US1844501A - Coupling transformer - Google Patents

Coupling transformer Download PDF

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US1844501A
US1844501A US205894A US20589427A US1844501A US 1844501 A US1844501 A US 1844501A US 205894 A US205894 A US 205894A US 20589427 A US20589427 A US 20589427A US 1844501 A US1844501 A US 1844501A
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tube
wire
coupling
transformer
condenser
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US205894A
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Robert L Davis
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CBS Corp
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Westinghouse Electric and Manufacturing Co
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F21/00Variable inductances or transformers of the signal type
    • H01F21/02Variable inductances or transformers of the signal type continuously variable, e.g. variometers
    • H01F21/04Variable inductances or transformers of the signal type continuously variable, e.g. variometers by relative movement of turns or parts of windings

Definitions

  • the invention relates to radio devices and particularly to the coupling between two vacuum tube devices.
  • the two inductors are replaced by the two windings of a transformer, the leakage inductance of the transformer will cooperate with the tube capacities to cause parasitic oscillations. If the transformer be very closely coupled, the
  • leakage inductance is small, but unless the leakage inductance is reduced to practicall zero, the parasitic oscillations, althoug higher in frequency, continue to be troublesome.
  • the leakage inductance may give rise to trouble, in this'way. With the higher frequencies at which condenser coupling is usually employed, the trouble is more pronounced.
  • tel-leaving the windings is a common example. All such expedients result only in diminishing the separation between the primzfiy and secondary.
  • the tubular conductor is electrically equivalent to a linear conductor coinciding with the actual linear conductor.
  • the two windings thereshowlng one form of the insulation separating the two conductors.
  • the vacuum tube 1 is the final amplification stage from a master oscillator which is to control the frequency of the oscillations generated in the tube 2.
  • the input circuit of the tube 1 extends from any suitable or known frequency-controlling device, such as a crystal-controlled oscillator or an oscillator controlled by a tuning 'fork. Between the oscillator itself and the input circuit, any number of amplifiers, frequency multipliers, or other similar devices may be inserted. The last of these devices is conattery 8 or other source of plate-current energy.
  • the inductance which is to cooperate with the condenser 6 to form a tuned circuit is supplied by one member of a double winding, which constitutes the important feature of i the coupling device.
  • the double winding is composed of a tube- 11 and a wire 12.
  • heads 13 of insulating material are threaded upon the wire 12 and the cylindrical surface of the beads contacts with the inside surface of the tube 11. It is not necessary, that the beads shall make a close lnechanicalifit, either with the tube or with the wire. Neither is it necessary that the beads closely contact with each other at their ends.
  • the tube 11 is connected, as shown at 14 and 15, to the two sides of the condenser 6.
  • the inductance of the. primary 11 and the capacity of the condenser 6 are thus in parallel with one another and constitute the tuning elements in the plate circuit of the tube 1.
  • the helical wire 12, within the tubular conductor 11 is the secondary of the transformer and the terminal thereof adjacent the connection 14 is connected, as shown at 16, to the grid of the tube 2.
  • the other end ot the helical wire is connected, as shown at 17, to the filament of the tube 2.
  • the latter connection includes a condenser 18 in parallel to the C-battery 19.
  • the tube 2 is a power tube. Its output circuit 22 is supplied by means of a highpotential source 23 which is in parallel with the usual by-pass condenser 24 and the output circuit delivers power to the antenna in the usual way.
  • the filaments are grounded, as usual, and are supplied in parallel from the common A- battery 26.
  • An adjustable resistor 27 is shown for controlling the heating of both filaments and a supplementary rheostat 28 is supplied for additional control of the filament 5, if desired.
  • the beads instead of having plain ends, as shown in Fig. 2, shall be formed with ends which dove-tail, as illustrated in Fig. 3.
  • One end of each bead is furnished with a projecting central portion 30, and the other end of each head is provided with a corresponding recess 31.
  • the protrudin parts are all directed in the same way re ative to the wire, whereby the projections on each bead fit into the recesses in the neighboring bead.
