RU2617071C2 - Method of cooling melting unit housing and melting unit for its implementation - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: method of cooling the melting unit housing comprises feeding of liquid metal heat carrier into the melting chamber housing. The liquid metal heat carrier is cooled by gaseous heat carrier in the heat exchanger. The temperature of the liquid metal heat carrier is recorded. The liquid metal heat carrier cools the upper part of the sealed cavity by supplying liquid metal heat carrier into the cavity, covering the free space, slag bath and the top of the lined metal bath. The lower part of the sealed cavity is cooled by gaseous heat carrier supplied through nozzles arranged on a side surface of the heat exchanger outer wall. The heated gas is withdrawn from the heat carrier from the heat exchanger through nozzles. The liquid metal heat carrier temperature is maintained within the prescribed limits. Consumption of gaseous cold heat carrier is changed automatically or manually. The invention also includes a device for cooling the melting unit housing.

EFFECT: increased productivity and efficiency.

14 cl, 3 dwg

Description

The invention relates to metallurgy and to the field of processing of solid industrial and household waste. They can also be used in the energy sector for burning or gasifying coal with a high ash content on a layer of molten slag.

The high temperature in the working space of the melting chambers makes it necessary to protect the walls of their metal casing with refractory lining. During the operation of the melting chamber, the refractory lining is gradually destroyed (worn out) as a result of exposure to high temperature, chemical corrosion and mechanical erosion of the refractory material. Therefore, the melting chamber cannot operate continuously, and is periodically stopped for cold repair of the lining. This reduces productivity and affects the technical and economic performance of the melting chamber.

The period of continuous operation of the melting chamber can be significantly increased by providing the conditions for the formation of a skull (refractory conglomerate consisting of sintered charge materials, refractory lining, slag, dust, etc.) on the inner surface of the walls of the metal body of the melting chamber.

Known water cooling of the walls of the housing of the melting devices. This technique has been successfully used to cool walls and arches of arc steel-smelting furnaces [1], non-ferrous metallurgy furnaces [2], making the walls hollow. But water as a coolant has significant disadvantages:

- when water is heated to a temperature of 55 ° C and above, intensive scale formation occurs on the surface of the cooled element, as a result of this, heat dissipation slows down and the cooled element gradually fails; therefore, the maximum water temperature is maintained below 45 ° C, which leads to a very large flow of water;

- with local overheating of individual volumes of water in the cooled cavity due to the low boiling point of water, steam "plugs" may be formed that impair the cooling of the casing and lead to the destruction of the casing wall;

- the ingress of water during the destruction of the wall of the water-cooled element in the molten slag and metal can cause an explosion, leading to the destruction of the melting device.

Recently, designers of melting devices have shown interest in creating cooling systems for the body of the melting unit, using not metal as the primary coolant, but liquid metal coolants that have several advantages over water [3]: higher boiling points, better thermal properties (thermal conductivity, heat capacity) and etc.).

In practice, melting chambers with case cooling by liquid metal coolants are not yet used due to the complexity of the design and the difficulty of maintenance and repair of such devices [4-7].

A simpler method of cooling the body of the melting unit and the melting unit for its implementation were proposed in [8].

As the closest analogue of the claimed technical solutions, the applicant selected the well-known "Method of cooling the body of the melting unit and the melting unit for its implementation" (patent RU 2383837) [8].

A known method of cooling the body of the melting unit includes feeding a liquid metal coolant — sodium to the body of the melting chamber, made in the form of a double-walled metal shell with an airtight cavity, cooling the liquid metal coolant with a cold gaseous coolant passing through a heat exchanger. Cold gaseous coolant is fed into the cavity formed by the outer wall of the melting chamber body and the outer shell of the heat exchanger located directly on the melting chamber housing and containing pipe ends at the ends for supplying cold and selecting heated gaseous coolant.

Cold gaseous heat carrier is swirled in the cavity of the heat exchanger and is fed first to the parts of the heat exchanger adjacent to the sections of the casing of the melting chamber with the highest thermal loads, and then to the parts of the heat exchanger adjacent to the sections of the casing of the melting chamber with lower thermal loads.

