SU1731830A1 - Method and apparatus for heat treatment of strip from amorphous magnetically-soft alloys - Google Patents

Abstract

The invention relates to metallurgy. The purpose of the invention is to increase the productivity and quality of processing by increasing the initial magnetic permeability of the tape while maintaining its technological plasticity. The device contains a horizontal muffle pulling electric furnace 1, a cooling unit 2 with a source 3 of a magnetic field, a heating unit 4, cantilever located at the output end of the electric furnace 1, a tape drive mechanism 5, a device 7 for winding the processed tape and a device 11 for unwinding the tape 12. Fast the cooling of the latter takes place in a cooling unit 2 in a perpendicular magnetic field. The invention allows to increase the static and dynamic magnetic properties of the tape, to avoid embrittlement and surface oxidation. 2 sp.f-ly, 1 ill., 1 tab. (Ls

Description

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The invention relates to metallurgy, to methods of thermomagnetic processing, in particular, an amorphous ribbon made of magnet magnet alloys with zero magnetostriction, used in radio electronics, automation and computer technology.

Obtaining the maximum properties of amorphous magnet soft alloys (AMMS) is due to their chemical composition and optimal heat treatment conditions.

There are several methods of thermal and thermomagnetic (t / o and TMO) AMMS treatment based on cobalt.

There is a method in accordance with which the subject t / o magnetic circuits are annealed in two stages. The essence of the first stage is that the magnetic cores are heated to a temperature close to the crystallization temperature Tx (T0tzh. 0.98TX), but above the Curie temperature Tc, stand for 3 to 20 minutes, and cool at a rate of at least 100 degrees / sec. The most preferred cooling rate is considered to be above 500 degrees / second in order to prevent magnetic ordering processes. To ensure such a high cooling rate, the magnetic core, fixed on a special clamp, is placed in the coolant immediately after annealing, after which it is annealed in the second stage t / o in the same heating chamber. Annealing temperature Ta of the second stage is 250-300 ° C, holding time 20 min. Such a two-step annealing allows permeability to AMMS with a saturation induction of 0.75 T on the order of 5000 to 10,000 and to maintain these values up to a frequency of 100 kHz.

The disadvantage of this method of t / a is the low productivity and two-stage process, since it can be applied only to small-sized magnetic pipelines to provide the required cooling rates and does not have technological continuity when the furnace switches from one mode of operation to another.

There is a method in which the ribbon from AMMS is annealed in a magnetic field at a temperature less than Tx AMMS and its Tc. To prevent induced magnetic anisotropy, the amorphous ribbon and magnetic field rotate continuously relative to each other. That for obtaining magnetic permeability on the order of 7000-30000 is 400 ° C, a shutter speed of 5-40 minutes, a magnetic field of 5 K e, cooling is in a magnetic field. In addition, amorphous ribbon has the shape of a circle with a diameter of 10 mm, from which a ring with an internal diameter of 6 mm is cut out after TMT. AT

During the annealing process, the AMMS discs rotate in a stationary magnetic field of 5 Ke at a speed of 20 rpm, while the plane of the tape is parallel to the direction of the magnetic field.

The disadvantage of this method is its low productivity due to the limited amount of annealed tape, the loss of the necessary technological

0 plasticity, since at the indicated temperature-time parameters of annealing, the amorphous strip of alloys containing metalloids is highly embrittled. Using this method in industrial

5 scales is limited to one type of magnetic conductor, namely, assembled from rings, and is inapplicable for more common twisted magnetic circuits.

In addition, methods are known for which short-term annealing is proposed, while a sharp decrease in the annealing time at a sufficiently high heating rate makes it possible to significantly increase the annealing temperature Ta. when at

5 ordinary annealing crystallization processes are.

The closest in technical essence and the achieved result is the TMT method, which includes short-term pulse heating and cooling of the tape. According to a known method, the AMMS tape sections are heated by passing a short current pulse. Upon termination of the current, the tape is cooled in a liquid

5 nitrogen. At the moment of impact of a pulse, a magnetic field arises, directed perpendicular to the axis of the tape.

