DE1539983B2 - Coil arrangement for magnet forming - Google Patents

Description

The invention relates to a coil arrangement for magnet deformation with a coil having the shape of a coil, insulated conductor between two mating, an axial opening for receiving of a workpiece to be reshaped and one that extends from the axial opening to the circumference the coil extending slot delimiting metal parts is embedded in recesses that are in the mating surfaces of these metal parts are located.

In a coil arrangement of this type known from US Pat. No. 3,126,937, the separating surfaces run between the metal parts and cylindrical axially to the receiving opening. In addition, the coil is helical wrapped.

The object of the invention is to provide a coil arrangement of the type mentioned at the beginning, which in the case of pulses by the coil pushes the metal parts apart less than the coil arrangement according to the US-PS 126 937.

To solve this problem, the coil arrangement of the type mentioned is characterized in that the conductor has the shape of a plane spiral and that the mating surfaces of the two metal parts run plate-shaped at right angles to the axis of the spiral.

A spiral wound coil is according to Fig. 13c of the magazine “Werkstatt und Betrieb”, December 1963, p. 897, known, but this coil is not required two metal parts embedded.

The coil arrangement according to the invention thus has a coil body made of conductive material consists and has a bore whose shape corresponds to the shape of the conductor. The leader is across the street insulated from the bobbin. The conductor serves as the primary winding. If the workpiece is deformed, a strong current impulse sent through the conductor. The bobbin itself serves as the secondary winding; in a current is induced to him when a current pulse is sent through the conductor. The one in the bobbin Induced current creates a magnetic field, which in turn generates a current in one located in the opening Workpiece induced or also in the field shaper possibly located in the opening. The bobbin is divided by a gap that extends from its opening to its perimeter. This division prevents current flow around the opening in the bobbin. Such a current flow would be the magnetic field weaken in the opening.

The coil arrangement according to the invention prevents expansion or stretching of the primary winding, such as it occurs in the known arrangement. Among other things, this prevents the primary winding material from becoming fatigued. In addition, the primary winding without losing its electrical effectiveness, physically strengthened and supported so that the Magnetic field in the opening is exactly reproducible. The structure of the arrangement according to the invention is also relatively easy. The resistance losses and the magnetic losses are proportional small amount.

Formations of the invention, particularly the type of clamping of the metal parts, the training the field shaper and the formation of the insulating layers are in the subclaims specified. Protection is sought for this only in the context of subclaims.

Measures to clamp together permanent coils for magnet forming are according to the magazine "Werkstatt und Betrieb", December 1963, p. 897, Fig. 14, known.

In the following, exemplary embodiments of the invention are described in conjunction with the drawings. It shows

F i g. 1 is a perspective view of a first embodiment of the coil arrangement,

F i g. 2 shows a view of the coil arrangement according to FIG. 1, with various parts broken away,
F i g. 3 shows a section along the line 3-3 in FIG. 2,

FIG. 4 shows a section corresponding to FIG. 3 by a second embodiment of the coil arrangement.

The drawn coil arrangement has a bobbin 10, which consists of a pair of flat one on top of the other flat plates 12 and 14 consists. The bobbin formed by the plates has a central opening 16 with a field former 18 inserted therein into which a workpiece (not shown) is inserted

can. A filled with insulating material extends from the central opening 16 to the outer edge of the bobbin Gap 20, whereby a magnetic field can be built up in the opening. The opposite Surfaces of the Plattentl2 and 14 are each provided with a spiral groove, which together form a spiral Form extending bore 22 in which a spiral-shaped primary winding 24 is located. The winding 24 is thus practically completely enclosed and surrounded by the coil body 10.

When a high amperage rush current is passed through primary winding 24, it develops in the bobbin 10 as a result of induction, a current which in turn builds up a field that is in the central opening 16 arranged field shaper 18 induces a current. This field in turn creates an impulsive, strong one Magnetic field in the field shaper emerges, creating a current in the lying within the field shaper Workpiece is induced. Under the interaction between the strong magnetic field in the field shaper and the current induced in the workpiece transforms the workpiece. So that the bobbin itself In the area of the gap 20 as a result of the forces generated by the field, there are clamping devices 26 provided.

