RU2478935C1 - Method of determining curie point of high-temperature ferromagnetic metal alloys - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: disclosed method is realised using an apparatus for photometric determination of kinematic viscosity of an alloy. An alloy sample is placed in a crucible on a twisted elastic thread inside an electric heater of a vertical electric furnace; a mirror attached to said elastic thread is illuminated and the light beam path is determined by a photodetector. Further, the electric heater is turned on and parameters of the output signal of the photodetector are determined. Heating of the sample is continued and the first change in the output signal of the photodetector during the sample heating process is detected. Temperature at which change in the output signal began is recorded, indicating the Curie point of the sample.

EFFECT: high information content and accuracy of data of thermal dependencies of physical properties of high-temperature ferromagnetic metal alloys based on Fe, Co and Ni.

Description

The proposed method relates to technical physics, namely to methods for monitoring and measuring the physical properties of substances. It is intended to indicate the Curie point during photometric measurements of torsional vibrations of a crucible with a melt when determining the temperature dependence of the viscosity of high-temperature metal ferromagnets - alloys based on Fe, Co, Ni. Additional areas of application are metallurgy, in particular, the development of technology for forming the nanostructure parameters of amorphizing alloys for magnetic cores, as well as training university students, with an additional demonstration of the thermal dependence of various physical properties of the alloy.

It is known that metallic ferromagnets - alloys based on Fe, Co, Ni - lose their magnetic properties when heated and exceeding the temperature t ° _k , called the Curie point for ferromagnets, and turn into paramagnets. At the Curie point t ° _k , a series of abrupt changes in the parameters characterizing the state of the alloy under study are observed, in particular, a change in its magnetic susceptibility, a jump in the heat capacity of this alloy, a sharp increase in the magnetocaloric effect, which consists in a functional relationship between the magnetization of the alloy and changes in its temperature, and t .d. - see A.I. Akhiezer. General physics. Electrical and magnetic phenomena: a reference guide. Kiev: Naukova Dumka, 1981, p. 353, 372, fig. 13.1-13.3; R. Bozort. Ferromagnetism. Per. from English M., IL, 1956, p. 573, 574, Fig. 721. Therefore, in some cases, even an indication of t ° _k , and not just an accurate measurement of t ° _k , may be necessary and sufficient. For example, it is advisable in workshop conditions for a group assessment of the thermal dependencies of various physical properties, for example, kinematic viscosity and magnetic characteristics of produced or designed alloys for the electrical industry, used, in particular, to create magnetic cores. Knowledge of the Curie point t ° _{k is} necessary to optimize the technological modes of melting of metallic ferromagnetic alloys, their cooling, quenching, etc., since, for example, rapid cooling of the alloy below this point affects the speed of the directed atomic ordering process.

It is known that the determination of the Curie point t ° _k can be carried out by using various thermomagnetic methods based on the use of electromagnetic, thermal, mechanical effects and, accordingly, highly specialized installations to study the relationship of the magnetic characteristics of the material and its temperature near the Curie point t ° _k - cm R. Bozort. Ferromagnetism. Per. from English M., IL, 1956, p. 573, 574, Fig. 721 - analogue.

The disadvantage of these methods is the need to use specialized facilities in experiments that do not allow obtaining, in addition to data on the Curie point t ° _k , group data on several properties of the alloy under study, significantly exceeding the temperature of the Curie point t ° _k and reflecting its high-temperature characteristics, for example, kinematic fluid viscosity, which limits information about these alloys. In addition, to conduct research on obtaining a complex of group temperature characteristics of other physical properties of the studied alloys, for example, viscosity, additional equipment is required, which makes experiments more expensive, requires highly qualified staff and requires additional time to conduct new experiments.

The thermomagnetic method for determining the Curie point t ° _{k of} metal high-temperature ferromagnetic alloys is known, based on monitoring the temperature dependence of the parameters of a heated sample of a high-temperature ferromagnetic metal alloy when it interacts with a magnetic field - see Y. Starodubtsev. Soft magnetic materials. Encyclopedic reference dictionary. M .: Technosphere, 2011, p.440, Fig. T1 - prototype. The method is based on measuring the temperature dependence of the initial magnetic permeability of the alloys.

The disadvantage of the prototype is the inability to determine other, non-magnetic, properties of this alloy, in particular, reflecting its high temperature (1500 ° C-2000 ° C) properties, for example, the kinematic viscosity in the fluid state, and the temperature range of the prototype slightly exceeds the Curie point. This does not allow obtaining additional information on the high-temperature thermal dependence of the nonmagnetic physical properties of alloys, for example, viscosity, when the study, by definition, requires a fluid state of the melt and its temperature is significantly higher than the Curie point t ° _k . In addition, the simplification, acceleration and cheapening of experiments, as well as improving the quality of the educational process, for example, on the study of group thermal dependencies of the physical properties of high-temperature metal ferromagnetic alloys during the training of students, are not provided.

