RU2296165C2 - Metal direct reduction method from dispersed raw ore material and apparatus for performing the same - Google Patents

Abstract

FIELD: coke - free metallurgy, namely manufacture of continuously cast billet by reducing metals from metal-containing oxide raw material by means of gaseous and dispersed reducing agents in plasma-chemical reactors.

SUBSTANCE: method comprises steps of feeding partially reduced charge and gaseous reducing agent into electric-arc furnace onto surface of melt ore bath through cavity arranged outside working electrode; compensating consumption of working electrode without interrupting process; in zone of electric arc burning creating axial magnetic field promoting uniform heating and reduction of charge while preventing fine particles discharge in such field by means of plasma; discharging gaseous reaction products through inner cavity of working electrode and using them for preliminary reduction. At process of preliminary reduction circular, axial, pulsating or traveling magnetic field is created for optimizing gas dynamics and thermal conditions of reduction. In process of collecting ready product metal crystallization is realized for discharging product in the form of blank suitable for further processing.

EFFECT: lowered specific consumption of working electrode material, possibility for using any gaseous reducing agent with hazard of clogging its inlet duct with coke, lowered consumption of reducing agent.

25 cl, 6 dwg, 1 tbl

Description

The field of technology.

The invention relates to non-coke metallurgy, in particular to the production of a continuously cast billet by reducing metals, not only iron, from metal-containing oxide raw materials, such as dispersed ores, partially reduced ores, ore concentrates and metal-containing oxide wastes, gaseous and dispersed reducing agents in plasma-chemical reactors, the main share of energy which is introduced using an arc discharge.

The level of technology.

As is known, a method in which iron is produced by reducing iron ore bypassing blast furnace production is classified as a “direct reduction method”. Methods of direct reduction of metals and corresponding devices based on arc discharges are described in the well-known technical literature ("Industrial Electric Furnaces. Arc Furnaces and Special Heating Units." Edited by AD Svenchansky, M. Energoizdat, 1981, p. 251, 247). Typically, the device comprises a molten bath with means for collecting and removing metal and slag, means for supplying feedstock and plasma-forming gas, a solenoid and a working electrode located on the central axis made of graphite or tungsten. In some cases, the source material and plasma-forming gas are supplied through a working electrode, usually located in the upper part of the device, and the working electrode is the cathode of the arc plasmatron, the role of the anode is played by the molten metal bath located on the bottom of the furnace.

A common drawback of these devices and methods is the presence of a consumable electrode - the cathode and the limited volume of the melting chamber, which requires a process stop to replace the cathode and the release of metal, as well as high wear of the wall of the melting chamber of the reactor - crucible, which must be protected with graphite or ceramic lining (e.g. , Russian patents No. 2022491, 2072639, No. 2002930); the latter is intensively destroyed upon contact with oxide melts. Even in the case when the electrode is not replaced, but moved to the working area by means of the devices provided for this (RF patents Nos. 1781306 and 2007463), the process remains intermittent due to the limited capacity of the furnace and the need to disconnect the ore feed material from the cathode to the installation time of the backup electrode, and the final material is contaminated by the products of cathode erosion and furnace lining.

In addition, it is practically impossible to ensure a stably uniform flow of the processed material into the arc region due to the significant size of the melt bath mirror and the chaotic movement of the contracted arc spot on the surface of the working electrode due to the relatively low temperature of the end of the cathode. At the same time, energy costs are high for heating a gaseous medium, a significant part of the energy of which is irretrievably lost, despite attempts to reuse it (Development of Coxless Metallurgy, edited by N. Tulin, Mayer K., M., Metallurgy, 1987 city, Pat. of Russia No. 2037524), and the high costs of various reagents are required.

In some cases, it is possible to reduce the energy and reagent costs by accurately maintaining the ratio between the amount of feedstock and reagents, but then the process becomes multi-stage with a corresponding increase in the number of redistributions, energy consumption and ultimately the cost of the product (Russian patents Nos. 2037524, 2213787, US Pat. USSR No. 1811539).

All this does not allow to develop an arc continuously operating economical recovery plasma-chemical reactor at a power level corresponding to the required performance in the metallurgical industry.

The closest prototype of the present invention is a method of direct reduction of metals from dispersed ore raw materials, including preliminary reduction of the starting material — a charge, supply of a partially reduced charge together with alloying additives and a reducing agent to an electric arc furnace, electric arc excitation, melting and finishing restoration of a partially restored charge, product from the device and its collection, cooling of thermally loaded parts of the device (“Development of coke-free m metallurgy. ”Under the editorship of N. Tulin, Mayer K. Metallurgy, M., 1987, p. 77). According to this method, ore raw materials and a reducing agent (carbon) are fed into the working space through the internal cavity of the working electrode at a temperature of 1500-3000 ° C. Due to its high affinity for oxygen, the carbon of the electrode intensively interacts with metal oxide, which leads to its erosion and high consumption of electrode material, and when using natural gas as a reducing agent, it also pyrolyzes the latter and overlaps the cavity of the working electrode with pyrolysis products.

