US1816913A - Protective circuit for vacuum tubes - Google Patents
Protective circuit for vacuum tubes Download PDFInfo
- Publication number
- US1816913A US1816913A US280666A US28066628A US1816913A US 1816913 A US1816913 A US 1816913A US 280666 A US280666 A US 280666A US 28066628 A US28066628 A US 28066628A US 1816913 A US1816913 A US 1816913A
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- Prior art keywords
- circuit
- relay
- current
- source
- anode
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/52—Circuit arrangements for protecting such amplifiers
- H03F1/54—Circuit arrangements for protecting such amplifiers with tubes only
- H03F1/548—Protection of anode or grid circuit against overload
Definitions
- This invention relates to rotective devices and more particularly to t ose used in systems where overload surges of energy are to be uarded against.
- ne 'of the objects of the invention is to rotect the electrodes of a space discharge evice when current in the anode circuit eX- Ceeds a predetermined value.
- Another object of the invention is to in- ⁇ m dicate immediately to an observer without the necessity of testing each individual tube, which of agroup of parallel tubes is drawing an excess of plate current.
- the invention is particularly applicable to high Apower radio installations which require the use of tubes whose power supply circuits may be in parallel, operating with direct current on the filament.
- a differential relay in the filament Aleads of each individual space discharge device which operates to disconnect the source of plate potential when the current exceeds a predetermined value but which 25 is unresponsive to any change in the filament current.
- a differential relay may be used comprising two windings so arranged that one winding is included in one yfilament lead and the second winding is included in the second filament lead.
- the filament current passes through the two windingsin series but the clarity of the windings is such that the resu ytant magnetic effect due to the filament current is Zero or at least substantially constant and is insufficient to attract they relay armature.
- the plate circuit kis connected in such a manner that the plate current traverses the windings in parallel. The magnetic effect of the current under $0 these conditions is additive and when of sufficient value will attract the relay armature.
- a predetermined value is set beyond which an increase of plate current operates the ref lay which in turn controls means for discon- ⁇ li necting the source of plate potential from the plate circuit.
- a relay is associated with each parallel tube and can also be arranged to operate a signal to indicate which of the tubes is recelvin g the overload.
- the pair of space discharge vacuum tubes 1V andy 2 are shown with their grids 3 and 4l connected in pushpull relation to a source of waves 5 which waves in this instance, are to be amplified,
- the input circuit of the amplifier tube 1 may be traced from the grid 3 of the tube 1 through the coil 6, the condenser 7 tor ground and from ground at 52 through the parallel paths comprising leads 53 and 55 and 62 and 63, through windings 19 and 20 of relay 61, and leads 17 and18 to the filament 10.
- Thecorresponding grid circuit for vthe vacuum tube 2 may be traced from the grid 1 to the coil 9, the condenser 8 to ground and from there through the parallel paths comprising ⁇ leads 53 and 54 and 62 and 64, through windings 14 and 15 of relay 60, leads 12 and 13 to the filament 11.
- the source 5 is connected across the circuit branch 6, 7, 8 and 9.
- the filaments of the tubes are connected in parallel to the source of direct heating current 16.
- the filament circuit Afor the tube 1 may be traced from the ground 52, terminal 57, through the lead 53, lead 55, the relay winding 20, through lead 1'T,ila1nent 10, lead 18, relay winding 19, back to the source 16 at terminal 58.
- the corresponding circuit for tube 2 also may be traced from the ground 52, terminal 5T, through l-eads 53 and 54, relay winding 15, lead 13. filament 11, lead 1Q, relay winding 14; and back to the source 16 at terminal 58.
- the source 16 may be of any suitable type
- the grids ot the tubes are supplied with the required biasingI volta Ue by adjustable resistances 22 and 23 which may be connected across a suitable source 21.
- - Thc circuit through the resistance may be traced from ground through source 21, resistances 22 and 23 in parallel to ground.
- Filters 2l are provided to eliminate variations which may be present due to fluctuations 1'n the source of grid potential 21.
