US2443541A - Voltage regulator - Google Patents
Voltage regulator Download PDFInfo
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- US2443541A US2443541A US572347A US57234745A US2443541A US 2443541 A US2443541 A US 2443541A US 572347 A US572347 A US 572347A US 57234745 A US57234745 A US 57234745A US 2443541 A US2443541 A US 2443541A
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05F—SYSTEMS FOR REGULATING ELECTRIC OR MAGNETIC VARIABLES
- G05F1/00—Automatic systems in which deviations of an electric quantity from one or more predetermined values are detected at the output of the system and fed back to a device within the system to restore the detected quantity to its predetermined value or values, i.e. retroactive systems
- G05F1/10—Regulating voltage or current
- G05F1/46—Regulating voltage or current wherein the variable actually regulated by the final control device is dc
- G05F1/52—Regulating voltage or current wherein the variable actually regulated by the final control device is dc using discharge tubes in series with the load as final control devices
Definitions
- GURVE A INSUFFIGIENT REGENERATION OUTPUT CURVE B Excesswg REGENERATION INPUT VOLTAGE Tic z.
- the object of this invention is to provide a D. C. power supply voltage which stays constant in spite of normal variations in A. C. line voltage, or in current drawn by the load.
- a feature of the invention is the provision of an amplifier stage having practically infinite gain which is responsive to variations in output voltage for providing a voltage to control the regulation.
- Another feature of the invention is the provision of means for regeneratively amplifying a voltage corresponding to variations in output voltage with a time delay to prevent hunting.
- Another feature of the invention is circuit connections permitting the amplifying stage having infinite gain to be connected across the varying input voltage.
- Figure 1 is a diagram illustrating a circuit which has been previously used for voltage regulation and which is included here for use in explaining my invention
- Figure 2 is a graph illustrating certain features of my invention.
- Figure 3 is a circuit diagram illustrating one form of my invention.
- Figure 1 there is impressed across the input terminals, l, 2 a varying D. C. input voltage of approximately 400 volts. This is the voltage which is to be regulated. It may be the output of a rectifier connected to an A. C. power line, for example.
- the circuit of Figure l is illustrated as regulating such a varying D. C. input voltage of approximately 400 volts to produce across the output terminals 3, 4, a regulated output voltage of exactly 300 volts. In the circuit any increase in the output voltage will cause increased current to fiow through the resistances 5. 6. This will, of course, cause an increased voltage drop through resistance 8 between the grid and cathode of tube Tl, resulting in a higher positive voltage on this grid.
- FIG 3 illustrating my invention, shows how I employ D. C. regeneration to provide infinite gain, and consequently perfect regulation.
- the circuit for obtaining D. C. regeneration is disclosed in copending application of Francis H. Shepard, Jr., Serial No. 499,774, filed August 24,
- the input voltage to be regulated is again connected across the terminals l. 2 and may be the same voltage as before, and the regulated output voltage is taken from the output terminals 3, 4.
- the circuit illustrates an actual apparatus constructed and operated by me which provides voltage regulation with great accuracy.
- the actual apparatus constructed employed the components shown in Figure 3 with the values shown. Such components and values are therefore to be taken as illustrative of my invention, which is, however, not necessarily limited thereto.
- D. C. regeneration for the tube 1, in order to produce infinite gain is accomplished in the following manner, as described in said pending application of Francis H. Shepard, Jr.
- This plate is connected through resistances RI l, RI 8 to the grid of tube 8. making this grid go negative.
- the grid of tube 8 goes negative its plate goes positive.
- This plate is connected through resistances RIS and R8 to the grid of tube 1, making this grid go positive, and thereby regenerating the positive impulse first applied to this grid.
- the amount of regeneration may be controlled by varying resistance R.
- This voltage could be made less negative by returning the 6Y6 grid lead in Figure 3 to a tap on RIO.
- this tap would reduce the efiective gain of tube I because it would apply only a portion of the signal output of tube to the 6Y6 grids. This loss of gain is not entirely eliminated but it is made small by means of the arrangement used in Figure 3.