In addition, the introduction of reagents under the electrode cavity, i.e. mainly in the central part of the bath, causes their uneven distribution over the volume of the bath, which has large transverse dimensions. As a result, the efficiency of mass transfer processes in the molten bath decreases, which reduces the rate of metal reduction and, consequently, increases the energy costs of its production. The high erosion of the electrode is also caused by the presence of sedentary contracted spots resulting from the insufficiently high temperature of the electrode end. The absence of an axial magnetic field in the combustion zone of the arc leads to a deflection of the arc from the axis of the electrode and to the reagent slip past the discharge. This increases the removal of ore from the working volume of the furnace, i.e. metal loss.

The closest prototype of the present invention is also described in the same source, a device for direct reduction of ore raw materials containing a feeder of the source material - the mixture, a solid-phase reactor for preliminary reduction of the charge, means for supplying partially restored charge and reducing reagents to the electric furnace, including a mixer located on the central axis of the working electrode with an internal cavity, a liquid-phase reactor with a cylindrical body, a device for collecting the finished product with a bath melt and cooling means for thermally loaded parts, with the working electrode and the collection device connected to the poles of the power source. In this device, the working electrode is the cathode, and the device for collecting the finished product is the anode of the arc plasma torch connected to a constant current source. The disadvantages of the known device, in addition to erosion of the cathode, the use of collapsing ceramic lining and other disadvantages of such devices noted above, also include the absence of a mold, which increases the number of redistributions to obtain slabs of the required shape.

SUMMARY OF THE INVENTION

The present invention solves the technical problem of reducing material consumption and increasing the efficiency of the process, the implementation of almost continuous operation and increasing the purity of the metal.

The main technical result of the use of the present invention is to reduce the specific consumption of the working electrode material, the possibility of using any gaseous reducing agent without the risk of coking of its input channel, and reducing the consumption of reducing agent.

Additionally, the task of simplifying the technological scheme for the production of continuously cast billets from dispersed ore or other metal-containing oxide raw materials and ensuring explosion safety is solved.

The specified result is achieved in the present invention, one aspect of which is a method of direct reduction of ore raw materials. According to the proposed method, the preliminarily partially reduced material is fed into the electric furnace — a mixture and a gaseous reducing agent are produced into the ore bath mirror through a cavity located outside the working electrode, after arc excitation, melting and finishing reduction of the charge, the gaseous reduction reaction products are removed through the internal cavity of the working electrode and used them for preliminary restoration, during which they create a circular, axial, pulsating or moving the existing magnetic field, and the flow rate of the working electrode is compensated. In addition, an axial magnetic field is created in the combustion zone of the arc and the molten bath, in the process of preliminary reduction, reducing gas is mixed with the gaseous reaction products, and in the process of withdrawal and collection of the finished product, metal crystallization is carried out and it is withdrawn in the form of a workpiece suitable for further processing.

The problem is also solved by the fact that in the furnace of the device for direct reduction of ore raw materials between the mixer and the liquid-phase reactor, the first clamping device with holes for the passage of the mixture and placed on its inner surface electrically conductive spring contact rollers or plates is placed, a cooled metal is attached to the clamping device from below a glass, on the axis of which a working electrode is placed, the device comprises means for creating a circular, axial, pulsating or moving In addition to the magnetic field in the solid-state reactor and the device for supplying electric current to this means, the reactor itself consists of a cylindrical part with a cap and a conical part facing downward narrowing, with a bottom provided with holes, and includes a non-ferromagnetic perforated cylinder located on the central axis with ferromagnetic pins or ribs on its outer surface, in the cavity of the cylinder, a hollow backup electrode and a metal rod are installed, while the working, backup electrodes and the rod are arranged in series with upside down and connected, and the rod in the lower part is provided with perforation, on the cover of the solid-phase reactor there is a second clamping device, a casing with a drive device for reversing movement and rotation of the rod and a charge feeder pipe attached to it, under which the atomizer is placed in the reactor, the supply means is partially restored the charge is placed between the bottom of the solid-phase reactor and the electric furnace mixer, while the collecting device, the liquid-phase reactor body, the first clamping device and the mixer are separated by an electrical insulation with ionic gaskets, the reducing gas supply means comprises a first valve, after which the gas line is divided into two branches, one of which is connected to the solid-state reactor with the second valve, the other to the mixer with the third valve, and the neutral gas line is connected to the inner hole of the second clamping device with the fourth valve.

In addition, the collecting device is made in the form of a cooled mold made of an electrically and thermally conductive material chemically resistant to oxide melts, the shape and dimensions of which correspond to the shape of the cast billet, the first solenoid is installed around the molten bath and the body of the liquid-phase reactor, and the supply means is partially restored charge is made in the form of a feed section with a screw feeder. When using poor ores as a raw material, the mold contains an opening for the release of slag.

Means of creating a magnetic field in a solid-state reactor according to the invention can be performed in six versions, four of which contain a two-position three-pole switch connected to an AC or DC source. In the first embodiment, the source of the magnetic field in the solid-state reactor is the rod and the backup electrode, in the second - conductors with current, located around the cylindrical part of the reactor, in the third embodiment, the source of the magnetic field is the second solenoid, in the fourth - the "shoulders" of the rectifier bridge, placed around the cylindrical parts of the reactor, in the fifth - the stator poles of an induction motor, the sixth is a combination of the first and second options.

Terms and definitions used.

An arc plasmatron is a device containing two or more electrodes between which an electric discharge is excited in a plasma-forming gas medium, controlled by gas or magnetodynamic methods, the plasma of which is used to heat the gas, melt and recover ore materials.