  • the fitting is not close, in order that the compound conductor may be bent into the .helical form.
  • the oscillations from the master oscillator are amplified by the tube 1 and produce oscillations, of the same frequency or its harmonic, in the circuit 6 11 which is tuned to said oscillations or to said harmonic.
  • the oscillations in the primary 11 give rise to an alternating flux through the helix composed of the wire 12 and electromotive forces are set up in this wire as a consequence of the alternations in said flux. If the transformer coupling is not absolutely without leakage, the changes in voltage upon the tube 11 induce changes in voltage upon the wire 12 electrostatically, which constitute an addition to the electromotive forces alread noticed. If the condenser 20 is employedi still further potential changes are conveyed by it. All of these potential changes are so related in phase that an additive result is impressed upon the conductor 16, and thus upon the grid of the tube 2.
  • the condenser 21 also adds to the electrostatic coupling. Although a connection from one side of this condenser to the other can be traced through batteries 8 and 19 in series, leads, which ordinarily are long and, there fore, possess a substantial amount of inductance. Some difference of alternating p07 this connection includes thebattery tential is, therefore, present across the condenser 21 and this alternating potential difference acts upon the grid of the tube 2 in the same sense as the potential changes alreadynoted.
  • the direct-current source 8 is larger than the direct-current source 19. Moreover, the negative terminal of the source 19 is connected to the wire 12 and the positive terminal of the source 8 is connected to the tube 11. The other terminals of each of said sources are connected, either directly or through a relatively small resistance, to ground. Consequently, the wire 12 is at a lower direct-current potential than the tube 11. When the device is used in high-power transmitting apparatus, this difference of direct-current potenial is of substantial amount, and the tube 11 must be thorough-1y insulated from the wire 12. Under 'such circumstances, the structure shown in Fig.
  • the wire 12 is in the position occupied by the secondary and, consequently, no leakage occurs as a result of separation between primary and secondary. Becausethe leakage will be very small, the likelihood of parasitic oscillations being set up is also small. It is not, however, completely removed.
  • inductance in the leads 14 and 15, for example, may cause parasitic oscillations.
  • a transformer comprising a tubular conductor, a conductor within said tube, and
  • a transformer comprising a tubular conductor, a conductor within said tube,
  • a transformer comprising a tubularconductor, a conductor within said tube, and
  • Fig. 1 of the coupling between the final amplification stage of the master oscillator and'the' power tube is by way of example only. The invention may be applied to the coupling between any two tubes.

Description

Feb. 9, 1932. R. L. DAVIS 1,844,501
COUPLING TRANSFORMER Filed July 15, 1927 INVENTOR i 'ATTORNEY Patented Feb. 9, 1932 UNITED, STATES.
PATENT OFFICE ROBERT I4. DAVIS, OF PITTSBURGH, PENNSYLVANIA, ASSIGNOR T0 WESTINGHOUSE ELECTRIC & MANUFACTURINQ COMPANY, A! CORPORATION OF PENNSYLVANIA COUPLING TRANSFORMER Application filed July 15, 1927. Serial No. 205,894.
The invention relates to radio devices and particularly to the coupling between two vacuum tube devices.
It has been frequently the practice to insert in the plate circuit of one tube, a parallelresonant circuit or some other high impedance device, including an inductor. The terminal of this impedance nearest the plate has frequently been connected to the grid of a second tube by a condenser, and between said grid and the filament of the second tube, a radio-frequency choke coil is frequently required.
The structure just described has several disadvantages, among which may be mentioned that the inductance on either side of the connecting condenser may cooperate with the capacity between tube elements to give rise to troublesome parasitic oscillations. If,
in order to avoid this, the two inductors are replaced by the two windings of a transformer, the leakage inductance of the transformer will cooperate with the tube capacities to cause parasitic oscillations. If the transformer be very closely coupled, the
leakage inductance is small, but unless the leakage inductance is reduced to practicall zero, the parasitic oscillations, althoug higher in frequency, continue to be troublesome.
