US3204151A - Fast-acting relay controlled circuit - Google Patents
Fast-acting relay controlled circuit Download PDFInfo
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- US3204151A US3204151A US244992A US24499262A US3204151A US 3204151 A US3204151 A US 3204151A US 244992 A US244992 A US 244992A US 24499262 A US24499262 A US 24499262A US 3204151 A US3204151 A US 3204151A
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03K—PULSE TECHNIQUE
- H03K3/00—Circuits for generating electric pulses; Monostable, bistable or multistable circuits
Definitions
- An electromechanical relay is often used to either establish or disestablish a connection from one circuit element to another.
- a winding associated with the relay is energized to create a magnetic field which acts upon a set of contacts that link the circuit elements. Where the contacts are normally separated, the field serves to draw them together and establish a conduction path between the elements, but where the contacts are normally closed, the field causes their separation and disrupts the path.
- a related object is to eliminate the vibration that ofiten accompanies the operation of the contacts.
- the invention provides for shunting the contacts by a unidirectionally conductive device which is coupled to the winding, i.e., coil, of the relay through a resistor of appreciable resistive magnitude.
- the coupling resistor is readily proportioned to allow the coil energy to build up to a level which operates the contacts slightly before the current through the device falls below the level required to maintain the clamping action.
- the unidirectionally conductive device is rendered conductive by the control source until a control signal attributable to it decays exponentially, substantially according to the relation li eto a cut-off point K, at the time T.
- the control source energizes the relay winding by a control signal that increases monotonically, substantially according to the relation K -K r until the contacts are operated at a time T, which occurs earlier than the cut-oil time T.
- one circuit element is initially connected to another through the unidirectionally conductive device and subsequently through the relay contacts.
- FIG. 1 is a schematic diagram of a fast acting relay circuit according to the invention.
- FIG. 2 is a graphical diagram explanatory of the operation of the circuit in FIG. 1.
- an electromechanical relay r is used 'for cont-rolling a work circuit that includes a source E and a load R
- the relay r is rep-resented by a pair of normally open contacts r1 in the work circuit and a winding, i.e., coil, in an operate circuit.
- the winding is characterized by an impedance with a reactive constituent of inductance L.
- the coil is energized from a source E through a resistor R by the closure of a switch S.
- the resist-or may expressly limit the flow of current through the coil after the switch S has been operated, or it may represent the impedance of another device employed in conjunction with the relay r.
- the operate circuit When the operate circuit is activated, the contacts in the work circuit are brought together after a duration determined by the time required for a sufficient buildup of magnetic field energy in the coil.
- a unilaterally conductive device such as a rectifying diode D, shunts the contacts r1 and is connected to the operate circuit through an isolating element 10.
- the isolating element is desirably a resistor of appreciable resistance magnitude R and the signal strength of the operate source E is proportioned to be greater than the corresponding strength of the work source, i.e., E E
- the inductive inertia of the coil L prevents the immediate flow of current through it so that the shunt diode, being subjected to greater volt age at its anode than at its cathode, is rendered conductive and the work voltage E is directly applied to the load as desired.
- the loop current flow i through the isolating resistor R is greater than the loop current flow i in the load the diode will be maintained in a forward-biased condition and the work voltage E will continue to be applied at the load R
- the current i through the isolator resistor neglecting the coil resistance
- the fiux q) reaches a preassigned magnitude (FIG. 2) that is of sufficient strength to operate the relay contacts and
- the coil inductance is on the order of 240 henries and the operate time is on the order of 7 milliseconds.
- R is 24,000 ohms, and of a smaller magnitude than R the relationship among the parameters of Expression 4b is mil
- R j R or R Expression 4b becomes from which appropriate resistive magnitudes can be determined in the manner previously described.
