RU2542190C2 - Inductor for magnetic-pulse expansion of pipe billets - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to metal forming, particularly, to inductors for magnetic-pulse processing. Coaxial lead wire is used composed of end lead-out composed of a steel pipe with flange secured at the inductor spiral end and isolated at central lead-out. Additional cooling means is composed of PVC tube fitted in helical groove for feed of head sink agent.

EFFECT: higher efficiency, enhanced processing performances.

2 cl, 2 dwg

Description

The invention relates to the processing of metals by pressure, in particular to inductors for magnetic pulse processing.

Known inductor for magnetic-pulse distribution of tubular blanks (see ed. Certificate. No. SU1605375 of 03.22.1989, IPC B21D 26/14. Inductor for distribution of tubular blanks by pressure of a pulsed magnetic field), containing a multi-turn spiral, between which turns are installed paired insulating plates, a textolite base mounted in the inner cavity of the spiral in contact with the insulating plates, a central current lead, an end current lead made in the form of a plate, mounted on the end of the spiral, while the periphery is textolite on the base screw groove formed for cooling. In this case, to compensate for axial forces, the spiral with gaskets is compressed by flanges by means of a current-carrying stud.

In the process of workpiece distribution by a pulsed magnetic field, multidirectional currents with an amplitude value of up to 700 kA arise in the current outputs.

In this case, an interaction force arises between the current outputs, which is invisible at low currents, but causes a significant deformation of the inductor at large.

The negative influence of this factor on the design is the stronger, the greater the length of the current leads. For example, for cases of distribution of long workpieces, this leads to a significant deformation of the current leads and the impossibility of their further operation.

The large length of current leads of the applied design also leads to a noticeable increase in inductance and, accordingly, a decrease in the natural frequency of the discharge circuit, which may impose certain restrictions on the dimensions of the workpieces.

It should be noted that the cooling method used in the inductor makes high demands on the humidity and frequency of the cooling air passing through the inter-turn channels, which creates difficulties in the operation of the equipment. In addition, in the case of a large number of repetitions of charge-discharge cycles in one technological cycle, the cooling method loses its efficiency due to the limited channel capacity.

The technical result of the present invention is to increase the operational stability of the inductor, to increase the rigidity of the structure, to provide the possibility of increasing the length of the processed tube blanks and to provide a low inductance of the inductor for distributing long tube blanks.

The specified technical result is achieved by the fact that in the known inductor for magnetic-pulse distribution of tubular billets containing a multi-turn spiral, between the turns of which are installed pair of insulating spacers, a textolite base mounted in the inner cavity of the spiral in contact with insulating spacers, a central current output, an end current output, fixed at the end of the spiral and made around the periphery of the textolite base with a screw groove for cooling, according to the proposed invention face cold end is formed as a steel pipe with a flange for fastening on the end of the helix mounted on a central cold end isolated from it by a PTFE tube to form a coaxial-type current lead.

In addition, an additional helical groove is made in the textolite base, along which a polyvinyl chloride tube passes for supplying a heat-removing agent and having contact with the inner surface of the spiral coil.

The proposed invention is illustrated by drawings, where

figure 1 presents the proposed inductor in the context;

figure 2 is a view a of figure 1.

The inductor for magnetic pulse distribution of tubular blanks contains a multi-turn spiral 1. Between its coils, paired insulating gaskets are installed 2. A textolite base 3 is placed in the inner cavity of the spiral in contact with the insulating gaskets. Spiral flange 4 serves to contact with the central cold end 5 and has a non-closed annular groove 6 formed on ^{_three quarters} of a circle. With the passage of pulse current, this design provides unloading of the extreme turns of the spiral. The end current output is made in the form of a steel pipe 7 with a flange 8, which is mounted on the end face 9 of the spiral. The steel pipe 7 is isolated from the central current lead by means of a fluoroplastic pipe 10. The steel pipe 7, the central current lead 5 and the fluoroplastic pipe 10 form a coaxial current lead, which together with the flanges 4 and 8 form a pulse electric current passage. Moreover, even with a large value of size L, structural rigidity and low inductance of the inductor are provided, which positively affects the frequency of the discharge circuit during magnetic pulse processing. The insulating sleeve 13 eliminates the contact of the inductor coil with the workpiece.

In the textolite base 3, a helical groove 11 is made, which forms a cooling channel with insulating gaskets, as well as an additional helical groove 12, through which the PVC pipe 14 for supplying a heat sink agent passes. As a heat sink agent, water or another agent that provides reliable heat removal can be used.

The present invention allows to increase the operational stability of the inductor, to increase the rigidity of the structure, makes it possible to increase the length of the processed tube blanks and provides a low inductance of the inductor for the distribution of long tube blanks.

Claims (2)

1. An inductor for magnetic-pulse distribution of tubular billets, containing a multi-turn spiral, between the turns of which are paired insulating gaskets, a textolite base mounted in the inner cavity of the spiral in contact with insulating gaskets, a central current output, a mechanical current output mounted on the end of the spiral, on the periphery of the textolite base there is a helical groove for cooling, characterized in that the mechanical current output is made in the form of a steel pipe with a flange for fixing on the end pyran, installed on the cold end center isolated from it by a PTFE tube to form a coaxial current supply type. 2. The inductor according to claim 1, characterized in that an additional helical groove is made in the textolite base, along which a polyvinyl chloride tube passes for supplying a heat sink agent having contact with the inner surface of the spiral coil.

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