- the alternating current output circuits of the tubes are arranged in push-pull relation and are shown connected to terminals 71 and 72. ilrnother stage of amplification or a utilization circuit may be connected to these terminals.
- the direct current path of the plate circuit 'for tube 1 may be traced from the plate or anode Q5, through coil 2T, rectifier 30 to ground and back to the filament 10, through the pair ot parallel paths one of which comprises leads 53, 55, relay winding 2O and lead 17 while the other comprises leads 62, 63, relay winding 19 and lead 18.
- the correspondi g plate circuit for tube 2 may be traced from the anode 26 through the coil 2S, rcctiiier 30 to ground and back to the filament 11 through a pair of parallel pa hs one et which compri. leads 53 and 54, relay winding 15 and leal. 13 while the other comprises leads 62 and 64;, relay winding 14 and lead 12.
- the relays and 61 have their windings diiierentially arranged so that magnetic fields which are produced l'iy the Vfilament current oppose each other so as to make the resultantiporce upon their respective armatures substantially zero.
- the iilament current through the windin 14 and 15 in the case of relay 60. and 19 and Q0 in the case ot relay 61 flows in a series circuit and the windings are so pol-ed as to produce the zero resultant magnetic force as mentioned above.
- the relay armatures 44 and 65 may be arranged so that they do not operate until a certain predetermined value of plate current is flowing through the relay coil. Thus, for normal operation the value of plate current not su'liicient to attract the armatures but it an overload occurs in either of the tubes the relays operate to interrupt the flow of plate current.
- the high voltage re 'ier 3l is connected to the high side ot a high voltage transformer 66, the low side of which is connected to a source 32 ot alternating current.
- a protective circuit breaker in the primary or low voltage side of the transformer. uch a circuit breaker, provided with a handle T3 for manual operation, is shcuvn in iis open position at l'll. The circuit breaker is maintained closed by the current through its solenoid from .source Sal., through contacts di) and lil of relays 35 and 35 during normal operation ot the system.
- Relay 35 is maintained in its closed position by current ⁇ flowing in the circuit which may be traced from ground 4.5, through switch 6T in closed position, through the armature All, through the contact elil, through lead GS, closed contacts 1T ol relay 35, through the leads L16 and 4:8, the energizing winding of relay 35 bach to grounded supply source 4l).
- llelay 35 duringl normal operation maintained in its closed position by current flowing through the circuit which may be traced from ground L15, through switch 6T and in its closed position through the armature 65.
- a similar circuit for the other relay may be traced from the source 40 through the winding of the relay 35, contact 42 and its associated armature, lead 70, contact 43', armature 65 and through the switch 67 to ground at 45.
- IVhen relay 35 or 35 or both are reset contact is again made at 49 or 49 or both as the case may be, thus completing the circuit through the coil of the circuit breaker 33, placing it in condition for closing by the operator.
- reset button 37 when operated causes current to flow through relay 38 only momentarily and after the circuit is established through relay 35 or 35 by the armatures and associated contacts 42 and 42 of relay 38, this reset circuit is broken and the holding circuit maintained through contacts 47 and 47.
- a space discharge device having an anode and an electron emitting cathode, a heating circuit therefor, an anode circuit comprising a portion of said heating circuit and anode protecting means in said heating circuit comprising a differential relay, insensitive to changes of heating current, but operating to interrupt the flow of anode current upon its reaching a predetermined value.
- a space discharge device having ananode, an electron emitting cathode, having a heating circuit therefor, an anode circuit comprising a port-ion of said heating circuit and anode protecting means in said heating circuit comprising a differential relay having a pair of windings, said windings being in series in said heating circuit but in parallel in said anode circuit, said relay being sensitive only when current is flowing through said windings in parallel.
- a space discharge device having an anode, and an electron emitting cathode, a heating circuit therefor, an anode circuit comprising a portion of said heating circuit and anode protecting means in said heating circuit comprising a ldifferential relay having a pair of windings,
- said windings being in series in said heating circuit but in parallel in said anode circuit, said relay being insensitive to changes of current in said heating circuit, but operating to interrupt the current in said anode circuit upon its reaching a predetermined value.
