US3209293A - Magnetic core structures - Google Patents

Magnetic core structures Download PDF

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US3209293A
US3209293A US232498A US23249862A US3209293A US 3209293 A US3209293 A US 3209293A US 232498 A US232498 A US 232498A US 23249862 A US23249862 A US 23249862A US 3209293 A US3209293 A US 3209293A
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core
segments
disc
magnetic
cup
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Archie R Cornell
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F29/00Variable transformers or inductances not covered by group H01F21/00
    • H01F29/08Variable transformers or inductances not covered by group H01F21/00 with core, coil, winding, or shield movable to offset variation of voltage or phase shift, e.g. induction regulators
    • H01F29/10Variable transformers or inductances not covered by group H01F21/00 with core, coil, winding, or shield movable to offset variation of voltage or phase shift, e.g. induction regulators having movable part of magnetic circuit

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  • This invention relates to magnetic core structures, and more particularly to magnetic core structures such as those used in reactor and transformer coil and core assemblies, designed to have air gaps which can be readily adjusted to vary the reactance of the assembled unit.
  • the present invention accomplishes the above cited objects by providing a core composed of two facing E-section core members having a split annular magnetic shunt disc interposed therebetween. Adjustment of the air gap is effected by movement of the inner annular surface radially relative to a similarly shaped centrally extending core leg within the respective core members.
  • FIG. 1 is a longitudinally sectioned view taken generally along reference line II of FIG. 2 and showing the cup-core arrangment according to the invention utilizing a split shunt disc;
  • FIG. 2 is a cross-sectional view showing the cup-core arrangement of FIG. 1 with a broken away portion of a manipulative tool and taken generally along reference line IIII thereof.
  • the core members depicted therein are generally of the type which have a central core leg having one or more coil windings located thereon while the remaining portion of the core forms a closed magnetic circuit enclosing the coil windings.
  • the core structure shown in FIG. 1 comprises two E- section cup-cores 10 and 12 in facing relationship with an annular magnetic shunt disk 14 interposed therebetween.
  • the shunt disk is shown as being composed of two segments 17, but it is to be understood that any number of segments could be used to form the annular disk without departing from the spirit and scope of the invention. It is to be understood, too, of course, that the cup-cores 1t) and 12 and split shunt disk 14 can be of other than circular configuration.
  • the device illustrates the cup-core 10 as having a centrally extending leg 18 of substantially the same length as the outer barrel 19 thereof and the cup-core 12 as having a centrally extend- 3,209,293 Patented Sept.
  • leg 16 which is longer than the outer barrel 21 thereof by a distance determined by the width of the split shunt disk 14 so that legs 18 and 16 are in abutting relationship.
  • An air gap 20 is formed in the radial direction between the outer periphery of the leg 16 and the inner periphery of the shunt disk segments 17. The reactance of the circuit can be changed by varying the width of the radial air gap 20, in the manner presently to be described.
  • the air gap 20 can be varied by moving the shunt disk segments 17 either inwardly toward the central leg which decreases the air gap 20 or outwardly which increases the air gap 20.
  • a simple hand tool (partially shown) can be constructed to facilitate the spreading of the shunt disk segments 17, the tool having opposing wedge-shaped portions 22 which cooperate with the tapered edges 15 of the shunt disk segments 17, and, as force is exterted by the wedge-shaped portions 22 toward the center leg 16, the shunt disk segments 17 are spread apart with respect to one another to increase the radial air gap 20.
  • This process can also be accomplished by using tapered screws (not shown) and matingly threading the tapered edge portions 15 of the disk segments 17.
  • Two winding receiving openings 26 and 28 are provided on either side of the shunt disk 14 and with the coils inserted therein the final adjusted assembly can be maintained in a fixed relationship by a suitable fastening means such as a bolt 24 inserted through a bolt-receiving opening in legs 18 and 16, which when tightened, clamps the shunt disk segments 17 between the opposing rim portions of the cup-core barrels 19 and 21 in order to preserve the adjusted width of the air gap 20.
  • a suitable fastening means such as a bolt 24 inserted through a bolt-receiving opening in legs 18 and 16, which when tightened, clamps the shunt disk segments 17 between the opposing rim portions of the cup-core barrels 19 and 21 in order to preserve the adjusted width of the air gap 20.
  • the core structures as illustrated contain a completely closed magnetic circuit in its outer periphery while still providing an air gap within the unit to vary the reactance by external means or manipulation after the coil and core are assembled.
  • FIGS. 1 and 2 can be of planar configuration insofar as at least the cup-cores 10 and 12 are concerned, as denoted by the dashed outline 32 of FIG. 2.
