SU1765667A1 - Of electrical automatic control system of electrical condition of six-electrode ore electric arc furnace - Google Patents

Abstract

The method of automatic control of the electric mode of a six-electrode ore-thermal, electro furnace and its implementation system relates to the field of electrometallurgy, primarily to electric furnaces and can be used in the smelting of phosphorus, calcium carbide, copper-nickel and other alloys. The method involves the measurement of active power. The invention relates to the field of electrometallurgy, mainly to electric furnaces, smelting ferroalloys, and can be used in the smelting of phosphorus, calcium carbide, nickel-copper and other alloys. When smelting ferroalloys in the ore-thermal furnace, the magnitude of the input power and its even distribution across phases to a decisive extent determine the full reduction reactions, and the phase gap and active resistance of the electrode-bottom circuit, stabilization of the established resistance by moving the electrode holder phases by switching the voltage levels of the transformers. The system for automatic control of the electric mode of a six-electrode ore-thermal electric furnace includes a sensor and setters of active power of the phases, sensors and setters of resistance of the electrode hearth circuit, comparison units, threshold elements, control units for raising and lowering electrodes, control units for switching voltage steps of transformers, phase sensor and current setting unit, timer, cells, AND, NOT; The invention improves the performance of the electric furnace, reduces the specific consumption of electric power It also increases the reliability of operation of furnace transformers by stabilizing active power, distributing it evenly across phases and switching voltage levels of furnace transformers in nominal modes. 2 sp.f-ly, 1 ill. The effectiveness of the work of the electric furnace unit. The task is to choose, at a given electrical disturbance, the most effective regulating effect — moving the electrode or switching the voltage levels of the furnace transformer (PSN) to stabilize the active power of the furnace while it is evenly distributed over the phases and ensuring the safety of the furnace transformer. At the same time, it is necessary to exclude the error w Ё 1 Os

Description

measuring active power associated with inductive phase interaction.

At present, when controlling the electric mode, the electrode current, impedance or phase power, and furnace power are used as an adjustable parameter. If the controlled parameter deviates from the set value, a control action is introduced — the movement of the electrode or the switching of the voltage level of the furnace transformer.

The disadvantages of these devices are the low accuracy of the regulation of the active power of the furnace, its uneven distribution over the phases and the possibility of failure of the transformer.

In the device according to A.S., USSR No. 12458740, in contrast to other analogs, correction of the measurement error of the electrode subsidence associated with the inductive interaction of the phases is performed, which improves the accuracy of determining the controlled parameter, the electrode impedance. The displacement of the electrode as a function of the deviation of the impedance of the electrode is used as a regulating influence. The main disadvantage of this device is the low accuracy of controlling the active power of the furnace and its phase distribution, which is associated with the use of an indirect parameter, impedance. In addition, it does not use the second control action, PSN, which significantly impairs the quality of regulation of the electric mode of the furnace.

Therefore, on ore-thermal electric furnaces, these and other electric mode control devices are either not used or are used inefficiently.

As a prototype, an APP-1-36 device was selected for controlling the active resistance and active power of three-phase six-electrode furnaces.

The control method implemented in the APP-1-36 regulator provides for the regulation of the active resistance of the electrode-podina chain and the phase active power. The following are used as control actions: moving the electrode as a function of resistance and switching the voltage level of the transformer as a function of the active phase power. A series of locks are provided in the controller, mainly related to the end position of the electrode holders.

The main drawbacks of this device are: low accuracy of stabilization of the active power of the furnace, associated with regulation through two functionally independent channels, which leads to an oscillatory control mode due to the different reaction times of the furnace bath to the effect of electrode movement and switching voltage levels; the possibility of transformer failure due to switching when overloaded by 8-10%.

These and other shortcomings did not allow the use of the APP-1 series regulators in industry.

A further development of the series of APP-1 controllers became the control cabinets W 9701, with which the control algorithm is not supplied and must be developed by the user.

Thus, the known devices do not provide the necessary accuracy in the regulation of the active power of the furnace, its even distribution over the phases and trouble-free operation of the furnace transformers.

