RU2480694C1 - Reverberatory furnace for metal remelting - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: furnace includes a housing formed with side, front and rear external end refractory walls, a storage bath that is restricted with a bottom and walls, an inclined platform, an arch, a drain tap-hole and a gas duct. The housing is arranged on a welded concrete-cast frame with filler from diatomite chips and provided with two heat-insulating layers from light brick and asbestos board plates under the bottom, two heat-insulating layers from light brick and four layers of asbestos board plates under the inclined platform. The storage bath and the inclined platform are made of mullite-corundum blocks MKP-72 laid on three layers of asbestos board and have packing from diatomite chips, which are mixed with crushed asbestos chips. The furnace has lower and upper large arches located one above another so that a gap for a flue gas duct is formed between them. The furnace is equipped with a rotating chute having the possibility of being turned during liquid metal pouring and having an intermediate nose, a rotating bowl with a shaft welded in its lower part, the end of which is pressed into an inner shell of a ball bearing, and its outer shell is fixed in a bracket fixed in the rear wall of the furnace; at that, a long pouring nose with two handles is welded to the turning bowl for series pouring of metal molten in the furnace to the pouring equipment located in the service sector at an angle of 140°. Front wall of the furnace is provided with a row of injection burners of intermediate pressure, out of which two eight-mixer burners with long flame are directed on edges to the charge contained on the inclined platform and to the bath with molten metal, one burner BIGm 2-6 and two burners BIGm 2-12 are directed to the charge.

EFFECT: high furnace capacity, reduction of heat losses and melting loss and possible environmentally safe remelting of aluminium scraps.

7 cl, 5 dwg

Description

The invention relates to ferrous metallurgy, and in particular to smelting units for remelting secondary aluminum scrap and waste aluminum alloys into ingots and ingots. The furnace can be used for refining, producing alloys, averaging the chemical composition of scrap.

A known analogue is a reflective furnace for remelting metal (RF patent No. 2155304), comprising a housing formed by masonry of external walls, as in the claimed furnace, a storage bath and an inclined platform limited by a hearth and walls, a vault, a drainage drain and a gas duct.

The disadvantages of this furnace are:

1. The complexity of the design due to the presence of two arches (small above the loading table and large above the bathroom).

2. The lack of external thermal insulation of the furnace, reducing heat loss to the external environment.

3. The furnace does not have a dust and gas cleaning system and during operation will pollute the environment with harmful emissions.

4. The furnace uses a stationary chute to drain molten metal.

5. From the description of the furnace it follows that it is equipped with only one nozzle. This is clearly not enough to ensure a high rate of penetration of the charge and maintaining a forced melting mode. Due to the above disadvantages, the furnace cannot provide a solution to the technical problem.

A known analogue is a reflective furnace for remelting metal (RF patent No. 2047663), comprising a housing formed by brickwork of external walls, as in the claimed furnace, a storage bath and an inclined platform bounded by a hearth and walls, a vault, a drain and a flue.

The furnace is designed for remelting secondary aluminum and has the following disadvantages:

1. The high cost and complexity of the accumulating heat pillows (lightweight refractory bricks, blooms).

The large depth of the liquid metal in the bath makes the mixing process difficult, as a result of which the liquid metal will not be homogeneous.

2. The lack of external thermal insulation of the furnace, reducing heat loss to the external environment.

3. The furnace does not have a dust and gas cleaning system and during operation will pollute the environment with harmful emissions.

4. The furnace uses a stationary chute to drain molten metal.

Due to the above disadvantages, it is impossible to obtain a technical result.

A known analogue is a reflective furnace for melting metal (RF patent No. 2361161), which is the closest (prototype), containing a housing formed by refractory outer side, front and rear end walls, as in the claimed furnace, a storage bath and an inclined platform bounded by a hearth and walls, a vault, a drainage notch and a gas duct, the housing being placed on a welded frame. The oven, taken as a prototype, has the following disadvantages:

1. External thermal insulation of the walls, the vault, as well as the storage bath and the inclined platform is good, but it can be improved.

2. The furnace is not high performance.

3. The furnace has satisfactory tightness. Due to the design of the shutters of the working and slag windows proposed by the author, it is possible to create a sealed furnace, which allows to reduce emissions of harmful gases into the atmosphere, to reduce the loss of metal and heat into the environment.