Even when ordinary transformer coupling with no connecting condenser is used,
the leakage inductance may give rise to trouble, in this'way. With the higher frequencies at which condenser coupling is usually employed, the trouble is more pronounced.
It is an object of this invention to provide a coupling between vacuum-tube devices which shall have a minimum tendency to produce parasitic oscillations.
It is a further object of this invention to provide a transformer, suitable for use in coupling two vacuum tube devices together, in which the leakage flux shall be very small.
It is a further object of this invention to produce a transformer in which the tightness of coupling shall be a maximum.
It is a further object of the invention to provide a capacity coupling which shall supplement the transformer coupling.
It is'well known that leakage flux in the transformer usually results from the fact that the primary winding, is necessarily spaced somewhat from the secondary winding. Numerous expedients have been adopted for diminishing the leakage, of which in-,
tel-leaving the windings is a common example. All such expedients result only in diminishing the separation between the primzfiy and secondary.
athematical theory indicates that a current flowing in atubular conductor is equiva- -lent to a current flowing along the axis of the tube. I take advantage of this fact to produce a. transformer in which the primary and secondary are, in effect, in identically the same place. Thereby the separation between the primary and secondary is, in effect, reduced to zero and the leakage of the transformer is, therefore, reduced to so small an amount that it is practically ,zero.
I do this by making one of the two windings a tubular conductor and placing the other in the axis of said tube. The tubular conductor is electrically equivalent to a linear conductor coinciding with the actual linear conductor. The two windings, thereshowlng one form of the insulation separating the two conductors.
In Fig. 1, the vacuum tube 1 is the final amplification stage from a master oscillator which is to control the frequency of the oscillations generated in the tube 2. The input circuit of the tube 1 extends from any suitable or known frequency-controlling device, such as a crystal-controlled oscillator or an oscillator controlled by a tuning 'fork. Between the oscillator itself and the input circuit, any number of amplifiers, frequency multipliers, or other similar devices may be inserted. The last of these devices is conattery 8 or other source of plate-current energy.
The inductance which is to cooperate with the condenser 6 to form a tuned circuit is supplied by one member of a double winding, which constitutes the important feature of i the coupling device.
The double winding is composed of a tube- 11 and a wire 12. The the axis of the tube 11. wire and they walls of wire 12 extends along Contact between the the tube is prevented by any suitable means.
In the, illustration shown in Fig. 2, heads 13 of insulating material are threaded upon the wire 12 and the cylindrical surface of the beads contacts with the inside surface of the tube 11. It is not necessary, that the beads shall make a close lnechanicalifit, either with the tube or with the wire. Neither is it necessary that the beads closely contact with each other at their ends.
It is preferable that all of these parts fit loosely enough to enable the compound con ductor consisting of the wire 12 and the tube 11 to be wound into a helix, as shown in Fig. 1. If, however, the beads fit the wire and tube with a moderate degree of closeness, the helix will be self-supporting.
. In the circuit shown in Fig. 1, the tube 11 is connected, as shown at 14 and 15, to the two sides of the condenser 6. The inductance of the. primary 11 and the capacity of the condenser 6 are thus in parallel with one another and constitute the tuning elements in the plate circuit of the tube 1. The helical wire 12, within the tubular conductor 11 is the secondary of the transformer and the terminal thereof adjacent the connection 14 is connected, as shown at 16, to the grid of the tube 2. Likewise, the other end ot the helical wire is connected, as shown at 17, to the filament of the tube 2. The latter connection includes a condenser 18 in parallel to the C-battery 19.