A solid-phase reactor is a container in which the reduction of oxide feedstock with a gaseous reducing agent is carried out without melting it and from which the partially reduced feedstock is fed to the mixer.

A liquid-phase reactor is a vessel in which the reduction of oxide raw materials is carried out in a molten liquid state. The reactor contains a cooled housing on which one or more plasmatrons are mounted and to which a product collection device is docked at the bottom.

A crystallizer is a device for recovering ore raw materials and collecting a product, a metal, in which the molten metal is cooled to a solid state. In the case of slag formation, the mold is provided with an opening for its output.

Feeder - a device, usually containing a bunker with the original ore raw materials and means for feeding it at a given speed.

A solenoid is a coil formed by a conductive or superconducting material.

A slab is a semi-finished product, which is a metal billet of rectangular cross section with a large ratio of width to height, prepared for further processing, for example, rolling, forging, etc.

Rectifier bridge - a device for converting AC to DC. In the simplest case, the bridge contains four “arms” with rectifier diodes, connected in such a way that one pair of diodes passes current in one half-cycle, in the next period another pair of diodes, and constant polarity voltage is provided at the output terminals of the bridge.

Synthesis gas is a gas mixture whose main components are carbon monoxide and hydrogen.

Iron ore raw materials - mineral raw materials containing one or more iron oxides of various valencies.

Poor ore raw materials - raw materials with a metal content of 60% or less.

Rich ore raw materials - raw materials with a metal content of about 70%.

Clamping device is an actuating mechanism, consisting, for example, of two parts enclosing the clamped element and driven by electric, pneumatic or hydraulic means. To pass the mixture, the clamping device is provided with axial holes, for the passage of gas - radial channels.

A cylindrical stator of an induction motor is a fixed electromagnetic system of a three-phase current, consisting of a magnetic circuit with poles rolled into a cylinder and a winding laid in it, creating a rotating magnetic field.

A linear (expanded) stator of an induction motor is a fixed linear electromagnetic system of three-phase current, consisting of a rectilinear magnetic circuit with poles and a winding laid in it, creating a linearly moving ("running") magnetic field.

Description of the drawings.

Figure 1 schematically shows the main variant of the device in longitudinal section.

Figure 2 shows the cross section of the device in the plane aa.

Figure 3-6 presents the options for creating a magnetic field in a solid-state reactor preliminary reduction.

The device contains a solid-phase pre-reduction reactor 1, including a cylindrical body 2, passing into the conical part 3, a cover 4, a bottom 5, a pipe for the exhaust gas outlet channel 6, a perforated cylinder 7 mounted on the axis of the device, and an outlet pipe 8 for the ore feedstock is mounted on the cover 4 (not shown). Under the nozzle 8 in the reactor 1 is placed a nozzle 9 with a drive (not shown).

Under the bottom 5 there is a feed section 10 for partially reduced raw materials with a feed device 11, for example, in the form of a screw with a drive (not shown), and a mixer 12, under which there is a first clamping device 13 and a liquid-phase reduction reactor 14 with a housing 15.

A crystallizer 16 is adjacent to the housing 15 of the reactor 14 from below, in which the oxide melt 17 is located, beneath it, the metal melt 18 and the cooled part 19 of the metal melt are solid metal, for the extraction of which the drawing and cutting mechanism 20. The first solenoid 21 is located around the reactor 14.

A working hollow electrode 22, enclosed in a cooled sealing cup 23, and a backup electrode 24, connected with its upper end to the rod 25, which is connected to one of the transfer poles of the switch 29 through the third clamping device 26, flexible bus 27, and upper current lead 28, are installed on the device axis The lower current supply 30 connects the other transfer pole of the switch 29 to the first clamping device 13. The switch 29 is made on-off and contains three poles - a receiving pole connected to a current source 31, and two transfer.

The reducing gas supply system comprises a gas source 32 and a line with a valve 33, divided after it into two branches. The branch with valve 34 is connected to the reactor 1 above its conical part 3, and the branch with valve 35 is connected to the mixer 12. The neutral gas line with valve 36 is connected to the radial channel in the second clamping device 37 mounted on the cover 4 of the reactor 1.

The device 38 for the reverse drive of the rod 25 is placed on the casing 39, which houses the mechanisms of axial movement and rotation of the rod 25 with electrodes 22 and 24. As an example, the axial movement mechanism is made in the form of a screw 40, and the rotation mechanism is in the form of a rod 41 of rectangular cross section, passing through the rectangular hole of the plug of the rod 25. The casing 39 is mounted on the second clamping device 37.

The parts of the device located under different potentials are separated from each other by means of insulating gaskets 42-46. The power source 31 is connected by current leads 47 and 48 to the switch 29 and the mold 16, respectively.