4. The furnace uses a stationary chute to drain molten metal.

5. The hearth blocks ShSU-33-1 GOST 7151-74, having a sufficiently long service life, are used in the furnace, however, by using other hearth blocks for the hearth and inclined platform, the service life can be increased.

The objective of the invention is the creation of a high-performance gas bath of a reflective type furnace for remelting aluminum scrap of a simple design, hermetic, which allows to reduce emissions of harmful gases into the atmosphere, reduce metal and heat losses into the environment, as well as increase its life and introduce a rotary trough into the furnace.

EFFECT: developed furnace is simple in design, airtight, having a long service life, highly productive, allowing to use scrap unsorted from foreign inclusions, to reduce heat loss to the environment due to good thermal insulation, to conduct the remelting process on natural and artificial draft with a dust and gas cleaning system, which makes it environmentally friendly, in addition, increase the service area when filling.

The specified technical result is achieved due to the fact that in a reflective furnace for remelting aluminum scrap, containing a housing formed by refractory outer side, front and rear end walls, a storage bath and an inclined platform bounded by a hearth and walls, a roof, a drain drain and a flue, according to the present invention introduced a welded frame, poured concrete with filler diatomaceous crumb and having two heat-insulating layers of lightweight brick and sheet asbestos under the hearth, two heat oizolyatsionnyh layer of brick and lightweight four sheet asbestos board under ramp.

Concrete with a filler of diatomite crumb, two heat-insulating layers of lightweight brick and sheet asbestos under the bottom, two heat-insulating layers of lightweight bricks and four sheet asbestos under an inclined platform can reduce heat loss.

In addition, the storage tank and the inclined platform are made of MKP-72 mullite-corundum blocks TU 14-8-556-87, laid on three layers of asbestos-cardboard, and are tamped with diatomaceous crumbs mixed with crushed asbestos chips. The service life of the furnace is increased due to the use of mullite-corundum blocks MKP-72 TU 14-8-556-87, which have high refractoriness and resistance (service life according to practical data is 7-9 years). The use of mullite-corundum blocks MKP-72 TU 14-8-556-87 instead of conventional piece products can reduce the number of joints, which reduces gas permeability and increases the slag resistance of the lining; get cost savings, because the process of prefabrication of piece refractories disappears, speed up the construction process and reduce the proportion of manual labor. Thermal insulation, consisting of three layers of sheet asbestos board and tamping of diatomaceous crumbs mixed with crushed asbestos chips, allows you to further maintain the temperature of the metal in the bathtub and an inclined platform.

It should be noted that the proposed reflective furnace for remelting aluminum scrap has two large arches: the lower and upper, located one above the other, between them there is a gap that acts as a chimney. The proposed design of the arches allows you to: firstly, use the heat of the exhaust flue gases having a high temperature to heat the lower arch from two sides and the upper arch from the lower side, increase the efficiency ovens; secondly, the accumulated heat allows you to increase the rate of penetration of the charge and reduce fuel consumption. Thanks to the aforementioned, the lower large arch is washed on both sides by hot flue gases, heat is reflected on the bathtub and the inclined platform, of course, the reflective furnace melts more than aluminum scrap.

At the same time, the reflective furnace for remelting aluminum scrap has a number of medium-pressure injection burners in the front (burner wall): two eight-mixing (at the edges) with a long torch, directed to the charge located on an inclined platform and to a bath with molten metal, one burner BIGm 2-6 TU 51-464-89 and two burners BIGm 2-12 TU 51-464-89, aimed at the charge. This arrangement of the burners allows to achieve a high melting speed, reduce waste (according to practical data), as well as load an uncontaminated charge through a slag window and quickly melt it. The total thermal power of the burners is 10 150 kW, which makes the furnace highly efficient, which allows forcing a forced melting mode.

In this case, the reflective furnace for remelting aluminum scrap has a rotary trough that can be rotated during the casting of liquid metal, and has an intermediate sock in design, a rotary bowl with a shaft welded in its lower part, the end of which is pressed into the inner cage of the ball bearing, and its outer the holder is fixed in the bracket, which is fixed in the rear wall of the furnace, and a long casting sock with two handles is welded to the rotary bowl, which allows sequentially pouring the weld deposit Chi metal in casting equipment located in the service sector with an angle of 140 °. This design of the rotary groove on the ball bearing makes it very easy to rotate during the casting of liquid metal, improves the working conditions of the staff.

