US1596558A - Method and apparatus for amplifying electric currents - Google Patents
Method and apparatus for amplifying electric currents Download PDFInfo
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- US1596558A US1596558A US591347A US59134722A US1596558A US 1596558 A US1596558 A US 1596558A US 591347 A US591347 A US 591347A US 59134722 A US59134722 A US 59134722A US 1596558 A US1596558 A US 1596558A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04M—TELEPHONIC COMMUNICATION
- H04M1/00—Substation equipment, e.g. for use by subscribers
- H04M1/02—Constructional features of telephone sets
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- This invention relates to the amplifica- The wires 6 and 7 carrying the weak curtion of relatively weak electric. currents, rents to be rectified and amplified are conand has for an object to provide an imnected respectively to the grid 8 of the proved methodand apparatus for accomaudion tube and to the wire 3 connecting 5 plishing the amplification in a simple, efthe A battery to the filiament.
- a further obnal of a magnetic coil 9 is connected at one ject is to accomplish the amplification by end by an adjustable contact device 10 and apparatus which is relatively simple, dura- ,a wire 11 to the plate 12 of the audion tube ble, compact, light in weight and inexpen- '2, and the other terminal of the coil 9 is ⁇ 0 sive.
- Other objects and advantages will be connected by a wir 13 150cm pole of a batcs apparent from the following description of tery B.
- the other pole of battery B is con an embodiment of the invention and the nected by a wire 14 to the wire 3 passing novel features will be pointed out in claim. between the filament and the A battery.
- FIG. 1 is a wiring diagram illustrating to the plate and grid of the audion tube, W the principle of the invention; are connected together through a variable Fig. 2 is an elevation of a portion of the condenser 15, which provides an electroapparatus which may be utilized; static coupling between the plate and grid Fig. 3 is an elevation of a conductor unit circuits.
- Fig. 4 is an elevation, partly in section, greater amplification in the plate circuit of a modification of th apparatus shown will be obtained than would be possible if in Figure 2; the regenerative connections were not util- Fig. 5 is a sectional elevation through ized.
- Fig. 6 is a section of the same taken subof the apparatus. stantially along the line of 6-6 of Figure I have also provided a variable condenser 4; and 16 bridged between the wires 11 and 13 85
- Fig. 7 is a wiring diagram of a portion leading to the terminals of the magnetic of the circuit and illustrating a modified Winding 9 so as to by-pass the radio freapparatus. quency currents in the plate circuit of the Referring particularly to Fig.
- One of the terminals of the conductor the tubes connected to one another through 17 is connected by Wire 18 to a telephone retransformers in order to secure a current DCver 19, which may be of the loud speaker with a strength sufficient to operate a teletype, and the other terminal of the conduc- 5 phone receiver or loud speaker.
- a current DC signal which may be of the loud speaker with a strength sufficient to operate a teletype
- the other terminal of the conduc- 5 phone receiver or loud speaker is connected to a current
- variable condenser I plification to be gained by the use of the ad- 24 may be bridged across the termlnals of ditional audion tubes.
- the telephone receiver 19 for the urpose The filament 1 of the audion tube 2 is of forming a by-pass for any ra 1o freconnected by wires 3 and 4 to opposite poles quency currents which may be found 1n the of a battery A, and the wire 4 includes circuit of the conductor 17
- the condenser therein a suitable adjustable rheostat 5.
- the 24 may be omitted without greatly afiect- 1W the diaphragm of the receiver ing the operation of the device, and particularly so when the wires connected to the receiver 19 run parallel for a short distance so as to furnish the necessary capacity for by-passing the radio frequency currents.
- the amplified and rectified currents in the plate circuit act through the magnetic winding 9 and produce a pulsating magnetic field around the conductor 17. n
- the ohmic resistance of a conductor of electricity varies under the influence of a varying magnetizing force and therefore the fluctuations in the magnetic field around the conductor which are set up by the currents in the winding 9, will cause changes in the ohmic resistance of the conductor 17.
