SU1767709A1 - Method for electric mode control of arc steel-making furnace - Google Patents

Abstract

The essence of the invention: make alternate adjustment of the power of each phase, determining the numbers of the dead and wild phases, respectively. After determining the number of the dead phase, the settings of the regulators of other phases are reduced, the control actions between the current regulators of the second, third and first phases, respectively, of the first, second and third dead phases, respectively. After determining the number of the wild phase, the current settings of the two other phases are adjusted, and for the detected first and second liters of the third wild phases, the phase current settings in the same sequence are reduced and the current settings of the regulators are increased, respectively, in the third and first phases.

Description

The invention relates to electrothermal conditions, and specifically to methods for influencing the electric mode of arc-type steel-making electric furnaces.

A known regulator (; m, avt.S. No. 639160, class H 05 B 7/148, 1977) implements a method for controlling the power of an arc multiphase electric furnace, consisting in controlling the position of an electrode according to the indications of the electrical mode of the phases under the condition of signal to move.

The disadvantage of this method is the low quality of regulatory actions and increased power consumption due to the autonomous, independent nature of the formation of controls for the displacement of electrodes in phases, not taking into account the sequence in the correction of the phases and the asymmetry of the load in phases.

Also known is the power regulator of an electric arc furnace (see auth.S. no. 559471, class H 05 B 7/148, 1975), which implements a method for adjusting the power of each phase according to the deviations of its measured electrical indicators from the given values.

A disadvantage of the known method is also uncontrollable energy waste due to the independent nature of the formation of effects on the electrical modes of each phase without taking into account their mutual interaction and the necessary redistribution due to the asymmetry of the phase load.

Closest to the proposed method (see auth.St. No. 383229, CL H 05 B 7/148, 1970) automatic control of electric furnaces, consisting in that it ignites arcs, controls the stages of melting, measures the depth of the electrodes and changes These are the controller settings.

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A disadvantage of the known method is the excessive consumption of electricity due to limited possibilities in the formation of impacts on each phase to create conditions for rationalization of their electrical modes, since a multivariate analysis of the electrical state of each phase is not carried out to select the optimal control law for each phase with the necessary redistribution of impacts —Lorers, and also do not take into account the operating conditions of the furnace at various stages of melting.

The purpose of the invention is to reduce the specific energy consumption by optimizing the control.

To achieve the goal of the proposed method of controlling the electric mode of an electric steel arc furnace containing a motion controller for each electrode, arc is ignited, melting stages are monitored, electrode depths are measured, and the settings for the melting of wells are changed The phases with the largest and smallest depths of the electrodes are determined, and in the phase with the greatest depth, the setpoint of the regulator is reduced, and in the phase with the smallest is increased.

The essence of the proposed method is as follows.

The basis of the proposed method is the choice of the input melting of the mode of influence on the current settings of the electrode position regulators to create rational electrical conditions for controlling the phases of interaction of the electrode with the metal.

In this case, the control of the electric mode of the phases according to the proposed method is directly related to a change in the position of the electrodes, i.e. with the values of their immersion in a liquid bath.

A change in the electric modes occurs for phases with the most pronounced changes in the position of the electrodes, i.e. for the phases with the greatest and the smallest depths of the electrodes in the metal bath at the stage of the active smelting process - the penetration of wells.

For this, according to the proposed method, the values of the depths of the electrodes of each phase are measured, the phases with the largest and the least depth are determined from them.

Then, after detecting the phases with the largest and smallest measured depths of the electrodes, these phases are influenced by their electrical modes (current settings of the regulators) in accordance with the measurement results.

At the same time, for the phase with the greatest deepening of the electrodes, the setpoint of the regulator currents is reduced, and for the phase with the smallest depth, respectively, they increase.

Such is the sequence of actions of the proposed method for creating economical laws of rational control of the electrical regimes of the phases, with the selection for regulating the most preferable ones among them by comparing the indicators characterizing them.

Therefore, a set of additional techniques of the proposed method allows to organize a completely different sequence of actions, in comparison with the known solutions, to control the phase modes, i.e. according to the proposed method, a logical system of monitoring and comparing the indicators of the state of the phases and a sample of a rational path was set up by adjusting the current settings of their controllers with the redistribution of control actions between the phases according to the above schemes, which ensures a positive effect.

Claims (1)

Invention Formula The method of controlling the electric mode of a steel-making arc furnace, containing for each electrode a displacement controller, at which arcs are ignited, controlling the melting stages, measuring the depth of the electrodes, and changing the settings of the regulators, characterized in order to reduce the specific energy consumption by optimizing control, at the stage of penetration of wells, phases with the largest and smallest depths of the electrodes are determined; in the phase with the greatest depth, the setpoint of the regulator is reduced, and in phase with the names of PWM is increased.