The purpose of the present invention is to improve the performance of the electric furnace, reduce the specific energy consumption and increase the reliability of furnace transformers by stabilizing the active power of the furnace, uniformly distributing it in phases and switching PSNs in transformer-rated modes.

This goal is achieved by measuring the active power of the phases and the active resistance of the electrode-bottom circuit by known methods, stabilizing the specified resistance by moving the electrode holder and the specified active power of the phases by switching the voltage levels of the transformers.

What is new is that the average values of the current, active phase power and active resistance of the electrode-bottom circuit are determined for a technology-specified time interval, compared with the technology-specified values, and when the phase current exceeds the limit of the technology, the phase electrode is lifted. whose resistance is less than the given value of the technology, the flow of no more than the limit of the technology and the excess of the power of the phase of the value specified by the technology reduces the voltage of the transformer, while reducing power and at a current of no more than the limit value of the technology, lower that electrode of the phase, the resistance of which is greater than the value specified by the technology, and if the resistance is within the limits specified by the technology, then increase the voltage of the transformer.

In the system for implementing the method, the output of the active phase power sensor is connected to the first input of the first threshold element, the second and third inputs of which are connected respectively to the behind active phase power sensor and timer, and two bipolar outputs are connected to the first inputs of the first and second cells I The positive output is connected to the first one, and the negative output to the second cell I, the output of the phase current sensor, the phase current setting device and the timer are connected to the first, second and third inputs of the second threshold element, respectively, The main output of which is connected to the second inputs of the first and second cells I, and the positive output to the first terminals of the third and fourth cells I, the output of the active resistance sensor of the 1st electrode is connected to the first input of the first comparison unit, the second input of which is connected to the output of the unit of minimum resistance and the output is connected to the second input of the third cell I, the output of which is connected to the yri-block by raising the 1st electrode, the output of the active resistance sensor of the 2nd electrode is connected to the first input of the second block whose second input is connected to the minimum resistance unit, and the output is connected to the second input of the fourth And cell, the output of which is connected to the 2nd electrode rise control unit, the second And output cell is connected to the first inputs of the fifth, sixth and seventh And cells, the second input of the first cell And is connected to the output of the third comparison unit, the first input of which is connected to the output of the active electrode sensor of the 2nd electrode, and the second input is connected to the maximum resistance unit, the output of the fifth And cell is connected The control unit for lowering the 2nd electrode, in addition, the second input of the sixth cell YI is connected to the output of the fourth comparison unit, the first input of which is connected to the active resistance sensor of the 1st electrode, and the second input is connected to the maximum resistance unit, and the output the sixth AND cell is connected to the control unit for lowering the 1st electrode, the output of the third comparison unit is connected to the first cell NOT, the output of which is connected to the second input of the seventh And cell, the output of the fourth comparison unit is connected to the second part ykoy NO, the output of which is connected to the third input of the seventh AND cells, the output of which is connected to a second input of the switch control unit stages the voltage of the furnace transformer, the first input coupled to an output of the first cell I.

The drawing shows a block diagram of a system for implementing a method for automatically controlling the electric mode of a six-electrode ore-thermal electric furnace (for a single phase). The system contains sensor 1 and unit 2 active phase power, timer 3, threshold element 4, first and second cells 5.6 And, sensor 7 and unit current 8 phase, the second threshold element 9, third and fourth cells 10.11 And sensor 12 active resistances of the 1st electrode, first and second blocks 13, 15 comparison, unit of minimum resistance 14, lift control unit 1 of the 1st electrode, 2nd resistance electrode resistance sensor 17, lift control unit 2 of the 2nd electrode, p thuy, sixth, seventh cells 19,20,21, AND, unit of maximum resistance 22, t ety and fourth comparator blocks 23,24, cell 25 does not, the control unit 26 by lowering the 2nd electrode, the second cell, the control unit 28 by lowering the 1st electrode, the switch control unit 29 steps the voltage of the furnace transformer.

The outputs of sensor 1, setpoint 2 active phase power and timer 3 are connected respectively to the first, second and third inputs of the first threshold element 4. Two bipolar outputs of element 4 are connected respectively to the first inputs of the first and second cells 5.6 I.

