHNIQUE
    • H03K3/00Circuits for generating electric pulses; Monostable, bistable or multistable circuits
    • H03K3/02Generators characterised by the type of circuit or by the means used for producing pulses
    • H03K3/35Generators characterised by the type of circuit or by the means used for producing pulses by the use, as active elements, of bipolar semiconductor devices with more than two PN junctions, or more than three electrodes, or more than one electrode connected to the same conductivity region
    • H03K3/351Generators characterised by the type of circuit or by the means used for producing pulses by the use, as active elements, of bipolar semiconductor devices with more than two PN junctions, or more than three electrodes, or more than one electrode connected to the same conductivity region the devices being unijunction transistors
    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03KPULSE TECHNIQUE
    • H03K17/00Electronic switching or gating, i.e. not by contact-making and –breaking
    • H03K17/51Electronic switching or gating, i.e. not by contact-making and –breaking characterised by the components used
    • H03K17/56Electronic switching or gating, i.e. not by contact-making and –breaking characterised by the components used by the use, as active elements, of semiconductor devices
    • H03K17/70Electronic switching or gating, i.e. not by contact-making and –breaking characterised by the components used by the use, as active elements, of semiconductor devices the devices having only two electrodes and exhibiting negative resistance

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  • This invention relates to relay control means and more particularly to means for electronically controlling such relays responsive to pulses of extremely short time duration.
  • relays it is old to use relays in strictly electromechanical systems. Recently, much research and development has been directed to replacing or controlling these electromechanical systems by electronic means, thereby creating interim problems during the time when mechanical and electronic parts and components must work together in the same system. For example, it may be necessary to control relays by electronically produced pulses having lengths which are measured in terms of microseconds. Also, there may be times when it is desirable to replace only certain electromechanical means by electronic means while retaining, in general, many other of the electromechanical means.
  • An object of this invention is to provide new and improved means for controlling electromechanical switching devices.
  • Another object of this invention is to provide means for electronically controlling relays.
  • Another object of this invention is to provide means whereby a relay may be controlled by a double-base diode.
  • a preferred embodiment of my invention accomplishes the above cited and other objects by providing electromechanical means, such as a relay, controlled by electronic means, such as a bi-stable, triggered electronic switch means comprising a double-base diode.
  • electromechanical means such as a relay
  • electronic means such as a bi-stable, triggered electronic switch means comprising a double-base diode.
  • a descrip-- tion of a double-base diode may be found in an article by I. A. Lesk and V. P. Mathis, The Double-Base Diode-A New Semi-Conductor Device, published in the convention record of the I.R.E.,- part 6, March 1953.
  • the term semi-conductor is used hereinafter to describe an element such as germanium, for example, having an added impurity.
  • the impurity such as phosphorus, has an atomic structure which may have either an excess of electrons when compared with the atomic structure of germanium or a deficit of electrons when compared with the atomic structure of germanium.
  • the impurity in an N-type semi-conductor has an excess of electrons so that current flow results primarily from flow of such excess electrons.
  • the impurity in a P-type semi-conductor has a deficit of electrons so that current flow results primarily from electrons moving into or filling the atomic structure where there is such a deficit thereby causing what appears to be the formation of a hole in the atomic structure at the point from which the electron moved; hence, there appears to be a drift of holes in P-type semi-conductors.
  • Semi-conductors may have a variety of characteristics. For example, a semi-conductor that is useful in an amplifier has characteristics that provide a continuous, enlarged reproduction of an input signal; whereas, another type of semi-conductor that is useful in flip-flop circuits has characteristics that provide a triggered or snapped otf"/on circuit condition.
  • the following specification and claims refer to the trigger or snap type semi-conductor as one of bi-stable operation.”
  • a double-base diode comprises semi-conductive material having two base electrodes (sometimes called ohmic connections) and an emitter electrode (sometimes called a rectifying junction).
  • Each base electrode makes an ohmic connection with opposite portions of the semiconductor while the emitter electrode makes a rectifying junction connection to the semi-conductor at a point which may be displaced from one of the base connections by a distance which is approximately 0.7 of the total distance between the bases.
