RU121587U1 - DEVICE FOR EXPRESS DIAGNOSTICS OF HOMOGENEITY OF HIGH-TEMPERATURE METAL MELTS - Google Patents

Abstract

A device for express diagnostics of the homogeneity of high-temperature metal melts, containing a laboratory photometric viscometer installation, a computer with a memory device, an alarm unit, characterized in that a comparison device and a communication line are inserted into it, one of the inputs of the comparison device is connected to the first port of the computer, the other input and the output of the comparator are connected to the second and third ports of the computer, respectively, and the communication line is connected between the fourth port of the computer and the signaling unit.

Description

The proposed utility model relates to technical physics, namely, to methods for measuring the physical parameters of substances and is intended for rapid diagnostics of the uniformity of high-temperature metal melts based on Fe, Co, Ni in a workshop by non-contact determination of the viscosity of these melts by measuring the damping parameters of torsional vibrations crucible with an alloy sample in a measuring installation. In addition, the scope is metallurgical production, in particular, the correction of technological schemes for the formation of specified melt parameters, for example, for use in magnetic cores, by optimizing the structural features of the melt.

Measurement of the physicochemical parameters of metallic liquids, melts and slags, in particular, viscometry - determination of the viscosity v of high-temperature melts, in the amount of several cm ³ , makes it possible to give corrective recommendations at enterprises for obtaining alloys with given uniform or equilibrium characteristics. At the same time, the prepared melt should have no traces of history, it should be in equilibrium, i.e. under these conditions, as homogeneous as possible - see B. A. Baum et al. "Equilibrium and nonequilibrium states of metal melts" - In the book. "Fundamental studies of the physical chemistry of metal melts." M., Information Center "Academic Book", 2002, p.216. This implies the need to obtain uniformity of the melt in the melting unit. It should be noted that the kinematic viscosity ν of metal melts is a structurally sensitive property that can be used to detect structural changes in the form of hysteresis or anomalous kinks in the temperature dependences (polytherms) of viscosity ν = F (T °). Therefore, the use of devices for viscometry for thermo-time studies of viscosity ν - depending on temperature T ° and time t, allows us to judge the homogeneity of multicomponent melts based on Fe, Co, Ni.

Viscosity polytherms ν = F (T °) contain characteristic critical temperature points and hysteretic characteristics of the heating-cooling cycle. However, for high-temperature - + 1200 ° C and more, melts, few devices for viscometry can be used in practice. In particular, these are photometric devices for measuring the amplitudes of damped vibrations A _i , damping decrement δ = ln (A _i / A _{i + 1} ), time values t _i , number n _{i of} torsional vibrations of a crucible with a melt when heating and cooling a melt. Repeatedly repeated (dozens of times in one experiment) procedure is spinning a crucible with a melt suspended on an elastic thread and measuring the deviations of the reflected light beam, i.e. amplitude-time parameters of damped torsional vibrations, is typical for the above devices for measuring the viscosity of v melts. In this case, the number n, the amplitudes A _{i of the} damped oscillations are determined to determine the damping decrement δ _i at points i of the temperature range from several hundred degrees to temperatures exceeding the critical T _k . The characteristic points of the temperature range are the melting points T _PL , hysteresis T _g and critical T _to . The value of the damping decrement δ _i and viscosity ν, primarily at these points, determined from the temperature dependences - polytherm, provides the necessary information about the melt. If the behavior of viscosity polytherms ν = F (T °) is known for a particular alloy previously studied in the laboratory, hysteresis and its temperature T _{g are} detected, then it is advisable to control whether or not the melt has transferred to a new, more uniform state.

A photometric device is known for determining the viscosity ν by recording the amplitude-time parameters of the trajectory of a light beam reflected from a mirror mounted on a twisted elastic filament, on which a crucible with a melt is suspended, and, ultimately, measuring the damping parameters of torsional vibrations (and calculating them δ) a crucible with a melt that occurs after turning off the process of forced twisting of the elastic thread at a certain angle. In this case, the calculated value of the damping decrement δ is used, for which the amplitudes of the damped oscillations A _n and the number of oscillations n between them are measured — see S. I. Filippov et al. “Physicochemical Methods of Investigation of Metallurgical Processes”, M., Metallurgy, 1968 , p. 244, 243, 246 - 251, analogue. The basis for calculating the viscosity ν is its relationship with the damping decrement δ: ν ~ δ ² - see formula XVI-37, the above S.I. Filippov ..., p.248.

