SU930756A1 - Method of regulating temperature of ferromagnetic blanks in heating plant - Google Patents

Description

(54) METHOD FOR REGULATING THE TEMPERATURE OF THE FERROMAGNETIC BILLETS IN THE HEATING UNIT INSTALLATION

I

The invention relates to electrothermal and j can be used in the metallurgical, engineering and other areas, using methodological heating installations, for example, induction for continuous heating of ferromagnetic blanks to temperatures exceeding the temperature of magnetic transformations.

The known method of heating ferromagnetic blanks in an induction heating unit, which supplies voltage to a heater (inductor) from the source, moves the blanks along the heater, controls the intermediate temperature of the blanks in the zone of magnetic transformations, generates a mismatch signal and regulates the final temperature of the output from setting the workpiece by changing the power of the heater 1.

The disadvantage of this method is that the intermediate temperature is controlled with the help of temperature sensors having a large methodological difference and sensitive to the composition of the environment.

This reduces the accuracy of maintaining the final temperature of the workpieces and the reliability of the installation.

The closest in technical essence is a method for controlling the temperature of ferromagnetic blanks in a heating unit, the temperature of which is controlled by measuring the magnetic properties of the blank, compare this signal with a given proportional to the Curie temperature and, in the presence of an error signal, change the power of the heater to eliminate this signal 2.

Claims (2)

This method has higher accuracy and sensitivity, although it is not applicable to methodical furnaces. In methodical furnaces, it is necessary not spatial but spatial definition of the zone of magnetic transformations. In this case, the measurement of the magnetic properties in one place of the workpiece does not give an unambiguous answer about the temperature, since after heating above the Curie point in the whole range of temperatures, the magnetic properties do not change. 39 The purpose of the invention is to improve the accuracy of temperature control in furnaces. To achieve this goal, measurements of the magnetic properties of the workpiece are carried out at two points before and after the zone of magnetization transformations of the workpiece, and each of these signals is compared with a given signal. The drawing shows a block diagram of an inductive methodical heating installation. The installation comprises an inductor 1, outside of which there are two inductive arcs 2 and 3, the outputs of which are connected to the inputs of the regulator 4, which is connected to the regulated power supply 5. The installation works as follows. In steady-state operation with a constant rate of advancement of the workpieces, there is a rigid relationship between the temperature of the workpiece, the magnetic permeability in the zone of magnetic transformations and the voltage or power | The zone of magnetic transformations is between sensors 2 and 3. The signal from 2 is equal to 10 or more units, respectively, of magnetic permeability, and from sensor 3 is equal to one. This combination of signals is nominal, i.e. no error signal. When any parameter deviates (initial temperature, workpiece dimensions, speed, voltage on the inductor, structure of the workpiece material, etc.), the temperature of the workpiece changes along the length of the heater and the position, coordinates of the magnetic transformation zones (Curie point) and, consequently, the magnetic permeability in the controlled area. In the case of underheating of the blanks, the Curie point is displaced to the right of sensor 3. In this case, both sensors produce almost equal networks, for example, 10 or more units. This combination of signals at the input of the regulator differs from the nominal one, this difference and is caused by the error signal. In this case, the regulator will increase the power at the inductor until the Curie point is between sensors 2 and 3. If the workpieces overheat, the Curie point is shifted to the left of sensor 2. In this case, both sensors also give odd signals equal to one. This combination of signals at the input of controller 4 differs from the nominal one and controller 4 decreases: the power of the inductor. The change in the power of the inductor is carried out by changing the current, the voltage of the inductor, the frequency of the current. As the error signal, you can use the deviation of the signal of both sensors from the nominal, the sum of the signals of both sensors, once the product. The high accuracy in controlling the position of the Curie point and, consequently, the final temperature of the workpiece is ensured by a large change in the error signal, from one to tens or hundreds of units. The method can be implemented on methodical heating installations with a different type of heating: resistive, arc, flame, etc. Claims The method of controlling the temperature of ferromagnetic blanks in a heating installation, at which the temperature of the blank is controlled by measuring the magnetic properties of the blank, compares this signal to a given one proportional to the Curie temperature and, in the presence of a mismatch signal, changes the power of the heater to eliminate this signal, in order to increase the accuracy of temperature control in methodological installations, the measurement of the magnetic properties of the workpiece is carried out at two points before and after the zone of magnetic transitions workpiece, and a predetermined signal compares each of these signals. Sources of information taken into account during the examination 1. USSR author's certificate number 725277, cl. H 05 B 5/04, 1978. 2. Sibiov A.V. Electric Furnaces, 1934, p. 153.