- a source of potential for impressing a high voltage upon said anodes and lneans comprising a plurality of relays associated with respective individual cathode circuits for disconnecting said source of high potential when the current in the anode circuit of any of said tubes exceeds a predetermined value.
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Particle Accelerators (AREA)
- Testing Of Short-Circuits, Discontinuities, Leakage, Or Incorrect Line Connections (AREA)
- Emergency Protection Circuit Devices (AREA)
Description
Aug. 4, 1931.
J. c. scHELLENG 1,816,913
PROTECTIVE CIRCUIT POBNACUUM TUBES Filed May 26, 1928 42 fes 12' (L ../oH/v C SCHELLENG BYj" TOPNEY Patented ug. 4, 1931 UNITED STATES JOHN C. SCHELLENG, OF MILLBURN, JERSEY, ASSIGNOR TO BELL TELEPHONE LABORATORIES, INCORPORATED, F NEW YORK, N. Y., A CORPORATION OF YORK PATENT OFFICE a PROTECTIVE CIRCUIT Fon VACUUM TUBEs Application med may r26, 192s. serial No. 260,666.
This invention relates to rotective devices and more particularly to t ose used in systems where overload surges of energy are to be uarded against.
ne 'of the objects of the invention is to rotect the electrodes of a space discharge evice when current in the anode circuit eX- Ceeds a predetermined value. y n
Another object of the invention is to in-` m dicate immediately to an observer without the necessity of testing each individual tube, which of agroup of parallel tubes is drawing an excess of plate current.
y The invention is particularly applicable to high Apower radio installations which require the use of tubes whose power supply circuits may be in parallel, operating with direct current on the filament.
One of the `features of the linvention resides in yplacing a differential relay in the filament Aleads of each individual space discharge device which operates to disconnect the source of plate potential when the current exceeds a predetermined value but which 25 is unresponsive to any change in the filament current. A differential relay may be used comprising two windings so arranged that one winding is included in one yfilament lead and the second winding is included in the second filament lead. The filament current passes through the two windingsin series but the clarity of the windings is such that the resu ytant magnetic effect due to the filament current is Zero or at least substantially constant and is insufficient to attract they relay armature. However, the plate circuit kis connected in such a manner that the plate current traverses the windings in parallel. The magnetic effect of the current under $0 these conditions is additive and when of sufficient value will attract the relay armature.
A predetermined value is set beyond which an increase of plate current operates the ref lay which in turn controls means for discon- `li necting the source of plate potential from the plate circuit.
A relay is associated with each parallel tube and can also be arranged to operate a signal to indicate which of the tubes is recelvin g the overload.
Some of theadvantages of the system re* sult from the positioning of the relays in the low voltage leads thus permitting the use of relays having light windings, which relays are comparatively cheap. This position is also desirable in high powered systems wherein tubes arranged in parallel have their anodes physically strapped "together since each tube may have an individual indicator.
Other objects and features of the invention will be apparent on reading the follow-l ing description in connection with the attached drawing which illustrates schemati-` cally the application of the invention to a pair of space discharge power amplifiers connected in push-pull relation forthe purpose of amplifying the waves from a source which may generate either audio or radio frequency waves. While it has been necessary to show in considerable detail various arrangements for disconnecting the plate current .and for' indicating in which device the trouble has occurred, is obvious that many changes ymay be made in the circuit connections and that the invention should not be limited to'the specific arrangement of the drawing.