  • the resistivity of the semiconductor is relatively high. Since a semi-conductor is essentially a linear resistance over the distance between the two base electrodes, the voltage of the area of the semi-conductor at the rectifying junction is approximately 0.7 of the voltage applied between the two base electrodes.
  • the emitter junction When the emitter junction is biased in the forward direction, either holes or electrons, depending upon whether the semi-conductor is N or P type, are injected into the bar from the emitter so as to lower the resistivity of the semi-conductor between the emitter and the first base electrode. As a result, the potential of the semiconductor is lowered at the junction point toward the potential of the first base electrode so that the rate of injection of holes or electrons is increased.
  • the emitter input characteristic shows a negative impedance region and the device is bi-stable in operation.
  • a first circuit is connected b ween the first base of the double-base diode and a reference potential such as ground, for example.
  • Asecond ci cuit is connected between the emitter electrode and a source of control potential.
  • the semi-conductor When the semi-conductor is in its low current conducting state, it presents a very high impedance between the two circuits.
  • the semi-conductor when the semi-conductor is in its high current conducting state, signals appearing in either circuit may be passed by the semi-conductor in a bi-lateral manner with virtually no attenuation.
  • the semi-conductor may be triggered from its low current conducting state to its high current conducting state or vice versa by the application of suitable pulses to either a base or emitter electrode.
  • Fig. 1 shows a relay arranged so that it may be controlled by a double-base diode
  • Fig. 2 shows the characteristics of the double-base diode.
  • a differential relay 10 which may be provided with any number of contacts.
  • the contacts have been shown as simple make contacts 11 which may be used to control a useful work load. Quite obviously any other type or number of contacts may be substituted therefor.
  • Ditferential relay 10 is provided with two windings having an equal number of turns that the flux produced by each winding is equal and opposite to that produced by the other winding when the relay is equally energized over its upper and lower windings.
  • a source of power is shown by plus and minus signs which represent two potentials that may be connected to the windings of the differential relay 10 and to the two bases or ohmic connections B1 and B2 of double-base diode 12.
  • double-base diode 12 When double-base diode 12 is in its off condition, there is practically zero current flowing through emitter or rectifying junction E and its associated circuit. Differential relay 10 does not operate, because the currents flowing through windings ac and b-d are in opposition so that no useful flux is developed. To turn double-base diode 12 on, it is only necessary to introduce a positive pulse at terminal A.
  • the heavily inked curve shows typical characteristics of a double-base diode, such as element 12, for example. That is, a double-base diode conducts emitter current only when the voltage emitter E is at a point on the curve (Fig. 2) which is to the right of the vertical line marked V The semiconductor is triggered to its off position when the voltage on emitter electrode E is at the point marked off.
  • the resistances of relay windings ac and b-d are proportioned to form a voltage divider which maintains points and d at a potential that is slightly below the emitter peak point (Fig. 2) so that emitter E is biased in the reverse direction during the off condition.
  • a positive pulse introduced at terminal A causes the voltage on emitter electrode E to be elevated to the emitter peak point (Fig. 2).
  • emitter E of double-base diode 12 begins to conduct current; however, it has a negative-resistance characteristic so that the voltage at emitter E immediately falls as the current builds up until the point marked on is reached.
  • double-base diode 12 is stable and its conduction is controlled by the resistance of the circuit including winding ac of relay 10. In this stage, there is a minimum resistance path between emitter E and base B1, and another minimum resistance path between base B1 and base B2, thereby increasing the current fiow through winding a-c of relay 10.
  • the low resistance path between emitter E and base B1 in effect shunts the lower or bd winding of relay 10. Under these conditions, the magnetic flux produced in the upper or a-c winding overpowers that produced in the lower or bd winding, thus causing relay 10 to operate and close its contacts 11 thereby performing a useful work load function.
  • Differential relay 10 remains operated until doublebase diode 12 is triggered to its off condition by a pulse which may be applied over the conductors marked Release Pulse to cause a positive potential at base B1 due to the inductive effect of the transformer TR.
  • base B1 becomes more positive
  • emitter E becomes more negative or less positive with respect to base B1.
  • the voltage V shown in Fig. 2 is lowered to a point which, on the graph of Fig. 2, is below the heavily inked line.