The objective of the proposed method is to expand the functionality of devices designed to study the thermal dependence of the physical properties of high-temperature metal ferromagnets - alloys based on Fe, Co, Ni, to obtain additional information on the thermal dependence of their properties, simplification, acceleration and cheapening of experiments, as well as improving the quality of the learning process when teaching university students.

To solve the problem, a method is proposed for determining the Curie point of metallic high-temperature ferromagnetic alloys.

In the method for determining the Curie point of metallic high-temperature ferromagnetic alloys, based on monitoring the temperature dependence of the parameters of a heated sample of a metallic high-temperature ferromagnetic alloy during its interaction with a magnetic field, a photometric determination of the kinematic viscosity of the alloy is used to determine the Curie point, while the sample of the heated alloy is placed in a crucible, vertical vacuum suspended on a twisted elastic thread inside an electric heater electric furnace, illuminate with a light beam from a light source a mirror mounted on an elastic filament, determine by direct measurement with a photodetector the path of the reflected light beam that is adequate to the torsional vibrations of the crucible with this sample, include an electric heater, determine the parameters of the output signal of the photodetector, and first record the parameters of the output signal of the photodetector, established after the end of transient processes at the beginning of the procedure for heating a sample of metallic high-temperature ferromagnetic alloy, then continue heating this sample, record the first change in the parameters of the output signal of the photodetector, which occurs during the heating of the sample, record the temperature value corresponding to the beginning of the change in the parameters of the output signal of the photodetector, after which it is concluded that this temperature indicates the Curie point of the measured sample of the metal high-temperature ferromagnetic alloy.

Distinctive features of the proposed technical solution - the method - provide the expansion of the functionality of devices designed to study the temperature dependences of the physical properties of high-temperature metal ferromagnets - alloys based on Fe, Co, Ni, to obtain additional information about the temperature dependence of their properties, simplification, acceleration and cheapening of experiments, as well as improving the quality of the educational process when teaching university students.

The method for determining the Curie point t ° k of metal high-temperature ferromagnetic alloys is as follows.

The experiment is carried out by using a computerized photometric setup to determine the kinematic viscosity of high temperature melts by means of a vertical vacuum furnace - see US Pat. RF №2349898. A sample weighing 10-30 g is placed in a cylindrical crucible made of beryllium ceramic with a diameter of 10-15 mm and a volume of several cm3, which is suspended on an elastic twisted nichrome thread about 0.8 m long coaxially in a molybdenum cylindrical electric heater 200 mm long with a diameter of 42 mm . At the top of the elastic thread there is an electromagnetic device for twisting the elastic thread, similar to the stator and rotor of the micromotor, a mirror is mounted 0.3 m below to reflect the light beam from the light source. Electric heater - low voltage (6 V), electric current power 15-18 kVA, 50 Hz. Temperature measurement, like photometry, is carried out with a thermocouple with an error of +/- 3 ° C continuously throughout the experiment. The electric furnace is vacuumized, after which the reflected light beam is recorded - a “bunny” at the input of the photo-measuring device with two TSL250 integrated photosensors at the input. When moving, the beam subsequently hits the photosensors, the output signal of which is sent to a computer, where the amplitude-time characteristics of this signal are determined, by which the attenuation of the elastic rotational vibrations of the crucible with the sample is calculated, which is connected by known formulas with the measured properties of the alloy - see US Pat. RF №2349898.