' Referring to the drawing, the pair of space discharge vacuum tubes 1V andy 2 are shown with their grids 3 and 4l connected in pushpull relation to a source of waves 5 which waves in this instance, are to be amplified,
although the invention is not dependent upon any particular type of inputor output connection. The input circuit of the amplifier tube 1 may be traced from the grid 3 of the tube 1 through the coil 6, the condenser 7 tor ground and from ground at 52 through the parallel paths comprising leads 53 and 55 and 62 and 63, through windings 19 and 20 of relay 61, and leads 17 and18 to the filament 10. Thecorresponding grid circuit for vthe vacuum tube 2 may be traced from the grid 1 to the coil 9, the condenser 8 to ground and from there through the parallel paths comprising` leads 53 and 54 and 62 and 64, through windings 14 and 15 of relay 60, leads 12 and 13 to the filament 11. The source 5 is connected across the circuit branch 6, 7, 8 and 9.
The filaments of the tubes are connected in parallel to the source of direct heating current 16. The filament circuit Afor the tube 1 may be traced from the ground 52, terminal 57, through the lead 53, lead 55, the relay winding 20, through lead 1'T,ila1nent 10, lead 18, relay winding 19, back to the source 16 at terminal 58. The corresponding circuit for tube 2 also may be traced from the ground 52, terminal 5T, through l- eads 53 and 54, relay winding 15, lead 13. filament 11, lead 1Q, relay winding 14; and back to the source 16 at terminal 58. The source 16 may be of any suitable type, The grids ot the tubes are supplied with the required biasingI volta Ue by adjustable resistances 22 and 23 which may be connected across a suitable source 21.- Thc circuit through the resistance may be traced from ground through source 21, resistances 22 and 23 in parallel to ground. Filters 2l are provided to eliminate variations which may be present due to fluctuations 1'n the source of grid potential 21. The alternating current output circuits of the tubes are arranged in push-pull relation and are shown connected to terminals 71 and 72. ilrnother stage of amplification or a utilization circuit may be connected to these terminals.
Energy is supplied to the plate circuits of the tubes 1 and in parallel. The direct current path of the plate circuit 'for tube 1 may be traced from the plate or anode Q5, through coil 2T, rectifier 30 to ground and back to the filament 10, through the pair ot parallel paths one of which comprises leads 53, 55, relay winding 2O and lead 17 while the other comprises leads 62, 63, relay winding 19 and lead 18. The correspondi g plate circuit for tube 2 may be traced from the anode 26 through the coil 2S, rcctiiier 30 to ground and back to the filament 11 through a pair of parallel pa hs one et which compri. leads 53 and 54, relay winding 15 and leal. 13 while the other comprises leads 62 and 64;, relay winding 14 and lead 12.
The relays and 61 have their windings diiierentially arranged so that magnetic fields which are produced l'iy the Vfilament current oppose each other so as to make the resultantiporce upon their respective armatures substantially zero. In other words, the iilament current through the windin 14 and 15 in the case of relay 60. and 19 and Q0 in the case ot relay 61 flows in a series circuit and the windings are so pol-ed as to produce the zero resultant magnetic force as mentioned above.
However, for current flowing in the plate circuit the windings 14 and 15 -for relay 6() and windings 19 and 20 for relay 61 are in parallel and the flow ot' current in the respective pairs of windings is in the same direction.
he windings are arranged in such av manner that current 'flowing therethrough in the same direction produces magnetic fields which are additive in effect. The relay armatures 44 and 65 may be arranged so that they do not operate until a certain predetermined value of plate current is flowing through the relay coil. Thus, for normal operation the value of plate current not su'liicient to attract the armatures but it an overload occurs in either of the tubes the relays operate to interrupt the flow of plate current.
The type ot circuit in which such a protective device could be used to great advantage one in which the values or plate potential are very high, as tor instance, in the order et 1,600 to ninth) volts, or eren higher. One arrangement by which the high voltage plate supply is interrupted is shown in the drawing.
The high voltage re 'ier 3l) is connected to the high side ot a high voltage transformer 66, the low side of which is connected to a source 32 ot alternating current. gWith such high potentials in the plate circuits it is desirable to place a protective circuit breaker in the primary or low voltage side of the transformer. uch a circuit breaker, provided with a handle T3 for manual operation, is shcuvn in iis open position at l'll. The circuit breaker is maintained closed by the current through its solenoid from .source Sal., through contacts di) and lil of relays 35 and 35 during normal operation ot the system.