The outputs of the phase current sensor 7, the phase current setpoint 8, timer 3 are connected respectively to the first, second and third inputs of the second threshold element 9. The first output of element 9 is connected to the second inputs of cells 5 and 6, and the second output is connected to the first inputs of the third and fourth cells 10.11 I.

The output of the active resistance sensor 12 of the 1st electrode is connected to the first input of the first comparison unit 13. The output of the minimum resistance setting device 14 is connected to the second inputs of the first and second comparison units 13, 15. The output of the unit 13 is connected to the second input of the cell 10. The output of the cell 10 is connected to the input of the lifting control unit 16 of the 1st electrode.

The output of the active resistance sensor 17 of the 2nd electrode is connected to the first input of the second comparison unit 15. The output of the unit 15 is connected to the second input of the cell 11. The output of the cell 11 is connected to the input of the lifting control unit 18 of the 2-electrode.

The output of cell 6 is connected to the first inputs of the fifth, sixth and seventh cells of 19,20,21 I. The output of the unit 22 maximum resistance is connected to the inputs of the third and fourth blocks 23,24 comparison. The output of block 23 is connected to the second input of the cell 19 and the input of the first cell 25 NOT. The output of the cell 19 is connected to the input of the lowering control unit 26 of the 2nd electrode. The output of block 24 is connected to the second input of the cell 20 and the input of the second cell 27 NOT. The output of the cell 20 is connected to the input of the lowering control unit 28 of the 1st electrode. The outputs of the cells 25,27 are connected respectively to the second and third inputs of the cell 21. The outputs of the cells 5,21 are connected respectively to the first and second inputs-1 of the voltage transformer control unit 29 of the furnace transformer.

The system works as follows. After turning on the furnace, the output signal Ruf of the setting device 2 is fed to the input of the first threshold element 4, where it is compared with the value of the active power of the phase of the Russian Federation supplied by the source of 1. The RF signal is averaged over the interval t, the value of the previously adjusted active power of the phase. At the output of element 4 with a periodicity of t, determined by timer 3, a signal is generated, or - Rf, respectively. When Rf Ruf And Rf Ruf. THESE

The signals arrive at the first inputs of the first and second cells 5.6 I, respectively. At the same time, the signal of the phase current Ip averaged over t comes from the sensor 7 to the input of the second threshold element 9, where it is compared with the setting 1Uf coming from the setting unit 8. At the output of the element 9, with a periodicity of t determined by timer 3, signals are generated + с11ф or -оМф, which correspond to the phase current exceeding the setting or the norm (taking into account the dead band dl). The signal arrives at the second inputs of cells 5 and 6, and the signal + cLf arrives at the first inputs of the third and fourth cells 10.11 I.

At the simultaneous arrival at both inputs of element 5 of the signals + c) 1f and -slf, the signal -sl1f is generated at its output, which is fed to the input of the voltage level switching unit 29. The voltage of the furnace phase transformer is reduced by one step.

The signal RI of the averaged over t and corrected value of the active resistance of the 1st electrode from the sensor 12 is fed to the input of the block 13, where it is compared with the setpoint RMHH of the minimum resistance value supplied from the setpoint

14. At RI RMKH, a signal is generated at the output of the unit 13, which is fed to the second input of the cell 10. When signals are simultaneously received at both inputs of the cell 10, a signal is generated at its output, which is fed to the input of the 1st electrode lift control unit 16. The 1st electrode is raised by a specified amount.

Similarly, the signal RZ of the active resistance value of the 2nd electrode of the sender 17 is fed to the input of the unit 15, where it is compared with RMHH. With Ra Nmin, a signal is generated at the output of block 15, which

enters the second input of the cell 11. When signals are simultaneously received at both inputs of the cell 11, a signal is generated at its output, which is fed to the input of the 2nd electrode lift control unit 18.

The rise of the 2nd electrode is carried out by a given amount.

When simultaneously entering to both inputs of element 6 signals -4Рф and -сЛф, at its output a signal is generated, which

enters the first entrances of the fifth, sixth and seventh cells of 19.20 and 21 I.

