US2113421A - Cascade transformer - Google Patents

Cascade transformer Download PDF

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Publication number
US2113421A
US2113421A US44370A US4437035A US2113421A US 2113421 A US2113421 A US 2113421A US 44370 A US44370 A US 44370A US 4437035 A US4437035 A US 4437035A US 2113421 A US2113421 A US 2113421A
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Prior art keywords
transformer
casing
units
liquid
metallic
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Expired - Lifetime
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US44370A
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Camilli Guglielmo
William E Linch
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General Electric Co
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General Electric Co
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F38/00Adaptations of transformers or inductances for specific applications or functions
    • H01F38/18Rotary transformers

Definitions

  • Our invention relates to cascade transformers.
  • a transformer of the usual construction with one or both of its windings arranged for operation at very high voltages is necessarily large and expensive because of the large amount of insulation which is required. If the power to be transmitted is rather small, it has been found more economical in many cases to use two or more much smaller transformer units connected in series or cascade.
  • the general object of the invention is to provide an improved transformer of the cascade type.
  • FIG. 1 is a view in elevation, partly in section, of a cascade transformer constructed in accordance with the invention
  • Fig. 2 is a diagrammatic view of the transformer connections.
  • the cascade transformer shown in the drawing includes three transformer units, each having a magnetic core I and a high voltage winding II.
  • the transformer units are enclosed in a vertical casing formed of alternate metallic sections I2 and insulating sections I3.
  • the lowermost casing section I2 encloses the lowermost transformer unit and is preferably connected to a ground I4.
  • Each of the other transformer units is supported in a metallic casing section I2 by spaced supports I5.
  • the metallic casing sections I2 and insulating casing sections I3 are secured together by clamping rings I6 to form a single tubular vertical wall with liquid-tight joints.
  • the casing is filled with an insulating liquid I!
  • the high voltage windings H of the transformer units are connected in series or cascade by conductors 20 between a high voltage terminal 2
  • Adjacent transformer units are coupled together by a coupling circuit including a coupling winding 22 on each core, as indicated in Fig. 2', t maintain the uniform distribution of the voltage between the transformer units during normal operation.
  • the use of only one of the coupling windings is necessary of course in the upper transformer unit and in the lower transformer unit.
  • the other winding 22 of the lower transformer unit is connected to terminals 23 and acts as a secondary winding to supply current to a local low voltage circuit.
  • the magnetic cores I0 of the transformer units are disposed horizontally in their respective casing sections I2 so that the insulating liquid Il may rise by convection through the openings in the cores as the cores and windings are heated during operation. After rising into the 110 expansion cap I8, the liquid descends along the inner surface of the casing where it is cooled so that after reaching the lower or base section i2 of the casing, it is ready to rise again through the transformer units and absorb more heat.
  • An insulating cylinder 01 bailie 24 extends above each transformer unit and is spaced from the wall of the casing to separate the current of liquid flowing upwardly through the transformer units and the current of liquid flowing down- Wardly close to the casing wall, the upward and downward paths of the liquid being indicated by broken lines in Fig.
  • the provision of these bafiles increases the velocity of flow of the liquid and consequently the rate at which heat is ab- 25 sorbed from the transformer units and dissipated through the casing wall.
  • the insulating sections I3 of the casing need be only long enough to provide necessary insulation between the transformer units and between the upper transformer unit and the expansion cap I8. They need be only large enough in cross section to provide necessary mechanical strength and to enclose the connections between the transformer units and between the upper transformer unit and the terminal 2! and to conduct the upwardly and downwardly flowing liquid without undue restriction.
  • the inner diameters of the insulating casing sections I3 may therefore be substantially smaller than the outer diameters of the transformer units as indicated in Fig. 1.
  • the metallic casing sections i2 are of considerably greater diameter so that they may be spaced sufficiently from the transformer units to permit the descending current of liquid to flow freely.
  • a particularly advantageous feature of the invention is the disposition of the insulating casing sections I3 between the transformer units where these casing sections may be of substantially smaller diameter than that of the trans former units.
  • the insulating casing sections I3 are preferably formed. of porcelain which is very expensive and the size of these insulating sections is therefore very important.
  • the metallic casing sections I2 are in intimate contact with the descending current of insulating liquid I1 and they have excellent heat-conductive characteristics so that they act effectively in cooling the liquid.
  • the magnetic cores W are connected to the high voltage transformer circuit, as indicated in Fig. 2, and the metallic casing sections l2 are electrically connected to their respective magnetic cores I 9 through the supports l5 so that each magnetic core and its enclosing metallic casing section assume the potential of the corresponding part of the high voltage circuit.
  • an abnormally high voltage surge such as may be caused by lightning or switching operations and which is of extremely brief duration
  • a concentration of voltage tends to appear in a small part of the high voltage circuit nearest the high voltage terminal. It is well known, however, that the initial distribution of a sudden surge voltage may be made more uniform throughout the high voltage circuit by increasing the series capacitance between the two ends of the circuit.
  • a cascade transformer including two series connected transformer units, a casing enclosing said units, and an insulating liquid in said casing, said casing including a metallic section enclosing each unit and an insulating section between said metallic sections, the inner diameter of the insulating section being smaller than the outer diameter of the transformer units, said transformer units having openings to permit upward flow of said liquid through the units, each metallic casing section being spaced from the transformer unit which it encloses to provide a path for downward flow of the liquid between the transformer units and casing and in contact with said metallic casing sections and said metallic sections being also in contact with the air surrounding the casing to provide effective heat dissipation from the liquid in contact with their inner surfaces.
  • a cascade transformer including two series connected transformer units, and a casing enclosing said units, said casing including a metallic section enclosing each transformer unit and electrically connected to the series transformer circuit, and an insulating casing section between said metallic sections and holding the metallic sections in spaced relation, the inner diameter of the insulating section being smaller than the outer diameters of the transformer units, each metallic casing section being spaced from the transformer unit which it encloses to provide a path for downward flow of the liquid between the transformer units and casing and in contact with said metallic casing sections, and each metallic casing section being also in contact with the air surrounding the casing to provide effective heat dissipation from the liquid in contact with their inner surfaces.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Coils Of Transformers For General Uses (AREA)