The known melting unit comprises a melting chamber with a metal casing made in the form of a double-walled metal shell with an airtight cavity filled with a liquid metal heat carrier sodium, a heat exchanger for cooling the liquid metal heat carrier with a gaseous heat carrier, a refractory lining of a bath of molten metal, a device for loading, heating and melting of the charge for metal and slag, removal and purification of furnace gases and utilization of their heat.

A heat exchanger for cooling the liquid metal coolant with a gaseous coolant is located directly on the body of the melting chamber, its outer shell is located at a distance of 50-300 mm in diameter from the outer wall of the melting chamber and is made in the form of a sealed metal cylinder or part thereof with pipes for supplying cold and selection of heated gaseous coolant covering the melting chamber. The outer wall of the chamber serves as the inner shell of the heat exchanger, while curved copper strips are fixed at a distance of 3-300 mm from each other in the cavity between the outer wall of the melting chamber and the outer shell of the heat exchanger on the outer wall of the melting chamber.

The known method of cooling the casing of the melting unit and the unit for its implementation "have the following disadvantages:

- there is a supercooling of the lower part of the bath of the metal melt, the formation of a layer of solidified metal on the refractory lining of the metal bath, a decrease in the volume of the metal bath, difficulties in opening the metal gap when the metal is drained from the melting chamber due to intensive cooling of the entire inner wall of the body of the melting chamber with a liquid metal coolant;

- difficulty in transportation, storage and technical operation of the liquid metal coolant - sodium;

- the possibility of changing and regulating the flow of gaseous coolant in the heat exchanger is not provided for the purpose of reducing energy consumption, increasing the productivity of the melting chamber and increasing the overhaul periods of its operation;

- the supply of cold and the selection of heated gaseous heat carrier to the heat exchanger through the nozzles located at the ends of the melting device does not make it possible to place combined fuel-oxygen burner tuyeres in the ends of the melting chamber to accelerate the melting of the charge, as well as a metal and slag discharge device;

- copper plates placed in the cavity of the heat exchanger are expensive and significantly increase the mass of the melting chamber.

The task of the invention is to increase the efficiency of the method and the melting unit for its implementation.

The technical result of the method of cooling the casing of the melting unit and the melting unit for its implementation is to increase productivity and efficiency due to:

- effective heat removal from the inner working wall of the housing and intensive cooling of only its necessary parts;

- elimination of supercooling of the lower part of the bath of the metal melt, exclusion of the layer of solidified metal on the refractory lining of the metal bath;

- maintaining the volume of the metal bath;

- simplification of transportation of the coolant and maintenance of the cooling system of the melting unit;

- energy saving, gaseous coolant flow rate while lowering the temperature of the liquid metal coolant, eliminating the destruction of the skull or reducing the thickness of its layer;

- uniform and rapid melting of the charge and the rational location of the combined fuel-oxygen burner-tuyeres and the device for the release of metal and slag;

- reducing the total mass of the melting chamber and the cost of its manufacture.

The technical result is achieved by the following solutions, united by a common inventive concept.

In the method of cooling the body of the melting unit, comprising supplying a liquid metal coolant to the body of the melting chamber, made in the form of a double-walled metal shell with a sealed cavity, cooling the liquid metal coolant with a gaseous heat carrier passing through a heat exchanger located directly on the case of the melting chamber, according to the first invention, the liquid metal coolant is cooled part of the sealed cavity formed by a double-walled metal shell to the housing of the melting chamber, by feeding a liquid metal coolant into the cavity covering the free space, the slag bath and the upper part of the lined metal bath, and the lower part of the sealed cavity formed by the double-walled metal shell of the body, separated from the upper part and covering the lower part of the lined metal bath, is cooled only gaseous coolant supplied through nozzles placed on the side surface of the outer wall of the heat exchanger, heated gaseous the heat carrier is taken from the heat exchanger through nozzles located on the side surface of the outer wall of the heat exchanger, the temperature of the liquid metal coolant is maintained within specified limits, automatically or manually changing the flow rate of the gaseous cold coolant passing through the heat exchanger, depending on the readings of the device fixing the temperature of the liquid metal coolant.