Means of creating a magnetic field in the solid-state reactor 1 according to the invention can be performed in six versions, four of which contain a two-position three-pole switch 29 connected to an AC or DC source (Figs. 1, 3, 4). In the first embodiment (Fig. 1), the means of creating a magnetic field is placed inside the solid-state reactor 1 and its role is played by the rod 25 and the backup electrode 24, in four other variants it is placed around the cylindrical part 2 of the reactor 1 and is made as follows: in the second embodiment, in the form coaxial current-carrying conductors 49 (Fig. 3), in the third embodiment, in the form of a second solenoid 50 (Fig. 4), in the fourth embodiment, in the form of coaxial current-carrying conductors 51 of a rectifier bridge with diodes 52 connected to the poles of an AC power supply 53 ( ig.5), in the fifth embodiment, a cylindrical or unfolded stator 54 of the linear induction motor is connected to a source of three-phase 55 (Figure 6). The sixth option is a combination of the first and second options. The perforated cylinder 7 is provided with ferromagnetic pins 56.

Arc 57 burns between the working electrode 22 and the melt 17.

The hollow graphite electrode 22 is placed in a sealing cooled cup 23, the outflow of the electrode 22 from the cup 1 is 0.5-1 of the outer diameter of the electrode 22. A smaller outlier leads to the excitation of the arc on the cup 23, a large one leads to erosion of the electrode 22 from the ingress of oxide . The diameter of the inner cavity of the electrode 22 is equal to 1 / 3-1 / 4 of its outer diameter. An increase in the diameter of the channel leads to an increase in the flow rate of the electrode 22; decrease - to an excessive increase in gas pressure in the installation volume.

The cooled mold 16 is made of an electrically conductive and thermally conductive material resistant to oxide melt, for example, of copper, and is equipped with a mechanism 20 for drawing and dimensional cutting of the obtained ingot.

The implementation of the invention.

The installation is designed to use two types of ore raw materials: with an iron content of about 70% and poor ore raw materials, the iron content of which is at the level of 60% or less. When restoring poor ores, it is necessary to provide a device for removing slag from the working volume.

The particle size of the dispersed ore should be 0.1-3 mm. The use of smaller particles leads to an increase in dust removal, with larger particles, the rates of heat and mass transfer processes slow down, therefore, such raw materials must be crushed. The larger the particles of the raw materials used, the stronger the magnetic field should be used to intensify the pre-reduction process in reactor 1.

The proposed method and device can operate on alternating and direct current direct and reverse polarity. The method and device described in FIG. 1 described below, as an example, demonstrate direct current operation with direct polarity (electrode 22 is a cathode).

The device operates as follows. First, the dovetail mechanism 20 of the workpiece, acting as the anode of the plasma torch, load the metal "seed". An arc discharge 57 is excited between the “seed” and electrode 22. The operating parameters of the installation are established: induction of the magnetic field of the solenoid 21, magnitude of the arc current, magnitude of the arc gap, flow of reducing gas through the reactors: liquid-phase reduction 14 through valve 35 and solid-state reduction 1 through valve 34.

After pointing the molten bath 17 into the solid-state reactor 1 through the outlet pipe 8 of the feeder feed ore is supplied - the charge, which is distributed by the atomizer 9 throughout the volume of reactor 1. In this case, the dispensing pole of the switch 29, the receiving pole of which is connected by a conductor 47 to the negative pole of the power source 31, through the upper current lead 28, the flexible bus 27 and the third clamping device 26 is connected to the rod 25 and the current flowing through the rod 25 and the backup electrode 24 creates a circular magnetic field in the reactor 1. Then, after a sufficient time for the specified level of preliminary recovery of the charge (20-70%) in the reactor 1, the switch 29 switches the negative pole of the power source 31 to another transfer pole connected to the electrode 22 through the lower current supply 30 and the first clamping device 13 The magnetic field in the reactor 1 disappears and the partially reduced charge falls into the conical part 3 of the reactor 1 and the feed chamber 10. The screw 11 continuously feeds the charge into the mixer 12, where they are mixed in the vortex of the reducing gas sewing.

As the partially restored charge from the conical part 3 of the reactor 1 is consumed, the feed is resumed by the feeder and the switch 29 again switches the power supply to the rod 25, preventing the complete draining of the reactor 1. The process of switching the power supply and supply of raw materials is periodically repeated while maintaining the operation of the device.

In other embodiments of creating a magnetic field in the reactor 1, involving the use of a switch 29, the power supply is switched according to the same scheme with periodic connection to one of the poles of the power source 31 of the upper ends of the conductors 49 (Fig. 3) or the upper end of the second solenoid 50 (Fig. four).

In the variant with a rectifier bridge (Fig. 5), the magnetic field in the reactor 1 exists continuously, and the pulsating nature of this field determines the high efficiency of preliminary restoration of the initial charge at a high feed rate.

In the embodiment with the stator 54 of the induction motor (FIG. 6), it is possible to periodically turn off the magnetic field with the supply of feed being cut off while filling the partially restored charge of the cone part 3 of reactor 1, and to select the operation mode of the stator 54, which ensures the supply of feedstock continuously.

From the mixer 12, the resulting mixture is transferred by a flow of reducing gas to the working volume of the liquid-phase reactor 14. In the working volume of the reactor 14, the mixture of gas and the mixture passes through the guide gap formed by the sealing cup 23 and the reactor shell 14 and is distributed almost uniformly throughout the mirror of the rotating oxide melt bath. 17. The resulting gaseous products of the reduction reaction pass through a plasma arc into the central cavity of the electrode 22.