Using the known method allows to obtain the initial magnetic

0, the permeability is on the order of 17,000 at a frequency of 1 kHz, and the material remains ductile. TMT is carried out by means of a special device with built-in tokovodami.

5 However, the known method is not technologically advanced, since during heating by current pulses the magnetic field affects the tape only at the moment when the pulse passes through it, while cooling occurs without a magnetic field, therefore the magnetic properties increase slightly. In addition, due to the limited size of the annealing tape, the known method is unproductive and not applicable in

5 cases when it is necessary to anneal a long tape.

A device for thermomagnetic treatment of twisted magnetic cores from AMMS, consisting of a tubular heater, made in the form of short-circuited

the turn of the transformer secondary winding; and the solenoid, which is the primary winding of the transformer.

The main disadvantage of the design of this device is the impossibility of accelerated cooling in the magnetic field of the processed magnetic cores and low productivity.

A known unit for the heat treatment of a cold-rolled strip, comprising two horizontal muffle stretching furnaces for quenching and tempering, a cooling unit, a tape drive mechanism and a winding device.

The disadvantage of this unit is the absence of a magnetic field source, which prevents the AMMS from thermomagnetic processing, and this unit does not allow accelerated cooling of the tape.

The aim of the invention is to increase the magnetic permeability while maintaining the technological plasticity of the processed AMMS tape.

This goal is achieved by the fact that with the method of heat treatment of a tape of amorphous magnetically soft alloys with zero magnetostriction, including heating and cooling the tape, the latter is continuously moved during processing and after heating additionally heated to a temperature above the Curie point of the alloy field perpendicular to the plane of the tape.

A device for heat treatment of a strip of amorphous magnetically soft alloys with zero magnetostriction, containing a horizontal muffle extended electric furnace, a cooling unit, tape and an accessory mechanism, is equipped with a heater unit located at the output end of the electric furnace and a magnetic field source installed in the cooling unit.

The results of studies of changes in magnetic properties and the degree of technological plasticity show that the temperature of short-term heating depends on Tx of the annealed AMMS. The heating temperature is limited by the onset of the crystallization process, which destroys the amorphous structure of the material - the tape becomes brittle and has low magnetic permeability. Increasing the heating temperature makes it necessary to increase the speed of the tape to prevent embrittlement, however, with a noticeable increase in speed, the tape does not have time to warm up and its magnetic properties remain at the level of the non-heat-treated tape.

The circumstance is explained by the fact that they do not have time to completely go through the processes of relaxation of quenching stresses. Lowering the heating temperature requires low

speeds of movement of the tape, while the stay of the tape in the furnace increases, which leads to the development of crystallization processes.

When the thickness of the annealing tape is changed, the speed of its movement is also changed, while the heating temperature remains unchanged. After short-term heating, it is necessary to carry out additional heating of the tape to the Tc of the alloy in order to prevent the process of stabilization of the domain boundaries by cooling in a magnetic field perpendicular to the plane of the tape. Since the process of stabilization of domain boundaries is a reversible process, the main requirement for

0 heating is the temperature, and the implementation of heating is not related to the temperature-time parameters of the preceding short-term heating. However, the preheating temperature affects the temperature briefly 5 temporary heating.

Cooling in a magnetic field, perpendicular to the plane of the tape, is necessary to prevent stabilization of the domain boundaries and the formation of a domain structure that provides high values of magnetic permeability. In order to magnetize the tape perpendicular to the plane, a magnetic field of 15 ke is needed due to the large demagnetizing factor of the tape.

In the case of AMMS processing with a TC of 250 ° C or less, the cooling condition in a magnetic field is not mandatory.

Short-term heating and heating

0 AMMS tape with subsequent cooling in a magnetic field perpendicular to the plane of the tape, is carried out continuously, thereby achieving high performance of the proposed method of TMT, C

Taking into account the time of filling the tape with the proposed method and fixing it according to the known performance of the proposed method of TMT is higher than the known one.