The gaseous coolant is fed into the cavity formed by the outer wall of the housing of the melting chamber and the outer wall of the heat exchanger.

The temperature of the liquid metal coolant is maintained within 450-500 ° C.

Sodium can be used as a liquid metal coolant.

Lead may be used as the liquid metal coolant.

As a liquid metal coolant, a lead-bismuth alloy can be used.

Air can be used as the gaseous heat carrier.

Nitrogen can be used as the gaseous heat carrier.

The gaseous heat carrier heated in the heat exchanger is used for injecting injectors into the melt located in the melting chamber of finely divided charge materials and dust trapped by gas cleaning.

The gaseous coolant heated in the heat exchanger is mixed with the gases having a temperature of 1600-1800 ° C leaving the melting chamber or charge heater.

The air heated in the heat exchanger is used for afterburning CO and H ₂ present in the composition of the gas mixture leaving the melting chamber or heater.

In a melting unit containing a melting chamber with a metal body in the form of a double-walled metal shell with an airtight cavity filled with a liquid metal coolant, a heat exchanger for cooling the liquid metal coolant with a gaseous coolant, refractory lining of the molten metal bath, loading, heating and melt melting devices for metal and separate slag, removal and purification of furnace gases and utilization of their heat, according to the second invention, the upper part of the tight the cavity formed by the double-walled metal shell of the casing of the melting chamber and filled with liquid metal coolant in the free space, the slag bath and the upper part of the metal bath, is separated by a partition from the lower part of the same cavity filled with gaseous coolant in the region of the lower part of the lined metal bath, the outer wall of the lower part the double-walled metal shell of the housing of the melting chamber has openings for supplying and withdrawing gaseous coolant from the system to toric cooling of the liquid metal coolant, nozzles for supplying cold gaseous coolant to the heat exchanger located on the body of the melting chamber for cooling the liquid metal coolant and selection of the heated gaseous coolant are located on the side surface of the outer wall of the heat exchanger, in the upper part of the melting chamber body and in the cavity of the body filled with the liquid metal coolant a device detecting the temperature of the liquid metal coolant is installed, associated with the automatic process control system or the operator of the melting chamber, adjusting the flow of gaseous coolant in the heat exchanger.

The diameter of the holes in the lower part of the outer wall of the metal shell of the housing may be 30-50 mm.

The holes in the lower part of the outer wall of the metal shell of the housing can be located at a distance of 150-200 mm from each other.

The cavity in the housing of the melting chamber for the liquid metal coolant may be filled with sodium.

The cavity for the liquid metal coolant in the housing of the melting chamber may be filled with lead.

The cavity for the liquid metal coolant in the body of the melting chamber may be filled with a lead-bismuth alloy.

Combined fuel and oxygen tuyeres are located in the side and end walls of the body of the melting chamber.

Holes for the release of metal and slag are located in the end walls of the body of the melting chamber.

In the cavity between the outer wall of the melting chamber and the outer shell of the heat exchanger, curved strips of aluminum or aluminum alloy are fixed at a distance from each other on the outer wall of the melting chamber.

In the method of cooling the case of the melting unit, the cooling of the upper part of the sealed cavity formed by the double-walled metal shell of the body of the melting chamber is carried out by feeding a liquid metal coolant into the cavity, covering the free space, the slag bath and the upper part of the lined metal bath, which provides intensive heat removal only from that part internal working walls of the case, which are subjected to the greatest thermal loads, and guarantees the formation of garnishes on them soot. The skull protects the internal working walls of the housing and reduces the heat loss of the chamber, ensuring the efficiency of the method.