- the switch 21 When the switch 21 is closed, current from the battery C will pass through the conductor and through the telephone receiver 19. in the ohmic resistance of the conductor produced by the fluctuating magnetic field the current in the conductor 17 and through the telephone receiver 19 will pulsate in accordance with the changes in the magnetic field.
- the current passing through the conductor 17 and the telephone receiver may be given any desired initial strength and, therefore, will have an intensity sufficient to perform suitable work under the fluc tuations produced by the varying resistance.
- a low resistance receiver 19 may be employed and ample energy in the circuit thereof will be available for operation of so as to produce sound waves of the desired intensity.
- the contact 10 may be adjusted along the winding 9 so as to vary the effective number of ampere turns in the magnetizing coil, and therefore vary the intensity of the magnetic field.
- materials which change their ohmic resistance with changes in a surrounding magnetic field are bismuth, cobalt, iron and nickel, but for a given change in the strength of the magnetic field, nickel shows the greatest change in resistance, its rate of change being about 8 times greater than that for iron or steel for the same field changes.
- the rate of change of the resistance for changes in the strength of the magnetic field is greatest in the highest strengths of fields, such as for example from one thousand to ten thousand c. g. s.
- the preferred material forthe conductor 17 is nickel or nickel al- .loy because of the fact that its rate of change of resistance in a changing magnetic field is the greatest of known materials.
- FIG. 1 one. form of the magnetic winding and the conductor is shown.
- the winding 9 With the changes is placed upon a core 25 of suitable magnetic material such asiron or nickel, the poles 26 of which extend along vone side of the winding 9 and terminate in spaced relation to one another. shown as provided with the adjustable contact 10 because for any given instrument the coil can ordinarily be given the proper number of turns and subsequent adjustment will be unnecessary.
- taps can be run out from various turns of the winding at intervals therein and connected to suitable terminals over which anadjustable contact 10 may pass to vary the effective number of turns.
- one or more conductor units 27 may be disposed so as to be within the path of the lines of force passing between the poles.
- the conductor units may each comprise a double conductor extending spirally in a plane with the branches of the double conductor connected together at their inner ends so that currents induced in one branch by the varying magnetic field will be counteracted by currents induced in the other branch by said field. Any number of these conducting units may be connected either in parallel or in series with one another until the desired length of conductor 17 is obtained, but in Figure 2 these units are illustrated as connected in series with one another.
- the coil 9 is connected in the circuit having the currents to be amplified, either directly or in the manner illustrated in Figure 1, and the conducting units are connected to the wires 18 and 20 in the manner shown in Figure 1.
- the conductor is disposed longitudinally in the direction of travel of the lines of force.
- the coil A is preferably formed in two parts 9 and 9 having central longitudinal passages 28 through which the conductor 17 is threaded alternately so as to form a secondary coil which also forms a closed core for the coils 9 and 9.
- I may provide strips 29 and 30 of suitable insulating material upon the corresponding ends of the coils 9 and 9 so as to extend between the longitudinal passages 28.
- the strips 29 and 30 are each provided in its outer face with a semi-circular groove 31 in which the turns of the conductor 17 are disposed, and the two insulating strips may be clamped together and to the ends of the coils in any suitable manner such as by a screw 32 which is countersunk into one of the strips such as 29, passes between the coils and is threaded'into the other insulating strip.
- the terminals of the conductor 17 are connected to binding posts 33 which are pro- The coil 9 is not vided upon constant and one of the strips. such as 30. To these binding posts 33, the wires 18 and 20 of the wiring diagram of Figure 1 are to be Connected.
- the conductor 17 forms a core through which the lines of force pass in a closed path and since the direction of travel of the lines of force i lengthwise of the conductor 17, no secondary currents will be induced in the conductor by the changes in the magnetic flux set up by the windings 9 and 9.