The disadvantages of this device are the duration of the experiment with its use - up to 10 hours, the subjectivity of the choice of the number of oscillations n between the measured amplitudes A ₀ and A _n - for example, 8 ... 11 oscillations - see the above S. I. Filippov ..., p. 249, and also measuring parameters in the maximum number of temperature points T _i to build an accurate polytherm. This makes it difficult to carry out rapid diagnostics of homogeneity of high-temperature melt in production conditions - in the workshop near the melting unit.

The prototype of the proposed utility model is a device for studying the kinematic viscosity of melts - see RF Pat. No. 2434222, containing a laboratory photometric viscometric installation, a computer with a storage device, a visual and audible alarm unit. The device is used to determine the viscosity v of a melt during heating and cooling of a sample of this melt by illuminating with a light beam from a light source a mirror located on a twisted elastic thread on which a crucible with a melt is suspended. In this case, the amplitude-time parameters of the trajectory of the light beam reflected from this mirror are recorded, the received signal is measured, from which the damping parameters of the torsional vibrations of the crucible with the melt are determined, and the logarithmic damping decrement δ of the torsional vibrations of the crucible with the melt for subsequent calculation of the kinematic viscosity ν. The disadvantages of the prototype are the lack of a device for comparing the obtained and preliminary data, as well as the communication line between the laboratory device for studying the kinematic viscosity of the melts and the operators of the melting unit. Hence, the prototype does not provide rapid diagnosis of the uniformity of the high-temperature melt directly in the workshop near the melting unit.

The objective of the proposed utility model is to simplify and accelerate the determination of the uniformity of high-temperature metal melts in the workshop production conditions.

To solve this problem, a device is proposed for rapid diagnostics of the uniformity of high-temperature metal melts.

A device for express diagnostics of the uniformity of high-temperature metal melts, containing a laboratory photometric viscometer, a computer with a memory device, an alarm unit, characterized in that a comparison device and a communication line are inserted into it, one of the inputs of the comparison device is connected to the first port of the computer with a memory device , the other input and output of the comparison device are connected to the second and third ports of the computer, respectively, and the communication line is connected between the four th computer port and alarm unit.

The proposed technical solution provides a simplification and multiple acceleration of determining the uniformity of the melts and the ability to adjust the melting conditions in the workshop production conditions.

The proposed utility model is illustrated by drawings:

Figure 1. Block diagram of a measuring complex;

Figure 2. Thermal-time relations with the standard full version of the determination of the viscosity ν of the melt (• - heating, о - cooling);

Figure 3. Thermo-temporal relations in the accelerated version of determining the viscosity ν of the melt.

A device for express diagnostics of the uniformity of high-temperature metal melts comprises a laboratory photometric viscometer installation 1, a computer 2 with a storage device 3, an alarm unit 4, a comparison device 5, a communication line 6.

The device is made on the following elements: laboratory photometric viscometric installation 1 in the form of a device for studying the kinematic viscosity of melts, together with a control and computing personal computer 2 with a storage device 3 and an acoustic and visual alarm unit 4 are a measuring complex made according to the prototype - see US Pat. RF number 2434222. Comparison device 5 optimally represents a computer program built into computer 2 with a memory device 3, or is implemented as a discrete device — a digital comparator in the form of a CMOS chip K561IP2 - see A. Lantsov. and others. "Digital devices on complementary TIR integrated circuits", M., Radio and communications, 1983, p. 33, table 2.1; or TTL - a device for binary comparison of numbers - see Goroshkov B.I. "Elements of electronic devices", M., Radio and communications, 1989, p.140, Fig. 11.16. As the communication line 6, a prefabricated telephone line, cordless cordless telephone or mobile telephone is preferably used.

The device operates as follows.