The lower part of the sealed cavity formed by the double-walled metal shell of the housing and separated from its upper part, covering the lower part of the lined metal bath, is cooled only by gaseous heat carrier. The heat from the lower part of the metal bath is less intensively removed, the metal in it does not cool down, the difficulties with opening the metal notch and draining the metal from the melting chamber are excluded, the lining service life is increased, a long continuous process of melting and processing of various charge materials is carried out without stopping the melting unit, those. achieved increased productivity of the method and efficiency.

The supply of cold gaseous coolant into the cavity formed by the outer wall of the melting chamber body and the outer wall of the heat exchanger, and the selection of heated gaseous coolant from the cavity through nozzles located on the side surface of the outer wall of the heat exchanger, allows you to free the end walls of the melting chamber and place combined fuel and oxygen burners in them lances to ensure a more uniform and faster melting of the charge, and tap holes for the release of metal and slag, which increases production telnost and economical fashion.

Adjusting the flow rate of gaseous cold coolant passing through the heat exchanger, depending on the readings of the device that fixes the temperature of the liquid metal coolant in the upper part of the cavity of the melting chamber, allows you to save energy by reducing the flow of gaseous coolant while lowering the temperature of the liquid metal coolant to 450 ° C and lower, and to avoid destruction of the skull or reducing the thickness of its layer, increasing the consumption of gaseous coolant with increasing temperature metal coolant up to 500 ° С.

The use of sodium as a liquid metal coolant allows intensive heat removal from the cooled internal surfaces of the melting chamber. Sodium has high thermal conductivity and heat capacity, low melting point and high boiling point (900 ° C). But the use of sodium requires a high culture and technological discipline of production and careful maintenance of the cooling system.

The use of lead as a liquid metal coolant greatly simplifies the transportation of the coolant, simplifies and facilitates the maintenance of the cooling system of the melting unit, does not require a very high technological discipline and production culture. But lead has lower thermal conductivity and heat capacity and a higher melting point than sodium.

The use of lead-bismuth alloy as a liquid metal coolant allows you to realize the same advantages as when using lead, and has the same disadvantages as using lead. But the lead-bismuth alloy has a lower melting point, which is more convenient than when using lead.

The use of air as a gaseous coolant is the simplest and cheapest option for the secondary cooling of a liquid metal coolant.

The use of nitrogen as a gaseous coolant can reduce the fire hazard of the cooling system of the melting chamber case during the initial cooling of the case with sodium, since in case of leakage from the cooling cavity it will not be oxidized in a nitrogen atmosphere.

The use of a gaseous heat carrier heated in a heat exchanger instead of a cold carrier gas for injecting finely divided charge materials and dust collected by gas cleaning into the melt in the melting chamber allows to reduce heat loss by the melt, reduce fuel consumption and increase the productivity of the melting chamber.

Mixing the gaseous heat carrier heated in the heat exchanger with the gases having a temperature of 1600-1800 ° C leaving the melting chamber or the charge heater, allows to reduce the temperature of the exhaust gas, increase the degree of utilization of the heat generated in the melting chamber due to the heat of the heated gaseous coolant and to reduce dust buildup on the working surface of the recovery boiler.

The use of heated air in the heat exchanger for the afterburning of CO and H ₂ present in the composition of the gas mixture leaving the melting chamber or the heater makes it possible to increase the degree of utilization of the heat produced in the melting chamber due to the heat of the heated air, reduce energy consumption and reduce the total amount of gases, passing through gas cleaning.

In the smelting unit, a partition separates the upper part of the sealed cavity formed by the double-walled metal shell of the casing of the melting chamber and filled with liquid metal coolant in the free space, the slag bath and the upper part of the metal bath, and the lower part of the same cavity filled with gaseous coolant in the lower part of the lined metal bathtubs, allows to increase productivity and profitability. Intensive heat removal is provided only from those parts of the melting chamber body that are subjected to the greatest heat loads, since only a sealed cavity covering the free space, the slag bath and the upper part of the lined metal bath is filled with the liquid metal coolant. A skull forms on the walls of the melting chamber, which protects the outer walls of the casing and reduces the heat loss of the chamber through them. Heat is not intensively removed from the lower part of the metal bath, the metal in it is not supercooled, difficulties with opening the metal door (doors for metal release) are excluded, and metal drainage from the melting chamber is facilitated.