- Apparatus comprising a relay having a pair of normally open contacts, and
- control winding characterized by electrical inertia
- Apparatus comprising a relay with a control winding and a pair of normally open contacts
- means including a first source and a resistor, for energizing said control winding
- a first path including said contacts for connecting a second source to a load by the closure of said contacts
- means including a first source, for energizing said relay,
- a fast-acting relay controlled circuit comprising a relay having a pair of normally open contacts and a winding characterized by electrical inertia
- a fast-acting relay controlled circuit comprising a relay having a winding and a pair of contacts
- Apparatus responsive to energizing means for connecting a source with a load comprising first means energized from the energizing means substantially according to the relation K r for clamping the source to the load as long as K e 1 K where K is the initial signal level of said first means,
- diode having a cathode and an anode, said anode being connected to said second terminal of said pair of contacts and said cathode being connected to the first terminal of said pair of contacts,
- third resistor having first and second terminals and characterized by a resistance R the second terminal of said third resistor being connected to said second terminal of said pair of contacts, and a source characterized by a voltage E interconnecting the first terminal of said third resistor with said first whereby said source is initially connected to said load terminal of said pair of contacts.
- Apparatus responsive to energizing means capable said winding from said switchable source; and of supplying increasing and decreasing signals, for consaid winding, said first resistor, said second resistor, nectingasource witha load, comprising said third resistor, said switchable source, and said means controlled by an asymptotically increasing sigsecond named source are proportioned according to nal supplied by the energizing means for connecting the relation said second means changes during time t, K is the 10 level which said second means operates, and T is its operate time,
- Apparatus responsive to energizing means for connecting a source to a load comprising means energized by a steadily increasing signal supplied by the energizing means for connecting the source to the load after a delay time T, and the relation means energized by a steadily decreasingsignal supplied L( R2) (E1R2R3+E3R1R3) by said energizing means for connecting said source T R 13 1n E (R1+Rz) ris) to said load until the attainment of a time T after said delay time 12.
- a relay-controlled circuit comprising mg and a pan of normally Open contacts an operate circuit including the winding of the relay and means for energizing it,
- a work circuit including the contacts of said relay and a source connectable to a load therethrough
- a first resistor having first and second terminals and being characterized by a resistance R the first terminal of said first resistor being connected to the first terminal of said winding
- a switchable source characterized by a voltage E and interconnecting the second terminal of said first resistor with the second terminal of said winding, 5
- a second resistor having first and second terminals and characterized by a resistance R the first terminal of said second resistor being connected to the junction of said first terminal of said first resistor with said first terminal of said winding and the second ter- SAMUEL BBRNSTEIN Pfimm? Examine"-
Description
G. E. KERSEY FAST-ACTING RELAY CONTROLLED CIRCUIT Filed Dec. 1'7, 1962 FIG! NORM/ILL Y FIG. 2
TIME
INVENTOR G. E. KERSE V A T TORNE V Aug. 31, 1 965 United States Patent 3,204,151 FAST-ACTING RELAY CGNTR'ULLED CIRCUIT George E. Kersey, Milliugton, N..l., assignor to Bell Telephone Laboratories, Incorporated, New York, N.Y., a corporation of New York Filed Dec. 17, 1962, Ser. No. 244,992 1?. Claims. (Cl. 317-441) This invention relates to relay-controlled circuits, and more particularly to the rapid openation of such circuits employing electromechanical relays.
An electromechanical relay is often used to either establish or disestablish a connection from one circuit element to another. In such a case a winding associated with the relay is energized to create a magnetic field which acts upon a set of contacts that link the circuit elements. Where the contacts are normally separated, the field serves to draw them together and establish a conduction path between the elements, but where the contacts are normally closed, the field causes their separation and disrupts the path.
While an electromechanical relay is simple and reliable, it is subject to several disadvantages. In the first place the electrical inertia of its winding prevents a rapid change in the magnetic field that acts upon the contacts, thus delaying their closure, when open, and their separation, when closed. In addition, the motion of the contacts :produced by the field often results in undesirable vibration, i.e., chatter.
Accordingly it is an object of the invention to reduce the extent of the delay interval that conventionally exists between the energizing of a relay winding and the operation of associated relay contacts. A related object is to eliminate the vibration that ofiten accompanies the operation of the contacts.
To accomplish the foregoing and relate-d objects the invention provides for shunting the contacts by a unidirectionally conductive device which is coupled to the winding, i.e., coil, of the relay through a resistor of appreciable resistive magnitude.
