US2626324A

US2626324A - Electronic alternating current amplifier

Info

Publication number: US2626324A
Application number: US783265A
Authority: US
Inventors: David L Markusen
Original assignee: Honeywell Inc
Current assignee: Honeywell Inc
Priority date: 1947-10-31
Filing date: 1947-10-31
Publication date: 1953-01-20
Anticipated expiration: 1970-01-20

Description

Jan. 20, 1953 Q L, MARKUSEN 2,626,324

ELECTRONIC ALTERNATING CURRENT AMPLIFIER Filed OC. 5l, 1947 @e Gttorncg Patented Jan. 20, 1953 ELECTRONIC ALTERNATING CURRENT AMPLIFIER David L. Markusen, Minneapolis, Minn., assignor to Minneapolis-Honeywell Regulator Company, Minneapolis, Minn., a corporation of Delaware Application October 31, 1947, Serial No. 783,265

8 Claims.

The present invention relates to electronic amplifiers in which the plate potentials of the various stages have been placed closer to ground than has hitherto been customary.

Another object of the invention is to reduce the signal potential necessary to cause operation of the amplifier.

Another object of the invention is to advance the ring of the electron 4tube in one of the stages.

I accomplish the above objects by placing the plate supply of one of the stages in the cathode circuit of the succeeding stage. I also place a portion of the filament voltage in theA cathode circuit of one stage in such a manner as to drive the cathode negative with respect to the grid. A portion of the filament voltage is also placed between the cathode and screen grid of another of the stages such that the screen is positive with respect to the cathode and tend-s to advance the firing of that stage.

For a further understanding, reference may be made to the drawing which shows a circuit embodying the principles of the invention.

in the drawings, a bridge I!) feeds a signal to a first amplifying stage 2) through a grid current limiting resistor Il. Stage 28 is electrically coupled to a second amplifying stage 35. This in turn is coupled to the thyratron output stage 40 which operates a load circuit designated as 50.

If desired, all voltage supply sources may be taken from a single transformer having a primary dil and. secondaries 6|, B2, 53 and 65. An advantage of having all voltage supply sources from one transformer is to more easily obtain the desired phase relation between the various voltage supplies. Secondary 55 is a heater lament sup-ply voltage transformer having a center tap SB to ground. The bridge l5 has a power source which may be, and in this case is shown to be, the secondary winding 3| of the transformer above described. The bridge also has two resistors l2 and i3 which are joined together at opposite ends of transformer secondary 6|. Two adjustable contacts Id and |5 are operatively connected to resistors I2 and i3 respectively. Movement of contact 4 or |5 with respect to the other contact along resistor |2 or |3 determines the phase and magnitude of the signal sent to stage 25.

Amplifying stage Eil has a tube 2| containing an anode 22, control electrode or grid 23, cathode 24, and a heater'lament 25. A cathode bias resistor 25 has also been provided. The plate supply voltage for stage 28 is furnished by tran-s.-

former secondary 62 mentioned above. The filament 25 is energized by transformer secondary 65 through leads 10, I, 12, filament 25, leads- 13, 'I4 and 'I5 back to transformer secondary 65.

The cathode to grid circuit of stage 20 is from cathode 24, resistor 26, leads 14, '|5, the left half of transformer secondary 65, center tap 66, lead '|6, ground, lead bridge |0, lead 88, resistor and lead 8|, to grid23.

The plate to cathode circuit of stage 20 is from the left hand terminal of transformer secondary 62, leads 82 and 83, resistor 36, lead 84, anode 22, cathode 24, resistor 26, leads `|4 and '|5, the left half of transformer secondary winding 65 to center tap 66, leads 'Hik and 85, to the right hand terminal of transformer secondary 62.

Stage 30 has an amplifier tube 3| containing an` anode 32, grid or control electrode 33, cathode 34, and heater filament 35. A grid biasing resistor 36. is also electrically connected between grid 33 and cathode 34. The output of stage 20 is impressed upon grid- 33 of stage 30 through

leads

84 and 86. Heater filament 35 is energized by a circuit extending from transformer secondary windingl 65 through leads |0, 'Il and 81, filament 35, leads 90 and |5 back to transformer secondary 65. The plate supply for stage 30 is obtained from transformer secondary winding 63 which is sh-own in this case to be a secondary winding of the transformer having a primary which supplies all the voltage sources needed in this circuit.