- the two coils 9 and 9 may have 40,000 turns each of #36 copper wire, and with a current in the plate circuit of an audion tube of 3 milliamperes there will be 9A0 ampere turns.
- the magneto motive force 4 1r N. T equals 3,000.
- the secondary circuit #23 B & S nickel wire, annealed may be used with a normal resistance ofapproximately 30 ohms.
- A. receiver of 1 ohm resistance may be employed and the resistance of the battery G is approximately 3 ohms. The resistance of the connections is negligible.
- the voltage of the battery may be 14 volts so that the permanent current in the second ary circuit will be approximately .42 amperes.
- a magnetic field around the conductor ranging from one thousand to ten thousand c. g. s. the fractional increase of resistance, i. e. the increase of resistance divided by the resistance in zero field, for longitudinal magnetization in nickel wire is practically amounts to approximately
- a coil 9 is employed-for setting up a constant magnetic field some where between 1,000 and 10,000 0. g.
- the coil being supplied with current by wires 34 and 35 the wire 35 having included therein a suitable regulating rheostat 36.
- the circuit coil 9 is arranged adjacent the coil 9? and the conductor 17 is disposed in the combined magnetic field produced bythese two coils 9 and 9. This may be accomplished conveniently by winding the conductor 17 through the cores of the coils 9 and 9 so as to form a continuous magnetic core therefor.
- the coil 9 is connected by wires 37 and 38 to the source of the weak currents to be amplified. In, this arrange- .suitable material,
- the ohmic resistance ment a strong magnetic field will be maintained by the coil 9, and the relatively weak currents passing through the coil 9 will produce varlations' in the strength of the resultant magnetic field around the conductor 17 so thatthe change in the resistance of the conductor 17 by the changing of the field intensity will
- the terminals of the conductor 17 are connected to wires 18 and 20 of the secondary circuit as illustrated in Figure l.
- the relatively weak electric currents will be employed to produce changes in a magnetic field around the conductor 17 of nickel, iron, or other resistance.
- a working circuit imoludesthe conductor 17 therein so that the changes in resistance will produce corresponding changes in the current passing in the working circuit.
- the arrangements herein described are particularly valuable when utilized in connection with radio telephone and telegraph receiving circuits in which the relatively weak currents in the antenna circuit must be amplified considerably in order to operate suitable apparatus such as telephone receivers. It will be understood however, that the invention is applicable to all instances where relatively weak currents are to be amplified and is not to be limited to radio apparatus.
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Description
Aug. 17 1926.
B. N. SOKOLOFF METHOD AND APPARATUS FOR AMPLIFYING ELECTRIC CURRENTS Filed Sept. 29, 1922 2 Shoots-Sheet 1 INVENTOR BOB/S MSO/fOLOFF ATTORNEYS Aug. a.
B. N. SOKOLOFF METHOD AND APPARATUS FOR AMPLIFYING ELECTRIC CURRENTS 2 Sheets-Sheet z Filed Se 1;. 29, 1922 5 7 INVENTOR.
ATTORNEY3.
Patented Aug. 17, 1926. 9 ,558
UNITED STATES PATENT OFFICE.
BORIS N. SOKOLOFZE, OF NEW YORK, N. Y.
METHOD AND APPARATUS FOR AMPLIFYING ELECTRIC GURRENTS. Application filed'september 29, 1922. Serial No. 591,347.