As a result, when a load is to be energized through the contacts 'from a work source, and a control source, producing an output level of greater magnitude, energizes the coil, the unidirectionally conductive device becomes operated and the load is clamped to the signal level of the work source so long as the current supplied to the device by the control source is greater than that drawn by the load.
It is a feature of the invention that the coupling resistor is readily proportioned to allow the coil energy to build up to a level which operates the contacts slightly before the current through the device falls below the level required to maintain the clamping action.
In effect, the unidirectionally conductive device is rendered conductive by the control source until a control signal attributable to it decays exponentially, substantially according to the relation li eto a cut-off point K, at the time T. Simultaneously, the control source energizes the relay winding by a control signal that increases monotonically, substantially according to the relation K -K r until the contacts are operated at a time T, which occurs earlier than the cut-oil time T. Hence, one circuit element is initially connected to another through the unidirectionally conductive device and subsequently through the relay contacts.
Other aspects of the invention will become apparent after the consideration of an illustrative embodiment taken in conjunction with the drawings in which:
FIG. 1 is a schematic diagram of a fast acting relay circuit according to the invention; and
FIG. 2 is a graphical diagram explanatory of the operation of the circuit in FIG. 1.
As shown in FIG. 1, an electromechanical relay r is used 'for cont-rolling a work circuit that includes a source E and a load R The relay r is rep-resented by a pair of normally open contacts r1 in the work circuit and a winding, i.e., coil, in an operate circuit. The winding is characterized by an impedance with a reactive constituent of inductance L. In the operate circuit, the coil is energized from a source E through a resistor R by the closure of a switch S. The resist-or may expressly limit the flow of current through the coil after the switch S has been operated, or it may represent the impedance of another device employed in conjunction with the relay r. When the operate circuit is activated, the contacts in the work circuit are brought together after a duration determined by the time required for a sufficient buildup of magnetic field energy in the coil.
To apply the source voltage E to the load R within the delay interval that normally attend-s relay operation, a unilaterally conductive device, such as a rectifying diode D, shunts the contacts r1 and is connected to the operate circuit through an isolating element 10. The isolating element is desirably a resistor of appreciable resistance magnitude R and the signal strength of the operate source E is proportioned to be greater than the corresponding strength of the work source, i.e., E E
When the switch S is operated the inductive inertia of the coil L prevents the immediate flow of current through it so that the shunt diode, being subjected to greater volt age at its anode than at its cathode, is rendered conductive and the work voltage E is directly applied to the load as desired. As long as the loop current flow i through the isolating resistor R is greater than the loop current flow i in the load the diode will be maintained in a forward-biased condition and the work voltage E will continue to be applied at the load R The current i through the isolator resistor, neglecting the coil resistance, is
where E the inductor voltage, is an exponentially decaying function given in Expression 1 R2+ s 1 R1+R2 6 1) Usually R R and, since E E B is approximately Rlt E ZE 8 T and the isolating resistor current i becomes At the same time, the current i flowing through the load R because of the work voltage is E /R The work voltage E will continue to be applied through the diode The left-hand and right-hand sides of Expression 4a, which substantially give the currents i and i flowing through the diode D due respectively to the voltage of the coil L and the work source E are plotted in FIG. 2. When the two currents are equal, at time T given by Expression 4b R E 4b T 1 ln R2 3 the diode D is no longer able to clamp the load R at 1 LE f L (o) where N is the number of turns in the coil, B is the voltage of the coil, and L is the inductance of the coil.
At time T, the fiux q) reaches a preassigned magnitude (FIG. 2) that is of sufficient strength to operate the relay contacts and For a typical relay, the coil inductance is on the order of 240 henries and the operate time is on the order of 7 milliseconds. Thus, when R is 24,000 ohms, and of a smaller magnitude than R the relationship among the parameters of Expression 4b is mil In the event that the restrictions imposed upon R R and R do not apply, i.e., R j R or R Expression 4b becomes from which appropriate resistive magnitudes can be determined in the manner previously described.