The anode to cathode circuit of stage 30 is from the left hand terminal of transformer secondaryk 63, lead 9|, anode 32, cathode 34, leads 92 and 82, transformer secondary winding 62, resistor 3'!v having condenser 38 in parallel therewith, to the right hand terminal of transformer secondary winding 63.

Stage 40 has a tube 4| shown as a gas lled tube and having an anode 42, control electrode 43, cathode 44, and heater filament 45. A second control electrode or screen grid 46 is also shown in this tube. The output of stage 30 is fed from the anode 32 of stage 30, lead 9|, transformer second-ary winding 63, grid current limiting resistor 41 andlead 93 to control grid 43 of stage 40. Heater lament 45 is energized from transformer secondary through leads 'l0 and 94, filament heater 45 and lead 95 back to transformer secondary 65. The plate potential supply for stage 40 is fed from across the line.

The anode to cathode circuit in stage 40 is from lead 96, energizing coil 5| of relay 5 0, having condenser 52 in parallel therewith, lead 91.

anode 42, cathode 44, lead 98, ground, and lea-d 99.

The load circuit 53 is shown in this circuit to be a relay having an energizing coil 5|, a condenser 52 in parallel with relay energizing coil 5| and relay contacts 53 and 54 which are biased to open position and are moved to closed position upon energization of coil 5|.V

Though it is understood that the disclosure in this invention is not coniined to the use oiV the following values of components in this circuit it has been found that the following set of figures will cause the circuit to operate satisfactorily. In the bridge I Transformer secondary 6I volts-- 10-20 Resistor l2 ohms 1,000 Resistor I3 do 1,000

As to the rest of the circuit:

Resistor megohms 0.4 Resistor 26 ohms 13,000 Resistor 36 megohms 1.0 Resistor 31 do 0.05 Resistor 41 g do 0.1 Condenser 38 microfarads-- 0.6

In stage 40 the tube 4| used is a GL546 thyratron tube. Tubes 2| and 3| in stages 20 and 30 are two halves of a 12AN7 duotriode. The voltage across transformer secondary 62 is 30 volts and the voltage across transformer secondary 63 is 60 volts.

Operation As can be seen from the drawing, the plate supply of all three amplifying

stages

20, 30 and 40 are positive simultaneously. During the same half of the cycle when the plates 22, 32 and 42 are positive the right hand terminal of filament transformer secondary 65 is positive with respect to its left hand terminal. As a result of this polarity of the filament transformer secondary the screen grid 45 of tube 4| is positive during the conducting half cycle of tube 4|. This results in advancing the firing point of this tube during that portion of the cycle when the plate is positive with respect to the cathode.

The left hand portion of the filament transformer secondary winding 55 is also connected between the grid and cathode of the stage 20. The circuit has already been described and it can easily be seen that on the half cycle when the plate is positive with respect to the cathode that portion of the filament secondary in the grid to cathode circuit drives the cathode 24 more negative with respect to the grid 23. As a result, the operating point of the bridge l0 necessary to open Aor close the relay 50 has been reduced a substantial amount. With the constants named above usedA in this circuit, the operating signal given off by the bridge which would be necessary to lopen and close the contacts 53 and 54 of relay 50 if this portion of the filament transformer secondary were not in the grid to cathode circuit 0f stage 20 would be: 2.8 volts to energize the relay and close the .contacts 53 and 54, and 2.50 volts necessary to deenergize the relay coil 5| and open the relay contacts 53 and 54. With the left hand portion of the filament transformer secondary E5 in the grid to cathode circuit of stage 20, the necessary operating point of the bridge has been reduced to: 0.010 volt to energize coil 5| of relay 5U and close contacts 53 and 54, and 0.004 volt lto deenergize relay coil 5| and open contacts 53 and`54.

As has been described above the plate supply of stage 20 which is transformer secondary 62, is in the plate to cathode circuit of stage 30. As can be seen by the drawing the polarity of the two transformer secondaries B2 and 63 are such that the voltage across transformer secondary 62 will subtract from that voltage across transformer secondary 63.

