SU840144A1 - Device for inductional heating of cylindrical ferromagnetic billets - Google Patents

Description

; I The invention relates to devices for the induction heating of various cylindrical ferromagnetic blanks, and can also be used to automate the movement of ferromagnetic parts of these geometric shapes in other technological processes. A device for induction heating of ferromagnetic cylindrical billets is known, in which the magnetic field of permanent magnets or electromagnets 1 is used to reliably push them into the inductor to reliably push them into the inductor. In this device the magnetic flux from stationary permanently mounted magnetic devices. passes through the magnetic pipelines moving over the magnets, attached to the conveyor belt, assembled from special non-magnetic carriages, two roller skating on rails. The supplied blanks are stacked on the upper ends of the said magnetic ducts in the working gap of the matting system formed by them and pressed against them by magnetic forces. However, the stationary magnets acting on the gaps between the poles and the magnetotransmitters moving over them, the ponderomotive forces are quite large, and this creates additional significant resistance to the movement of the conveyor belt, which ultimately can lead to rapid wear of the rollers and the guides supporting them. The gaps between the poles of the stationary magnets and the magnetic cores moving above them are unstable, and these gaps in the magnetic circuit are connected in series with the working gaps where the workpieces are transported, which can lead to instability in magnitude of the pushing forces, to the fuzzy and unreliable work of the transporting Melanism )but.

The purpose of the invention is the provision of the magnitude of the magnitude of the pushing forces.

This goal is achieved by the fact that in a known device for induction heating of cylindrical ferromagnetic blanks containing an inductor, a transporting mechanism with two roller chains and magnetic conductors fixed to them, with working zazras, and fixed magnets, magnetic conductors are L-shaped, their ends are bent The ends are located oppositely, the working gaps are formed, and the magnets are located between the free vertical lines; the ends of the L-shaped magnetogons are OB with gaps.

In addition, in order to provide a fixed gap between the magnets and the magnetic cores, the device is provided with a guide placed between the magnetic cores with a protrusion on which the magnets are mounted.

Thus, the magnetic cores, which cover the fixedly mounted magnets and form together with them a magnetic circuit with working gaps to accommodate the transported blanks, pass along horizontally mounted straight linear magnets along the sides of the poles from the poles. gaps. The forces that arise in this case and in the above-mentioned gaps almost equilibrate each other and do not affect the transport mechanism. Moreover, these forces in the proposed magnetic instructions of the magnetic system can be minimized. This also achieves stability and constancy in the magnitude of the useful pushing billet forces. The location of the magnetogovodov at a distance of 0.7-O, 8 magnet lengths - and the approach of the working gap to the magnets largely leads to a better experience and improvement of the energy characteristics of the use of magnets. I .. Fig, 1 shows the proposed

A device for induction heating of cylindrical ferromagnetic blanks, the general VVD1 in FIG. 2 shows section A-A in FIG. one.

The device contains an inductor 1 and a transfer mechanism 2 with a drive designed to weld cylindrical ferromagnetic blanks 3 into an inductive (p Transport "feeder mechanism consists of two roller chains 4 attached to

them using non-magnetic studs 5, spacer sleeves b and intermediate wires 7 L-shaped magnetic cores 8 with working clearances 9, designed to accommodate the blanks 3 supplied to inductor 1. In addition, the transporting mechanism 2 includes fixed and horizontally mounted Straight magnets 1O for 6 with glued pole tips 11 made of magnetically soft material. Magnetic 10 can be permanent or electromagnets and mounted on a common lagoon guide with a protrusion 12, and L-shaped magnet the wires 8 to cover the magnets 10 so that the latter are located between the free vertical ends of the L-shaped magic pipelines 8 with a clearly fixed guide lugs 12 with minimum gaps 5; The working gaps 9 are at a distance H 0.7-0.8 t from the magnets 10 which was optimal in terms of decreasing stray fields.

A device for induction heating of cylindrical ferromagnetic blanks works as follows,

. The inductor 1 is supplied — a voltage of a high frequency — and heating begins. The drive of the transporting mechanism 2 is turned on. In this case, the L-shaped magnetic cores 8, mounted on roller chains 4 with a certain shaky position, are set in motion. In the horizontal section of roller chains 4, cylindrical ferromagnetic blanks 3 are placed into the working gaps 9 of the magnetic cores 8. As soon as the L-shaped magnetic cores 8 pass to the side of the poles 11 horizontally installed linear magnets 10, magnetic forces occur in the working gaps 9 The guiding workpieces 3 to the working clearances 9, and the frictional forces that are formed at the same time, push through the inductor 1 all of which are located forward in the direction of movement of the workpieces 3.

Claims (2)

The proposed device for induction heating of cylindrical ferromagnetic blanks, as compared with the known ones, possesses stability and stability in magnitude of useful pushing vultures; reduced drive power consumption and reduced wear of the transport mechanism; a decrease in the scattering fields and an improvement in the energy characteristics of the use of magnets, as a result of which a reduction in the consumption of expensive magnetically hard materials is achieved. Claim 1. Device for induction heating of cylindrical ferromagnetic blanks, comprising an inductor, a transport mechanism with two roller chains and magnetic conductors fixed to them with working gaps between them, as well as fixed magnets, which ensure the stability of the magnitude of the pushing billet forces. 8 4 6 magnigoprovodov made L-shaped, the ends of their bent ends are located opposite to the image of working gaps, and the magnets are located between the magnetic cores with gaps. 2. Device pop. l, differing from the fact that, in order to ensure. A fixed gap between the magnets and the magnetic cores, it is provided with a guide placed between the magnetic conductors with a protrusion on which the magnets are mounted. Sources of information taken into account when exported 1. Patent of France No. 1419989, cl. From 21D 1965.