This invention relates to the amplifica- The wires 6 and 7 carrying the weak curtion of relatively weak electric. currents, rents to be rectified and amplified are conand has for an object to provide an imnected respectively to the grid 8 of the proved methodand apparatus for accomaudion tube and to the wire 3 connecting 5 plishing the amplification in a simple, efthe A battery to the filiament. One termi- 0e fective and 'eflicient manner. A further obnal of a magnetic coil 9 is connected at one ject is to accomplish the amplification by end by an adjustable contact device 10 and apparatus which is relatively simple, dura- ,a wire 11 to the plate 12 of the audion tube ble, compact, light in weight and inexpen- '2, and the other terminal of the coil 9 is \0 sive. Other objects and advantages will be connected by a wir 13 150cm pole of a batcs apparent from the following description of tery B. The other pole of battery B is con an embodiment of the invention and the nected by a wire 14 to the wire 3 passing novel features will be pointed out in claim. between the filament and the A battery. In the accompanying drawing: The wires 6 and 11, leading respectively 15 Fig. 1 is a wiring diagram illustrating to the plate and grid of the audion tube, W the principle of the invention; are connected together through a variable Fig. 2 is an elevation of a portion of the condenser 15, which provides an electroapparatus which may be utilized; static coupling between the plate and grid Fig. 3 is an elevation of a conductor unit circuits. With this electrostatic coupling, which may be used in the device of Figure the advantages of a regenerative action of 2; the audion tube are obtained, so that a Fig. 4 is an elevation, partly in section, greater amplification in the plate circuit of a modification of th apparatus shown will be obtained than would be possible if in Figure 2; the regenerative connections were not util- Fig. 5 is a sectional elevation through ized. It will be understood however, that $0 the same, taken substantially along the the electrostatic coupling may b omitted line 0-0; of Figure 4; if desired without preventing the operation Fig. 6 is a section of the same taken subof the apparatus. stantially along the line of 6-6 of Figure I have also provided a variable condenser 4; and 16 bridged between the wires 11 and 13 85 Fig. 7 is a wiring diagram of a portion leading to the terminals of the magnetic of the circuit and illustrating a modified Winding 9 so as to by-pass the radio freapparatus. quency currents in the plate circuit of the Referring particularly to Fig. 1 the inaudion tube, but it will be understood of vention is illustrated in connection with an course, that this condenser maybe omitted 96 audion tube of a radio telephone and teleif desired without rendering the device ingraph set which serves as a preliminary amoperative. plifier and rectifier of relatively Weak cur- A conductor 17 is disposed in the magnerents to be amplified. In radio telephone tic field of the magnetic winding 9, and and telegraph apparatus, for example, it is may form the core for th magnetic wlnd- 95 often necessary to have a large number of ing. One of the terminals of the conductor the tubes connected to one another through 17 is connected by Wire 18 to a telephone retransformers in order to secure a current ceiver 19, which may be of the loud speaker with a strength sufficient to operate a teletype, and the other terminal of the conduc- 5 phone receiver or loud speaker. "When more tor 17 is connected by a wire 20 'through a W9 than two audion tubes are connected in switch 21 and wire 22 to a battery C. The this manner. difficulties such as howling other terminal of the battery C is connected and other noises are encountered, which oifby wire 23 to the other term nal of the teleset, to some extent, the advantages of amphone receiver 19. variable condenser I plification to be gained by the use of the ad- 24 may be bridged across the termlnals of ditional audion tubes. the telephone receiver 19 for the urpose The filament 1 of the audion tube 2 is of forming a by-pass for any ra 1o freconnected by wires 3 and 4 to opposite poles quency currents which may be found 1n the of a battery A, and the wire 4 includes circuit of the conductor 17 The condenser therein a suitable adjustable rheostat 5. 24 may be omitted without greatly afiect- 1W the diaphragm of the receiver ing the operation of the device, and particularly so when the wires connected to the receiver 19 run parallel for a short distance so as to furnish the necessary capacity for by-passing the radio frequency currents. The amplified and rectified currents in the plate circuit act through the magnetic winding 9 and produce a pulsating magnetic field around the conductor 17. n
The ohmic resistance of a conductor of electricity varies under the influence of a varying magnetizing force and therefore the fluctuations in the magnetic field around the conductor which are set up by the currents in the winding 9, will cause changes in the ohmic resistance of the conductor 17. When the switch 21 is closed, current from the battery C will pass through the conductor and through the telephone receiver 19. in the ohmic resistance of the conductor produced by the fluctuating magnetic field the current in the conductor 17 and through the telephone receiver 19 will pulsate in accordance with the changes in the magnetic field. The current passing through the conductor 17 and the telephone receiver may be given any desired initial strength and, therefore, will have an intensity sufficient to perform suitable work under the fluc tuations produced by the varying resistance. A low resistance receiver 19 may be employed and ample energy in the circuit thereof will be available for operation of so as to produce sound waves of the desired intensity.