In this way it has been possible to elfectively ground the plate supply for stage 20 by placing the plate supply between the cathode 34 of stage 30, and ground. This prevents any possibility there might be of the plate supply `62 floating as it would if it were placed between plate 22 in stage 20 and grid 33 in stage 30.

The general operation of the circuit is as follows: When a signal of proper polarity is sent from bridge l0 to grid 23 of stage 20 tube 2| will be made to conduct. Upon iiring by tube 2|, a voltage will be impressed across resistor 36 in stage 30 and drive the grid 33 suiciently negative with respect to cathode 34 to prevent the tube 3| from conducting. When tube 3| does not conduct there will be no voltage impressed across resistor 31 to drive grid 43 suiiiciently negative with respect to cathode 44 of stage 40 as to prevent tube 4I from firing. Thus tube 4| will iire, energizing relay coil 5| which will close contacts 53 and 54.

Upon zero signal or a signal of wrong polarity given from the bridge I0 the grid 23 will be driven negative with respect to cathode 24 of stage 20 and prevent tube 2| from conducting. When tube 2| dries not conduct, there will be no voltage across resistor 36 to drive grid 33 negative with respect to cathode 34 in stage 30. As a result tube 3| will conduct and place a potential across resistor 31. Resistor 3'! is tied between grid 43 and cathode 44 of stage 40 and the polarity placed upon resistor 31 by tube 3| will be such as to drive grid 43 negative with respect to cathode 44. As a result tube 4| will not fire and relay coil 5| will be deenergized permitting relay contacts 53 and 54 to open.

It will thus be seen that I have provided an ampliiier in which a small signal of proper polarity will be suiiicient to cause operation of the amplifier such that the relay will be energized.

Although a specific example of the invention has been shown and described, it will be understood of course, that it is but illustrative and that various modifications may be made therein without departing from the scope and spirit of the invention as described in the appended claims.

I claim as my invention:

1. In combination: a plurality of electron discharge devices, including a first and a second of said devices each having an anode, a control electrode, a cathode and a separate cathode heater for heating said cathode; means electrically interconnecting the first and second of said devices, said means including a connection between each of said cathodes and a point of reference potential and a connection between the anode of said first device and the cathode of said second device; separate means connecting an alternating voltage source between the cathode of said second device and said reference point and the anode of said second device and said reference point such that the anodes of said devices are positive simultaneously with respect to the cathodes; a single alternating cathode heater voltage supply source electrically connected in energizing rel-ation to al1 of said cathode heaters;

means `electrically connecting afirs't portion of applying the alternating voltage between the cathode of said second device and s-aid reference point and in such 'a phase relation with said means .as to increase the maximum .potential difference between the anode and cathode of 'said rst stage; means electrically connecting said rst portion of said cathode' heater voltage source between the cathode and control electrode .of the first of said devices in such a phase relation with respect to the potential applied between the cathode of said -second device and said reference point that the anode and the control electrode of the iirst `device have the same polarity with respect to the cathode of the first device; and means electrically connecting a portion of said cathode heater voltage source between vthe -cathode and control electrode of the second of said devices in such a phase'relation with respect to the lpotential applied between the anode and cathode of said second device that the anode and control electrode of the second device vhavethe `same polarity with lrespect tothe cathode of the seconddevice.

f2. In combination: a plurality of electron discharge devices including a first device having an anode, a cathode, and a separate heater for heating said cathode, and a second device having an anode, a control electrode, a cathode, anda separate cathode heater for heating said cathode; vmeans electrically linterconnecting said vrst and second devices, said means including a connection between each of said cathodes and a point vof reference potential; means connecting an alternating voltage source between said anode and said cathode of said rst device, said means including an alternating voltage supply source f connected between said reference point and the cathode of said second discharge device; means connecting an alternating voltage between the anode and the cathode of said second device in such a phase relation with respect to the potential applied between the cathode of said second device and said reference point that the anode of said rst and said second devices are positive simultaneously; a single alternating cathode heater voltage supply source electrically connected in energizing relation to both of said cathode heaters; means electrically connecting a Yportion of said cathode heater voltage source between said point of reference potential and the cathode of the rst of said devices in such a z phase relation with respect to the potential applied between the `cathode of said second device and said reference point as to increase the maximum potential difference between the anode and the cathode of said rst stage; and means electrically connecting a portion of vsaid cathode heater voltage source between the cathode and the control electrode of the second of said devices in such a phase relation with respect to the potential applied between'the anode of said second device and said lreference point that the anode and control electrode have the same polarity with respect to the cathode thereof.