Then the electric heater is turned on, after which the position of the reflected light beam changes due to the fact that the electric heater creates a powerful magnetic field. In this case, the crucible with the alloy sample changes its position, is attracted to the wall of the electric heater, comes into contact with it and ceases to oscillate freely inside the electric heater. Transient time, i.e. the time interval from turning on the electric heater and, accordingly, from some steady-state value of the parameters of the output signal of the photodetector, to the contact of the crucible with the wall of the electric heater and, accordingly, to the appearance of a new steady-state value of these parameters, is almost unpredictable and equal to units of seconds. In this case, the alloy sample is heated, its speed is approximately 100 ° C / min, and the average time for heating a metal ferromagnetic alloy sample to a fluid state is on average 10-15 minutes. For an alloy sample weighing approximately 25 g, the thermal inertia of its heating is sufficiently large and amounts to tens of seconds. In this case, it is very difficult to describe multifactor thermomagnetic phenomena, in particular, to determine the temperature gradient in a sample, taking into account the characteristics of the magnetic field of an electric heater, and the unpredictability of the location of a crucible with an alloy sample in this field. That is why the values of the parameters of the output signal of the photodetector, which was established after the end of transient processes at the beginning of the heating of the ferromagnetic alloy sample, are recorded as initial. Then the heating of this sample is continued and the change in the output signal of the photodetector that occurs during the heating is recorded. For high-temperature alloys based on Fe, Co, Ni, this change in parameters occurs a few minutes after the electric heater is turned on. When the Curie point t ° _{k of a} given alloy reaches its temperature with increasing temperature, its ferromagnetic characteristics become paramagnetic, and the effect of the magnetic field of the electric heater on the alloy decreases. The crucible with the alloy sample ceases to come into contact with the wall of the electric heater and occupies the initial coaxial position in it, which is recorded as a change in the trajectory of the reflected light beam and a corresponding change in the amplitude-time values of the output signal of the photodetector. At this point, the value of the controlled temperature is noted, equal or insignificant, by 10-20 ° C, theoretically exceeding the Curie point t ° _k due to thermal inertia, which is acceptable for practical use, and conclude that this temperature indicates the Curie point t ° _{k of the} measured alloy. From this temperature, the automation of the installation includes an electromagnetic device for twisting the elastic thread, after which the experiment on measuring kinematic viscosity is continued.

As an example, the table shows the values of the Curie point t ° _k experimentally obtained by the authors for Fe-based alloys (several types of rail steel) and Co (with different additives) at the above-described installation in the laboratory of the Research Center for Metallic Fluid Physics of UrFU, Yekaterinburg.

Table Alloy t ° _k , ° C (+/- 20 ° C) one Rail steel B511 780 2 H5464 rail steel 630 3 Rail steel H5453 790 four Co - alloy with additives B - 6%, Si - 8% 920 5 Co - alloy with additives B - 4%, Si - 2% first alloy 970 6 Co - alloy with additives B - 4%, Si - 2% second alloy 940 7 Co - alloy with additives B - 6%, Si - 4% 920 8 Co - alloy with additives B - 4% 910

An analysis of the table shows that the Curie point values obtained for alloys are t ° _k , in comparison with reference values for pure metals: t ° _k (Fe) = 770 ° C and t ° _k (Co) = 1130 ° C - see above P .Bozort ... p.570, tab. 84, correspond to physical ideas about the properties of these alloys.

Since Curie points T ° _k were obtained without the use of special facilities together with data on the kinematic viscosity of the alloy, the proposed method provides an extension of the functionality of devices designed to study the physical properties of ferromagnets - metals based on Fe, Co, Ni, for example, viscosity, at high temperatures , obtaining additional information on the temperature dependence of the properties of the studied metallic high-temperature ferromagnets, simplification, acceleration and cheapening of experiments, as well as increasing of the quality of the educational process in teaching university students.

The proposed technical solution containing the above set of distinctive features, as well as a set of restrictive and distinctive features are not identified in the prior art, which, when the above result is achieved, allows us to consider the proposed solution as inventive. This solution provides a technical result - expanding the functionality of devices designed to study the temperature dependences of the physical properties of high-temperature metal ferromagnets - alloys based on Fe, Co, Ni, obtaining additional information about the temperature dependence of their properties, simplifying, accelerating and cheapening experiments, as well as improving the quality of training process when teaching university students.

Claims (1)

A method for determining the Curie point of metallic high-temperature ferromagnetic alloys, based on monitoring the temperature dependence of the parameters of a heated sample of a metallic high-temperature ferromagnetic alloy when it interacts with a magnetic field, characterized in that the photometric determination of the kinematic viscosity of the alloy is used to determine the Curie point, and a sample of the heated alloy is placed in a crucible suspended on a spinning elastic thread inside an electric heater in of a vertical evacuated electric furnace, a mirror mounted on an elastic filament is illuminated with a light beam from a light source, the path of the reflected light beam adequate to the torsional vibrations of the crucible with this sample is determined by direct measurements with a photodetector, the electric heater is turned on, the output signal parameters of the photodetector are determined, and the parameters are recorded first the output signal of the photodetector, established after the end of transient processes at the beginning of the heating procedure and the sample of the metal high-temperature ferromagnetic alloy, then continue heating this sample, register the first change in the parameters of the output signal of the photodetector, which occurs during the heating of the sample, record the temperature value corresponding to the beginning of the change in the parameters of the output signal of the photodetector, after which it is concluded that this temperature indicates the Curie point of the measured sample of the metal high-temperature ferromagnetic alloy.