In block 23, the signals Ra and Rmac are compared, respectively, coming from the sensor 17 and the maximum resistance setting device 22. At R2 Rmac, at the output of block 23, a signal is generated, which is fed to the second input of cell 19. With simultaneous input of signals to both inputs of cell 19, a signal is generated at its output, which is fed to the input of block 2 of lowering control of the 2nd electrode. The 2nd electrode is lowered by a specified amount.

In block 24, the signals RI and

Rwaic, respectively, coming from the sensor 12 and the setting device 22. With RI RMSK, the output of the block 24 generates a signal that arrives at the second input of the cell 20. With simultaneous input of signals

At both inputs of the cell 20, a signal is generated at its output, which is fed to the input of the lowering control unit 28 of the 1st electrode. The 1st electrode is lowered by a specified amount.

With RI RMaK and Ra RMBK, there are no signals at the output of blocks 23 and 24, and their inverse signals generated by cells 25 and 27 do NOT arrive at the second and

the third inputs of cell 21. When signals simultaneously arrive at the three inputs of cell 21, a signal + s WF is generated at its output, which is fed to the input of unit 29. The voltage of the phase transformer is increased by one step.

In general, the system provides the formation of the following control actions:

at f 1Uf and Ri RMHH, the 1st electrode is lifted by a fixed amount;

when 1F 1UF and R2 RMMH, the 2nd electrode is lifted by a fixed amount;

At 1f 1uf And Ri Yamin, And R2 RMHH

lift the 1st and 2nd electrodes by a set amount;

When Russia Ruf And 1f UV - dl, And Ri RMait

the 1st electrode is lowered by a set amount;

in the case of RF Ruf and f uv - dl, and R2 RMBK, the 2nd electrode is exhausted by a fixed amount;

in the case of the RF, Ruff and FUV - dl, and Ri RMa. and R2 RMSK performs the lowering of the 1st and 2nd electrodes by the set value;

When Russia Rufi f uv - dl, And Ri Rmak, And

R2 RMSK performs the switching of PSN to increase the voltage of the phase transformer by one step;

in the case of RF Ruf and 1F 1Uf - dl, the PSN is switched to reducing the voltage of the phase transformer by one step.

. Thus, the selective application of control actions — the movement of an electrode or the switching of voltage steps, makes it possible to stabilize the active power of the furnace with a limitation of the phase current while evenly distributing it across the phases and switching the furnace transformers in nominal modes.

In order to eliminate the measurement errors of the active power and active resistance of the electrode-bottom circuit, a correction for auth. USSR № 1237051.

For representativeness of the values of active power and phase current, when generating control actions, they are averaged over a time of 1–3 min. The optimal value of the averaging interval adopted when testing the process under industrial conditions at the Nikopol Ferroalloy Plant (NFP) for melting silicomanganese and ferromanganese was 1-2 minutes. With an averaging interval of less than 1 min, the representativeness of the parameter decreases due to current and power fluctuations associated with the arc nature of the process. At an interval of more than 2 min, the dynamic properties of the system deteriorate, especially in limiting the phase current and the representativeness of the parameter decreases.

To adjust the effect of the constant bath time of the furnace on the control quality, the control action is applied once per 1 to 3 minutes per discrete value. For the conditions of the NFZ, the optimal cycle of the control action was 1-2 minutes. The control discrete on PSN was 1 step, and on the displacement of the electrode 10-15 minutes. With

0 control loop less than 1 min occurs overshoot. With a control cycle of more than 2 minutes, the accuracy of the stabilization of parameters decreases. When the control action is less than 10 mm, the accuracy of the stabilization of parameters decreases, and when the sampling is more than 1 step and more than 15 mm, overshoot is observed and overcurrent is possible.

The system can be implemented on the WT serial means and GPS devices.

The invention was created as a result of research and development: Development and implementation of an automated process control system for the smelting of ferroalloys based on manganese in electric furnaces with a capacity of 63

In 1991 - 1995. The invention is planned to be put into commercial operation at 10 NHF furnaces.

0 Experimental studies carried out on the NFZ electric furnaces showed the possibility of the following improvement of the technical and economic performance of the furnaces:

5 productivity increase by 3 - 4%;

reduction of specific energy consumption by 2–3%;

ensuring trouble-free operation of furnace transformers.

