RU2003696C1 - Method for purification of contaminated media of metallurgical production and device for its realization - Google Patents

Abstract

FIELD OF THE INVENTION This invention relates to the environmental and technological purification of contaminated media (ZC) of metallurgical production. The invention makes it possible to efficiently carry out cleaning of various pollutants in pipelines (T), matching the flow rate of a moving medium (DS) with the pulse frequency (I) of a sawtooth (P) voltage (H) and their amplitude (A). After measuring the diameter T and the flow rate of the DS, the ALP is established directly proportional to the diameter of T, the frequency of the NRP is regulated depending on the flow rate of the DS. The method is carried out in a device containing a flow meter DS, an APN control unit, a PI controller, a GPN generator, and pulsed electromagnets (E). a control panel, T for retracting the DZS. The flow meter is connected in series through the matching unit and the regulator of the frequency converter with the first input Г, the second input of Г is connected through the ALP control unit to the setpoint A, the second inputs of the regulators of the А AL are included in the control panel circuit. its cooling water cavity, and the core IE made in the form of a closed magnetic circuit with pole tips. 3 ill.

Description

The invention relates to ferrous metallurgy, and more particularly to the purification of contaminated media of metallurgical production.

For example, there is known a method for suppressing dust contained in the exhaust gases of an open-hearth furnace, a converter, an electric steel furnace, etc., based on the creation of a strong electrostatic field, which, when interacting with charged dust particles, leads to their deposition on the plates of electrostatic precipitator 1.

The disadvantage of this exhaust gas purification method is that it requires the use of very high voltages up to 100 kilovolts. Under actual operating conditions, breakdown often occurs between the high-voltage plates of the electrostatic precipitator, which leads to its failure. This is most often observed when moisture enters the flue gas, and the use of high voltages is life-threatening to the operator.

Another method for cleaning dusty gases is known, based on the interaction of iron-containing dust with a constant magnetic field created using a magnetic separator 2.

The disadvantage of this method is the lack of interaction between the constant magnetic field and the iron-containing dust at temperatures above the Curie point (768 ° C), at which the iron loses its magnetic properties. In addition, a constant magnetic field does not interact with diamagnetic materials (superheated iron, copper, etc.) contained in dust.

The closest in technical essence and the achieved result is a device for dedusting exhaust gases of the converter, in which pulse electromagnets with cores, the windings of which are connected in parallel with each other, are connected through a power amplifier and a work permit unit to a sawtooth generator along the perimeter of the gas duct wife 3.

The disadvantage of this device is that it does not allow you to adjust the amplitude and pulse repetition rate depending on the specific operating conditions and technological features of the melting process. In addition, in this device, the magnetic cores are made in the form of individual cores, which does not allow the magnetic flux to be concentrated from the external end surfaces of the cores, which reduces the effectiveness of the magnetic effect on the medium.

The proposed method for cleaning contaminated media of metallurgical production, including a moving contaminated medium in a pipeline of a certain diameter, which is exposed to a pulsed electromagnetic field generated by a sawtooth voltage generator and pulsed electromagnets with individual cores installed around the perimeter of the pipe, characterized in that it further measure the diameter of the pipeline and the flow rate of the moving medium, while the amplitude of the sawtooth generator April voltage is set directly proportional to the diameter of the pipeline by the relationship:

twenty

 DTp,

0)

where AIMP is the amplitude of the pulses, V;

Dip - diameter of the pipeline, m;

Ki - proportionality coefficient, V / m,

and the pulse repetition rate of the generator is regulated according to:

 HRSR

(2)

where Chimp is the pulse repetition rate, Hz;

Rav is the consumption of the polluted medium, m3 / min;

KZ - coefficient of proportionality,

Hz min / m

the cores of electromagnets are made in the form of a common closed magnetic conductor with pole tips.

The proposed device for implementing the method of cleaning contaminated media metallurgical production,

including metallurgical unit equipped with a pipeline for the removal of contaminated medium, pulse

Electromagnets with cores and windings connected through a power amplifier to a sawtooth voltage generator, as well as an aggregate control panel, are characterized in that it additionally

equipped with a flowmeter of a moving contaminated medium, a matching unit, a ramp amplitude regulator, a ramp amplitude control unit;

a pulse repetition rate regulator, and the electromagnet windings are made in the form of a hollow copper wire for supplying cooling water to its cavity, and the pulse electromagnet core is made in the form of a closed magnet wire with pole tips, while the flowmeter is sequentially through the matching unit and the pulse frequency regulator connected to the first input of the generator, the second input of the generator, in turn, is connected through the block of regulation of the amplitude of the sawtooth voltage with the setpoint amplitude, and orye inputs regulators frequency and amplitude pi loobraznogo voltage included in the remote control circuit unit.