The reduced metal, as a heavier fraction of the melt, accumulates in the lower part of the crystallizer 16 in the form of a metal melt 18 and, gradually cooling, crystallizes into solid metal 19. The reduced metal 19 is continuously extracted from the crystallizer 16 by the metal extraction and cutting device 20 and cut into slabs with sizes that allow their further use as blanks for subsequent processing.

Gas from the working volume of the liquid-phase reactor 14 through the hollow electrodes 22 and 24 enters the hollow rod 25, through the openings of which the perforation of the cylinder 7 enters the solid-state reactor 1. From the reactor 1, the spent reducing gas through the pipe 6 is supplied for further technological use.

The solenoid 21 creates in the region of the arc and crystallizer 16 an axial magnetic field with an induction of about 0.1 T, which drives the arc plasma and the melt. Higher magnetic induction leads to excessive ejection of the melt onto the walls of the crystallizer 16, lower - to too slow rotation of both the arc and the melt, which reduces the intensity of the recovery process.

The magnitude of the arc gap is set and maintained in the recovery process equal to 0.5-1 of the diameter of the electrode 22. With smaller values of the length of the arc, erosion of the electrode 22 increases due to the ingress of oxide melt onto it. At large values of the length of the arc increase heat loss due to energy exchange between the column of the arc and the housing 15 of the reactor 14.

The flow rate of the reducing gas through the liquid phase reactor 14 is set equal to 1-1.5 of the value of the thermodynamically necessary flow rate. The gas flow rate through the solid-state preliminary reduction reactor 1 is set so that the average temperature of the gas and the mixture in this reactor as a result of gas mixing - supplied through the valve 34 and exiting through the perforation of the cylinder 7 into the reactor 1 - is in the range of 700-1000 ° C. At lower temperatures, the speed of the recovery process decreases. At a higher temperature, oxide particles, such as iron, stick together.

The plasma arc current is set such that the thermodynamically necessary thermal conditions in the reaction volume are provided. For example, when recovering iron ore concentrate in a copper crystallizer 16, the specific heat flux to the melt pool mirror should be about 5 MW / m ² , which for a copper crystallizer 16 with a diameter of 100 mm corresponds to a current value of 1200 A. With a lower heat flux, iron does not recover, with a larger excessive evaporation of the metal occurs.

The role of the magnetic field in the reactor 1 is that it holds the particles of raw materials in suspension, prevents the removal of raw materials from the reactor 1 and helps to intensify its recovery. Since the ore raw material - magnetite has a certain electrical conductivity, and at a temperature below the Curie point (for iron 770 ° C) and ferromagnetic properties, the particles of the raw material are exposed to a magnetic field (Figs. 1, 3-5). However, when heated above the Curie point, the ferromagnetic properties decrease, the substance turns into a paramagnet, and the magnetic field ceases to act on the substance.

The moving magnetic field created by the stator 54 (Fig.6), differs from other proposed options for creating a magnetic field in that it acts on a substance having electrical conductivity, regardless of its magnetic properties and can be used at a temperature in the reactor 1 above the point Curie

The magnetic field generated by passing the arc current through the rod 25 (figure 1) is maximum near the axis of the reactor 1 and decreases to its periphery. Ferromagnetic pins or ribs 56 mounted on a cylinder 7 made of non-ferromagnetic material increase the uniformity of the field along the radius of the reactor 1.

The magnetic field formed by the conductors 49 (FIG. 3), on the contrary, is maximally at the periphery of the reactor 1 and is also aligned with pins 56.

In the combined system of creating a magnetic field, the upper current lead 28 is connected to both the rod 25 and the upper connection of the conductors 49, which are connected by their lower ends to the lower current lead 30 and the first clamping device 13. In this case, the magnetic field is distributed most uniformly along the radius of the reactor 1.

A significantly larger magnetic field can be created by the second solenoid 50; the intensity of this field can vary over a wide range by changing the number of turns of the solenoid (figure 4).

Current-carrying elements 51 included in the "shoulders" of the rectifier bridge 52 (Fig. 5) form a pulsating magnetic field. A pulsating magnetic field creates the mobility of the ore particles, intensifies heat and mass transfer and helps to increase the recovery rate.

The stator 54 creates a moving magnetic field (Fig.6). In this case, the stator of a conventional cylindrical shape creates a rotating magnetic field, and the linear stator (expanded stator) is made in the form of one or several sections placed around the cylindrical part of the solid-phase reactor so that their magnetic cores are oriented along the axis of the reactor and creates a field moving along the axis reactor 1.

In the reverse polarity mode (the working electrode 22 is connected to the positive, the crystallizer 16 to the negative poles of the DC power source) and with alternating electric arc current 57, the set and sequence of process steps remain the same as in the direct polarity mode, but the processes of the reducing agent interact with partially restored charge. In the reverse polarity mode, the positive ions of the reducing gas formed in the arc discharge are entrained in the direction of the melt 17 not only by the gas flow, but also under the action of attractive forces to the negatively charged melt 17. In this case, the metal recovery in the melt pool is more intense.

When using an electric arc of alternating current, recovery reactions occur, characteristic of the first two modes, and at the same time it becomes possible to abandon the rectifier, the cost of which at power consumption is a significant fraction of the cost of the device.