Relay 35 is maintained in its closed position by current `flowing in the circuit which may be traced from ground 4.5, through switch 6T in closed position, through the armature All, through the contact elil, through lead GS, closed contacts 1T ol relay 35, through the leads L16 and 4:8, the energizing winding of relay 35 bach to grounded supply source 4l). llelay 35 duringl normal operation maintained in its closed position by current flowing through the circuit which may be traced from ground L15, through switch 6T and in its closed position through the armature 65. contact 4P, through lead 70, contacts 47', ds Li6' and 4S', through the energizing ding ot the relay 1:35 to grounded supply ell). By thus energizing the windings ol. the relays 3:15 and S5 the circuits through contacts 47 and 4T', and 49 and L10 are maintained closed. During the normal operation of the circuit the contacts 50 and 55) of the relays and 35 are open.
rlhc operation of the circuit when an overload occurs in thc plate circuit ot either of the tubes will be readily understood from a description of the operation of either of' relays and 35', since the miei-ation of either will open contacts llf.) or 10' thereby opening the holding circuit of circuit breaker 323. For instance, when the current in the plate circuit ot tube 2 reaches a certain predetermined value relay 60 operates attracting armature lll, thus opening thc circuit by means of which relay So energized. The plunger of relay 35 falls to the position shown in the drawing, causing contacts 50 to close an obvious circuit for energizing lamp 51 which ment current is always zero.
indicates that tube 2 is overloaded. When relay 35 is deenergized, contacts 49 are opened, thereby opening the holding circuit for circuit breaker 33. Source 32 is disconnected and the supply of plate current to tubes 1 and 2 ceases. As soon as plate current ceases to How armature 44 of relay 60 falls back to its normal operating position, making contact with contact 43. A similar result would follow if an overload should occur in tube l, but in this instance relay 35 would operate causing the lamp 5l to light.
In order to reset relays 35 and 35 it is necessary to reestablish the circuit through the winding of the one which has operated. This is accomplished by means of a reset button 37. 0n pressing the button a circuit is established from the grounded source 36 through the winding of relay 38 to ground. When the winding of relay 38 is energized its armatures are attracted to close contacts 42 and 42. The circuit through the coil of the relay which has been opened (in this case relay 35) is reestablished which circuit may be traced from the source 4() through the Winding of relay, contact 42 and its associated armature, lead 68,' contact 43, armature 44, through the closed switch G7 to ground at 45. A similar circuit for the other relay may be traced from the source 40 through the winding of the relay 35, contact 42 and its associated armature, lead 70, contact 43', armature 65 and through the switch 67 to ground at 45. IVhen relay 35 or 35 or both are reset contact is again made at 49 or 49 or both as the case may be, thus completing the circuit through the coil of the circuit breaker 33, placing it in condition for closing by the operator.
It is to be understood that reset button 37 when operated causes current to flow through relay 38 only momentarily and after the circuit is established through relay 35 or 35 by the armatures and associated contacts 42 and 42 of relay 38, this reset circuit is broken and the holding circuit maintained through contacts 47 and 47.
With the differential relays and 61 in the circuits it is apparent that the filament emission of the tubes may be varied over a very wide range without causing the anode protecting circuits to operate since the resultant pull on the relay armature due to ila- It is also obvious that these relays may be made much smaller and cheaper than those Which would be necessary if individual relays were used in the high potential part of the plate circuit.
Further, when a large number of tubes are used in parallel the indication which is given by the invention also obviates the necessity of guessing at random which tube has received the overload current.
Other various forms will at once suggest themselves to those skilled in the art Within the spirit of the invention, which is to be `limited thereforeV only'by the-scope of the said leads comprising a diii'erential relayl operable when said anode circuit is overloaded.
3. An electron emitting cathode and a heating circuit therefor, an anode circuit comprising a portion of said heating circuit and indicating means in said heating circuit comprising a relay insensitive to changes in heating current, but operating to give an indication upon change of current in the anode circuit.