Description

CASCADE TRANSFORMER Filed 001;. 10, 1935 fih m m m n o t Mm WE P 4, IIH e M T y u rfl a (I Z Patented Apr. 5, 1938 --UNlTED STATES PATENT OFFIQE Application October 10, 1935, Serial No. 44,370
2 Claims.
Our invention relates to cascade transformers. A transformer of the usual construction with one or both of its windings arranged for operation at very high voltages is necessarily large and expensive because of the large amount of insulation which is required. If the power to be transmitted is rather small, it has been found more economical in many cases to use two or more much smaller transformer units connected in series or cascade.
The general object of the invention is to provide an improved transformer of the cascade type.
Further objects and advantages will appear from the following description taken in connection with the accompanying drawing in which Fig. 1 is a view in elevation, partly in section, of a cascade transformer constructed in accordance with the invention, andFig. 2 is a diagrammatic view of the transformer connections.
Like reference characters indicate similar parts in both figures of the drawing.
The cascade transformer shown in the drawing includes three transformer units, each having a magnetic core I and a high voltage winding II. The transformer units are enclosed in a vertical casing formed of alternate metallic sections I2 and insulating sections I3. The lowermost casing section I2 encloses the lowermost transformer unit and is preferably connected to a ground I4. Each of the other transformer units is supported in a metallic casing section I2 by spaced supports I5. The metallic casing sections I2 and insulating casing sections I3 are secured together by clamping rings I6 to form a single tubular vertical wall with liquid-tight joints. The casing is filled with an insulating liquid I! which extends into a metallic cap I8 secured above the uppermost insulating casing section I3, a gas space I9 being left above the level of the liquid in the cap to permit expansion and contraction of the liquid due to changes in temperature. The high voltage windings H of the transformer units are connected in series or cascade by conductors 20 between a high voltage terminal 2| and the ground M, the high voltage terminal 2| being secured to the cap I8. Adjacent transformer units are coupled together by a coupling circuit including a coupling winding 22 on each core, as indicated in Fig. 2', t maintain the uniform distribution of the voltage between the transformer units during normal operation. The use of only one of the coupling windings is necessary of course in the upper transformer unit and in the lower transformer unit. The other winding 22 of the lower transformer unit is connected to terminals 23 and acts as a secondary winding to supply current to a local low voltage circuit.
The magnetic cores I0 of the transformer units are disposed horizontally in their respective casing sections I2 so that the insulating liquid Il may rise by convection through the openings in the cores as the cores and windings are heated during operation. After rising into the 110 expansion cap I8, the liquid descends along the inner surface of the casing where it is cooled so that after reaching the lower or base section i2 of the casing, it is ready to rise again through the transformer units and absorb more heat. An insulating cylinder 01 bailie 24 extends above each transformer unit and is spaced from the wall of the casing to separate the current of liquid flowing upwardly through the transformer units and the current of liquid flowing down- Wardly close to the casing wall, the upward and downward paths of the liquid being indicated by broken lines in Fig. l. The provision of these bafiles increases the velocity of flow of the liquid and consequently the rate at which heat is ab- 25 sorbed from the transformer units and dissipated through the casing wall. The insulating sections I3 of the casing need be only long enough to provide necessary insulation between the transformer units and between the upper transformer unit and the expansion cap I8. They need be only large enough in cross section to provide necessary mechanical strength and to enclose the connections between the transformer units and between the upper transformer unit and the terminal 2! and to conduct the upwardly and downwardly flowing liquid without undue restriction. The inner diameters of the insulating casing sections I3 may therefore be substantially smaller than the outer diameters of the transformer units as indicated in Fig. 1. The metallic casing sections i2, however, are of considerably greater diameter so that they may be spaced sufficiently from the transformer units to permit the descending current of liquid to flow freely. A particularly advantageous feature of the invention is the disposition of the insulating casing sections I3 between the transformer units where these casing sections may be of substantially smaller diameter than that of the trans former units. The insulating casing sections I3 are preferably formed. of porcelain which is very expensive and the size of these insulating sections is therefore very important. The metallic casing sections I2 are in intimate contact with the descending current of insulating liquid I1 and they have excellent heat-conductive characteristics so that they act effectively in cooling the liquid.
The magnetic cores W are connected to the high voltage transformer circuit, as indicated in Fig. 2, and the metallic casing sections l2 are electrically connected to their respective magnetic cores I 9 through the supports l5 so that each magnetic core and its enclosing metallic casing section assume the potential of the corresponding part of the high voltage circuit. When an abnormally high voltage surge, such as may be caused by lightning or switching operations and which is of extremely brief duration, is impressed on the high voltage terminal 2|, a concentration of voltage tends to appear in a small part of the high voltage circuit nearest the high voltage terminal. It is well known, however, that the initial distribution of a sudden surge voltage may be made more uniform throughout the high voltage circuit by increasing the series capacitance between the two ends of the circuit. The presence of the metallic casing sections l2 extended substantially beyond the transformer units which they enclose and connected electrically to adjacent parts of the high voltage circuit obviously increases the series capacitance between the high voltage terminal 21 and. the ground l4 and therefore has the effect of substantially increasing the uniformity of distribution of a suddenly impressed high voltage surge on the terminal 2|.
The invention has been explained by describing and illustrating a particular construction of cascade transformer including three transformer units but it will be apparent that changes in the number of units and in other features of the construction described may be made without departmg from the spirit of the invention and the scope of the appended claims.
What we claim as new and desire to secure by Letters Patent of the United States, is:
1. A cascade transformer including two series connected transformer units, a casing enclosing said units, and an insulating liquid in said casing, said casing including a metallic section enclosing each unit and an insulating section between said metallic sections, the inner diameter of the insulating section being smaller than the outer diameter of the transformer units, said transformer units having openings to permit upward flow of said liquid through the units, each metallic casing section being spaced from the transformer unit which it encloses to provide a path for downward flow of the liquid between the transformer units and casing and in contact with said metallic casing sections and said metallic sections being also in contact with the air surrounding the casing to provide effective heat dissipation from the liquid in contact with their inner surfaces.
2. A cascade transformer including two series connected transformer units, and a casing enclosing said units, said casing including a metallic section enclosing each transformer unit and electrically connected to the series transformer circuit, and an insulating casing section between said metallic sections and holding the metallic sections in spaced relation, the inner diameter of the insulating section being smaller than the outer diameters of the transformer units, each metallic casing section being spaced from the transformer unit which it encloses to provide a path for downward flow of the liquid between the transformer units and casing and in contact with said metallic casing sections, and each metallic casing section being also in contact with the air surrounding the casing to provide effective heat dissipation from the liquid in contact with their inner surfaces.
GUGLIELMO CAMILLI. WILLIAM E. LINCH.
US44370A 1935-10-10 1935-10-10 Cascade transformer Expired - Lifetime US2113421A (en)