- the 6Y6 grids are returned to a tap on a high-resistance voltage divider connected'between the plate of tube and a highly positive voltage. Because of this high positive voltage, the tap can be set at the proper operating bias for the 6Y6 grids and still be fairly close to the plate 01' tube I.
- Condenser Cl makes the response of the regenerative circuit of the tubes I and 8 slower than the response of the 6Y6 tubes, and thus prevents hunting of the regulated output voltage.
- An increase or decrease in current through the tube therefore does not change the voltage on the grid 8, or at least changes it less than the voltage on the grid of tube 1 is changed, so that the regeneration previously described may occur despite the fact that resistance R22 and tube VRIUS are connectedin parallel with the resistances RI, R2 and R3.
- the resistance RI3 is made variable in order to provide a proper bias for the grids of tubes I and 8 with respect to their cathodes.
- the tap III on resistance R2 permits the system to operate properly despite variations between tubes I and 8'. It also regulates the output voltage. That is, if an output voltage of say 310 volts is desired tap l0 may be moved downward until the output voltage reaches this figure. Similarly, of course, tap I0 may be moved upward to decrease the output voltage.
- Figure 2 illustrates the effect of varying amounts of regeneration in the circuit of tubes I and 8.
- Curve A of this figure shows the efiect on the output voltage for variations in input voltage if there is insufiicient regeneration, showing that in this case the output voltage will increase with increase in input voltage.
- Curve B shows the effect of output voltage for variations in input voltage for excessive regeneration showing that in this case the output voltage will decrease with increases in input voltage.
- the resistance RH may be adjusted to give the correct amount of regeneration, so that, in spite of normal variations in the 400 volt input voltage, the 300 volt output voltage will be held constant with substantially perfect accuracy.
- a voltage regulator comprising an amplifying stage responsive to variations in output voltage, means for regeneratively amplifying in said stage a signal corresponding to variations in output voltage, and means responsive to said amplified signal for controlling said output voltage.
- a voltage regulator comprising an amplifying stage responsive to variations in output voltage, means for applying to said stage a signal corresponding to variations in output voltage, means for regeneratively amplifying said signal, means responsive to said amplified signal for controlling said output voltage, and means for delaying said regeneration so that it occurs more slowly than the controlling means operates.
- a voltage regulator comprising an input circuit and an output circuit, a power amplifier connected to said input circuit in series with said output circuit, a regenerative voltage amplifier having its anode-cathode circuit connected across said input circuit, means for applying a signal corresponding to variations in output voltage to the grid of said voltage amplifier so it is regeneratively amplified therein, and means for applying said amplified signal to the grid of said first mentioned amplifier.
- a voltage regulator comprising a regenerative D. C. amplifier stage having its anode-cathode circuit connected across the input circuit, means for applying a signal corresponding to a variation in output voltage to the grid of said amplifier, a second amplifier stage for regenerating said signal, and means for maintaining the grid of said second stage tube at a voltage which 6 remains more nearly constant than the voltage or the grid of said am mm.
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Description
June 15, 1948. M, s b 2,443,541
VOLTAGE REGULATOR Filed Jan. 11, 1945 2 Sheets-Sheet 1 500 V REGULATED OUTPUT VARYING Dc; INPUT VOLTAGE 400 V. APPROX.
Tic i. v
GURVE A INSUFFIGIENT REGENERATION OUTPUT CURVE B Excesswg REGENERATION INPUT VOLTAGE Tic z.
INVENTOR HERBERT M. NEUSTADT ATTORNEY Patented June 15, 1948 VOLTAGE REGULATOR Herbert M. Neustadt, New York, N. Y., asslgnor,
by mesne assignments, to Remco Electronics, Inc., New York, N. Y., a corporation of New York Application January 11, 1945, Serial No. 572,347
4 Claims. 1
The object of this invention is to provide a D. C. power supply voltage which stays constant in spite of normal variations in A. C. line voltage, or in current drawn by the load.
A feature of the invention is the provision of an amplifier stage having practically infinite gain which is responsive to variations in output voltage for providing a voltage to control the regulation.