Moreover, a steel box is welded to the furnace frame, which has heat insulation between it and each wall, consisting of asbestos chips, refractory wool, refractory mats, diatomite chips and a layer of sheet asbestos board. This design solution significantly reduces heat loss to the environment.

It is important to note that the upper large arch of the furnace has a double refractory heat-insulating coating and a layer of refractory heat-insulating mats is laid on top of it. This further reduces heat loss from the furnace.

In addition, the furnace has two drives for raising and lowering the furnace dampers, each of which consists of an electric motor, a coupling, a worm gear, two pulleys, a chain, a cable, an earring, a counterweight, copiers, a drum and a damper with a double heat-insulating layer of insulated cardboard lined with lightweight one-and-a-half refractory bricks of the ШЛ 04 brand, protruding 40-45 mm behind the frame and forming a reliable “lock” when closing, which helps to reduce fumes and reduce heat loss.

It should be noted that the rear (summer) wall is made expanding upward, which allows flue gases to smoothly turn towards the chimney laid in the front wall of the furnace and heat the lower side of the large lower arch, which then reflects the accumulated heat to the bathtub and the inclined platform.

It should be emphasized that the furnace is designed to operate on natural and artificial draft with the installation of dust and gas treatment in a "fluidized bed", equipped with 10 fabric filters, two loading grates with holes for loading on them an adsorbent layer consisting of fluff lime, activated carbon, silica gel, birch coal.

Finally, partly the side wall and partly the back are decorated with MKP-72 TU 14-8-556-87 mullite-corundum blocks, which have high fire resistance and a long service life.

Introduction to the furnace design of the above devices, materials, etc. provides a solution to the problem.

The presence of an inclined platform allows the melting of scrap unsorted from foreign inclusions in the furnace, since alterations (cast iron and steel rings, liners, bushings, studs, pushers, valves, etc.) do not fall into the molten metal.

Figure 1 A longitudinal section of the furnace.

Figure 2 Cross section of the furnace (view of the burner belt and chimney).

Figure 3 Cross section of the furnace (view of the notch).

Figure 4 View of the furnace in plan.

Figure 5 View of the installation of dust and gas cleaning.

The proposed furnace comprises a housing mounted on the furnace frame, formed by refractory outer side 1, front 2 and rear 3 end walls, a storage bath 4 and an inclined platform 5 of figure 1. The housing is mounted on a metal frame 6, in the inner cavity of the metal frame 6 on a heat-insulating cushion 7 made of concrete with filler diatomite crumb storage tank. In the heat-insulating cushion 7, in addition to concrete with a filler of diatomaceous crumb, there are two heat-insulating layers 8 of lightweight brick of the ШЛ 04 brand under the hearth 9 and under the inclined platform 5, moreover, there are two layers of 10 mm thick sheet of insulated cardboard 10 under the hearth 9 and four 22 thick mm under an inclined platform 5. Concrete with a filler of diatomaceous crumb, two heat-insulating layers 8 of lightweight brick of the ШЛ 04 grade under the hearth 9 and under the inclined platform 5, and also two additional layers 10 mm thick of sheet asphalt board 10 under length 9 and four with a thickness of 22 mm under an inclined platform 5 can reduce heat loss.

The storage bath 4 and the inclined platform 5 are made of MKP-72 mullite-corundum blocks TU 14-8-556-87, laid on three layers of asbestos-cardboard 11, and are tamped with diatomaceous crumbs mixed with crushed asbestos chips. The service life of the furnace compared with the prototype is increased due to the use of mullite-corundum blocks MKP-72 TU 14-8-556-87, which have high fire resistance and resistance (service life according to practical data 7-9 years). The use of mullite-corundum blocks MKP-72 TU 14-8-556-87 instead of conventional piece products can reduce the number of joints, which reduces gas permeability and increases the slag resistance of the lining; get cost savings, because the process of prefabrication of piece refractories disappears, speed up the construction process and reduce the proportion of manual labor. Thermal insulation, consisting of three layers of sheet asbestos board 11 and a tamping made of diatomaceous crumbs mixed with crushed asbestos chips, allows you to further maintain the temperature of the metal in the bathtub and the inclined platform. Mullite-corundum blocks MKP-72 TU 14-8-556-87 have the following dimensions: large - thickness 300 mm, width 400 mm, length 1000 mm; small - thickness 300 mm, width 400 mm, length 500 mm. The seams between mullite-corundum blocks MKP-72 TU 14-8-556-87 are filled with finely ground dry chamotte powder, and the author achieved even better results when the chamotte powder poured into the slit of the hearth blocks and the inclined platform was filled with liquid glass in the upper part, and then “flush” was smeared with the upper plane of the hearth and inclined area by refractory adhesive putty, developed by the author and having the composition: mortar, phosphon, technical lignosulfonate.