Claims (2)

The expected economic effect from the implementation of the invention will be 150-200 thousand rubles per furnace per year. Invention Formula 5 1. A method of automatically controlling the electric mode of a six-electrode ore-thermal electric furnace, which includes measuring the active power of the phases and the active resistance of the electrode bottom circuit, stabilizing the established resistance by moving the electrode holder and stabilizing the specified active power of the phases by switching the voltage levels of transformers, characterized in that, in order to increase the performance of an electric furnace, reduce the specific energy consumption and increase reliability furnace transformers, determine the average values of current, active power phase and active resistance of the electric-podin circuit for a time interval specified by the technology are compared with the technology-specified values and if the current exceeds the phase of the technology-limiting value, the electrode of the phase whose resistance is less than the technology-specified value at a current not exceeding h f bffi & Ґffi & Ј & - The maximum value of the technology and the excess of the power of the phase of the value specified by the technology reduces the voltage of the transformer, and when the power is reduced and at a current not exceeding the limit value of the technology, lower the electrode of the phase whose resistance is greater than the value specified by the technology, and if resistances are within the limits of the technology, then increase the voltage of the transformer. 2. Automatic control system of the electric mode of a six-electrode ore-thermal electric furnace, comprising sensors and setters of active power of the phases, sensors and setters of active resistance of the electrode-bottom chain, reference units, threshold elements, control units for raising and lowering electrodes, control units for switching voltage steps transformers characterized in that, in order to increase the performance of the electric furnace, reduce the specific power consumption and increase the reliability of transformers, it is equipped with a sensor and a phase current setting device, a timer, AND, NOT cells, and the output of the active phase power sensor is connected to the first input of the first threshold Element, the second and third inputs of which are connected respectively to the phase active power setting unit and a timer, two bipolar outputs are connected to the first inputs of the first and second And cells, the positive output being connected to the first, and the negative to the second And cell, the outputs of the phase current sensor, phase current setting device and timer are connected respectively to the first the second, third and third inputs of the second threshold element, the negative output of which is connected to the second inputs of the first and second and second cells, and the positive output - to the first inputs of the third and fourth cells And, the output of the active resistance sensor of the first electrode is connected to the first input of the first comparison unit, the second input of which is connected to the output of the minimum resistance setting device, and the output is connected to the second input of the third cell I, the output of which is connected to the lifting control module of the first electrode The second electrode is connected to the first input of the second comparison unit, the second input of which is connected to the minimum resistance unit, and the output is connected to the second input of the fourth cell And, the output of which is connected to the lifting control unit The second element, the output of the second cell And is connected to the first inputs of the fifth, sixth and seventh cells And, and the second input of the fifth cell And is connected to the output of the third comparison unit, the first input of which is connected to the output of the active resistance sensor of the second electrode, and the second input with the unit of maximum resistance, the output of the pthy cell And is connected to the control unit lowering control the second electrode, the second input of the sixth cell AND is connected to the output of the fourth comparison unit, the first input of which is connected to the active resistance sensor of the first electrode, and the second input connected to the maximum resistance unit, and the output of the sixth cell I is connected to the control unit for lowering the first electrode, the output of the third comparison unit is connected to the first cell HE, the output of which is connected to the second input of the seventh And cell, the output of the fourth comparison unit is connected to the second cell NOT, the output of which is connected to the third input of the seventh And cell, the output of which is connected with the second input of the control unit of the voltage step switch of the furnace transformer, the first input of which is connected to the output of the first cell AND LOCATOR ACTIBMA power rolls / fay antab power patu Attracted exercise switch e chen yupphem block cpu / blei yruniyen to mkrrZa Jim cfofnew Who 22 Maximum Locking System .OOWOinutjCfmB Aachik current groves Hvfr; bafamvifx MUHUHMbHOtO with rum / eniv Vlak yooЈle u1 podjone ie 3ftKmpoda Cell And .chan cpclntw.9 Vlok ynoafae- nor Txtittnom-u inexrtoffa fiC nwK of cff-etc CO / pot / Aitituo IJ-U WAVrt J