Another feature of the invention is the provision of means for regeneratively amplifying a voltage corresponding to variations in output voltage with a time delay to prevent hunting.
Another feature of the invention is circuit connections permitting the amplifying stage having infinite gain to be connected across the varying input voltage.
In the drawings,
Figure 1 is a diagram illustrating a circuit which has been previously used for voltage regulation and which is included here for use in explaining my invention;
Figure 2 is a graph illustrating certain features of my invention; and
Figure 3 is a circuit diagram illustrating one form of my invention.
In Figure 1 there is impressed across the input terminals, l, 2 a varying D. C. input voltage of approximately 400 volts. This is the voltage which is to be regulated. It may be the output of a rectifier connected to an A. C. power line, for example. The circuit of Figure l is illustrated as regulating such a varying D. C. input voltage of approximately 400 volts to produce across the output terminals 3, 4, a regulated output voltage of exactly 300 volts. In the circuit any increase in the output voltage will cause increased current to fiow through the resistances 5. 6. This will, of course, cause an increased voltage drop through resistance 8 between the grid and cathode of tube Tl, resulting in a higher positive voltage on this grid. This increase in the output voltage therefore makes the grid of tube Tl less negative with respect to its cathode. This change in grid voltage causes the anode on tube TI to be more negative. This anode is connected to the control grid of tube T2, and therefore causes this control grid to be more negative with respect to its cathode. With this increased negative grid voltage on tube T2, the internal resistance of the tube increases, and the voltage drop across T2 must increase in order for T2 to supply the current drawn by the load, the anode-cathode circuit of the tube T2 being in series with the load. As a result, when the input voltage increases by only a comparatively small amount most of the increase is absorbed by tube T2. In this way the circuit functions to hold the output voltage close to a constant value.
It may be seen that the accuracy with which this-circuit regulates the output voltage depends on the gain of tube Tl. If tube Tl could be made to have infinite gain the circuit would regulate with perfect accuracy.
Figure 3, illustrating my invention, shows how I employ D. C. regeneration to provide infinite gain, and consequently perfect regulation. The circuit for obtaining D. C. regeneration is disclosed in copending application of Francis H. Shepard, Jr., Serial No. 499,774, filed August 24,
\ 1943, -for Follow-up device.
Referring to Figure 3, the input voltage to be regulated is again connected across the terminals l. 2 and may be the same voltage as before, and the regulated output voltage is taken from the output terminals 3, 4. The circuit illustrates an actual apparatus constructed and operated by me which provides voltage regulation with great accuracy. The actual apparatus constructed employed the components shown in Figure 3 with the values shown. Such components and values are therefore to be taken as illustrative of my invention, which is, however, not necessarily limited thereto.
In Figure 3 the three 6Y6 tubes shown connected in parallel correspond to the tube T2 of Figure 1, while the tube 1 which may be one triode portion of a tube of the 6SN7 type corresponds to the tube Tl in Figure 1.
D. C. regeneration for the tube 1, in order to produce infinite gain, is accomplished in the following manner, as described in said pending application of Francis H. Shepard, Jr. When the grid of tube 1 goes positive its plate, of course. goes negative. This plate is connected through resistances RI l, RI 8 to the grid of tube 8. making this grid go negative. When the grid of tube 8 goes negative its plate goes positive. This plate is connected through resistances RIS and R8 to the grid of tube 1, making this grid go positive, and thereby regenerating the positive impulse first applied to this grid. The amount of regeneration may be controlled by varying resistance R.
In the circuit of Figure 1 it will be noted that the anode-cathode circuit of tube TI is connected in parallelwith the load, while in the circuit of Figure 3 the anode of tube 1 is connected through resistances R5, R6, and R1 to the positive teraeeaeei minal of the input voltage. This connection perinits the use of a potentiometer R6 in the plate circuit of tube 7, which is tapped to provide grid voltage for the 6Y6 tubes. If the grids of the 6Y6 tubes of Figure 3 were connected directly to the anode of tube I, as the grid of T2 in Figure 1 is connected directly to the anode of tube TI in that figure, the voltage applied to the grids of the 6Y6 tubes would be too highly negative. This voltage could be made less negative by returning the 6Y6 grid lead in Figure 3 to a tap on RIO. However this tap would reduce the efiective gain of tube I because it would apply only a portion of the signal output of tube to the 6Y6 grids. This loss of gain is not entirely eliminated but it is made small by means of the arrangement used in Figure 3. In this arrangement, the 6Y6 grids are returned to a tap on a high-resistance voltage divider connected'between the plate of tube and a highly positive voltage. Because of this high positive voltage, the tap can be set at the proper operating bias for the 6Y6 grids and still be fairly close to the plate 01' tube I.