A bathtub with a depth of 380 mm is limited by an inclined platform 5, which is a loading table, two side walls 1 and a rear wall 3 made of mullite-corundum blocks MKP-72 TU 14-8-556-87. Above the storage bath and inclined platform 5, the lower large arch 12 and the upper large arch 13 are assembled, which are supported by the heel bricks ША1 No. 67 pos.14, lined in the refractory side walls 1. The lower large arch 12 and the upper large arch 13 are located one above the other , between them there is a gap acting as a chimney. The proposed design of the arches allows you to: firstly, use the heat of the exhaust flue gases having a high temperature to heat the lower large arch on both sides and the upper large arch on the lower side, to increase the efficiency ovens; secondly, the accumulated heat allows you to increase the rate of penetration of the charge and reduce fuel consumption. Thanks to the aforementioned, the lower large arch is washed on both sides by hot flue gases, heat is reflected on the bathtub and the inclined platform, of course, the reflective furnace melts more than aluminum scrap.

Above the inclined platform 5 in the furnace body, a loading window 15 of FIG. 2 is made. The first small arch 16 is made above the loading window 15 and rests on the heel bricks ША1 No. 67, and is laid out in circles in 5 rows from the fireclay end wedge ША1 No. 22 and No. 23. The masonry of the set of loading and slag stands for a steel box 40-45 mm. In the front wall 2 of the furnace laid gas duct 17, made in the form of a sector. In the rear wall 3 below is a notch 18, on one side of which a slag window 19 is laid out in the side wall to remove slag from the surface of the molten metal. For the flow of molten metal into the groove 18 and for the convenience of cleaning the groove in the process of removing alterations and slag from the hearth 9, there is a recess 20 in front of the groove, made in the hearth block by a “grinder” during the lining of the furnace. The second small vault 21 is made over the slag window 19 and rests on the heel bricks ША1 No. 67, and is laid out in circles in 5 rows from the fireclay end wedge ША1 No. 22 and No. 23 of Figure 3. All furnace walls are laid out in two and a half bricks. A metal frame 6 with a furnace is installed on the foundation in the melting compartment of the workshop. There are steel blooms in the analogue, in the proposed furnace design, the metal frame 6 is transverse in the form of channels No. 16 pos.22, which partially play the role of blooms, have sufficient heat capacity and are in concrete with filler diatomite crumb.

The reflective furnace for remelting aluminum scrap has a number of medium-pressure injection burners in the front wall: two eight-mixing 23 (along the edges) with a long torch, directed to a charge located on an inclined platform and to a bath with molten metal, one BIGm 2-6 TU 51 burner -464-89 (in the center) 24 and two burners BIGm 2-12 TU 51-464-89 pos.25, aimed at the charge. This arrangement of the burners allows to achieve a high melting speed, reduce waste (according to practical data), as well as load an uncontaminated charge through a slag window and quickly melt it. The proposed two eight-mixing burners 23 (patent No. 2365816, author A. Trusov) with a long torch (according to practical data, having a length of 3.5-3.6 m) allow melt the charge located on an inclined platform 5, as well as the charge, abandoned into the bath through the slag window 19. The total thermal power of the burners is 10 150 kW, which makes the furnace highly efficient, allowing forcing the forced melting mode.

In the front 2 wall of the furnace, openings are made for placing burners in them. Each burner has a burner tunnel for sustainable torch burning.

The nominal operating pressure of the burners is 0.08 MPa. When the furnace is lined in five openings, five injection burners are stacked and overlapped by MKP-72 mullite-corundum blocks. Then, the burners are lined with a refractory ramming mass of their own design, having the following composition:

Quartz sand

Technical lignosulfonate TU 13-0281036-89;

Powder ground clay PHB TU 1522-009-00190495-99;

Foscon (aluminochromophosphate mixture) TU 2149-150-10964029-01;

Water

The process of preparing the refractory packing mass is as follows: the powder is soaked with ground clay for a day, then quartz sand is added in portions, the whole mass is constantly thoroughly mixed, technical lignosulfonate is added and everything is thoroughly mixed. In conclusion, with stirring, the phosphon diluted in water is poured into the mixture.