The contact 10 may be adjusted along the winding 9 so as to vary the effective number of ampere turns in the magnetizing coil, and therefore vary the intensity of the magnetic field. Among the materials which change their ohmic resistance with changes in a surrounding magnetic field are bismuth, cobalt, iron and nickel, but for a given change in the strength of the magnetic field, nickel shows the greatest change in resistance, its rate of change being about 8 times greater than that for iron or steel for the same field changes. The rate of change of the resistance for changes in the strength of the magnetic field is greatest in the highest strengths of fields, such as for example from one thousand to ten thousand c. g. s. There is also some variation in the rate of change of resistance ofthe material, dependent upon whether the field passes lengthwise or transversely of the conductor. The preferred material forthe conductor 17 is nickel or nickel al- .loy because of the fact that its rate of change of resistance in a changing magnetic field is the greatest of known materials.
Referring particularly to Figures 2 and 3, one. form of the magnetic winding and the conductor is shown. The winding 9 With the changes is placed upon a core 25 of suitable magnetic material such asiron or nickel, the poles 26 of which extend along vone side of the winding 9 and terminate in spaced relation to one another. shown as provided with the adjustable contact 10 because for any given instrument the coil can ordinarily be given the proper number of turns and subsequent adjustment will be unnecessary. Obviously, taps can be run out from various turns of the winding at intervals therein and connected to suitable terminals over which anadjustable contact 10 may pass to vary the effective number of turns. Between the spaced poles 28, one or more conductor units 27 may be disposed so as to be within the path of the lines of force passing between the poles.
The conductor units may each comprise a double conductor extending spirally in a plane with the branches of the double conductor connected together at their inner ends so that currents induced in one branch by the varying magnetic field will be counteracted by currents induced in the other branch by said field. Any number of these conducting units may be connected either in parallel or in series with one another until the desired length of conductor 17 is obtained, but in Figure 2 these units are illustrated as connected in series with one another. In the use of this type of coil and conductor, the coil 9 is connected in the circuit having the currents to be amplified, either directly or in the manner illustrated in Figure 1, and the conducting units are connected to the wires 18 and 20 in the manner shown in Figure 1.
In Figures 4 to 6 the conductor is disposed longitudinally in the direction of travel of the lines of force. In this embodiment of the coil and conductor, the coil A is preferably formed in two parts 9 and 9 having central longitudinal passages 28 through which the conductor 17 is threaded alternately so as to form a secondary coil which also forms a closed core for the coils 9 and 9. In order to hold the turns of the conductor 17 together while passing between the coils 9" and 9 I may provide strips 29 and 30 of suitable insulating material upon the corresponding ends of the coils 9 and 9 so as to extend between the longitudinal passages 28. The strips 29 and 30 are each provided in its outer face with a semi-circular groove 31 in which the turns of the conductor 17 are disposed, and the two insulating strips may be clamped together and to the ends of the coils in any suitable manner such as by a screw 32 which is countersunk into one of the strips such as 29, passes between the coils and is threaded'into the other insulating strip. The terminals of the conductor 17 are connected to binding posts 33 which are pro- The coil 9 is not vided upon constant and one of the strips. such as 30. To these binding posts 33, the wires 18 and 20 of the wiring diagram of Figure 1 are to be Connected. In this embodiment the conductor 17 forms a core through which the lines of force pass in a closed path and since the direction of travel of the lines of force i lengthwise of the conductor 17, no secondary currents will be induced in the conductor by the changes in the magnetic flux set up by the windings 9 and 9.