Despite a significant reduction in the consumption of the electrode 22 (at least 2 times), to ensure continuous production of cast billets, it is envisaged to build up the working electrode 22 with a backup electrode 24 without turning off the arc, terminating the recovery process and freezing the melt bath. The device 38, the casing 39, the screw 40, the rod 41 and the rod 25 form an electrode block that provides a working electrode 22 and its extension by a backup electrode 24. The rod 25 is made in the form of a metal pipe with a plug in the upper part containing a rectangular hole for the rod 41 . In the lower part of the rod 25 there is a thread for connection with the electrode 24 and openings for the exit of gas entering through the cavity of the electrodes 22 and 24 from the working volume of the liquid-phase reactor 14.

The electrode 22 as it is consumed is supplied to the arc zone by the drive device 38 by moving the rod 25 by the screw 40. Gradually, the electrode 22 is consumed to the end and the electrode 24, which was previously the backup, begins to play its role. With the consumption of this electrode, which has now become the working electrode 22, it is fixed to about half the length by the first clamping device 13, through which power is supplied to the electrode 22 by means of the switch 29. The rod 25 is unscrewed from the electrode 22 from the electrode 22 and lifted up by the screw device 40. The third clamping device 26 is thus unclenched. Then, the supply of reducing gas is shut off by the valve 34 and neutral gas is supplied to the radial channels of the second clamping device 37 through the line with the valve 36. The electrode unit is diverted away from the second clamping device 37 and a new backup electrode 24 is introduced through its central hole into the cylinder 7 and fixed by the second clamping device 3.

After that, the electrode block is returned to its working position and fixed. The rod 25 is screwed onto the fixed electrode 24, the clamping device 37 releases the fixation of the electrode 24, after which the rod 25 together with the backup electrode 24 is moved down and screwed to the fixed working electrode 22. The inert gas supply is shut off, the supply of reducing gas by the valve 34 is resumed, with the third clamping device 26 fix the flexible bus 27 on the upper part of the rod 25, switch the power supply to the rod 25 by the switch 29, open the first clamping device 13, and continue the process as usual.

The removal of the supply path of the material and the reducing gas beyond the working electrode and the removal of exhaust gases through its cavity made it possible to solve several technical problems. Namely, the present invention reduces the consumption of the working electrode due to at least four factors:

- the exclusion of contact of the oxide ore material with a graphite working electrode 22 and its oxidation;

- the release of the cavity of the electrode 22 from the feed through it of ore raw materials can reduce the diameter of this cavity, thereby increasing the working mass of the electrode 22 and reduce the current density in it;

- the passage of the reaction products through an arc discharge and their removal from the reaction volume through the cavities of the electrodes 22 and 24 ensures interaction with the electrode material 24 (usually carbon) not of primary reducing gas, for example unconverted natural gas, but of a gas mixture consisting mainly of CO, CO ₂ , H ₂ and H ₂ O. The total carbon content in this mixture is excessive with respect to oxygen, which prevents the erosion of electrode 22 due to oxidation of graphite and blockage of its cavity;

- heating the working end of the electrode 22 with hot exhaust gases (3000-6000 ° C) contributes to the formation of diffuse (distributed) binding of the arc to the electrode 22 and eliminates the contracted spots of the arc, which in the known devices are the main cause of erosion of the electrode 22.

Besides:

- it was possible to finish the stage of metal production in the mold 16; the metal is not contaminated by the erosion products of the mold 16 and the working electrode 22;

- introducing reducing gas into the liquid-phase reactor 14 through a mixer and device 13 located above the cooled glass 23, and then through the gap between this glass 23 and the reactor shell 14 when using natural gas as a reducing agent, eliminates the problem of coking of the corresponding paths, since the gas temperature in These conditions are obviously lower than the temperature of its pyrolysis;

- to build up the working electrode 22, it is not necessary to disassemble the feed path and the equipment is completely stopped only for preventive maintenance and repair, which increases the productivity of the process as a whole;

- it is possible to create a magnetic field in the reactor 1 in the simplest way - by passing the discharge current through the rod 25 and electrodes 22 and 24, as well as the continuous operation of the device by switching the power supply during the installation of the backup electrode 24,

- partially restored mixture and reagents fall almost evenly on the entire bath mirror, which ensures the effective flow of mass transfer processes, saving raw materials and energy.

The passage through the plasma arc of the gaseous reaction products, including the incompletely reacted reducing agent, and fine oxide particles, due to the high temperature of the plasma and intensive mass transfer during its rotation, helps to accelerate chemical processes and their course with the maximum use of the reducing properties of the reagents.

The implementation of the mold 16 from an electric and heat-conducting material chemically resistant to oxide melts using the rotation of the arc plasma and the melt in the axial magnetic field of the first solenoid 21 guarantees uniform heating and interaction with the reducing gas of the entire mass of the incoming charge and the formation of a homogeneous metal. Moreover, due to the possibility of using effective cooling of the crystallizer 16 and the presence of an axial magnetic field, it is possible to prevent accidental burning through an arc discharge, to abandon the use of a protective lining and ultimately to obtain a metal of the required composition with a low content of harmful impurities.

Arc plasma in the axial magnetic field of the solenoid 21 prevents the removal of the condensed phase (small particles) due to centrifugal forces arising from the rotation of particles in a rotating plasma, and this reduces the loss of raw materials.

The mold 16 can be made in a different cross-sectional shape. Several plasmatrons may be required to form a slab.