  • a magnetic core structure comprising a first cup-shaped member having a centrally extending leg portion therein, a second cup-shaped member having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second member being in facing coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between said disk and said leg portions, whereby a displacement of said segments with respect to adjacent segments results in a radial displacement of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap to adjust the reactance of said core structure and means for binding said structure in fixed relationship to maintain said adjustment.
  • a magnetic core structure comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core member but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between said disc and said leg portions, whereby a displacement of said segments with respect to adjacent segments results in a radial displacement of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap to adjust the reactance of said core structure, and means for binding said structure in fixed relationship to maintain said adjustment.
  • a magnetic core structure comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core members but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members and abutting therewith, said disc forming an air gap between the inner periphery thereof and at least one of said centrally extending leg portions, said annular shunt disc being composed of at least two segments, cooperating means on adjacent radial segmental surfaces for insertion of-a manipulative device, whereby said segments are displaced from one another to provide radial adjustment of said air gap.
  • a magnetic core structure comprising a first cup-shaped member having a centrally extending leg portion therein, a second cup-shaped member having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second members being in facing abutting coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc forming an air gap between the inner periphery thereof and at least one of said leg portions, said annular shunt disc being composed of at least two segments, cooperat ng means on adjacent radial segmental surfaces for insertion of a manipulative device, whereby said segments are displaced from one another to provide radial adjustment of said air gap.
  • a magnetic core structure comprising a first cup-shaped member having a rim portlon and also having a centrally extending leg portion therein, a second cup-shaped member having a rim portion and also having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second members being in facing coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between the segments comprising said disc and said leg portions, binding means extending through said core legs and adapted t o be loosened to permit movement of said segments comprising said disc, each of said segments being radially movable upon loosening of said binding means to provide a radial displacement of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap and vary the reactance of said
  • a magnetic core structure comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core member but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between the segments comprising said disc and said leg portions, binding means extending through said core legs and adapted to be loosened to permit movement of said segments comprising said disc, each of said segments being radially adjustable upon loosening of said binding means to provide a radial displacement'of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap to adjust the reactance of said core structure, and said structure normally held in fixed relationship by said binding means.
  • a magnetic core structure comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core members but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members and abutting therewith, an air gap formed between the inner periphery of said disc and at least one of said centrally extending leg portions, said annular shunt disc comprising at least two segments, cooperating means on adjacent radial surfaces of the segments comprising said disc and adapted to receive a manipulative device, binding means extending through said core legs and adapted to be loosened to permit movement of said segments comprising said disc, said segments adapted to be uniformly displaced from one another upon loosening of said binding means to provide a uniform radial adjustment of said air gap, and said structure normally held in fixed relationship by said binding means to maintain a desired air gap between the segments comprising said disc and at least one
  • a magnetic core structure comprising a first cup-shaped member having a rim portion and also having a centrally extending leg portion therein, a second cup-shaped member having a rim portion and also having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second members being in facing abutting coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc forming an air gap between the inner periphery thereof and at least one of said leg portions, said annular shunt disc comprising at least two segments, cooperating means on adjacent radial segmental surfaces of said segments and adapted to receive a manipulative device, binding means extending through said core leg and adapted to be loosened to permit movement of said segments comprising said disc, said segments being displaced from one another when said binding means is loosened to provide radial adjustment of said air gap, and said structure normally held in fixed relationship