As an example of apparatus which may be used, the following proportions regarding the circuits are given: In the primary circuit the two coils 9 and 9 may have 40,000 turns each of #36 copper wire, and with a current in the plate circuit of an audion tube of 3 milliamperes there will be 9A0 ampere turns. The magneto motive force 4 1r N. T equals 3,000. In the secondary circuit #23 B & S nickel wire, annealed, may be used with a normal resistance ofapproximately 30 ohms. A. receiver of 1 ohm resistance may be employed and the resistance of the battery G is approximately 3 ohms. The resistance of the connections is negligible. The voltage of the battery may be 14 volts so that the permanent current in the second ary circuit will be approximately .42 amperes. With a magnetic field around the conductor ranging from one thousand to ten thousand c. g. s. the fractional increase of resistance, i. e. the increase of resistance divided by the resistance in zero field, for longitudinal magnetization in nickel wire is practically amounts to approximately Referring particularly to Figure 7, I have illustrated a system in which weak currents may be employed without preliminary amplification such as by the audion tube in the diagram of Figure 1. In this system a coil 9 is employed-for setting up a constant magnetic field some where between 1,000 and 10,000 0. g. s., the coil being supplied with current by wires 34 and 35 the wire 35 having included therein a suitable regulating rheostat 36. The circuit coil 9 is arranged adjacent the coil 9? and the conductor 17 is disposed in the combined magnetic field produced bythese two coils 9 and 9. This may be accomplished conveniently by winding the conductor 17 through the cores of the coils 9 and 9 so as to form a continuous magnetic core therefor. The coil 9 is connected by wires 37 and 38 to the source of the weak currents to be amplified. In, this arrange- .suitable material,
from a battery D,
the ohmic resistance ment a strong magnetic field will be maintained by the coil 9, and the relatively weak currents passing through the coil 9 will produce varlations' in the strength of the resultant magnetic field around the conductor 17 so thatthe change in the resistance of the conductor 17 by the changing of the field intensity will |cause changes in the current passing in the conductor 17 and through the telephone receiver 19. The terminals of the conductor 17 are connected to wires 18 and 20 of the secondary circuit as illustrated in Figure l.
It will be observed that with all of the arrangements herein described, the relatively weak electric currents will be employed to produce changes in a magnetic field around the conductor 17 of nickel, iron, or other resistance. A working circuit imoludesthe conductor 17 therein so that the changes in resistance will produce corresponding changes in the current passing in the working circuit. The arrangements herein described are particularly valuable when utilized in connection with radio telephone and telegraph receiving circuits in which the relatively weak currents in the antenna circuit must be amplified considerably in order to operate suitable apparatus such as telephone receivers. It will be understood however, that the invention is applicable to all instances where relatively weak currents are to be amplified and is not to be limited to radio apparatus.
It will be obvious that various changes in the details and arrangements of parts herein described and illustratedfor the purpose of explaining the nature of the invention may be made by those skilled in the art within the principle and scope of the invention.
I claim:
In electric current amplifying devices, means by which the currents to be amplified produce variations in a magnetic field, a magnetic conductor disposed in said magnet-ic field and having sections running in opposite directions to neutralize currents induced therein by the magnetic field, and a circuit including a source of current and the conductor whereby the current in the conductor will be variedby the changes in of the conductor which Ere caused by the variations in the magnetic eld.
In witness whereof, I hereunto subscribe my signature.