As shown in FIGS. 1 and 2, the plates 12 and 14 of the spool 10 have a rectangular shape; they are preferably made of highly conductive Material, e.g. B. made of beryllium copper, copper or the like. Several bolts 28 reach through Holes in the plates and keep them tightly pressed against one another over a large area; each hole is at its ends Executed countersunk to receive a screw head or a screw nut. Each plate owns a centrally executed opening of circular cross-section, which is attached so that after screwing together of the plates, both openings are coaxial. In this way, the two openings form with one another the central opening 16, the diameter of which is so large that the field shaper 18 to be described later with very little play can be used.

The bobbin 10 is opposite the primary winding 24 represents a secondary winding; therefore, a current is induced in the bobbin when in the primary winding a stream flows. If the bobbin 10 were designed as a closed loop, it would practice the Effect of a magnetic shield, and inside the field shaper, where the workpiece is located, no magnetic field could be built up. Therefore, the already mentioned gap 20 is provided interrupts the bobbin; the gap is created by mutually aligned incisions in the plates 12 and 14 formed. These cuts extend from the cylindrical wall surface of the central opening 16 to the lower one Edge of the bobbin; the gap is preferably filled with a non-compressible insulation material 29, such as a thermosetting material Resin.

The flat plate 12 forming part of the coil former 10 has a practically flat inner side 30, into which a spiral groove 32 is cut which has a semicircular cross-section. The axis of the spiral groove runs practically collinear with the axis of the central opening 16; the inside beginning of the groove is at Edge of the central opening, while the outer end of the groove is on the outside of the spool. Corresponding the flat plate 14 forming the other half of the bobbin 10 has a practically flat inside 34, which can be guided tightly against the inside 30 of the plate 12 and contains a spiral groove 36 which represents the mirror image of the spiral groove 32 in the plate 12. When the two flat panels 12 and 14 are flat are placed against each other, the spiral grooves 32 and 36 together form the spiral-shaped, in one Flat hole 22.

The bore 22 receives the primary winding 24 which, in the embodiment shown, consists of an in Is made of spiral shaped wire; however, a tubular structure can also be used, if, for example, a coolant is to be passed through the windings. In any case, the wire or tubular turns of conductive material, e.g. B. made of copper, and the spiral turns are in laid a single level. Around the turns of the primary winding is a layer 38 of insulation material of suitably high strength, for example made of resin-impregnated glass fiber, to make electrical contact and sparks to prevent between the bobbin 10 and the winding 24 and at the same time to reinforce the winding. At one end of the winding 24, especially at the outer edge of the bobbin At the end, an input terminal 40 is formed which is connected to a suitable power source 41 for delivery can be connected to high current surges; such a power source is for example U.S. Patent Applications 170,062 dated January 31, 1962 and 311,427 dated September 25, 1963.

In the embodiment shown, an energy source, such as a capacitor bank 42, is connected to the input terminal 40 connected. Between the capacitor battery 42 and the primary winding 24 is a suitable switching means 44, such as an ignitron or a thyratron, to control the flow of current in the primary winding to be able to control. The capacitor bank 42 is supplied by a high voltage source connected in parallel therewith 45 brought to high tension. Furthermore, a switch 46 is inserted between the capacitor bank 42 and the voltage source 45 is placed so that the capacitor bank can be charged before a current surge high amperage must be sent.

The opposite end of the primary winding 24, in this case the inner end, is at the central opening 16 electrically connected to the bobbin 10. There is also a clamp on the bobbin 10 49 a grounded conductor 48, which also has a conductor 50 to the other side of the capacitor bank 42 is connected; this completes an electrical circuit. The coil body is thus at ground potential held so that any risk of electric shock is avoided if the bobbin 10 is accidentally is touched.

As already mentioned, the flowing of a strong current through the primary winding 24 causes it to develop a magnetic field of very high energy density in the space of the central opening 16. This field is preferred either by the size and shape of the central opening 16 surrounding areas of the coil former or, as drawn here, aligned and concentrated by the shape and size of the field shaper 18; the Field former fits into the central opening and can be exchanged to achieve different deformation effects will. The field is generated by the interaction of the coil former 10 and the field shaper 18 focused and shaped.