The device is placed, for example, in a factory laboratory at a steelmaking workshop. In the case of the release of the same alloy, for example, continuously or for several months in a row, the full detailed polytherms of a given melt are first determined by heating and cooling along the entire temperature scale. The presence of hysteresis on the polytherm during cooling reflects an increase in the viscosity ν with respect to the heating polytherm - see Elansky G.N., Elansky D.G. “The structure and properties of metal melts”, M., MGVMI, p.180-181. These results — complete detailed polytherms — are obtained using the measuring complex described above, the values of the results are stored as electrical signals in the memory device 3 of computer 2, and in subsequent experiments, these signals are transmitted through one of the ports of computer 2 to one of the inputs of the comparison device 5 as reference signals , the value of which serves as the standard for this melt.

In the course of melting in the melting unit, a sample of high-temperature melt is taken to check the chemical composition in the factory laboratory. A sample weighing several tens of grams is prepared from the same sample, placed in a crucible, which is suspended in the heating zone of the electric furnace (not shown in the diagram) of the above viscometric measuring apparatus 1. An accelerated experiment to determine the viscosity ν is carried out as quickly as possible, for which the number of temperature points T _{i is} limited to one measurement: i _t = 1, which is produced after the sample is melted near the melting temperature T _pl . Then, by means of computer 2 with storage device 3, the viscosity ν is calculated for an accelerated experiment, an electrical signal reflecting the value of this viscosity ν from one of the ports of computer 2 is fed to the other input of the comparison device 5, which compares this electrical signal with a reference signal reflecting the maximum value of the total temperature dependence of viscosity ν. Figure 2 shows the full thermal-time dependence of 7, 8 of a high-temperature melt, measured over several hours for viscosity ν, obtained earlier from samples of the same alloy grade smelted on the same melting unit in previous melts. In this case, i = 10-15 measurements are made on each measurement (the total time of each measurement is 10-15 minutes) at each temperature T _i with a standard accuracy of +/- 5 ° C. The temperature-time dependence is obtained by determining the viscosity ν with a step - “step” of + 20 ... + 50 ° C, starting from T _PL 9 from the beginning of heating procedure 7 to a temperature Ti exceeding T _to 10 by + 20 ... + 50 ° C. Cooling 8 is continued to a temperature of T _PL 9. In an accelerated experiment, one measurement 11 is made — see FIG. 3, while heating exceeds T _PL 9 by n ° C = + 10 ... + 40 ° C to increase the reliability of achieving complete melting of the sample. In this case, the signal from the output of the comparison device 5, for example, in the form of one or several pulses, enters the computer 2, which, in addition to controlling the measuring unit 1, transmits on-line from one of the ports, via the communication line 6, the signal to the input of the signaling unit 4 , which visually and acoustically signals to the personnel operating the melting unit the presence (or absence) of a new equilibrium homogeneous state of the melt with the possible simultaneous use of visual and audible signaling unit 4 as on the remote control control of the melting unit, and in close proximity to it.

If the result of an accelerated experiment obtained by the proposed utility model showed the viscosity ν of the alloy corresponding to the values of the polytherm cooling branch (with increased viscosity ν), then the melt in the melting unit at the time of sampling transferred to a new equilibrium homogeneous state. If in an accelerated experiment the values of the viscosity ν of the alloy remained at the level of the viscosity ν of the alloy on the heating branch of the full detailed experiment near the melting temperature T _PL , then during the smelting in the melting unit the melt was not brought into a uniform state, i.e. the critical temperature T _{k has} not been reached. Based on this result, it is possible to adjust the melting procedure by heating the melt to a temperature T _k and bring the melt into a homogeneous state directly in the melting unit during melting without crystallizing the alloy and re-melting with heating to the selected critical temperature T _k . The time reduction of the accelerated experiment is multiple and with comparable accuracy is approximately 4 times.

The proposed utility model provides a simplification and multiple acceleration of experiments to determine the uniformity of melts with the possibility of adjusting the melting conditions of high-temperature metal melts in workshop conditions, while monitoring the quality of smelting of this melt during melting.

Claims (1)

A device for express diagnostics of the uniformity of high-temperature metal melts, containing a laboratory photometric viscometer installation, a computer with a memory device, an alarm unit, characterized in that a comparison device and a communication line are inserted into it, one of the inputs of the comparison device is connected to the first port of the computer, another input and the output of the comparison device is connected to the second and third ports of the computer, respectively, and a communication line is connected between the fourth port of the computer and th alarm.