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Description

Sept. 28, 1965 A. R. CORNELL MAGNETIC CORE STRUCTURES Filed 001;. 25, 1962 lNVENTO Archie R. Cor
4 ATTOR N EY WITNESSES- fiwwil 6?. C;
k -z E e 1- WW United States Patent 3,209,293 MAGNETIC CORE STRUCTURES Archie R. Cornell, Avon Lake, Ohio, assignor t0 Westinghouse Electric Corporation, East Pittsburgh, Pa., a corporation of Pennsylvania Filed Oct. 23, 1962, Ser. No. 232,498 8 Claims. (Cl. 336134) This invention relates to magnetic core structures, and more particularly to magnetic core structures such as those used in reactor and transformer coil and core assemblies, designed to have air gaps which can be readily adjusted to vary the reactance of the assembled unit.
In recent years, ferrite cores, and especially ferrite cupcores have been increasingly utilized in such reactor and transformer devices. Due to manufacturing processes the tolerance of the magnetic properties of ferrites are not as close as commercially desirable, sometimes having a variance of as much as 20%. Therefore, some means are necessary to compensate for this variance during the final assembly of the coil and core into the completed unit to be used as a reactor or transformer or some other magnetic core device.
Accordingly, it is an object of this invention to provide a new and improved magnetic core structure.
It is a further object of this invention to provide an improved powdered and/or ferrite core structure which, when combined with a coil winding, can be readily adjusted to vary the reactance of the coil and core unit.
It is a general object of this invention to provide a means of obtaining adjustable air gaps in powdered and/ or ferrite core during the assembly thereof into core and coil structures, and a means of retaining the adjusted air gap.
Briefly, the present invention accomplishes the above cited objects by providing a core composed of two facing E-section core members having a split annular magnetic shunt disc interposed therebetween. Adjustment of the air gap is effected by movement of the inner annular surface radially relative to a similarly shaped centrally extending core leg within the respective core members.
Further objects, features and advantages of the invention will become apparent as the following description proceeds, and features of novelty which characterize the invention will be pointed out with particularity in the claims annexed to and forming a part of this specification.
FIG. 1 is a longitudinally sectioned view taken generally along reference line II of FIG. 2 and showing the cup-core arrangment according to the invention utilizing a split shunt disc; and
FIG. 2 is a cross-sectional view showing the cup-core arrangement of FIG. 1 with a broken away portion of a manipulative tool and taken generally along reference line IIII thereof.
Referring now to the drawings, the core members depicted therein are generally of the type which have a central core leg having one or more coil windings located thereon while the remaining portion of the core forms a closed magnetic circuit enclosing the coil windings.
The core structure shown in FIG. 1 comprises two E- section cup- cores 10 and 12 in facing relationship with an annular magnetic shunt disk 14 interposed therebetween. The shunt disk is shown as being composed of two segments 17, but it is to be understood that any number of segments could be used to form the annular disk without departing from the spirit and scope of the invention. It is to be understood, too, of course, that the cup-cores 1t) and 12 and split shunt disk 14 can be of other than circular configuration. The device, as shown, illustrates the cup-core 10 as having a centrally extending leg 18 of substantially the same length as the outer barrel 19 thereof and the cup-core 12 as having a centrally extend- 3,209,293 Patented Sept. 28, 1965 ing leg 16 which is longer than the outer barrel 21 thereof by a distance determined by the width of the split shunt disk 14 so that legs 18 and 16 are in abutting relationship. However, it is to be understood that these legs need not abut to be within the contemplated scope of the invention. An air gap 20 is formed in the radial direction between the outer periphery of the leg 16 and the inner periphery of the shunt disk segments 17. The reactance of the circuit can be changed by varying the width of the radial air gap 20, in the manner presently to be described.
As illustrated in FIG. 2 by utilizing a pair of complementary or split shunt disk segments 17 each having tapered edge portions 15 at the outer ends thereof, the air gap 20 can be varied by moving the shunt disk segments 17 either inwardly toward the central leg which decreases the air gap 20 or outwardly which increases the air gap 20.
A simple hand tool (partially shown) can be constructed to facilitate the spreading of the shunt disk segments 17, the tool having opposing wedge-shaped portions 22 which cooperate with the tapered edges 15 of the shunt disk segments 17, and, as force is exterted by the wedge-shaped portions 22 toward the center leg 16, the shunt disk segments 17 are spread apart with respect to one another to increase the radial air gap 20. This process can also be accomplished by using tapered screws (not shown) and matingly threading the tapered edge portions 15 of the disk segments 17. Two winding receiving openings 26 and 28 are provided on either side of the shunt disk 14 and with the coils inserted therein the final adjusted assembly can be maintained in a fixed relationship by a suitable fastening means such as a bolt 24 inserted through a bolt-receiving opening in legs 18 and 16, which when tightened, clamps the shunt disk segments 17 between the opposing rim portions of the cup- core barrels 19 and 21 in order to preserve the adjusted width of the air gap 20.
It can be readily seen from the foregoing description that the core structures as illustrated contain a completely closed magnetic circuit in its outer periphery while still providing an air gap within the unit to vary the reactance by external means or manipulation after the coil and core are assembled.
It is to be understood that the core arrangements of FIGS. 1 and 2 can be of planar configuration insofar as at least the cup- cores 10 and 12 are concerned, as denoted by the dashed outline 32 of FIG. 2. 7 Whi e there has been shown and described what is at present considered to be the preferred embodiment of the invention, modifications thereto will readily appear to those skilled in the art. It is not desired therefore that the invention be limited to the specific arrangements shown and described, and it is intended to cover in the appended claims all such modifications that fall within the true spirit and scope of the invention.
I claim as my invention:
1. In a magnetic core structure, the combination comprising a first cup-shaped member having a centrally extending leg portion therein, a second cup-shaped member having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second member being in facing coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between said disk and said leg portions, whereby a displacement of said segments with respect to adjacent segments results in a radial displacement of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap to adjust the reactance of said core structure and means for binding said structure in fixed relationship to maintain said adjustment.
2. In a magnetic core structure, the combination comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core member but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between said disc and said leg portions, whereby a displacement of said segments with respect to adjacent segments results in a radial displacement of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap to adjust the reactance of said core structure, and means for binding said structure in fixed relationship to maintain said adjustment.
3. In a magnetic core structure the combination comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core members but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members and abutting therewith, said disc forming an air gap between the inner periphery thereof and at least one of said centrally extending leg portions, said annular shunt disc being composed of at least two segments, cooperating means on adjacent radial segmental surfaces for insertion of-a manipulative device, whereby said segments are displaced from one another to provide radial adjustment of said air gap.
4. In a magnetic core structure, the combination comprising a first cup-shaped member having a centrally extending leg portion therein, a second cup-shaped member having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second members being in facing abutting coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc forming an air gap between the inner periphery thereof and at least one of said leg portions, said annular shunt disc being composed of at least two segments, cooperat ng means on adjacent radial segmental surfaces for insertion of a manipulative device, whereby said segments are displaced from one another to provide radial adjustment of said air gap.
5.- In a magnetic core structure, the combination comprising a first cup-shaped member having a rim portlon and also having a centrally extending leg portion therein, a second cup-shaped member having a rim portion and also having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second members being in facing coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between the segments comprising said disc and said leg portions, binding means extending through said core legs and adapted t o be loosened to permit movement of said segments comprising said disc, each of said segments being radially movable upon loosening of said binding means to provide a radial displacement of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap and vary the reactance of said core structure, and said structure normally held in fixed relationship by said binding means to maintain proper radial displacement of said segments.
6. In a magnetic core structure, the combination comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core member but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members, said disc comprising a plurality of segments each spaced from said leg portions to form a radial magnetic gap between the segments comprising said disc and said leg portions, binding means extending through said core legs and adapted to be loosened to permit movement of said segments comprising said disc, each of said segments being radially adjustable upon loosening of said binding means to provide a radial displacement'of the inner portion thereof with respect to the legs of said members to alter the radial length of said magnetic gap to adjust the reactance of said core structure, and said structure normally held in fixed relationship by said binding means.
7. In a magnetic core structure the combination comprising a first core member having a centrally extending leg portion therein, a second core member spaced from said first core members but having a centrally extending leg portion therein extended into abutting engagement with said first core member leg portion, an annular magnetic shunt disc interposed in the space between said first and said second members and abutting therewith, an air gap formed between the inner periphery of said disc and at least one of said centrally extending leg portions, said annular shunt disc comprising at least two segments, cooperating means on adjacent radial surfaces of the segments comprising said disc and adapted to receive a manipulative device, binding means extending through said core legs and adapted to be loosened to permit movement of said segments comprising said disc, said segments adapted to be uniformly displaced from one another upon loosening of said binding means to provide a uniform radial adjustment of said air gap, and said structure normally held in fixed relationship by said binding means to maintain a desired air gap between the segments comprising said disc and at least one of said centrally extending leg portions.
8. In a magnetic core structure, the combination comprising a first cup-shaped member having a rim portion and also having a centrally extending leg portion therein, a second cup-shaped member having a rim portion and also having a centrally extending leg portion therein protruding beyond the rim portion thereof, the leg portions of said first and second members being in facing abutting coaxially aligned relationship, an annular magnetic shunt disc interposed between the rim portions of said first and said second members and abutting therewith, said disc forming an air gap between the inner periphery thereof and at least one of said leg portions, said annular shunt disc comprising at least two segments, cooperating means on adjacent radial segmental surfaces of said segments and adapted to receive a manipulative device, binding means extending through said core leg and adapted to be loosened to permit movement of said segments comprising said disc, said segments being displaced from one another when said binding means is loosened to provide radial adjustment of said air gap, and said structure normally held in fixed relationship by said binding means to maintain a desired air gap between said segments and at least one of said centrally extending leg portions.
References Cited by the Examiner UNITED STATES PATENTS 755,829 3/04 Zani 336134 X 2,055,175 9/36 Franz 336-478 X 2,541,797 2/51 Wagner 336-133 2,646,652.- 7/53 Shingledecker et a1, 336-133 JOHN F. BURNS, Primary Examiner,
E. JAMES SAX, Examiner.