After the burners are lined, they are calcined for 50-60 minutes with a portable burner, the final calcination is carried out together with the furnace.

Partially the side wall 1 and partially the back 3 are decorated with MKP-72 TU 14-8-556-87 mullite-corundum blocks, which have high fire resistance and a long service life.

A refractory solution consisting of refractory clay (25%), fireclay powder (75%), water glass (4%), phosphon (alumina-chromophosphate mixture, 1%) and water is used as a binder during lining.

The thickness of the seams is 1-2 mm, thermal expansion joints are not laid out.

The metal frame 6 of the welded furnace, welded from I-beams No. 22, 35 and channels No. 16, item 21, is poured with concrete of grade B40 with filler diatomite crumb to reduce heat loss through the concrete frame on the floor of the workshop. When pouring concrete B40 with chamotte filler, layers of asbestos board 10 and lightweight brick 8 are laid. After hardening of concrete B40 with filler diatomaceous crumb, a block of diatomaceous crumb mixed with crushed asbestos crumb under the furnace hearth 9 and inclined platform 5. is made. seven rows of mullite-corundum blocks MKP-72 TU 14-8-556-87, three pieces in each row, laid on the "edge". The size of the hearth is 2.1 × 3 meters. Inclined platform 5 consists of six rows of mullite-corundum blocks MKP-72 TU 14-8-556-87, three pieces in each row, laid on the "edge". The size of the inclined platform is 3 × 1.8 meters. Mullite-corundum blocks of hearth 9 and inclined platform 5 are lined with MKP-72 mullite-corundum blocks and SHA1 straight chamotte brick, product No. 5 GOST 8691-73. The walls of the furnace are laid out of fireclay bricks ША1 product No. 5 and No. 12 GOST 8691-73. It should be noted that the rear wall 3 is made expanding upward, which allows flue gases to smoothly turn towards the chimney 17 laid out in the front wall of the furnace 2 and heat the lower side of the large lower arch 12, which then reflects the accumulated heat to the storage bath 4 and inclined pad 5.

Letka 18 has dimensions Ø24 × 36 mm, drilled with a conical drill in the flying brick 26. The flying brick 26 is located in the recess of the rear wall 3 and is blocked by the MKP-72 mullite-corundum block.

A steel box 27 is welded to the metal frame 6 of the furnace, having heat insulation between it and each wall, consisting of asbestos chips, refractory wool, refractory mats, diatomite chips and a layer of sheet asbestos board 1, 3. This design solution significantly reduces heat loss to the environment Wednesday

The walls of the furnace are laid out in a steel box 27. The fastening of the steel box 27 to the metal frame 6 is made by vertical channels No. 20 pos. 28 figure 1.

To prevent the masonry from spreading, the vertical channels have a bunch of horizontal channels No. 20 (29). For additional support of vertical channels 28, channels No. 14 pos.30 are welded to the I-beam of the metal frame 6.

Heel beams 31 are welded from channels No. 24 and 30.

The furnace can operate on natural draft with the power off due to the use of five injection burners.

The lower large vault 12 is made in circles from the wedge of the butt ША1 No. 22, No. 23. The upper large vault 13 is made in circles from the wedge of the butt ША1 No. 22, No. 23. It is important to note that the upper large arch 13 of the furnace has a double refractory heat-insulating coating and a layer of refractory heat-insulating mats is laid on top of it. This further reduces heat loss from the furnace. The first layer with a thickness of 30 mm refractory heat-insulating coating has the following composition:

- asbestos chips - 80%;

- liquid glass - 10%;

- refractory clay - 10%;

- water

After drying the first coating layer, a second layer of 20 mm thickness is applied, which has the following composition:

- refractory clay - 15%;

- fireclay powder - 80%;

- liquid glass - 5%;

- water.

In this case, the reflective furnace for remelting aluminum scrap has a rotary trough that can be rotated during the casting of molten metal, and has an intermediate nose 32, a rotary bowl 33 with a shaft welded in its lower part, the end of which is pressed into the inner race of the ball bearing 34, and its outer cage is fixed in the bracket 35, which is attached to the rear wall of the furnace, and a long casting sock 36 with two handles 37 is welded to the rotary bowl, which allows sequential casting metal in the furnace to casting equipment located in the service sector with an angle of 140 °. This design of the rotary groove on the ball bearing 34 makes it very easy to rotate it during the casting of liquid metal, improves the working conditions of staff. The rotary cup 33 is lined with a refractory composition and has a diameter of 350 mm, an intermediate sock 32, a long casting sock 36 are lined with a refractory composition.