The use of a magnetic field in the reactor 1 prevents the removal of the charge from the reactor and provides optimal and efficient interaction of the raw material with the exhaust gases, which can significantly save energy consumption.

Reducing gas, mixed with the gaseous reaction products entering reactor 1, cooling the latter to a temperature of 700-1000 ° C, not only prevents the particles from sticking together, but also uses some of the arc energy expended to heat them in the reactor 14.

The use of the proposed technological processes and structural elements in the complex allows to reduce the number of redistributions, namely, by loading the raw materials into the device, to obtain a workpiece of the required composition and configuration at the output, in particular, when using iron-containing ore raw materials, continuously obtain steel slabs suitable for rolling, stamping etc.

Thus, the present invention allows:

- get a homogeneous metal with a low content of impurities (e.g. carbon),

- reduce the consumption of graphite working electrode,

- use any reducing agents, including unconverted natural gas and hydrogen,

- reduce the loss of ore raw materials,

- provide almost continuous operation

- abandon the use of the hearth electrode while ensuring the explosion safety of the process,

- to simplify the technological scheme of production from dispersed ore raw materials of continuously cast metal billets.

As follows from the description of the operation of the device, the main technical result is achieved in the case of using the product collection device described in the prototype, or similar, because The difference between the proposed collection device and the prototype is the absence of a special hearth electrode, which is used as a mold 16 and a dovetail mechanism for drawing the blank 20. This difference affects the efficiency, but not the very possibility of implementing the main process. The design of the device, including the mold 16 and the first solenoid 21, is the most effective, because allows you to fully use the proposed features of the input of raw materials and gas and exhaust gas, in particular, creates the possibility of a reaction of final reduction at a higher temperature in the reaction volume with the achievement of the above advantages.

The invention can be used at the enterprises of metallurgy and engineering for the direct production of cast metal billets from dispersed ore materials using gaseous and dispersed reducing agents, including unconverted natural gas and hydrogen.

The environmental indicators of the proposed method and device are significantly higher than that of analogues: no coke is consumed, no agglomeration and pelletizing of ore materials is required. The use of hydrogen radically solves the problem of greenhouse gas emissions into the environment.

Test melting with the reduction of dispersed ore and ore concentrate was carried out on an experimental plasma-arc installation of direct polarity with a graphite electrode and using methane (an analogue of natural gas) as a reducing agent. With a plasma arc power of 70 kW, a direct reduction process was carried out to obtain iron in the form of an ingot with a diameter of 100 mm with a total impurity content of not more than 1.5%.

The industrial applicability of the invention is also confirmed by the widespread use in industry of individual elements of the invention, as follows from the description of the above analogues, but in other combinations and with other technical results.

The terms of reference have been prepared and an agreement has been concluded with a metallurgical complex enterprise for the development and manufacture of an industrial plant in accordance with the invention.

The possibility of realizing all the effects accompanying the transfer of the charge input outside the working electrode 22 proposed in the present invention, and the removal of reaction products through the cavity of the electrode 22, was established by us for the first time and has not been published anywhere. The following is a comparative table of indicators of the prototype and the proposed device for the recovery of iron ore concentrate with methane (model gas of natural gas).

TABLE Device view Energy technology indicator Product received Cathode consumption Reductant used Energy intensity of the process Removal of ore raw materials Explosion proof Prototype Cast iron 10 kg / t metal Dispersed metallurgical coal High: gasifier losses, process frequency High: up to 20% Low: large mass of melt in the furnace Proposed invention High purity iron: 1.5% impurities 3 kg / t metal Unconverted natural gas Low: process continuity Low: up to 5% High: low melt mass in the mold

Claims (25)