  • Double-base diode 12 is then in an unstable condition, and its conduction characteristics are triggered or snapped over to the extreme left-hand portion of the heavily inked curve (Fig. 2) at which time current is flowing at emitter B.
  • double-base diode 12 corresponds to the point on the curve which is marked off and virtually no current is flowing in emitter circuit E thus causing differential relay 10 to release.
  • a plurality of pulses such as those which may be produced by an electronic switching circuit may be used to control an electromechanical relay.
  • Diode 2 is provided to prevent false operation when double-base diode 12 is turned off. Otherwise, when the off pulse is effective, there might be a surge current which would tend to turn on double-base diode 12.
  • Diode 3 is provided to prevent loading of the on pulse source by the relay windings.
  • Diode 4 is provided to prevent a false turn-on which otherwise might result from a negative transient, if any, which may follow the release pulse.
  • An electronic device comprising semiconductive material, means providing two ohmic connections with said material, means providing a rectifying junction with said material, means comprising a source of potential having at least two terminals, means for coupling one of said terminals to one of said connections and means for coupling the other of said terminals to the other of said connections, means for producing two fields of equal and opposite magnetic flux when energized from said source of potential, and means for connecting said two terminals of said source through said flux producing means to said rectifying junction means.
  • Electronically controlled relay means comprising semi-conductive material, means for making two ohmic connections with said material, means for making a rectifying junction with said material, means comprising a source of potential having two terminals, electromechanical means having a plurality of windings which are turned to provide opposing magnetic flux, means for connecting one of said terminals to a first of said ohmic connections, means for connecting the other of said terminals to a second of said ohm c means, means for connecting said one terminal to said rectifying junction through one of said windings, and means for connecting the other of said terminals to said rectifying junction through the other of said windings.
  • a bistable, triggered electronic device comprising semi-conductive material, said semi-conductive material having a stable state of low current conduction and another stable state of high current conduction, means including a pair of electrodes each having ohmic connection with said material, means including a third electrode forming a rectifying junction with said material, means for providing a source of potential comprising two terminals of opposite polarity, means for coupling one of said terminals of said potential source to one of said connections and means for coupling the other of said terminals of said potential source to the other of said connections, means having two windings, each of said windings having two terminals, said windings providing equal and opposite magnetic fiux when energized simultaneously, means for connecting a first terminal of one of said windings to one of said terminals of said potential source, means for connecting a first terminal of the second of said windings to said other terminal of said potential source, means for intercon necting the second terminals of each of said two windings, and means for connecting said interconnected second terminals to said
  • the device of claim 5 and means connected to one of said ohmic connections for biasing said material toward a non-conductive state.

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Description

Dec. 22, 1959 G. ELLIOTT 2, 1 09 ELECTRONICALLY CONTROLLED RELAY Filed March 6, 1956 4 EM ITTER PEAK POINT FIG. 2
0 61 DOUBLE BASE mom:
ONH BI PULSE l RELEASE PULSE I t H 18.
LOAD 1 ,Ln
FIG. I
INVENTOR.
GEORGE E LIOTT United States Patent 2,918,609 ELECTRONICALLY CONTROLLED RELAY George Elliott, Rochester, N.Y., assignor to General Dynamics Corporation, Rochester, N.Y., a corporation of Delaware Application March 6, 1956, Serial No. 569,844 7 Claims. (Cl. 317-1485) This invention relates to relay control means and more particularly to means for electronically controlling such relays responsive to pulses of extremely short time duration.
It is old to use relays in strictly electromechanical systems. Recently, much research and development has been directed to replacing or controlling these electromechanical systems by electronic means, thereby creating interim problems during the time when mechanical and electronic parts and components must work together in the same system. For example, it may be necessary to control relays by electronically produced pulses having lengths which are measured in terms of microseconds. Also, there may be times when it is desirable to replace only certain electromechanical means by electronic means while retaining, in general, many other of the electromechanical means.
An object of this invention is to provide new and improved means for controlling electromechanical switching devices.
Another obiect of this invention is to provide means for electronically controlling relays.
'Still another object of this invention is to provide means whereby a relay may be controlled by a double-base diode.