In addition, the furnace has two drives for raising and lowering the furnace dampers, each of which consists of an electric motor 38, a coupling 39, a worm gear 40, two pulleys 41, a chain 42, a cable 43, an earring 44, a counterweight 45, copiers 46, a drum 47 and shutters with a double heat-insulating layer of sheet asbestos-board 48, lined with a lightweight one and a half fire-resistant brick of the ШЛ 04 brand, item 49, protruding 40-45 mm behind the frame and forming a reliable “lock” when closing, which helps to reduce fumes and reduce heat loss. The damper consists of a welded frame 50, has two welded nozzles 51, which are supported by two copiers 46, with the help of the actuator, the damper can move up and down, opening and closing the window (slag or loading). The shutter when closing, for example, the loading window 15 rests on the bottom of the window sill 52. The shutter has a rear wall 53. A double heat-insulating layer of sheet asbestos board 48 and a lightweight one and a half brick 49 significantly reduce heat loss. The refractory lining protruding beyond the welded frame 50, in addition to performing the tightness function, performs the function of protecting the metal structure of the welded frame 50 of the furnace damper from the action of hot furnace gases, which cause it to warp and form gaps and leaks. The tightness of the shutter closure of the furnace window is provided by the entrance of the copiers 46, which has an angle of 33 degrees.

It is important to note that the furnace can operate both on artificial draft and on natural draft. When using dust and gas cleaning plants, the process becomes environmentally friendly. Behind the stove, the birch 54 bifurcates: one straight branch goes to the chimney 55, the other (inclined birch) 56, which has an explosive valve 57, to the mixing chamber 58, the smoke exhauster 59 and the dust and gas treatment of FIG. In the mixing chamber 58, two gates are installed: one of which 60 closes or opens the supply of exhaust gases to the exhaust fan 59, the other 61 regulates the supply of fresh air to dilute the combustion products. The same valves (gates) regulate the amount of vacuum in the furnace, which is 2-20 DaPa.

After cleaning from dust and harmful gases in a dust and gas cleaning installation located in a fenced room, the combustion products through a metal return box 62 are pumped by a smoke exhauster 59 and a blower, which is part of the dust and gas cleaning installation, into the chimney 55. Flue gases exit the furnace at a temperature of 950- 1100 ° C, and if you immediately submit them to the dust and gas cleaning installation, the fabric filters will burn out, in addition, the dust and gas cleaning design will quickly fail at such a high temperature, since the housing and the main components of the installation They are made of structural steel of ordinary quality (groups A, B, C). To reduce the temperature of flue gases to 180-210 ° C, it is necessary to install a mixing chamber 58, in which the flue gases are mixed with the air of the workshop. For the injection of flue gases into the dust and gas cleaning, the DN-10 smoke exhauster is used, which has an operating temperature of up to 250 ° C. Gate 63 regulates natural traction, and gate 64 regulates artificial traction. A platform 65 has been mounted for servicing the gate 63.

Purification of flue gases from dust and harmful occurs in the installation of dust and gas purification, developed by the author and depicted in figure 5, which has a wide range of purified harmful substances in flue gases. Dust and gas cleaning is a prefabricated steel cylindrical body 66, in the lower part of which there is a lower rotary loading grill 67 with holes. In the middle of the cylindrical body 66 there is an upper rotary loading grill 68 with openings. The rotation of the gratings around the axes is carried out using the handles 69, mounted on the axles. The lower loading nozzle 70 is located above the lower rotary loading grill 67. The upper loading nozzle 71 is located above the upper rotary loading grill 68. In the upper part of the cylindrical body 66 there are 10 bag rotating filters that capture dust particles from flue gases. At the top of the dust and gas cleaning installation, a bag filter rotation drive is installed, consisting of an electric motor 72, a coupling 73, a worm gear 74 and a gear plate 75.