Condenser Cl makes the response of the regenerative circuit of the tubes I and 8 slower than the response of the 6Y6 tubes, and thus prevents hunting of the regulated output voltage.
In describing above the operation of the circuit producing D. C. regeneration, this was defined with respect to a change in the voltage on the grid of tube 1. When the circuit is used for regulating, the voltage on the grid of tube I must also be considered. That is, if a change in output voltage causes the voltage on the grids of tubes I and 8 both to move in the same direction there would be no regeneration. The voltage on the grid of tube 8 is maintained substantially constant by the use of a voltage regulator tube VRII connected between point 9 and ground. This tube has the characteristic that the voltage across it remains substantially constant despite the variations in current through the tube. An increase or decrease in current through the tube therefore does not change the voltage on the grid 8, or at least changes it less than the voltage on the grid of tube 1 is changed, so that the regeneration previously described may occur despite the fact that resistance R22 and tube VRIUS are connectedin parallel with the resistances RI, R2 and R3.
The resistance RI3 is made variable in order to provide a proper bias for the grids of tubes I and 8 with respect to their cathodes.
The tap III on resistance R2 permits the system to operate properly despite variations between tubes I and 8'. It also regulates the output voltage. That is, if an output voltage of say 310 volts is desired tap l0 may be moved downward until the output voltage reaches this figure. Similarly, of course, tap I0 may be moved upward to decrease the output voltage.
The operation of Figure 3 should be clear from the foregoing description, but will now be described briefly in order to be sure it is fully understood. If the output voltage tends to increase more current will be drawn through resistances RI, R2 and R3. Thiswill result in the voltage on the grid of tube I being less negative with respect to its cathode. This voltage will be regenerated by the circuit connecting tubes I and I to make the grid of tube I still less negative. As the grid of who I goes less negative the anode of tube I goes more negative. As this anode is connected to the grids of the three 6Y6 tubes,
- these grids go more negative with respect to.
operation will take place.
their cathodes. This increases the resistance of its cathode, the anode of tube I will become lessnegative, the grids of the 6Y6tubes will become more positive, the resistance of the 6Y6 tubes will be decreased, the voltage across the 6Y6 tubes will decrease, and the output voltage will be restored to exactly 300 volts.
Figure 2 illustrates the effect of varying amounts of regeneration in the circuit of tubes I and 8. Curve A of this figure shows the efiect on the output voltage for variations in input voltage if there is insufiicient regeneration, showing that in this case the output voltage will increase with increase in input voltage. Curve B shows the effect of output voltage for variations in input voltage for excessive regeneration showing that in this case the output voltage will decrease with increases in input voltage. Between the two positions illustrated by curves A and B the resistance RH may be adjusted to give the correct amount of regeneration, so that, in spite of normal variations in the 400 volt input voltage, the 300 volt output voltage will be held constant with substantially perfect accuracy.
It will be understood that my circuit is capable of various modifications, and 'I do not, therefore,
desire to be restricted to the specific details of the circuit shown and described, but only within the scope of the appended claims.
What is claimed is:
1. A voltage regulator comprising an amplifying stage responsive to variations in output voltage, means for regeneratively amplifying in said stage a signal corresponding to variations in output voltage, and means responsive to said amplified signal for controlling said output voltage.
2. A voltage regulator comprising an amplifying stage responsive to variations in output voltage, means for applying to said stage a signal corresponding to variations in output voltage, means for regeneratively amplifying said signal, means responsive to said amplified signal for controlling said output voltage, and means for delaying said regeneration so that it occurs more slowly than the controlling means operates.