3. In combination: a plurality of electron discharge devices, including a first and a second of said devices each having an anode, a cathode and a separate cathode heater for heating said cathode, and a third of said devices having an anode, a control electrode, a cathode, and a separate cathode heater for heating said cathode;

means `electrically interconnecting said first, said second andsaid third of said devices, said means including .a lconnection between each of said cathodes and a point of reference potential; means connecting a potential source between the anode and the cathode of said rst device comprising a rst alternating voltage supply source electrically connected between the cathode of said second device and said point of reference potential; means connecting an alternatingvoltage source between the anode and the cathode of said third device in such a phase relation with respect to the potential applied between the cathode of said second device and said reference point that the anodes of said first and said third devices are positive simultaneously; a single alternating cathode heater voltage supply source electrically connected to all of said cathode heaters; means electrically connecting a portion of said heater voltage source between the point of reference potential and the cathode oi the iirst of said devices in such a phase relation with respect to the potential applied between the cathode of vsaid second device and said reference point as to increase the maximum potential difference between the anode and the cathode of s-aid rst stage; and means electrically connecting a portion of said cathode heater voltage source between the cathode and the control electrode of the third of said devices in such a phase relation with respect to the potential applied between the cathode ci said second device and said reference point that the anode and the control electrode have the same polarity with respect to the cathode thereof.

4. In combination: a plurality of electron discharge devices, including a rst and a second of said devices each having an anode, a cathode, and a separatecathode heater for heating said cathode, and a third of said devices having an anode, a control electrode, a cathode and a separate cathode heater for heating said cathode; means electrically interconnecting said first, said second, and said third of said devices, said means including a connection between each of said cathodes and a point of reference potential; means connecting a potential source between the anode and the cathode of said i'irst device com- `prising a rst alternating voltage supply source electrically connected between the cathode of said second device and said point of reference potential; means connecting a potential source from a second alternating voltage supply source between the anode and the cathode of said second device in such a phase relation with respect to the potential applied between the cathode of said second device and said reference point that the anodes of saidirst and said second devices will be -positive simultaneously; means electrically interconnecting said voltage sources such thatthe voltage supply for said. rst device will oppose `the voltage supply for said second device and reduce the potential between the anode and the cathode of said second device; means connecting an alternating voltage source between the anode and the cathode of said third device in such a phase relation with respect to the potential applied between the cathode of said second device and said reference point and the potential applied between the anode and cathode of said second device that the anodes of said rst, said second, and said third devices are positive simultaneously; a single alternating cathode heater voltage supply source electrically connected in energizing relation to all of said cath- 'ode heaters; means electrically connecting a, porltion of 'said cathode heater voltage source between the point of reference potential and the cathode of the iirst of said devices in such a phase relation with respect to the potential applied between the cathode of said second .device and said reference point as to increase the maximum potential difference between the anode and the lcathode of said rst stage; and means electrically connecting a portion of said cathode heater voltage source between the cathode and the control electrode of the third of said devices in such a phase relation with respect to the potential applied between the anode and cathode of said third device .that the anode and the control electrode of said third device have the same polarity with respect to the cathode thereof.

5. In combination: a plurality of electronic discharge devices each having an anode, a cathode, and a control electrode; a plurality of sources of alternating voltage supplies; a, reference point; circuit means connecting the anode of one of said discharge devices to the control electrode of the second of said discharge devices; a resistor; circuit means connecting said resistor between the control electrode and the cathode of said second of said discharge devices; circuit means connecting one of said voltage sources between said reference point and the cathode of said second of said discharge devices; a load cir-` cuit, comprising a third of said discharge devices having an anode, a cathode, and a control electrode, and a condenser and a resistor connected in parallel between the control electrode and the cathode of the third or" said discharge devices;

circuitmeans connecting the cathode ofthe third of said discharge devices to said reference point; and circuit means connecting a second of said voltage sources between the anode of said second of said discharge devices and said load circuit.