A preferred embodiment of my invention accomplishes the above cited and other objects by providing electromechanical means, such as a relay, controlled by electronic means, such as a bi-stable, triggered electronic switch means comprising a double-base diode. A descrip-- tion of a double-base diode may be found in an article by I. A. Lesk and V. P. Mathis, The Double-Base Diode-A New Semi-Conductor Device, published in the convention record of the I.R.E.,- part 6, March 1953. The term semi-conductor is used hereinafter to describe an element such as germanium, for example, having an added impurity. The impurity, such as phosphorus, has an atomic structure which may have either an excess of electrons when compared with the atomic structure of germanium or a deficit of electrons when compared with the atomic structure of germanium. The impurity in an N-type semi-conductor has an excess of electrons so that current flow results primarily from flow of such excess electrons. On the other hand, the impurity in a P-type semi-conductor has a deficit of electrons so that current flow results primarily from electrons moving into or filling the atomic structure where there is such a deficit thereby causing what appears to be the formation of a hole in the atomic structure at the point from which the electron moved; hence, there appears to be a drift of holes in P-type semi-conductors. Semi-conductors may have a variety of characteristics. For example, a semi-conductor that is useful in an amplifier has characteristics that provide a continuous, enlarged reproduction of an input signal; whereas, another type of semi-conductor that is useful in flip-flop circuits has characteristics that provide a triggered or snapped otf"/on circuit condition. The following specification and claims refer to the trigger or snap type semi-conductor as one of bi-stable operation."
ice
Briefly, a double-base diode comprises semi-conductive material having two base electrodes (sometimes called ohmic connections) and an emitter electrode (sometimes called a rectifying junction). Each base electrode makes an ohmic connection with opposite portions of the semiconductor while the emitter electrode makes a rectifying junction connection to the semi-conductor at a point which may be displaced from one of the base connections by a distance which is approximately 0.7 of the total distance between the bases. When the emitter junction is biased in the reverse direction, the resistivity of the semiconductor is relatively high. Since a semi-conductor is essentially a linear resistance over the distance between the two base electrodes, the voltage of the area of the semi-conductor at the rectifying junction is approximately 0.7 of the voltage applied between the two base electrodes. When the emitter junction is biased in the forward direction, either holes or electrons, depending upon whether the semi-conductor is N or P type, are injected into the bar from the emitter so as to lower the resistivity of the semi-conductor between the emitter and the first base electrode. As a result, the potential of the semiconductor is lowered at the junction point toward the potential of the first base electrode so that the rate of injection of holes or electrons is increased. Thus, the emitter input characteristic shows a negative impedance region and the device is bi-stable in operation.
According to the invention, a first circuit is connected b ween the first base of the double-base diode and a reference potential such as ground, for example. Asecond ci cuit is connected between the emitter electrode and a source of control potential. When the semi-conductor is in its low current conducting state, it presents a very high impedance between the two circuits. On the other hand, when the semi-conductor is in its high current conducting state, signals appearing in either circuit may be passed by the semi-conductor in a bi-lateral manner with virtually no attenuation. The semi-conductor may be triggered from its low current conducting state to its high current conducting state or vice versa by the application of suitable pulses to either a base or emitter electrode.
Otherobjects will be apparent by making reference to the attached drawing, in which:
Fig. 1 shows a relay arranged so that it may be controlled by a double-base diode; and
Fig. 2 shows the characteristics of the double-base diode.
The following specification and the attached drawing illustrate a particular embodiment of my invention. Further, simple and specific terms are used herein to facilitate an understanding of my invention. However, it should be understood that the showing of such particular embodiment and the using of such simple and specific terms are not to act in any manner as a disclaimer of the full range of equivalents which is normally given under established rules of patent law. For example, the semiconductor has been explained in terms of germanium and phosphorus when other materials may be equally useful.
Turning to the drawing in greater detail, there is shown a differential relay 10 which may be provided with any number of contacts. For purposes of illustration only, the contacts have been shown as simple make contacts 11 which may be used to control a useful work load. Quite obviously any other type or number of contacts may be substituted therefor. Ditferential relay 10 is provided with two windings having an equal number of turns that the flux produced by each winding is equal and opposite to that produced by the other winding when the relay is equally energized over its upper and lower windings. A source of power is shown by plus and minus signs which represent two potentials that may be connected to the windings of the differential relay 10 and to the two bases or ohmic connections B1 and B2 of double-base diode 12.