In the upper part of the cylindrical body 66, a service platform 77 is mounted on four brackets 76, which is supported by four supports 78 and has a ladder 79 on the left. A frame 80 is mounted on the service platform 77, on which a blower 81 with an electric motor 82 is mounted. The spent adsorbent and dust are collected in the conical part 83 of the cylindrical body 66. The gases to be cleaned from the furnace are fed to the dust and gas cleaning unit through the nozzle 84. The spent adsorbent is discharged through the lower neck 85 of the cylindrical body 66. After cleaning flue gases from harmful substances they are cleaned of dust in rotating bag filters located in the upper part of the cylindrical housing 66. The main technical characteristics of the dust and gas cleaning installation:

- productivity on the purified gas of 10 600 m ³ / h;

- filtering surface area of 15.8 m ² ;

- the number of bag filters 10 pcs .;

- the thickness of the adsorbent layer is 0.3-0.35 m;

- the degree of purification by hydrogen fluoride 70%;

- the degree of purification of copper oxide 86%;

- the degree of purification of carbon monoxide 87%;

- the degree of purification of nitric oxide 86%;

- the degree of purification of aluminum oxide 81%;

- degree of dust cleaning 92%;

- temperature of the purified gas from 20 to 100 ° C;

- the temperature of the outer surface of the installation from 40 to 55 ° C;

- sound level no more than 82 dBA;

- energy costs for cleaning 8 kW / h.

The furnace operates on natural draft as follows. The smelter of metal and alloys opens the gate 63, the gate 64 and 60 are closed, while the thrust should be 2-20 DaPa. The burners are turned on and the furnace is calcined according to the technological schedule of calcination, depending on the type of repair. After the calcination, the mechanism for raising the shutter of the filling window 15 is turned on and the metal and alloy smelters are fed to the inclined platform 5 through the loading window 15 to load undivided aluminum scrap with an ambient temperature. The flame of five gas injection burners heats the scrap to its melting point. The metal melts and flows down the inclined platform 5 into the storage tank of the furnace. Injection burners are installed obliquely, so the flame of the burners is tilted at an angle to the inclined platform 5, as it slides along the charge lying on the inclined platform and melts the mixture. Burners having a long torch melt the charge on an inclined platform 5, as well as the charge loaded through the slag window 19 into the storage bath 4 with molten metal. The hot flue gases hit the rear wall 3 of the furnace, then, spinning, rise to the large lower arch 12, flow around it in the opposite direction, enter the chimney 17, rotate 180 °, pass between the lower and upper large arches, enter the hog 54 and are removed into the atmosphere through the chimney 55. During operation, heat is accumulated in the large lower arch 12, from where it is reflected on the metal. The coating layers of the large upper arch 13, the thermal insulation of the walls, the hearth 9, the inclined platform 5 and the heat-insulating layers of the metal frame 6 of the furnace, tamping of diatom chips mixed with crushed asbestos chips, and three layers of asbestos board 11 provide high thermal insulation of the melting unit. At the same time, the concrete of the furnace frame with the filler of diatom chips, light-weight brick layers and asbokarton sheets provides additional thermal resistance to the heat flux emanating from the inclined platform 5 and the storage bath 4 down. The thermal efficiency of the furnace is above 65%. During the melting process, the scrap melts, and on the inclined platform 5, all inclusions remain, the melting temperature of which is higher than the aluminum alloy. These wastes (alterations: cast iron and steel rings, liners, bushings, studs, pushers, valves, etc.) do not enter the molten metal, since at the end of the smelting they are removed with a scraper from the surface of the inclined platform 5 to the slag. After the molten scrap scraped into the furnace is completely melted, the liquid metal is flux-treated, the metal is thoroughly mixed in the bath and the spectral analysis laboratory confirms the grade of the alloy obtained, the metal fill opens the notch 18 and casts the liquid metal into the molds of the casting carousel 86. Thus, liquid metal from the furnace can pour through a swivel chute into casting equipment located in a sector with an angle of 140 ° (also, say, into a casting conveyor 87). After casting from a liquid metal furnace, the smelter of metal and alloys turns on the drive for lifting the slag window shutter 19, raises the slag window shutter 19 and cleans the bottom 9 of the slag and alterations accidentally caught on it.

The operation of the furnace on artificial draft is as follows.