6. In combination: a plurality of electronic discharge devices each having an anode, a cathode, a control electrode, and a separate heater circuit for the cathode; a plurality of alternating voltage supply sources, one of said sources having two end terminals and a center tap thereon; a reference point; circuit means connecting said center tap to said reference point, the one of said end terminals to the cathode and the heater circuit of one of said discharge vdevices and to the heater circuit of the second and third of said discharge devices, and the other of said end :terminals to the heater circuits of said discharge devices and the control electrode of said third discharge device; circuit means connecting a second of said voltage sources between said reference point and the cathode of said second discharge device; a circuit network comprising a Vcondenser and resistor connected ina parallel `age sources between the anode of the second of saiddischarge devices and said circuit network. v 7. In combination: a plurality of electron discharge devices including a rst and a second device each having an anode, a cathode and a separate cathode heater for heating said cathode;

means electrically interconnecting said iirst and second devices, said means including a connection between each of said cathodes and a point of reference potential and further including a connection between the anode of said first device and the cathode of said second device; means applying "a potential -fro'm a r'st alternating voltage source between the anode and cathodeof said iirst device, said iirst source being electrically connected between the cathode of said second device and said point of reference potential; and means applying a potential of a larger magnitude than the potential from said iirst source from a second alternating voltage source between the anode and cathode of said second device, said second source being electrically connected between the anode of said second device and said point of reference potential such that said rst and second sources are connected in series between the anode and cathode of said second device and the potentials from said first and second sources are in opposition to each other such that the anodes of said iirst and second devices are positive simultaneously and the potentials across the anodev and cathode of each of said devices are substantially the same.

8. In combination: a plurality of electron discharge devices including a first and a second device each having an anode, a cathode and a separate cathode heater for heating said cathode; meansrelectrically interconnecting said rst and second devices, said means including a connection between each of said cathodes and a point of reference potential and further including a connection between the anode of said first device and the cathode of said second device; means applying a potential from a rst alternating voltage source between the anode and cathode of said rst device, said iirst source being electrically connected between the cathode of said second device and said point of reference potential; means applying a potential of a larger magnitude than the potential from said rst source from' a second alternating voltage source between the anode and cathode of said second device, said second source being electrically connected between the anode 0I" said second device and said point of reference potential such that said rst and second sources are connected in series between the anode and cathode of said second device and the potentials from said iirst and second sources are in opposition to each other such that the anodes of said rst and second devices are positive simultaneously and the potentials across the anode and cathode of each of said devices are substantially the same; a single alternating cathode heater voltage supply source electrically connected in energizing relation tov both of said cathode heaters; means electrically connecting a portion of said cathode heater voltage source between the control electrode and the cathode of the rst of said devices in such a phase relation with respect to the potentialsapplied between the cathode of said second device and said reference point that the anode and the control electrode vary in magnitude inthe same polarity with respect to the cathode thereof; and means electrically connecting a portion of said cathode heater voltage source between the control electrode and the cathode of the second of said devices in such a phase relation with respect tofthe lpotential applied between the cathode of said second device and said reference point that the anode and the control electrode have the same polarity with respect to the cathode thereof.

Y DAVID L. MARKUsEN.

(References on following page) 9 REFERENCES CITED Number The following references are of record in the 2,115,889 ille of this patent: UNITED STATES PATENTS 5 212181502 Number Name Date 2,403,956

1,752,839 Gardiner Apr. 1, 11930 1,960,689 Asch May 29, 1934 2,052,986 Nyman Sept. 1, 11936 Number 2,084,186 Braden June 15, 1937 1n 341,805

Name Date Steimel May 3, 1938 Shepard Nov. 22, 1938 Shepard May 30, 1939 Breitenstein Oct. 22, 1940 Schlesinger July 16, 1946 FOREIGN PATENTS Country Date Great Britain Jan. 22, 1931