The drawing shows the proposed device.

A device for thermomagnetic processing of a strip of amorphous soft magnetic alloys contains a horizontal muffle stretching furnace 1 resistance block

5 2 cooling with a source 3 of a magnetic field, a heating unit 4, a tape mechanism 5 with an electric drive 6 and a device 7 for winding the treated tape, a thermocouple 8-10 and a device 11 for unwinding the tape 12 being processed.

The device works as follows. An AMMS tape 12 from an unwinding device 11 is fed into a muffle stretch resistance furnace 1 heated to a temperature above the crystallization temperature Tx of the alloy of the tape being processed, then the tape passes through the heating block 4, where the temperature of the tape being processed is maintained not lower than the CurieTc temperature of the alloy, after whereby the tape enters the cooling unit 2 with the source 3 of the magnetic field, where the processable tape 12 is rapidly cooled in a perpendicular magnetic field.

The technological parameters of the TMT are selected in such a way that the tape heats up to a predetermined temperature of less than 5 seconds during the passage of the furnace, which allows the quenching stresses in the tape to be removed without its embrittlement during the annealing process. The temperature in the furnace zone is monitored and controlled by signals from thermocouples 9 and 10.

The tape heating unit is necessary so that before the tape enters the cooling unit, equipped with a magnetic field source, its temperature is not lower than the Curie temperature Tc of the alloy of which the tape is made. This makes it possible to avoid the effect of stabilization of the domain boundaries during accelerated cooling of the ribbon. The temperature in the heating unit is monitored and controlled by signals from thermocouple 8. In addition, the cooling of the tape in a magnetic field perpendicular to its plane provides the favorable domain structure necessary for obtaining high magnetic properties.

Thus, the presence in the proposed device of a preheating unit, a cantilever located at the end of a stretching furnace, and a cooling unit with a magnetic field source, allows a significant improvement in the technological parameters of the TMT, which significantly improves the static and dynamic magnetic properties of the treated tape, avoiding embrittlement and surface oxidation of the processed ribbon from AMMS due to uniform and high-speed heating of the ribbon along the length of the working zone of the furnace, increasing the accuracy of the temperature mode of the TMT.

PRI me R. At the experimental laboratory facility, TMC AMMS marks 84КХСР, 84КСР, 86КГСР are carried out.

For each grade of alloy, the required temperature is established in the zone of the continuous muffle furnace and in the preheating unit, which is cantilevered at the furnace end.

The magnetic properties of the tape and the relative deformation of the fracture after processing in the proposed and well-known device are presented in the table.

The relative deformation of the destruction of the tape after annealing is determined by a known method.

As can be seen from the table, TMO AMMS in a continuous furnace with a preheating unit and a cooling unit in a magnetic field allows to obtain a high level of magnetic properties in combination with high technological plasticity, which is impossible with the known heat treatment methods. The indicated advantage of processing the tape in the proposed device makes it possible to cut, bend, grind the tape during subsequent manufacturing operations for manufacturing magnetic cores.

Claims (2)

1. Method of heat treatment of a tape made of amorphous magnet soft alloys Zero magnetostriction, including heating and cooling the tape, characterized in that, in order to improve the quality of processing by increasing the initial magnetic permeability while maintaining the technological plasticity of the alloy, the tape is continuously moved during processing and further heated after heating to a temperature above the Curie point of the alloy, and cooling in a magnetic field perpendicular to the plane of the tape. 2. A device for heat treatment of a strip of amorphous magnetically soft alloys with zero magnetostriction, containing a horizontal muffle stretching electric furnace, a cooling unit, tape-cutting and accessory mechanisms, characterized in that, in order to improve the quality of processing by increasing the magnetic permeability while maintaining technological plasticity alloy, the device is provided with a preheating unit located at the outlet end of the electric furnace and a magnetic field source installed in the cooling unit.