A certain capacity, exists between the wire 12 and the tube 11. Consequently, there will be not only transformer coupling I but also electrostatic coupling between the output circuit of the tube 1 and the input circuit of the tube 2. If desired, this capacity coupling may be supplemented by a condenser 20 conmeeting the conductors 14 and 16. A similar condenser 21, shown at the lower end of the helix will further supplement the capacity coupling. 7
If the transformer were absolutel without any leakage whatever, the radioequency potential at any point I along the wire 12 would be the same as the radio-frequency potential at the neighboring point in the tube 11. No condenser action would therefore take place andthe capacity coupling would be without effect. It is to supplement the incomplete transformer-coupling which must in practice exist that the capacity coupling is of use. I The tube 2 is a power tube. Its output circuit 22 is supplied by means of a highpotential source 23 which is in parallel with the usual by-pass condenser 24 and the output circuit delivers power to the antenna in the usual way.
The filaments are grounded, as usual, and are supplied in parallel from the common A- battery 26. An adjustable resistor 27 is shown for controlling the heating of both filaments and a supplementary rheostat 28 is supplied for additional control of the filament 5, if desired.
In installations intended for high power, it is preferred that the beads, instead of having plain ends, as shown in Fig. 2, shall be formed with ends which dove-tail, as illustrated in Fig. 3. One end of each bead is furnished with a projecting central portion 30, and the other end of each head is provided with a corresponding recess 31. When the beads are threaded upon the wire 12, the protrudin parts are all directed in the same way re ative to the wire, whereby the projections on each bead fit into the recesses in the neighboring bead. Preferably, the fitting is not close, in order that the compound conductor may be bent into the .helical form.
y In the operation of the device, the oscillations from the master oscillator are amplified by the tube 1 and produce oscillations, of the same frequency or its harmonic, in the circuit 6 11 which is tuned to said oscillations or to said harmonic.
The oscillations in the primary 11 give rise to an alternating flux through the helix composed of the wire 12 and electromotive forces are set up in this wire as a consequence of the alternations in said flux. If the transformer coupling is not absolutely without leakage, the changes in voltage upon the tube 11 induce changes in voltage upon the wire 12 electrostatically, which constitute an addition to the electromotive forces alread noticed. If the condenser 20 is employedi still further potential changes are conveyed by it. All of these potential changes are so related in phase that an additive result is impressed upon the conductor 16, and thus upon the grid of the tube 2.
The condenser 21 also adds to the electrostatic coupling. Although a connection from one side of this condenser to the other can be traced through batteries 8 and 19 in series, leads, which ordinarily are long and, there fore, possess a substantial amount of inductance. Some difference of alternating p07 this connection includes thebattery tential is, therefore, present across the condenser 21 and this alternating potential difference acts upon the grid of the tube 2 in the same sense as the potential changes alreadynoted.
The direct-current source 8 is larger than the direct-current source 19. Moreover, the negative terminal of the source 19 is connected to the wire 12 and the positive terminal of the source 8 is connected to the tube 11. The other terminals of each of said sources are connected, either directly or through a relatively small resistance, to ground. Consequently, the wire 12 is at a lower direct-current potential than the tube 11. When the device is used in high-power transmitting apparatus, this difference of direct-current potenial is of substantial amount, and the tube 11 must be thorough-1y insulated from the wire 12. Under 'such circumstances, the structure shown in Fig.
3 is preferred, because the bends in the leakage path over the endv surfaces of the beads 13 cause the path to be longer than in the case of beads with plane ends.
The wire 12 is in the position occupied by the secondary and, consequently, no leakage occurs as a result of separation between primary and secondary. Becausethe leakage will be very small, the likelihood of parasitic oscillations being set up is also small. It is not, however, completely removed. The
inductance in the leads 14 and 15, for example, may cause parasitic oscillations.
The absence of all leakageinductance ensures that the potential will vary along the tube at the same rate that it does along the wire. Each point of the wire, therefore,'is
"at the same alternating-current potential as its neighboring pointin the tube. The insulation 13 is,'therefore, not subject to an alternating electrostatic field, and high frequency losses will not be produced in such insulation. It is, therefore, possible to make the beads 13 of material which would not be suitable for use in places where aIternat ing high-frequency electric fields are present. Ordinary glass, instead of pyrex glass an untuned coupling. Wheneverthere is a tuning condenser it is preferable that it be associated with the tube instead of the wire because the tube affords a greater surface for carrying the alternating current.