3. A voltage regulator comprising an input circuit and an output circuit, a power amplifier connected to said input circuit in series with said output circuit, a regenerative voltage amplifier having its anode-cathode circuit connected across said input circuit, means for applying a signal corresponding to variations in output voltage to the grid of said voltage amplifier so it is regeneratively amplified therein, and means for applying said amplified signal to the grid of said first mentioned amplifier.
4. A voltage regulator comprising a regenerative D. C. amplifier stage having its anode-cathode circuit connected across the input circuit, means for applying a signal corresponding to a variation in output voltage to the grid of said amplifier, a second amplifier stage for regenerating said signal, and means for maintaining the grid of said second stage tube at a voltage which 6 remains more nearly constant than the voltage or the grid of said am mm. a [mum STATES PATENTS HERBERT M. ms'rsnr. Number Name Dete 2,247,082 Gardiner June 24, 1941 sameness man 5 2,302,100 Parratt' Nov. 14, 1944 The following references are of recordm the tile of this patent:
Certificate of Correction Patent No. 2,443,511. June 15, 1948.
HERBERT M.. NEUSTADT It is hereby certified that the name of the assignee in the above numbered patent was erroneously described and s ccified as Remco Electronics, Inc., whereas said name should have been describe and specified as Ren'ico Electronic, 1110., as shown by the record of assignments in this Office; and that the said Letters Patent should be read with this correction therein that the same may conform 'to the record of the case in the Patent Office.
Signed and sealed this 14th day of September, A. D. 1948.
THOMAS F. MURPHY,
Assistant Commissioner of Patents.
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US572347A US2443541A (en) | 1945-01-11 | 1945-01-11 | Voltage regulator |
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US572347A US2443541A (en) | 1945-01-11 | 1945-01-11 | Voltage regulator |
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US2443541A true US2443541A (en) | 1948-06-15 |
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Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2502342A (en) * | 1944-12-09 | 1950-03-28 | Harvey Radio Lab Inc | Current supply system |
US2555680A (en) * | 1946-02-21 | 1951-06-05 | Harvey Radio Lab Inc | Power supply regulation |
US2650996A (en) * | 1950-08-24 | 1953-09-01 | Dynamatic Corp | Regulating control and regenerative circuit |
US2810105A (en) * | 1953-05-19 | 1957-10-15 | Sorenson & Company Inc | Voltage regulator |
US2825023A (en) * | 1954-03-23 | 1958-02-25 | Boeing Co | Load compensated voltage regulated power supplies |
US2867764A (en) * | 1955-12-27 | 1959-01-06 | Harrison Lab Inc | Direct-voltage regulating circuit |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2247082A (en) * | 1939-03-29 | 1941-06-24 | Gen Electric | Electronic voltage regulator |
US2362769A (en) * | 1942-02-02 | 1944-11-14 | Cornell Res Foundation Inc | Electronic voltage stabilizer |
-
1945
- 1945-01-11 US US572347A patent/US2443541A/en not_active Expired - Lifetime
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2247082A (en) * | 1939-03-29 | 1941-06-24 | Gen Electric | Electronic voltage regulator |
US2362769A (en) * | 1942-02-02 | 1944-11-14 | Cornell Res Foundation Inc | Electronic voltage stabilizer |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2502342A (en) * | 1944-12-09 | 1950-03-28 | Harvey Radio Lab Inc | Current supply system |
US2555680A (en) * | 1946-02-21 | 1951-06-05 | Harvey Radio Lab Inc | Power supply regulation |
US2650996A (en) * | 1950-08-24 | 1953-09-01 | Dynamatic Corp | Regulating control and regenerative circuit |
US2810105A (en) * | 1953-05-19 | 1957-10-15 | Sorenson & Company Inc | Voltage regulator |
US2825023A (en) * | 1954-03-23 | 1958-02-25 | Boeing Co | Load compensated voltage regulated power supplies |
US2867764A (en) * | 1955-12-27 | 1959-01-06 | Harrison Lab Inc | Direct-voltage regulating circuit |
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