Holes with a diameter of 30-50 mm, located at a distance of 150-200 mm from each other, in the outer wall of the lower part of the double-walled metal shell of the housing of the melting chamber, separated from the upper part, serve to supply and select gaseous coolant from the secondary cooling system of the melting chamber. The supply of gaseous coolant into the cavity of the lower part of the double-walled shell of the housing of the melting chamber allows less intensive cooling of the refractory lining of the metal bath, to increase the service life of the lining, without overcooling the metal in the bath.

The location of the nozzles for supplying a cold gaseous coolant to a heat exchanger located on the body of the melting chamber for cooling the liquid metal coolant and selecting heated gaseous coolant from it on the side surface of the outer wall of the heat exchanger allows you to free the end walls of the melting chamber and place combined fuel-oxygen burner-tuyeres and letlets in them for exhaustion metal and slag.

Placing combined fuel-oxygen tuyere burners in the end walls of the melting chamber allows for more uniform and faster melting of the charge.

Placing the slots for the release of metal and slag in the end walls of the melting chamber allows simplifying the layout of the melting department of the workshop by dividing the flows of metal and slag after draining them from the melting chamber.

The installation of the temperature recording liquid metal coolant device in the upper part of the housing of the melting chamber, in the cavity of the body filled with liquid metal coolant, allows you to register the highest temperature of the liquid metal coolant (450-500 ° C) in the melting chamber. This temperature determines the required flow rate of the cold gaseous heat carrier in the heat exchanger for cooling the liquid metal coolant. The connection of the recording device with the automatic process control system or the operator of the melting chamber allows you to quickly adjust the flow of cold gaseous coolant in the heat exchanger. Regulation of the flow of gaseous coolant depending on the maximum temperature of the liquid metal coolant can reduce energy consumption and increase the stability of the skull layer on the wall of the melting chamber.

Filling the cavity in the housing of the melting chamber for a liquid metal coolant with sodium allows you to intensively remove heat from the inner working wall of the melting chamber, provides the formation and constant presence of a skull on the walls of the melting chamber.

Filling the cavity for the liquid metal coolant in the body of the melting chamber with lead or a lead-bismuth alloy also allows you to intensively remove heat from the inner working wall of the melting chamber, ensures the formation and constant presence of a skull on the walls of the melting chamber.

The use of lead and a lead-bismuth alloy is more profitable in cases where it is not possible to ensure a high production culture and high qualification of service personnel in a workshop equipped with a melting chamber.

The installation of combined fuel-oxygen burner-tuyeres in the side and end walls of the body of the melting chamber provides a more uniform and faster melting of the charge than in the case when the burner-tuyeres are located only in the side walls of the melting chamber.

The location of the holes (let) for the release of metal and slag in the end walls of the melting chamber allows you to separate the flows of metal and slag, improve the organization of production, increase the productivity of the melting unit.

Fastening the curved strips of aluminum or aluminum alloy at a distance from each other on the outer wall of the melting chamber in the cavity between the outer wall of the melting chamber and the outer shell of the heat exchanger allows you to swirl the gaseous coolant flows, reduces the total mass of the melting chamber and reduces the cost of manufacturing the melting chamber compared to option for using copper strips.

The following is a description of a method for cooling a case of a melting unit and a melting unit with reference to the accompanying drawings.

In FIG. 1 shows a longitudinal section of a melting unit with a heat exchanger assembly.

In FIG. 2 is a cross-sectional view of a melting unit with a heat exchanger assembly.

In FIG. 3 shows a top view of a melting unit with a heat exchanger assembly.

