FI57498B - LUFTLINDAD DROSSEL - Google Patents

Description

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National Board of Patents and Registration (44) Nthttviksip ^ j. month date, Q

Patent · och ragieteretyreleen AmSkan utbfd och utUkrifun public · ™ * 30.04.80 (32) (33) (31) PjnrJutty «tuolkaut — B« (ird priorltM 28.12.72

Canada (CA) 160059 (71) Trench Electric Limited, 390 Midwest Road, Scarborough, Ontario,

The present invention relates to an air-core choke consisting of two or more concentrically nested choke devices. The present invention relates to an air-core choke consisting of two or more concentrically nested choke devices. (72) Anthony B. Trench, Thornhill, Ontario, Canada (CA) (7 ^) Berggren Oy Ab a cylindrical coil structure with an air gap between them, each having one or more conductors wound in the form of a helix and incorporated in a resin material forming a rigid, longitudinally extending sleeve-like portion, the coil structures having means for electrically connecting all said coils in parallel, and at the opposite end there are connector members connected to the respective coil windings to form their individual connections.

Chokes of this type are already known, for example, from GB patent 1 017 029 and U.S. patent 2 959 75 ^.

The object of the invention is to provide an improved choke structure compared to known solutions, which achieves an even higher coupling factor, and to fulfill this function the choke according to the invention is characterized in that the coil windings extend only a part of the axial length of at said opposite end considerably more than at said other end, and that the film-like insulation is deposited on the protruding part of the sleeve, overlapping a part of the helical winding.

The resin material may preferably be reinforced with glass. According to a preferred embodiment of the invention, the choke consists of two or more combinations comprising two rigid cylindrical coil structures arranged concentrically and radially spaced apart and all electrically connected at one end, the opposite ends of each coil being connected to each other. for coil groups.

In addition, the choke may have spacers arranged circumferentially spaced apart between adjacent coil structures, keeping these at the desired distance from each other.

The invention is illustrated by the accompanying drawings, in which Figure 1 is a partially sectioned perspective view of a double choke according to an embodiment of the invention; Figure 2 is an axial vertical section of the double choke of Figure 1; Fig. 3 is a vertical section similar to Fig. 2, but with a double choke consisting of a plurality of nested coils; Fig. 4 is a plan view of an embodiment of the type shown in Fig. 3.

Figure 1 shows an air-core double choke 10 consisting of two rigid cylindrical coil structures 20 and 30 arranged concentrically nested. The coil structures 20 and 30 are on a rigid radial base 40 and support insulators 50 are attached below the base. The radial base 40 is made of a conductive material and the base is formed by a plurality of beams extending radially from the common axis of the concentric coil structures. Any commonly used insulators are suitable for the stand support insulator 50 and can be attached to the stand in a conventional manner. The coils of the coils of the coil assemblies 20 and 30 are connected to the radial base 40, so that the coils of the double choke 3,5498 of Fig. 1 are connected at the lower end. The upper ends of the coils are connected to separate poles such that the upper end of the coil of the coil assembly 30 is connected to the terminal 60 and the upper end of the coil assembly 20 is connected to the terminal 70. The poles 60 and 70 are rigid metal rods extending radially outward from the coil structures.

In the embodiment shown in Figure 1, the spool assemblies 20 and 30 are separate rigid cylindrical components whose relative position is maintained by the tie ties 80 and 81. The upper end of the tie 80 is located in a notch in the pole rod 60 securing the pole rod in place. Correspondingly, the upper end of the fastening bandage 8l is placed in the notch in the pole rod 70 and the lower end is fastened to the corresponding beam 41 of the radial base 40.

The coil of the coil structure 20 consists of one or more conductors 21 helically wound around the axis of the cylinder inside a resinous material, possibly reinforced with filler 22. As the reinforcing material of said resinous material, glass fiber is best suited so that a rigid structure is obtained from the coil structure when the heat treatment is performed. The lower end of the conductor 21 is connected to the radial base 40 and the upper end is connected by the connecting conductor 24 to the terminal 70. The conductor 21 is wound from the base 40 side along the cylinder to the point indicated by reference numeral 25, leaving part of the coil between the upper end and hub. The part of the coil structure between the upper end of the coil winding and the terminals 60 and 70 acts as a protective insulation which prevents sparking between the ends of the winding. The length of this part, i.e. the distance of point 25 from terminals 60 and 70, depends on the required surge voltage and this length can be selected according to the nominal values of the choke.

Similarly, the coil of the coil of the coil structure 30 consists of a conductor 31 helically wound around the axis of the cylinder inside a resinous, filler-reinforced material. Fiberglass is the best reinforcement. The lower end of the conductor 31 is connected to the radial base 40 by a connecting conductor 33, so that the coils 20 and 30 are connected from the lower end. The upper end of the coil 30 is connected to the pole rod 60 by a connecting conductor 36. The coil formed by the conductor 31 is wound from the base 40 side to the position indicated by reference numeral 35, so that part of the coil structure remains between the upper end of the coil and the terminals 60 and 70

ί 57498

It is recommended, though not necessary, to place a protective insulation 90 in the coil structure 30 which extends from the terminals 60 and 70 to such an extent that it covers part of the windings of the coil 30. Any insulating material can be used as said protective insulation, preferably an insulating film, e.g. a film known under the trademark ‘Mylar’, which is placed between the surface layers of a rigid cylindrical component.