In FIG. 1 presents a block diagram of the proposed device; in FIG. 2 is a diagram of an arrangement of electromagnets on a pipeline; in FIG. 3 - design of a pulsed electromagnet.

The device comprises a pipeline 1 of a metallurgical unit with a contaminated medium moving in it, pulsed electromagnets 2 installed along the perimeter of the pipeline with a closed magnetic wire and pole tips 3, windings of 4 poles made in the form of a hollow insulated copper wire for supplying cooling water, connected through a power amplifier 5 with the output of a sawtooth voltage generator 6, a flowmeter 7 of a moving contaminated medium, connected through a matching unit 8 to the input of the trace frequency controller 9 Ani pulses and pulse amplitude setting unit 10 is connected to the input of the regulator 11, pulse amplitude, and outputs regulators 9 and 11 are connected respectively to the second inputs of the generator 6 and the second inputs of the regulators 9 and 11 included in the circuit 12, the remote control unit. Electromagnets 2 with pole pieces 3 are attached to the pipe 1 via flange connections 13 and sealed by a gasket 14 to prevent leakage and leakage of the connection. The windings 4 are connected to the power amplifier using special terminals 15.

The following is one embodiment of the method and device.

Under the conditions of the converter shop of the Cherepovets Iron and Steel Works, in the gas outlet of the 400-ton converter, after the first stage of cleaning, pulse electromagnets 2 with a closed magnetic circuit and pole pieces 3 were installed around the perimeter of the gas duct. The magnetic circuit is made of E310 electrical steel. The windings of 4 pole pieces connected in parallel with each other are connected to the output of a power amplifier 5, the input of which is connected to the output of the sawtooth voltage generator 6. Amplifier

power is assembled from standard microcircuits of type K174UN, and generator 6 is used of type G345-I. A flowmeter of a moving medium is used of the DM4284-03 type. The output of the flow meter 7 is connected to the pulse repetition rate controller 9 through a matching unit 8, which serves to match the output signal of the flow meter 7 to the pulse frequency controller 9. In this block, frequency control and regulation are implemented according to the expression FIM K2XRSp, where Nim is the pulse repetition rate, Hz; Rav - flow rate, m3 / min; "2 - proportionality coefficient, Hz / min / m. The adjuster 10 is used to set a predetermined amplitude of the pulses depending on the diameter of the pipe at the installation site of the electromagnets according to the expression: Xdtr, where Aimp is the pulse amplitude, V; DTR - pipe diameter, m; CT is the coefficient of proportionality, V / m. This signal enters the pulse amplitude control unit. The matching unit 8 is made of standard equipment using ADC systems. The adjuster 10 is made in the form of a rheostat divider of the reference voltage. The controllers 9 and 11 of the frequency and amplitude of the sawtooth pulses are made on the basis of K155 microcircuits and serve to match the signals from block 8 and the setter 10 with the inputs of the generator 6 through the channels for regulating the frequency and amplitude of the sawtooth pulses. Signals from the control panel of the converter are supplied to the second inputs of the controllers 9 and 11.

Inclusion of the device into operation is carried out from the control panel of the converter at the moment of the start of purging. The method is implemented as follows: during purge of the converter, intense emission of CO and CO2 gases occurs. In addition to these components, the exhaust gases contain evaporated iron, its oxides, as well as a number of complex compounds in the form of dust and red smoke. The amount of dust generated during smelting is 10-20 kg / t of steel, and its content in the exhaust gases reaches 250 g / m3. More than 70% of the particles are smaller than 40 microns. The sanitary norm allows the emission into the atmosphere of gases containing not more than 0.1 g / m3 of dust. Under real conditions of the converter shop, it is possible to achieve such a concentration of dust in the exhaust gases only with the additional equipment of gas purification with electrostatic precipitators. However, the above disadvantages and difficulties in using electrostatic precipitators do not allow gas purification to be carried out efficiently and reliably.

The empirical coefficients K1 and K2 were determined empirically on the basis of a comparative analysis of the results of the degree of gas purification under various operating conditions of the installation. The degree of gas purification was determined by monitoring the chemical and dispersion compositions of specially selected gas samples in places before and after the installation of electromagnets. As a result of processing the obtained data, the best results of gas purification were achieved with the values of the coefficients K1 and K2 equal to 0.52 and 3.57 X 102, respectively. The physical meaning of expression (1) is that it is necessary to take into account the diameter of the pipeline when determining the sawtooth amplitude pulses, since, for example, as the diameter of the pipeline increases, the amplitude of the pulses should be increased so that the magnetic field does not weaken over the entire diameter of the pipeline.