Consequently as long as the circuit parameters are adjusted so that the contacts close before the expiration of the clamping interval, operation of the switch S associated with the source E results in the rapid application of a work voltage E to a load R unaccompanied by contact chatter. When the contacts r-l ultimately close the Work voltage is then applied through them until the coil is deenergized, at which time the diode D is prevented from interfering with the disengagement of the contacts r-l by being further back-biased by the voltage induced in the coil through the collapse of its magnetic field.
Other adaptations of the invention will occur to those skilled in the art.
What is claimed is:
1. Apparatus comprising a relay having a pair of normally open contacts, and
a control winding characterized by electrical inertia,
a source connectable to a load through said contacts,
means for energizing said control winding to close said contacts and establish a conduction path therethrough after a delay interval governed by the electrical inertia of said control winding,
a unidirectionally conductive diode connected in shunt with said contacts and poled in its direction of nonconduction with respect to said source, and
a path, whose impedance is greater than that of said load, interconnecting said diode with said winding, whereby energy applied to said winding by said enenerging means is able to establish a conduction path from said source to said load through said diode before the closure or" said contacts.
2. Apparatus comprising a relay with a control winding and a pair of normally open contacts,
means, including a first source and a resistor, for energizing said control winding,
a first path including said contacts for connecting a second source to a load by the closure of said contacts,
and a second path in shunt with the first and responsive to said energizing means for connecting said second source to said load.
3. Apparatus comprising a relay,
means, including a first source, for energizing said relay,
means controlled by the energized relay for connecting a second source to a load after a time delay T,
and means controlled by the energizing means for clamping said second source to said load for a preassigned interval commencing before the lapse of said time delay T and terminating thereafter.
4. A fast-acting relay controlled circuit comprising a relay having a pair of normally open contacts and a winding characterized by electrical inertia,
a source connectable to a load through said contacts,
means for energizing said winding to close said contacts and connect said source to the said load through the closed contacts after a time delay governed by said electrical inertia,
a unidirectionally conductive device connected in shunt directly with said contacts,
and a path extending from said winding to said device,
thereby to clamp said source to said load through said device for a preassigned interval commencing before the lapse of said time delay and terminating thereafter.
5. A fast-acting relay controlled circuit comprising a relay having a winding and a pair of contacts,
a source connectable to a load through said contacts,
a diode connected in shunt with said contacts, a resistor connecting said winding to said diode, and
means for energizing said winding.
6. Apparatus responsive to energizing means for connecting a source with a load, comprising first means energized from the energizing means substantially according to the relation K r for clamping the source to the load as long as K e 1 K where K is the initial signal level of said first means,
minal of said second resistor being connected to the second terminal of said pair of contacts,
diode having a cathode and an anode, said anode being connected to said second terminal of said pair of contacts and said cathode being connected to the first terminal of said pair of contacts,
third resistor having first and second terminals and characterized by a resistance R the second terminal of said third resistor being connected to said second terminal of said pair of contacts, and a source characterized by a voltage E interconnecting the first terminal of said third resistor with said first whereby said source is initially connected to said load terminal of said pair of contacts.
by said first means and subsequently connected to 10. Apparatus as defined in claim 9 wherein said consaid load by said second means. tacts operate after a time delay T from the energizing of 7. Apparatus responsive to energizing means capable said winding from said switchable source; and of supplying increasing and decreasing signals, for consaid winding, said first resistor, said second resistor, nectingasource witha load, comprising said third resistor, said switchable source, and said means controlled by an asymptotically increasing sigsecond named source are proportioned according to nal supplied by the energizing means for connecting the relation said second means changes during time t, K is the 10 level which said second means operates, and T is its operate time,
the source to the load after a preassigned interval, L R E and means controlled by a exponentially decreasing T ln signal supplied by said energizing means for connect- 1 2 3 ing said source to said load before said preassigned Apparatus as definedlin Claim 9 Whcrein Said 6011- i L tacts operate after a time delay T from the energizing of said Winding from said switchable source; and
said winding, said first resistor, said second resistor, said third resistor, said switchable source, and said second named source are proportioned according to 8. Apparatus responsive to energizing means for connecting a source to a load, comprising means energized by a steadily increasing signal supplied by the energizing means for connecting the source to the load after a delay time T, and the relation means energized by a steadily decreasingsignal supplied L( R2) (E1R2R3+E3R1R3) by said energizing means for connecting said source T R 13 1n E (R1+Rz) ris) to said load until the attainment of a time T after said delay time 12. In combination with a relay having a control wind- 9. A relay-controlled circuit comprising mg and a pan of normally Open contacts an operate circuit including the winding of the relay and means for energizing it,
a work circuit including the contacts of said relay and a source connectable to a load therethrough,
a clamping path conected in shunt with said contacts,
and
a control path extending from said operate circuit to said clamping path.