4. In a space discharge system, a space discharge device having an anode and an electron emitting cathode, a heating circuit therefor, an anode circuit comprising a portion of said heating circuit and anode protecting means in said heating circuit comprising a differential relay, insensitive to changes of heating current, but operating to interrupt the flow of anode current upon its reaching a predetermined value.
5. In a space discharge system, a space discharge device having ananode, an electron emitting cathode, having a heating circuit therefor, an anode circuit comprising a port-ion of said heating circuit and anode protecting means in said heating circuit comprising a differential relay having a pair of windings, said windings being in series in said heating circuit but in parallel in said anode circuit, said relay being sensitive only when current is flowing through said windings in parallel.
6. In a space discharge system, a space discharge device having an anode, and an electron emitting cathode, a heating circuit therefor, an anode circuit comprising a portion of said heating circuit and anode protecting means in said heating circuit comprising a ldifferential relay having a pair of windings,
said windings being in series in said heating circuit but in parallel in said anode circuit, said relay being insensitive to changes of current in said heating circuit, but operating to interrupt the current in said anode circuit upon its reaching a predetermined value.-
7. In combination a plurality of space discharge devices having anode and individual cathode circuits, a source of potential for no y impressing a high Voltage upon said anodes and mea-ns, in each individual cathode circuit, controlled hy an overload in any of the space discharge devices for disconnecting said 5 source.
8. In combination a plurality of space discharge devices connected in parallel having anode and individual cathode circuits, a source of potential for impressing a high voltage upon said anodes and lneans comprising a plurality of relays associated with respective individual cathode circuits for disconnecting said source of high potential when the current in the anode circuit of any of said tubes exceeds a predetermined value.
In Witness whereof.J I hereunto subscribe my naine this th day of May, 1928.
JOHN C. SCHELLENG.
kil
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US280666A US1816913A (en) | 1928-05-26 | 1928-05-26 | Protective circuit for vacuum tubes |
GB4935/29A GB312336A (en) | 1928-05-26 | 1929-02-14 | Improvement in protective circuit for vacuum tubes |
FR671564D FR671564A (en) | 1928-05-26 | 1929-03-16 | Improvements to protective devices for electronic discharge tubes |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US280666A US1816913A (en) | 1928-05-26 | 1928-05-26 | Protective circuit for vacuum tubes |
Publications (1)
Publication Number | Publication Date |
---|---|
US1816913A true US1816913A (en) | 1931-08-04 |
Family
ID=23074068
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US280666A Expired - Lifetime US1816913A (en) | 1928-05-26 | 1928-05-26 | Protective circuit for vacuum tubes |
Country Status (3)
Country | Link |
---|---|
US (1) | US1816913A (en) |
FR (1) | FR671564A (en) |
GB (1) | GB312336A (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2656487A (en) * | 1950-06-29 | 1953-10-20 | Bell Telephone Labor Inc | Voltage supply control circuit |
US2733338A (en) * | 1956-01-31 | Electronic protective circuits | ||
US2742595A (en) * | 1952-12-08 | 1956-04-17 | Burroughs Corp | Control circuits |
-
1928
- 1928-05-26 US US280666A patent/US1816913A/en not_active Expired - Lifetime
-
1929
- 1929-02-14 GB GB4935/29A patent/GB312336A/en not_active Expired
- 1929-03-16 FR FR671564D patent/FR671564A/en not_active Expired
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2733338A (en) * | 1956-01-31 | Electronic protective circuits | ||
US2656487A (en) * | 1950-06-29 | 1953-10-20 | Bell Telephone Labor Inc | Voltage supply control circuit |
US2742595A (en) * | 1952-12-08 | 1956-04-17 | Burroughs Corp | Control circuits |
Also Published As
Publication number | Publication date |
---|---|
FR671564A (en) | 1929-12-14 |
GB312336A (en) | 1930-05-14 |
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