A method of cooling a case of a melting unit includes supplying an intermediate liquid metal coolant to the upper part of the sealed cavity 10 formed by a double-walled metal shell of the body of the melting chamber 20 with an outer wall 8 and an inner wall 9. The liquid metal coolant is supplied into the cavity 10, which covers the free space 3, the slag bath 2 and the upper part of the lined metal bath 1 of the melting chamber 20. The intermediate liquid metal coolant is cooled in a heat exchanger 21, p Placed directly on the body of the melting chamber 20, a cold gaseous coolant. Separated from the upper part 10, the lower part of the sealed cavity formed by the double-walled metal shell of the casing of the melting chamber 20, covering the lower part 7 of the metal bath 1, is cooled only with cold gaseous coolant. Cold gaseous heat carrier is fed into the cavity 7, formed by the outer wall 8 of the housing of the melting chamber 20 and the outer wall 4 of the heat exchanger 21, through a pipe 17 located on the side surface of the outer wall 4 of the heat exchanger 21. The heated gaseous heat carrier is taken from the heat exchanger 21 through the pipe 18 located on the side surface of the outer wall 4 of the heat exchanger 21. The temperature of the liquid metal coolant is maintained within 450-500 ° C, automatically or manually changing the flow rate of cold gaseous about the coolant passing through the heat exchanger 21, depending on the readings of the device 12, fixing the temperature of the liquid metal coolant in the upper part 10 of the cavity of the housing of the melting chamber 20.

Sodium, lead, or a lead-bismuth alloy can be used as the liquid metal coolant.

Air or nitrogen may be used as the gaseous heat carrier.

The gaseous heat carrier heated in the heat exchanger 21 is used for injecting injectors (not shown in the figures) into the melt, located in the melting chamber 20, of finely divided charge materials and dust collected by gas cleaning (not shown in the figures).

The gaseous heat carrier heated in the heat exchanger 21 is mixed with the gases having a temperature of 1600-1800 ° C leaving the melting chamber 20 or the charge heater, reducing the temperature of the exhaust gases and reducing the buildup of dust on the walls of the recovery boiler (not shown in the figures), in which the gases are used to generate steam.

Heated air in the heat exchanger is used for afterburning of CO and H ₂ present in the composition of the gas mixture leaving the melting chamber or heater, increasing the degree of utilization of the heat produced in the melting chamber 20.

The melting unit for implementing the method comprises a melting chamber 20 with a metal body made in the cooling zone in the form of a double-walled metal shell, a heat exchanger 21 for cooling the primary liquid metal coolant, covering the body of the melting chamber 20, charging, heating and melting devices of the charge (not shown in the figures) , removal, purification of gases leaving the melting chamber and utilization of their heat (not shown in the figures).

The body of the melting chamber 20 is made in the form of a double-walled (wall 8, 9) metal shell. The upper part of the sealed cavity formed by the double-walled metal shell 10 is filled with a liquid metal coolant and covers only the free space 3, the slag bath 2 and the upper part of the metal bath 1 of the melting chamber 20. The lower part of the cavity 7 formed by the double-walled metal shell of the melting chamber 20 is separated from the upper part 10 of the cavity by a partition 19. The outer wall of the lower part of the double-walled metal shell of the casing of the melting chamber has holes with a diameter of 30-50 cm (in Fig. but not shown) located at a distance of 150-200 mm from each other for supplying gaseous heat carrier and the selection of the secondary cooling liquid metal coolant. On the side surface of the outer wall 4 of the heat exchanger 21 located on the housing of the melting chamber 20, there are nozzles 17 for supplying a cold gaseous coolant and a nozzle 18 for selecting a heated gaseous coolant. In the upper part of the casing of the melting chamber 20 and in the upper cavity of the casing filled with the liquid metal coolant, a device 12 is detected that records the temperature of the liquid metal coolant associated with an automatic process control system or the operator of the melting chamber that adjusts the flow rate of the gaseous coolant in the heat exchanger.

The cavity in the housing of the melting chamber for the liquid metal coolant is filled with sodium, or lead, or a lead-bismuth alloy.

Combined fuel-oxygen burner lances 11 are located in the side and end walls of the housing of the melting chamber 20.