When double-base diode 12 is in its off condition, there is practically zero current flowing through emitter or rectifying junction E and its associated circuit. Differential relay 10 does not operate, because the currents flowing through windings ac and b-d are in opposition so that no useful flux is developed. To turn double-base diode 12 on, it is only necessary to introduce a positive pulse at terminal A.
Referring to Fig. 2, the heavily inked curve shows typical characteristics of a double-base diode, such as element 12, for example. That is, a double-base diode conducts emitter current only when the voltage emitter E is at a point on the curve (Fig. 2) which is to the right of the vertical line marked V The semiconductor is triggered to its off position when the voltage on emitter electrode E is at the point marked off. The resistances of relay windings ac and b-d are proportioned to form a voltage divider which maintains points and d at a potential that is slightly below the emitter peak point (Fig. 2) so that emitter E is biased in the reverse direction during the off condition.
A positive pulse introduced at terminal A (Fig. 1) causes the voltage on emitter electrode E to be elevated to the emitter peak point (Fig. 2). At this point emitter E of double-base diode 12 begins to conduct current; however, it has a negative-resistance characteristic so that the voltage at emitter E immediately falls as the current builds up until the point marked on is reached. At this point, double-base diode 12 is stable and its conduction is controlled by the resistance of the circuit including winding ac of relay 10. In this stage, there is a minimum resistance path between emitter E and base B1, and another minimum resistance path between base B1 and base B2, thereby increasing the current fiow through winding a-c of relay 10. The low resistance path between emitter E and base B1 in effect shunts the lower or bd winding of relay 10. Under these conditions, the magnetic flux produced in the upper or a-c winding overpowers that produced in the lower or bd winding, thus causing relay 10 to operate and close its contacts 11 thereby performing a useful work load function.
Differential relay 10 remains operated until doublebase diode 12 is triggered to its off condition by a pulse which may be applied over the conductors marked Release Pulse to cause a positive potential at base B1 due to the inductive effect of the transformer TR. When base B1 becomes more positive, emitter E becomes more negative or less positive with respect to base B1. In effect, the voltage V shown in Fig. 2, is lowered to a point which, on the graph of Fig. 2, is below the heavily inked line. Double-base diode 12 is then in an unstable condition, and its conduction characteristics are triggered or snapped over to the extreme left-hand portion of the heavily inked curve (Fig. 2) at which time current is flowing at emitter B. At this point, the internal characteristics of double-base diode 12 correspond to the point on the curve which is marked off and virtually no current is flowing in emitter circuit E thus causing differential relay 10 to release. In this manner, a plurality of pulses such as those which may be produced by an electronic switching circuit may be used to control an electromechanical relay.
Next, attention is directed to the function of the windings of relay 10. Usually a separate power source is provided for emitter E to bias double-base diode 12 to the point on the curve of Fig. 2 that is indicated by the word off. This bias potential may be either a separate battery or a voltage divider connected between the plus and minus terminals as shown in the drawing. My invention avoids the requirement for an extra battery or a separate voltage divider since I use the resistance of the two windings of relay 10 to divide the voltage or potential existing between the plus (-1-) and minus terminals thereby providing a proper bias potential for emitter E.
Diode 2 is provided to prevent false operation when double-base diode 12 is turned off. Otherwise, when the off pulse is effective, there might be a surge current which would tend to turn on double-base diode 12. Diode 3 is provided to prevent loading of the on pulse source by the relay windings. Diode 4 is provided to prevent a false turn-on which otherwise might result from a negative transient, if any, which may follow the release pulse.
While I have shown and described a single embodiment of my invention, it should be obvious that various modifications may be made without departing from the scope thereof. Hence, it is my intention to cover in the attached claims not only the particular circuit shown in the drawing, but also all modifications which fall within the true spirit of my invention.