References Cited by the Examiner UNITED STATES PATENTS 2,062,274 11/36 Rees 307-64 2,932,774 4/60 Rice 317141 a relay having a winding with first and second terminals and a pair of contacts with first and second terminals, said winding being characterized by an inductance L,
a first resistor having first and second terminals and being characterized by a resistance R the first terminal of said first resistor being connected to the first terminal of said winding,
a switchable source characterized by a voltage E and interconnecting the second terminal of said first resistor with the second terminal of said winding, 5
a second resistor having first and second terminals and characterized by a resistance R the first terminal of said second resistor being connected to the junction of said first terminal of said first resistor with said first terminal of said winding and the second ter- SAMUEL BBRNSTEIN Pfimm? Examine"-
Claims (1)
1. APPARATUS COMPRISING A RELAY HAVING A PAIR OF NORMALLY OPEN CONTACTS, AND A CONTROL WINDING CHARACTERISTIZED BY ELECTRICAL INERTIA, A SOURCE CONNECTABLE TO A LOAD THROUGH SAID CONTACTS, MEANS FOR ENERGIZING SAID CONTROL WINDING TO CLOSE SAID CONTACTS AND ESTABLISH A CONDUCTION PATH THERETHROUGH AFTER A DELAY INTERVAL GOVERNED BY THE ELECTRICAL INERTIA OF SAID CONTROL WINDING, A UNDIRECTIONALLY CONDUCTIVE DIODE CONNECTED IN SHUNT WITH SAID CONTACTS AND POLED IN ITS DIRECTION OF NONCONDUCTIVE WITH RESPECT TO SAID SOURCE, AND A PATH, WHOSE IMPEDANCE IS GREATER THAN THAT OF SAID LOAD, INTERCONNECTING SAID DIODE WITH SAID WINDING, WHEREBY ENERGY APPLIED TO SAID WINDING BY SAID ENENERGIZING MEANS IS ABLE TO ESTABLISH A CONDUCTION PATH FROM SAID SOURCE TO SAID LOAD THROUGH SAID DIODE BEFORE THE CLOSURE OF SAID CONTACTS.
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US244992A US3204151A (en) | 1962-12-17 | 1962-12-17 | Fast-acting relay controlled circuit |
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US244992A US3204151A (en) | 1962-12-17 | 1962-12-17 | Fast-acting relay controlled circuit |
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US3204151A true US3204151A (en) | 1965-08-31 |
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US244992A Expired - Lifetime US3204151A (en) | 1962-12-17 | 1962-12-17 | Fast-acting relay controlled circuit |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4249150A (en) * | 1979-04-30 | 1981-02-03 | Motorola, Inc. | High power RF relay switch |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2062274A (en) * | 1935-07-22 | 1936-11-24 | Gen Railway Signal Co | Power supply system |
US2932774A (en) * | 1956-11-05 | 1960-04-12 | Gen Motors Corp | Electric circuit arrangement |
-
1962
- 1962-12-17 US US244992A patent/US3204151A/en not_active Expired - Lifetime
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2062274A (en) * | 1935-07-22 | 1936-11-24 | Gen Railway Signal Co | Power supply system |
US2932774A (en) * | 1956-11-05 | 1960-04-12 | Gen Motors Corp | Electric circuit arrangement |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4249150A (en) * | 1979-04-30 | 1981-02-03 | Motorola, Inc. | High power RF relay switch |
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