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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2879488A (en) * 1957-09-18 1959-03-24 Gen Electric Clamping arrangement for cascade transformer
US2902597A (en) * 1956-09-12 1959-09-01 Harold W Leidy Air-borne packaging unit for electronic equipment
US3222590A (en) * 1962-02-13 1965-12-07 Ritz Hans High-voltage instrument transformer
US3532963A (en) * 1968-02-07 1970-10-06 Gen Electric Compensating means for unbalance in cascade type instrument potential transformers
US4308420A (en) * 1980-03-13 1981-12-29 Mcgraw-Edison Company Electrical apparatus with convectively cooled bushing connector
US4757295A (en) * 1987-09-16 1988-07-12 Avco Research Laboratory, Inc. Transmission line pulsed transformer
US4860187A (en) * 1988-01-11 1989-08-22 Radiation Dynamics, Inc. Magnetic flux coupled voltage multiplication apparatus

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2902597A (en) * 1956-09-12 1959-09-01 Harold W Leidy Air-borne packaging unit for electronic equipment
US2879488A (en) * 1957-09-18 1959-03-24 Gen Electric Clamping arrangement for cascade transformer
US3222590A (en) * 1962-02-13 1965-12-07 Ritz Hans High-voltage instrument transformer
US3532963A (en) * 1968-02-07 1970-10-06 Gen Electric Compensating means for unbalance in cascade type instrument potential transformers
US4308420A (en) * 1980-03-13 1981-12-29 Mcgraw-Edison Company Electrical apparatus with convectively cooled bushing connector
US4757295A (en) * 1987-09-16 1988-07-12 Avco Research Laboratory, Inc. Transmission line pulsed transformer
US4860187A (en) * 1988-01-11 1989-08-22 Radiation Dynamics, Inc. Magnetic flux coupled voltage multiplication apparatus

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