Claims (1)

1. IN A MAGNETIC CORE STRUCTURE, THE COMBINATION COMPRISING A FIRST CUP-SHAPED MEMBER HAVING A CENTRALLY EXTENDING LEG PORTION THEREIN, A SECOND CUP-SHAPED MEMBER HAVING A CENTRALLY EXTENDING LEG PORTION THEREIN PROTRUDING BEYOND THE RIM PORTION THEREOF, THE LEG PORTIONS OF SAID FIRST AND SECOND MEMBER BEING IN FACING COAXIALLY ALIGNED RELATIONSHIP, AN ANNULAR MEGNETIC SHUNT DISC INTERPOSED BETWEEN THE RIM PORTIONS OF SAID FIRST AND SAID SECOND MEMBERS AND ABUTTING THEREWITH, SAID DISC COMPRISING A PLURALITY OF SEGMENTS EACH SPACED FROM SAID LEG
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4162433A (en) * 1974-03-28 1979-07-24 U.S. Philips Corporation Circuit arrangement including a line deflection circuit

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US755829A (en) * 1900-06-30 1904-03-29 Gen Electric Controlling induction-motors.
US2055175A (en) * 1934-05-10 1936-09-22 Western Electric Co Apparatus for electrical uses
US2541797A (en) * 1948-08-20 1951-02-13 Daphne Invest Trust Audio-frequency band filter with adjustable band width
US2646552A (en) * 1950-01-27 1953-07-21 Allegheny Ludlum Steel Variable transformer

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US755829A (en) * 1900-06-30 1904-03-29 Gen Electric Controlling induction-motors.
US2055175A (en) * 1934-05-10 1936-09-22 Western Electric Co Apparatus for electrical uses
US2541797A (en) * 1948-08-20 1951-02-13 Daphne Invest Trust Audio-frequency band filter with adjustable band width
US2646552A (en) * 1950-01-27 1953-07-21 Allegheny Ludlum Steel Variable transformer

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4162433A (en) * 1974-03-28 1979-07-24 U.S. Philips Corporation Circuit arrangement including a line deflection circuit

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