The smelter of metal and alloys closes the gate 63, and the gates 60, 64 are open. The operations are carried out the same as during natural draft melting. The difference is that before loading the charge into the furnace, the adsorbent is loaded into the dust and gas treatment unit and it is turned on, in addition, the smoke exhauster 59 is turned on. The combustion products, having passed through the inclined bore 56 and mixing chamber 58, are awakened (diluted) in it by the workshop air, then they pass removal of dust and harmful compounds in the dust and gas cleaning installation and pumped by a smoke exhauster 59 and blower 81 through a metal return duct 62 into the chimney 55. The principle of operation of the dust and gas cleaning installation is as follows: flue gases pass loi adsorbent on the bottom 67 and top 68 of boot lattices, forming a "fluidized bed", whereby the harmful substances present in exhaust gases are adsorbed pushonka lime, activated carbon, silica gel, birch charcoal. After cleaning the flue gases from harmful substances, they are cleaned of dust in rotating bag filters located in the upper part of the cylindrical body 66. The spent adsorbent is discharged through the lower neck 85 of the cylindrical body 66 into a metal container and transported to a dump. Flue gas cleaning makes the process environmentally friendly.

The operation of the furnace on natural draft is carried out if the dimensions of the sanitary protection zone of the enterprise allow, during calcination, casting of deposited metal or during a power outage, when the operation of the smoke exhauster and dust and gas cleaning system is impossible.

After casting the liquid metal, the bath is cleaned of slag, the tap hole 18 is plugged and the cycle repeats.

So, the proposed furnace can operate on both artificial and natural traction, it is simple in design, airtight, having a long service life, highly efficient, with low heat loss to the environment due to good thermal insulation.

Claims (7)

1. Reflective furnace for remelting aluminum scrap, comprising a housing formed by refractory outer side, front and rear end walls, an accumulation bath bounded by a hearth and walls, an inclined platform, a vault, a drain passage, a gas duct, characterized in that the housing is placed on a welded frame, filled with concrete with a filler of diatomite crumb and made with two heat-insulating layers of lightweight brick and sheet asbokarton under the hearth, two heat-insulating layers of lightweight brick and black with three layers of sheet asbestos-board under an inclined platform, the storage bath and inclined platform are made of MKP-72 mullite-corundum blocks, laid on three layers of asbestos-cardboard, and are tamped with diatomite chips mixed with ground asbestos chips, the furnace has large lower and upper arches located one above the other with the formation of a gap between them for the chimney, while the furnace is equipped with a rotary chute, made with the possibility of rotation in the process of casting liquid metal and having an intermediate juice, a rotary cup with a shaft welded in its lower part, the end of which is pressed into the inner race of the ball bearing, and its outer race is fixed in an arm fixed to the rear wall of the furnace, and a long casting sock with two handles is welded to the rotary cup for sequential casting of the deposited in a metal furnace into casting equipment located in the service sector with an angle of 140 °. 2. The furnace according to claim 1, characterized in that it has two drives for raising and lowering the furnace flaps, each consisting of an electric motor, a coupling, a worm gear, two pulleys, a chain, a cable, an earring, a counterweight, copiers and a drum, the flaps are made with double heat-insulating layer of sheet asphalt board lined with a lightweight one and a half refractory brick of the ШЛ 04 brand, protruding 40-45 mm beyond the frame and forming a lock when closing to reduce waste and reduce heat loss. 3. The furnace according to claim 1, characterized in that the upper large arch of the furnace has a double refractory heat-insulating coating and a layer of refractory heat-insulating mats is laid on top of it. 4. The furnace according to claim 1, characterized in that the furnace has a series of medium-pressure injection burners in the front wall, of which two eight-mixing ones with a long torch are directed along the edges to a charge located on an inclined platform and to a bath with molten metal, one burner BIGm 2-6 and two burners BIGm 2-12 are directed to the charge. 5. The furnace according to claim 1, characterized in that a steel box is welded to the furnace frame, having heat insulation between it and each wall, consisting of asbestos chips, refractory wool, refractory mats, diatomite chips and a layer of sheet asbestos board. 6. The furnace according to claim 1, characterized in that the partially side wall and partially back are decorated with MKP-72 mullite-corundum blocks, the back wall being expanded to the top to ensure smooth rotation of the flue gases to the chimney laid in the front wall of the furnace and heating the lower side large lower vault. 7. The furnace according to claim 1, characterized in that it is configured to operate on natural and artificial traction with the installation of a dust and gas treatment in a fluidized bed equipped with 10 cloth filters, two loading grates with holes for loading on them an adsorbent layer consisting of fluff lime activated carbon, silica gel or birch charcoal.

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