What is claimed is:
1. An electronic device comprising semiconductive material, means providing two ohmic connections with said material, means providing a rectifying junction with said material, means comprising a source of potential having at least two terminals, means for coupling one of said terminals to one of said connections and means for coupling the other of said terminals to the other of said connections, means for producing two fields of equal and opposite magnetic flux when energized from said source of potential, and means for connecting said two terminals of said source through said flux producing means to said rectifying junction means.
2. The electronic device of claim 1 and means for introducing a control voltage in said connect on between said flux producing means and said rectifying junction means, said control voltage being of sufiicient voltage to trigger said device to an on condition.
3. Electronically controlled relay means comprising semi-conductive material, means for making two ohmic connections with said material, means for making a rectifying junction with said material, means comprising a source of potential having two terminals, electromechanical means having a plurality of windings which are turned to provide opposing magnetic flux, means for connecting one of said terminals to a first of said ohmic connections, means for connecting the other of said terminals to a second of said ohm c means, means for connecting said one terminal to said rectifying junction through one of said windings, and means for connecting the other of said terminals to said rectifying junction through the other of said windings.
4. In combination a bistable, triggered electronic device comprising semi-conductive material, said semi-conductive material having a stable state of low current conduction and another stable state of high current conduction, means including a pair of electrodes each having ohmic connection with said material, means including a third electrode forming a rectifying junction with said material, means for providing a source of potential comprising two terminals of opposite polarity, means for coupling one of said terminals of said potential source to one of said connections and means for coupling the other of said terminals of said potential source to the other of said connections, means having two windings, each of said windings having two terminals, said windings providing equal and opposite magnetic fiux when energized simultaneously, means for connecting a first terminal of one of said windings to one of said terminals of said potential source, means for connecting a first terminal of the second of said windings to said other terminal of said potential source, means for intercon necting the second terminals of each of said two windings, and means for connecting said interconnected second terminals to said third electrode whereby the resistance of said two windings form a voltage divider for providing a bias voltage for said third electrode.
5. The device of claim 4 and means connected between said windings and said rectifying junction for biasing said material toward a conductive state.
6. The device of claim 5 and means connected to one of said ohmic connections for biasing said material toward a non-conductive state.
7. The device of claim 4 and means connected to one of said ohmic connections for biasing said material toward at non-conductive state.
References Cited in the file of this patent UNITED STATES PATENTS Reagan Mar. 7,
Rack Dec. 18,
Harris Sept. 20,
Lesk Nov. 6,
FOREIGN PATENTS France Apr. 4,
US569844A 1956-03-06 1956-03-06 Electronically controlled relay Expired - Lifetime US2918609A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3045150A (en) * 1958-10-13 1962-07-17 Leach Corp Time delay circuit
US3092760A (en) * 1959-12-14 1963-06-04 Square D Co Switching circuit
US3128415A (en) * 1959-12-14 1964-04-07 Cons Electronics Ind Timing circuit

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2343423A (en) * 1940-07-19 1944-03-07 Westinghouse Electric & Mfg Co Relay control system
US2579336A (en) * 1950-09-15 1951-12-18 Bell Telephone Labor Inc Stabilized transistor trigger circuit
FR1090759A (en) * 1953-01-22 1955-04-04 Teletype Corp Transistor relay
US2718613A (en) * 1952-10-08 1955-09-20 Bell Telephone Labor Inc Transistor circuit for operating a relay
US2769926A (en) * 1953-03-09 1956-11-06 Gen Electric Non-linear resistance device

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2343423A (en) * 1940-07-19 1944-03-07 Westinghouse Electric & Mfg Co Relay control system
US2579336A (en) * 1950-09-15 1951-12-18 Bell Telephone Labor Inc Stabilized transistor trigger circuit
US2718613A (en) * 1952-10-08 1955-09-20 Bell Telephone Labor Inc Transistor circuit for operating a relay
FR1090759A (en) * 1953-01-22 1955-04-04 Teletype Corp Transistor relay
US2769926A (en) * 1953-03-09 1956-11-06 Gen Electric Non-linear resistance device

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3045150A (en) * 1958-10-13 1962-07-17 Leach Corp Time delay circuit
US3092760A (en) * 1959-12-14 1963-06-04 Square D Co Switching circuit
US3128415A (en) * 1959-12-14 1964-04-07 Cons Electronics Ind Timing circuit

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