The coil structures 20 and 30 are relatively large in diameter, of the order of 1-1.3 m, and the radial distance between them is about 1 cm. The coils are thus close to each other, so a high coupling factor is obtained. The wall thickness of the coil structure is about 1 cm. The space between the nested coil structures, about 1 cm, forms a vertical cooling channel.

The embodiment shown in Figure 2 has one coil group formed of two rigid coil structures 20 and 30.

Figure 3 shows a double choke according to a further embodiment of the invention, consisting of two coil groups comprising two coil structures 20 and 30. All coils are placed evenly and centrally nested at regular intervals. The coils of the coils of the coil structures 20 and 30 are connected to the radial base 40 from the lower end so that the coils are connected from the lower end. The upper ends of the coils of the coils of the coil structures 20 are connected to the terminal 70 and the upper ends of the coils of the coil structures 30 are connected to the terminal 60. The two coils of the coil structures 20 are thus connected in parallel. Depending on the nominal values of the choke, several coil groups can be used if necessary. By dividing the coils into partial coils so as to use two coil structures 20 and two coil structures 30 which are relatively thin and close to each other, a high-power choke is obtained without the coupling coefficient being significantly deteriorated. In Fig. 3, the coils can be said to be in alternating order, because from the inside, first there is a coil 30, then a coil 20, then a coil 30 and the outermost coil 20. In the same way, additional coil groups can be arranged if necessary.

In the above embodiments, each rigid coil structure is fabricated separately and then the coil structures are nested concentrically. In the case of Figure 4, an alternative method has been used in which the coil structures are constructed directly in place from the innermost coil .30. The innermost coil structure 30 is made around a rigid cylinder that can later be either removed or left to support the inner coil. The coil structure 30 is made, for example, by winding a conductor 5 57498 around a cylinder and at the same time winding fiberglass and resin-like material. When the coil structure 30 is completely finished, axial spacers 100 are placed on its outer circumference at regular intervals.

Thereafter, a coil structure 20 is made on the spacers by the winding method described above. The spacers thus separate the coil structures from each other. When the coil structure 20 is completed, spacers are placed on its outer circumference again and an outer coil structure 30 is made on them. When all of the coil assemblies 20 and 30 are complete, the entire assembly is heat treated to provide a unitary rigid assembly containing the desired number of coils 20 and 30. The coil assembly is placed on a radial base 40, to the beams of which the poles, 60 and 70 at the upper end of the coil structures are attached by tie wires 80 and 8l.

In the embodiments described above, the protective insulation 90 is placed on the coils 30. In addition or alternatively, the protective insulation may be placed on the coil structures 20. In addition, the protective insulation may be a single or multi-layer film to maximize insulation at the coil winding tops 25 and 35. If more than one layer of protective insulation is used, the layers can be staggered together so that the protective insulation is strongest at the points where the probability of sparking between different coils is greatest.

In the embodiment of Figure 3, the windings of two adjacent coil structures are connected to different terminals 60 and 70. Alternatively, the windings of two adjacent coil structures may be connected to terminal 60 and the coils of other two adjacent coil structures to terminal 70. If protective insulation is used. between.

Claims (6)

6 57498 An air-core choke (10) consisting of two or more concentrically nested cylindrical coil structures (20, 30) with an air gap therebetween, each having one or more conductors (21, 31)> wound in a helical fashion and incorporated into the resin material (22, 32) forming a rigid, longitudinally extending sleeve-like portion, the one end of the coil structures having members (40) electrically connecting all said coils in parallel, and the opposite end having connector members (60, 70) connected to respective coil windings ( 31, 21) forming their individual connections, characterized in that the coil windings (21, 31) extend only in part (25, 35) of the axial length of the sleeve so that the sleeve of said coil combination extends considerably more at said opposite end than the end of said helical winding. at the other end, and that the film-like insulation (90) is layered ho to each protruding part, overlapping part of the helical winding. Choke according to Claim 1, characterized in that the resin material is reinforced with glass. A choke according to claim 1, characterized in that it has a rigid pole portion (40) supporting said coil structures at one end thereof and having said means for connecting the coil windings in parallel. A choke according to claim 1, characterized by two or more combinations comprising two rigid cylindrical coil structures (20, 30) arranged concentrically and radially spaced apart and all connected (40) at one end electrically in parallel, each coil assembly (20, 30) the opposite ends being connected in parallel and having individual connections (24, 36) for the respective coil groups. A choke according to claim 1, characterized in that it has spacers (100) arranged circumferentially spaced apart from adjacent coil structures, keeping them at the desired distance from each other. A choke according to claim 4, characterized in that each combination of coil structures comprises alternating centrally arranged coils.