The hole 5 for the release of metal and the hole 14 for the release of slag, the groove 6 for draining the metal and the groove 15 for draining the slag are located in the end walls of the housing of the melting chamber 20.

In the cavity between the outer wall 8 of the melting chamber 20 and the outer shell 4 of the heat exchanger 21 on the outer wall 8 of the melting chamber 20, curved strips of aluminum or aluminum alloy are fixed at a distance from each other (not shown conventionally in the figures).

The molten molten metal bath 1 is lined with refractory bricks 16, for example fused periclase bricks.

The method of cooling the housing of the melting unit and the unit for its implementation are as follows.

The housing of the melting chamber 20 is heated by turning on the combined fuel-oxygen burner tuyeres 11 for reduced power. The walls 8, 9 of the case are heated to a temperature of 200-250 ° C, the liquid metal coolant is heated in a reserve tank with a special heating system, and the liquid metal coolant is pumped into the upper part of the cavity 10 between the walls 8, 9 of the body of the melting chamber 20. After that, the power introduced into the melting chamber is increased the chamber 20 with combined tuyeres-lances 11, and cold gaseous heat carrier is supplied to the heat exchanger 21 for cooling the liquid metal coolant. A fusible metal mixture, for example cast iron shavings, is loaded into the melting chamber 20 through an opening 13, it is melted and the metal bath 1 is filled with molten metal to protect the refractory lining 16 from the aggressive effects of molten slag. After that, through the batch heater, the exhaust gases (not shown conventionally) start loading the standard batch at the required speed, and the melting chamber 20 then operates continuously. After filling the slag bath 2, open the slag notch 14, and through the trough 15, an excess amount of slag is poured from the melting chamber into the slag ladle or into the slag granulation unit. The slag discharge rate is maintained such that during continuous or periodic loading of the charge, the level of slag melt in the melting chamber changes insignificantly or remains constant. The metal melt accumulating in the metal bath 1 is periodically drained from the melting chamber 20 through a metal groove 5 along the lined groove 6 into the casting ladle so that the level of the metal melt does not decrease by more than 150-250 mm.

Due to the intense heat removal by the liquid metal coolant from the inner wall of the casing of the melting chamber 9 on its surface in the free space 3 and in the zone where the slag melt is located (slag bath 2), a layer of skull is formed from slag, dust, non-melted charge protecting the wall from destruction and reducing heat loss melting chamber. Due to the cooling of the upper most vulnerable part of the refractory lining of the metal bath with liquid metal coolant and the cold gaseous coolant of the rest of the lining of the metal bath, the service life of the lining 16 is significantly increased. In this case, there are no difficulties with the discharge of metal from the melting chamber.

Thus, the proposed invention makes it possible to carry out a long continuous process of melting and processing various charge materials without stopping the melting chamber for repairing the lining, and to reduce operating costs when using the melting chamber.

Information sources

1. Gudim Yu.A. Steel production in arc furnaces. Designs, technology, materials / Yu.A. Goodim, I.Yu. Zinurov, A.D. Kiselev. - Novosibirsk. Publishing house of NSTU, 2012 .-- 547 p.

2. Utkin N.I. Non-ferrous metal production. - M .: Intermet Engineering. - 2004 .-- 442 p.

3. Liquid metal coolants / Borishansky V. M., Kutateladze S. S., Novikov I. I. et al. - M.: Atomizdat, 1976 .-- 328 p.

4. UK patent No. 1566980, cl. F27D 1/12, 1980.

5. US patent No. 4913734, CL. F27B 11/08, 1990.

6. US patent No. 3735010, CL. F27D 1/12, 1973.

7. Patent RU 2067273 "Method for cooling a melting furnace and a melting furnace for its implementation." Authors: Belinsky V.S., Borisov V.V., Oleichik V.I., Poplavsky V.M., Denisov V.V., Reshetov O.I., Reshetin A.S., Oleichik I.V., Kravchenko I.N. Patentee: Joint Stock Company "Technoliga".