1. A method for the direct reduction of metals from dispersed ore raw materials, including preliminary reduction of the starting material — a charge, supply of a partially reduced charge, together with alloying additives and a reducing agent, to an electric arc furnace, excitation of an electric arc, melting and finishing reduction of a partially reduced charge, and removal of the finished product from the device and its collection, cooling of thermally loaded parts of the device, characterized in that the supply to the electric furnace of a partially reduced charge and gas A figurative reducing agent is produced on the mirror of the ore melt bath through a cavity located outside the working electrode, after arc excitation, melting and finishing reduction of the charge, the gaseous products of the reduction reaction are removed through the internal cavity of the working electrode and used for preliminary reduction, during which they create a circular, axial, a pulsating or moving magnetic field, and the flow rate of the working electrode is compensated. 2. The method according to claim 1, characterized in that in the process of preliminary reduction of the feedstock, reducing gas is mixed into the gaseous reaction products. 3. The method according to claim 2, characterized in that the flow rate of the working electrode is compensated by moving it to the arc region and, as the flow rate is increased, by introducing and connecting a backup electrode to it, while mixing the reducing gas into the separation zone cavity of the backup electrode from the surrounding space, a neutral gas is injected under pressure. 4. The method according to any one of claims 1 to 3, characterized in that in the combustion zone of the arc and the molten bath create an axial magnetic field. 5. The method according to claim 4, characterized in that in the process of output and collection of the finished product crystallize the metal and continuously output it in the form of a workpiece suitable for further processing. 6. A device for the direct reduction of metals from dispersed ore raw materials containing a feeder of the primary source material - the mixture, a solid-phase reactor for preliminary reduction of the mixture, means for supplying partially restored mixture and reducing reagents to the electric furnace, including a mixer located on the central axis of the working electrode with an internal cavity, liquid-phase reactor with a cylindrical body, a device for collecting the finished product from the molten bath and cooling means for thermally loaded hours This means that the working electrode and the collecting device are connected to the poles of the first power source, characterized in that an electrically conductive first clamping device with holes for passing a mixture of partially reduced charge and reducing gas and electrically conductive placed on its inner surface is placed in the electric furnace between the mixer and the liquid-phase reactor by pressing contact rollers or plates, a cooled metal cup is attached to the bottom of this device, in which on the axis of the clamping device a working electrode is placed, the solid-phase reactor is equipped with a means for creating a circular, axial, pulsating or moving magnetic field in the solid-phase reactor and a device for supplying electric current to this tool, the reactor itself consists of a cylindrical part with a cover and a conical part facing downward narrowing, with a bottom made with holes, and contains on the central axis a non-ferromagnetic perforated cylinder, a hollow backup electrode and a metal rod are installed in the cylinder cavity, while the working and reserve the electrodes and the rod are arranged sequentially from the bottom up and connected, and the rod in the lower part is made with perforation, a second clamping device, a casing with a drive for reversing movement and rotation of the rod and a charge feeder pipe mounted under it in the reactor are mounted on the cover of the solid-phase reactor a sprayer is placed, a partially reduced charge feed means is placed between the bottom of the solid-phase reactor and the mixer, the collecting device, the liquid-phase reactor body, the first clamping device The mixer and the mixer are separated by insulating gaskets, and the working electrode is connected to the power source through the first clamping device, the reducing gas supply means contains a first valve, after which the gas main is divided into two branches, one of which is connected to the solid-state reactor with the second valve, the other with the third valve - to the mixer, and the neutral gas line with the fourth valve is connected to the inner hole of the second clamping device. 7. The device according to claim 6, characterized in that the device for supplying current to the means of creating a magnetic field in a solid-state reactor contains a two-position three-pole switch, the "receiving" pole of which is connected to the first power source, and two transfer poles are connected to the means for creating the magnetic field, however, the first pole is also connected to the first clamping device. 8. The device according to claim 7, characterized in that a backup electrode and a rod are used as a means of creating a magnetic field, the upper end of which is connected to the second transfer pole of the switch through a flexible bus and a third clamping device. 9. The device according to claim 7, characterized in that the means of creating a magnetic field is made in the form of conductors longitudinal relative to the axis, arranged around the cylindrical part of the solid-phase reactor, the upper ends of the conductors are connected above the reactor and connected to the second transfer pole of the switch, and the lower ends are connected to the first dispensing pole. 10. The device according to claim 7, characterized in that the means of creating a magnetic field is made in the form of a second solenoid placed around the cylindrical part of the solid-phase reactor, the upper end of which is connected to the second transfer pole of the switch. 11. The device according to any one of claims 7 to 10, characterized in that the first power source is made in the form of a constant current source. 12. The device according to claim 11, characterized in that the "receiving" pole of the switch is connected to the negative and the collection device to the positive poles of the power source. 13. The device according to claim 11, characterized in that the "receiving" pole of the switch is connected to the positive and the collection device to the negative poles of the power source. 14. The device according to any one of paragraphs.7-10, characterized in that the first power source is made in the form of an alternating current source. 15. The device according to claim 6, characterized in that the means of creating a magnetic field in the solid-phase reactor is made in the form of a rectifier bridge, the "shoulders" of which are placed axially around the cylindrical part of the reactor, the device for supplying current to this tool contains a second power source in the form of an alternating source the current to which the input terminals of the bridge are connected, and the positive and negative output terminals of the bridge play the role of the first power source. 16. The device according to clause 15, wherein the first clamping device is connected to the negative, and the collection device to the positive output terminals of the bridge. 17. The device according to clause 15, wherein the first clamping device is connected to the positive, and the collection device is connected to the negative output terminals of the bridge. 18. The device according to claim 6, characterized in that the means of creating a magnetic field in the solid-state reactor is made in the form of a stator of an induction motor, and the current supply device includes a third current source, made in the form of a three-phase alternating current source. 19. The device according to p. 18, characterized in that the stator is cylindrical and placed around the cylindrical part of the solid-phase reactor. 20. The device according to p. 18, characterized in that the stator is linear in the form of one or more sections placed around the cylindrical part of the solid-phase reactor so that their magnetic circuits are oriented along the axis of the reactor. 21. Device according to any one of claims 6-10 or 15-20, characterized in that ferromagnetic pins or ribs are installed on the outer surface of the perforated cylinder. 22. A device according to any one of claims 6-10 or 15-20, characterized in that the collecting device is made in the form of a cooled mold made of an electrically and thermally conductive material, chemically resistant to oxide melts, the shape and dimensions of which correspond to the cast form blanks. 23. The device according to item 22, wherein the first solenoid is installed around the melt pool and the liquid-phase reactor vessel. 24. The device according to item 22, wherein the mold is provided with an opening for the release of slag. 25. The device according to any one of paragraphs.6-10 or 15-20, characterized in that the means for supplying partially restored charge is made in the form of a feed section with a screw feeder.

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