BORIS N. SOKOLOFF.
so as to change-its ohmic lee
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US591347A US1596558A (en) | 1922-09-29 | 1922-09-29 | Method and apparatus for amplifying electric currents |
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US591347A US1596558A (en) | 1922-09-29 | 1922-09-29 | Method and apparatus for amplifying electric currents |
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Cited By (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2659043A (en) * | 1949-10-01 | 1953-11-10 | Norden Lab Corp | Apparatus for converting direct current into alternating current |
US2712601A (en) * | 1951-06-09 | 1955-07-05 | Voltohm Processes Ltd | Mechanical-electrical transducer |
US2743322A (en) * | 1952-11-29 | 1956-04-24 | Bell Telephone Labor Inc | Solid state amplifier |
US2744223A (en) * | 1950-11-09 | 1956-05-01 | Bailey Meter Co | Servo system, including electrical inverter circuit |
US2752434A (en) * | 1949-10-19 | 1956-06-26 | Gen Electric | Magneto-responsive device |
US2767911A (en) * | 1952-11-21 | 1956-10-23 | Boeing Co | Electrical multiplier using hall effect |
US2828396A (en) * | 1954-10-06 | 1958-03-25 | Forman Ralph | Magnetoresistive device |
US2939091A (en) * | 1953-10-20 | 1960-05-31 | Bosch Arma Corp | Modulator or demodulator using magnetoresistive elements |
US2941163A (en) * | 1954-06-16 | 1960-06-14 | Sperry Rand Corp | Magneto-resistive bridge modulator |
US2952815A (en) * | 1957-01-03 | 1960-09-13 | Robotron Corp | High gain direct current amplifier |
US20100278602A1 (en) * | 2009-03-31 | 2010-11-04 | Clark Ii Galen R | Articulating drill method and apparatus for cuttig openings in nested strings of underwater piping and/or tubing for overturned wells or platforms |
-
1922
- 1922-09-29 US US591347A patent/US1596558A/en not_active Expired - Lifetime
Cited By (15)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2659043A (en) * | 1949-10-01 | 1953-11-10 | Norden Lab Corp | Apparatus for converting direct current into alternating current |
US2752434A (en) * | 1949-10-19 | 1956-06-26 | Gen Electric | Magneto-responsive device |
US2744223A (en) * | 1950-11-09 | 1956-05-01 | Bailey Meter Co | Servo system, including electrical inverter circuit |
US2712601A (en) * | 1951-06-09 | 1955-07-05 | Voltohm Processes Ltd | Mechanical-electrical transducer |
US2767911A (en) * | 1952-11-21 | 1956-10-23 | Boeing Co | Electrical multiplier using hall effect |
US2743322A (en) * | 1952-11-29 | 1956-04-24 | Bell Telephone Labor Inc | Solid state amplifier |
US2939091A (en) * | 1953-10-20 | 1960-05-31 | Bosch Arma Corp | Modulator or demodulator using magnetoresistive elements |
US2941163A (en) * | 1954-06-16 | 1960-06-14 | Sperry Rand Corp | Magneto-resistive bridge modulator |
US2828396A (en) * | 1954-10-06 | 1958-03-25 | Forman Ralph | Magnetoresistive device |
US2952815A (en) * | 1957-01-03 | 1960-09-13 | Robotron Corp | High gain direct current amplifier |
US20100278602A1 (en) * | 2009-03-31 | 2010-11-04 | Clark Ii Galen R | Articulating drill method and apparatus for cuttig openings in nested strings of underwater piping and/or tubing for overturned wells or platforms |
US8616811B2 (en) * | 2009-03-31 | 2013-12-31 | Tetra Technologies, Inc. | Articulating drill method and apparatus for cutting openings in nested strings of underwater piping and/or tubing for overturned wells or platforms |
US10018005B2 (en) | 2009-03-31 | 2018-07-10 | Epic Applied Technologies, Llc | Articulating drill method and apparatus for cutting openings in nested strings of underwater piping and or tubing for overturned wells or platforms |
US20190040704A1 (en) * | 2009-03-31 | 2019-02-07 | Epic Applied Technologies, Llc | Articulating drill method and apparatus for cutting openings in nested strings of underwater piping and or tubing for overturned wells or platforms |
US10619439B2 (en) * | 2009-03-31 | 2020-04-14 | Epic Applied Technologies, Llc | Articulating drill method and apparatus for cutting openings in nested strings of underwater piping and or tubing for overturned wells or platforms |
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