Although I have described my invention in terms of a wire and a tube around it, it will be evident to those skilled in the art that any two closely adjacent conductors may be used. Many of the advantages described herein can be obtained by winding two straps close together in one helix. Such helices are most conveniently prepared by fastening two straps together by insulation and then winding the two as a compound conductor by one winding operation.
Many other modifications of the invention here disclosed will be apparent to those skilled in the art and the specific description herein is not to beconsidered as a limitation.
I claim as my invention:
1. A transformer comprising a tubular conductor, a conductor within said tube, and
a plurality of spacing beads surrounding said inner conductor and'maintaining the said conductors substantially coaxial.
2. A transformer comprising a tubular conductor, a conductor within said tube,
and a pluralityof spacing insulators surrounding said inner conductor to maintain said conductors substantially coaxial, said insulators having non-planar ends to provide a relatively long leakage path between said conductors.
3."A transformer comprising a tubularconductor, a conductor within said tube, and
a plurality of spacing insulators having nonplanarends surrounding said inner conductor to maintain said conductors substantially coaxial, adjacent insulators being disposed .in nested relation each to the other.
In testimony whereof, I have hereunto subscribed my name this 11th day of July, 1927.
' ROBERT L. DAVIS.
will be suitable, or the beads may be made of moldable material, such as micarta. Theillustration'in Fig. 1 of the coupling between the final amplification stage of the master oscillator and'the' power tube is by way of example only. The invention may be applied to the coupling between any two tubes.
Also the association of the coiled com I pound conductor with a tuned circuit, such as that of which the condenser 6 forms a part is not essential. 1 It may form a part of
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Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2430640A (en) * 1945-05-31 1947-11-11 Allis Chalmers Mfg Co Induction heating system with alternately energized coaxial conductors
US2531820A (en) * 1943-02-03 1950-11-28 Rca Corp Voltage transformer
US2735988A (en) * 1956-02-21 fyler
US2771547A (en) * 1955-08-05 1956-11-20 Zenith Radio Corp Multiband frequency selector and frequency converter
US2934722A (en) * 1956-07-18 1960-04-26 Zenith Radio Corp Signal-translating networks
US3105287A (en) * 1957-05-08 1963-10-01 Rea Magnet Wire Company Inc Insulated wire particularly for coils and the manufacture thereof
US3436708A (en) * 1966-12-19 1969-04-01 Gates Radio Co Variable transformer having one coil conductor within the other
US4512343A (en) * 1982-05-07 1985-04-23 Richard Wolf Gmbh Medical coagulation device
US5301096A (en) * 1991-09-27 1994-04-05 Electric Power Research Institute Submersible contactless power delivery system
US5341083A (en) * 1991-09-27 1994-08-23 Electric Power Research Institute, Inc. Contactless battery charging system

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2735988A (en) * 1956-02-21 fyler
US2531820A (en) * 1943-02-03 1950-11-28 Rca Corp Voltage transformer
US2430640A (en) * 1945-05-31 1947-11-11 Allis Chalmers Mfg Co Induction heating system with alternately energized coaxial conductors
US2771547A (en) * 1955-08-05 1956-11-20 Zenith Radio Corp Multiband frequency selector and frequency converter
US2934722A (en) * 1956-07-18 1960-04-26 Zenith Radio Corp Signal-translating networks
US3105287A (en) * 1957-05-08 1963-10-01 Rea Magnet Wire Company Inc Insulated wire particularly for coils and the manufacture thereof
US3436708A (en) * 1966-12-19 1969-04-01 Gates Radio Co Variable transformer having one coil conductor within the other
US4512343A (en) * 1982-05-07 1985-04-23 Richard Wolf Gmbh Medical coagulation device
US5301096A (en) * 1991-09-27 1994-04-05 Electric Power Research Institute Submersible contactless power delivery system
US5341083A (en) * 1991-09-27 1994-08-23 Electric Power Research Institute, Inc. Contactless battery charging system

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