The field shaper 18 according to the drawn execution

Approximate shape has an outer cylindrical surface, the diameter of which is slightly smaller than that of the central opening 16; the inner surface of the field shaper slopes inwardly from opposite sides of the element and defines a reduced diameter cylindrical throat 51 which receives the workpiece. The field shaper consists of a pair of halves that belong together and can be removed from the central opening are; In this way, the field-shaped element can be reduced by a zone of reduced cross-section on the workpiece place, which has a larger cross-section than the neck piece 51. Furthermore, the division of the Field shaper interrupted its connection, with a field concentration in the central area of the form element becomes possible. Between the associated halves of the field shaper 18 is a suitable one Insulation 52 attached, for example made of thermosetting resin. Similar insulation 52a is on the exterior cylindrical edge of the field shaper 18 and isolates it from the coil body 10.

It should be noted that during the pulsed current flow through the coil 24 strong forces between the workpiece and the field shaper occur, which on an opening or separation of the coil body in the Aim the area of the gap 20 and thus put parts of the primary winding 24 under tension. To prevent, that the parts of the bobbin move away from each other as a result of these forces, is a holding device 26 provided, which has a pair of horizontally extending tie rods 53 made of steel or a consist of another durable material and next to the lower part of the outer sides of the bobbin 10 get lost; are located at the ends of the tie rods 53, lying flush opposite the ends of the bobbin, Blocks 54. The threaded ends of the rods 53 are through holes in the blocks guided and held with washers 55 and nuts 56. Opposite the bobbin 10 are the Blocks 54 isolated by an insulating layer 57; the tie rods 53 press the blocks 54 firmly against the spool 10.

F i g. 4 shows a bobbin 58 with a central opening 60 into which, through an insulating layer 63,

the opening 60 is insulated, a field shaper 62 is inserted; the field shaper 62 encloses an isolated one Primary winding 64 made from a wire of practically rectangular cross-section. The walls of the central opening 60 are inclined so that the diameter of the central opening on one side of the bobbin is smaller is than on the other side. The outside of the field shaper is beveled in a corresponding manner. the The conical shape of these surfaces facilitates the installation and removal of the field former in and out of the coil body. The tensioning device 66 prevents the bobbin from stretching in the area of the (not shown) Gap, which corresponds to the gap 20 in the embodiment described above.

For this purpose 2 sheets of drawings

Claims (8)

Patent claims: 1. Coil arrangement for magnet deformation with an insulated one having the shape of a coil Head between two mating, one axial opening for receiving one to be formed Workpiece leaving free and one extending from the axial opening to the circumference of the Coil extending slot delimiting metal parts is embedded in recesses that are in the matching surfaces of these metal parts are, characterized in that the Conductor (24, 64) has the shape of a plane spiral and that the mating surfaces of the the two metal parts (12, 14, 58) run plate-shaped at right angles to the axis of the spiral. 2. Arrangement according to claim I _1, characterized in that the two metal parts (12, 14, 58) are clamped together in the axial direction of the spiral. 3. Arrangement according to claim 1 or 2, characterized in that the two metal parts (12, 14, 58) clamped together in a direction running at right angles to the boundary surfaces of the gap (20) are. 4. Arrangement according to one of the preceding claims, characterized in that in the opening a separate middle part (18,62) designed as a field shaper is arranged. 5. Arrangement according to claim 4, characterized in that the opening in the axial direction of the spiral conical and the outer surface of the metal part (62) designed as a field shaper is correspondingly conical is shaped. 6. Arrangement according to one of the preceding claims, characterized in that the gap (20) is filled with an insulating material (29). 7. Arrangement according to claim 4 or 5, characterized in that between the field shaper formed metal part (18, 62) and the conductor (24, 64) enclosing metal parts (12, 14, 58) a layer of insulating material (52a, 63) is located. 8. Arrangement according to claim 6 or 7, characterized in that the insulating material (29,52a, 63) from thermosetting resin.