8. Patent RU 2383837 "Method for cooling the body of the melting unit and the melting unit for its implementation." Authors: Golubev A.A., Gudim Yu.A., Tregubov I.O., Sergeev VV, Nadinsky Yu.N. Patent holder: Limited liability company Industrial company "Technology of metals".

Claims (14)

1. The method of cooling the body of the melting unit, including the supply of liquid metal coolant to the sealed cavity formed by the double-walled metal shell of the body of the melting unit, cooling the liquid metal coolant with a gaseous heat carrier in a heat exchanger located on the body of the melting unit, and registering the temperature of the liquid metal coolant, which is different served in the upper part of the aforementioned airtight cavity, covering pr the space above the bath with the slag melt, the bath with the slag melt and the upper part of the bath with the molten metal, the lower part of the sealed cavity covering the lower part of the bath with the molten metal is separated from the upper part of the sealed cavity by means of a partition and the gaseous heat carrier is supplied through a nozzle located on the side surface of the outer wall of the heat exchanger, while the heated gaseous heat carrier is taken from the heat exchanger through a nozzle located on the side surface of the outer wall heat exchanger, and the specified temperature of the liquid metal coolant is maintained by automatically or manually changing the flow rate of the gaseous cold coolant passing through the heat exchanger. 2. The method according to p. 1, characterized in that the predetermined temperature of the liquid metal coolant is maintained within 450-500 ° C. 3. The method according to p. 1, characterized in that sodium is used as the liquid metal coolant. 4. The method according to p. 1, characterized in that lead is used as the liquid metal coolant. 5. The method according to p. 1, characterized in that the lead-bismuth alloy is used as the liquid metal coolant. 6. The method according to p. 1, characterized in that air is used as the gaseous heat carrier. 7. The method according to p. 1, characterized in that nitrogen is used as the gaseous heat carrier. 8. A device for cooling the body of a melting unit containing a metal body made in the form of a double-walled metal shell forming an airtight cavity for a liquid metal coolant, a heat exchanger for cooling the liquid metal coolant with a gaseous coolant installed on a metal case of the melting unit, and a device for recording the temperature of the liquid metal coolant the fact that the upper part of the sealed cavity, covering the space above a bath with slag melt, a bath with slag melt and the upper part of the bath with molten metal, separated by a partition from the lower part of the aforementioned pressurized cavity, covering the lower part of the bath with molten metal, made with the possibility of supplying gaseous coolant to it, in the outer wall of the lower part of the double-walled metal the shell shell of the melting chamber has holes for supplying and selecting a gaseous coolant, while on the side surface of the outer wall of the heat exchanger there are nozzles for supplying a cold gaseous coolant to a heat exchanger located on the metal housing of the melting unit and selecting a heated gaseous coolant, the temperature recording device for the liquid metal coolant is installed in the upper part of the sealed cavity of the metal housing of the melting unit and is connected to an automatic process control system for the melting unit that corrects the flow of the gaseous coolant in the heat exchanger. 9. The device according to p. 8, characterized in that the diameter of the holes in the lower part of the outer wall of the metal shell of the casing is 30-50 mm. 10. The device according to p. 8, characterized in that the holes in the lower part of the outer wall of the metal shell of the housing are made at a distance of 150-200 mm from each other. 11. The device according to p. 8, characterized in that the sealed cavity in the housing of the melting unit for the liquid metal coolant is filled with sodium. 12. The device according to p. 8, characterized in that the sealed cavity for the liquid metal coolant in the housing of the melting unit is filled with lead. 13. The device according to p. 8, characterized in that the sealed cavity for the liquid metal coolant in the body of the melting unit is filled with a lead-bismuth alloy. 14. The device according to p. 8, characterized in that in the sealed cavity between the outer wall of the metal housing of the melting unit and the outer wall of the heat exchanger on the outer wall of the metal housing of the melting unit, curved strips of aluminum or aluminum alloy are fixed at a distance from each other.

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