The physical meaning of expression (2) is that the pulse repetition rate must be synchronized with the flow rate of the moving medium. This is due to the fact that, for example, with an increase in the velocity (flow rate) of the moving medium at a constant pulse repetition rate, the mass of the gas that has not undergone magnetic treatment increases, since the magnetic field is pulsed. Therefore, by increasing the pulse repetition rate with increasing gas flow rate, it is possible to reduce the mass of gas that has not undergone magnetic treatment. The experimental data showed that the control of the pulse repetition rate in synchronism with the gas flow rate is significant and allows one to increase the dust suppression efficiency and the degree of gas purification.

The diameter of the pipeline at the installation site of the electromagnets was 2.8 m. Therefore, the amplitude was set on dial 10, equal to 57 X 102 X 2, V. At the moment of starting the purge of the converter from the converter control panel 12, a signal is sent to the regulators 9 and 11, which generator 6 is put into operation. On the control melting, the exhaust gas flow rate amounted to 4840 m3 / min and therefore, regulator 9 gave a signal to the generator to work out the pulse repetition rate of equal magnitude:

 X0 Hz. In turn, the generator 6 with the given parameters of the amplitude and pulse repetition rate delivers them to the power amplifier 5, the output

which is connected to the windings 4 of the electromagnets 2.

A powerful electromagnetic field is created in space in a contaminated environment using pulsed electromagnets,

the windings of which are supplied with a special sawtooth voltage. In turn, this electromagnetic field, acting on the medium, induces microcurrents in its particles that form its own magnetic fields. The magnitude of the intrinsic magnetic field of a particle is directly proportional to the rate of change of the external electromagnetic field, and is also determined by its paramagnetic or diamagnetic properties. Depending on these properties, the particles will be attracted or repelled from the source of the external electromagnetic field. In this case, they will accumulate in

any region of space, as well as as a result of a change in the trajectories of particles in a highly inhomogeneous magnetic field, their active coagulation will occur. Coagulation of particles leads to

enlarging their size and, therefore, improving their deposition in droplet eliminators or other treatment devices. The experiments showed that after a magnetic action on the particles, their size increases by 2-5

time.

At the selected operating parameters of the installation, control measurements of the dust content of the converter exhaust gases at 20 experimental melts showed high stability of the results, the dust content in the gases was not more than 0.05 g / m. The proposed method can be widely used to purify both gas and other media, for example, circulating water before and after sedimentation tanks,

oil pipelines, air ducts and other units requiring cleaning of the medium.

(56) 1. Voskoboinikov V.G.M .: General metallurgists, 1985, p. 207-209. 2. Copyright certificate of the USSR No. 514020, cl. C 21 C 5/38. 1972.

3. USSR author's certificate No. 685697, cl. C 21 C 5/38, 1977.

Claims (1)

1. A method of cleaning contaminated media of metallurgical production, including exposure to a moving contaminated medium in a pipeline of a certain diameter of a pulsed electromagnetic field created by a sawtooth voltage generator and pulse electromagnets with individual cores installed around the perimeter of the pipeline, characterized in that the pipe diameter and the flow rate of the moving medium are additionally measured, the amplitude of the sawtooth voltage is set directly proportional to the diameter DTp of the pipe according to the expression Aim Ki DTp, where Aim is the amplitude of the pulses, V; 2Q at the same time, the second inputs of the regulators are often Ki - the proportionality coefficient, and the amplitude of the sawtooth voltage, V / m, are not included in the control panel circuit, and the frequency of the FMM of the sawtooth pulses of the re-winding of the electromagnets is made in the fan, depending on the location of the insulated hollow copper wires of the flow rate of the moving medium according to the expression 25 with the cooling cavity supplied to them Him "2 Psr, medium, and the cores of electromagnets - in where the form of a closed magnetic circuit with a pole Рср is the flow rate of a moving medium with nibs. m3 / min; K2 - coefficient of proportionality, Hz min / m 10 2, A device for cleaning contaminated metallurgical production environments, 5 comprising a conduit for discharging contaminated medium, pulse electromagnets with cores and a sawtooth voltage generator connected through a power amplifier to windings, a control panel, characterized in that it is equipped with connected to the first input the generator through the matching unit and the pulse frequency regulator of the flow rate, by the measuring device of the contaminated medium and the amplitude adjuster, connected through the sawtooth amplitude amplitude control unit with the second input of the sawtooth generator, 2Q at the same time, the second inputs of the frequency and amplitude ramps FIG. / Fig.