RU2617087C1 - Tandem reverberatory furnace for aluminium scrap remelting - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: furnace includes a housing formed with refractory external side, front and rear end walls, two inclined platforms, two baths restricted by bottoms, a roof and walls, two tap holes, a gas duct and a welded frame on which all parts are arranged. The framework is laid inside with lightweight brick of "ШЛ-1.0" grade, two inclined platforms and two baths made of mullite blocks of "МКП-72" brand laid on three layers of asbest cardboard. The steel frame is welded to the furnace frame, having a thermal insulation between it and each wall, consisting of fireclay chips, fireproof wool, a triple layer of sheet asbestos cardboard and asbestos tailings, roofs above the inclined platforms, and above the first and second baths, the furnaces have a layer with double heat-insulating coating, and a double layer of refractory insulating mats and a layer of diatom brick are laid on top of it. The furnace has six double row injection six-mixer burners aimed at the inclined platforms, and the ten-row injection six mixer burners aimed at the bottoms. The furnace has four working windows, two of which are the slag window, and the device for lifting and lowering of the furnace and the slag window flap comprises an electric drive. The furnace has a rail-tracked platform with mounted on it two swivel attached steel spouts and a two-stage gas and dust treatment station to achieve an environmentally friendly process.

EFFECT: high furnace efficiency, reduced heat and burn-off losses and possibility of ecologically clean remelting of aluminium scrap.

6 cl, 12 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 melting metal (Information source A. A. Baranov, O. P. Mikulyak, A. A. Reznyakov. “Technology of secondary non-ferrous metals and alloys”, pp. 22-23), containing a housing formed by a brick masonry of external walls as in the declared furnace, two bathtubs limited by hearths and walls, two arches, a drainage notch and a gas duct.

The disadvantages of this furnace are as follows.

1. The second melting chamber acts as a mixer (piggy bank), which ultimately reduces the productivity of the furnace.

2. The furnace has insufficient thermal insulation of the walls, the arch, 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. In the hearth lining furnace, conventional refractory bricks are used, rather than hearth blocks, which significantly increase the life of the furnace.

5. From the description of the furnace it follows that it does not provide a forced melting mode. Due to the above disadvantages, the furnace cannot provide a solution to the technical problem.

A known analogue is a two-chamber reflective furnace for remelting aluminum scrap (Source of information MS Shklyar. “Furnaces of secondary non-ferrous metallurgy”, publishing house “Metallurgy”, 1987, pp. 35-37), containing a housing formed by brickwork of external walls as in the declared furnace, two bathtubs bounded by hearths and walls, two vaults, a drain outlet and a flue.

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

1. The second melting chamber acts as a mixer (piggy bank), which ultimately reduces the productivity of the furnace.

2. The furnace has insufficient thermal insulation of the walls, the arch, 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. In the hearth lining furnace, conventional refractory bricks are used, rather than hearth blocks, which significantly increase the life of the furnace.

5. From the description of the furnace it follows that it does not provide a forced melting mode.

Due to the above disadvantages, the furnace cannot provide a solution to the technical problem.

A known analogue is a two-shaft reflective furnace (Source of information MS Shklyar. "Furnaces of secondary non-ferrous metallurgy", publishing house "Metallurgy", 1987, pp. 87-89), which is the closest (prototype), containing a housing formed by brickwork external walls as in the declared furnace, two bathtubs limited by hearths, a vault and walls, drainage gaps and flues.

I believe that the oven, taken as a prototype, has the following disadvantages.

1. The furnace has insufficient thermal insulation of the walls, the arch, reducing heat loss to the external environment.

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

3. In the hearth furnace, a regular refractory brick is used instead of hearth blocks, which significantly increase the life of the furnace.

4. From the description of the furnace it follows that it does not provide a forced melting mode.

5. The furnace uses two stationary troughs to drain molten metal.

Due to the above disadvantages, the furnace cannot provide a solution to the technical problem.

The objective of the invention is the creation of a high-performance gas twin-shaft reflective type furnace for remelting aluminum scrap, which allows to reduce emissions of harmful gases into the atmosphere, reduce heat loss to the environment, as well as increase its life and introduce into the furnace a moving platform on rails with two installed on it swivel access chutes.

EFFECT: developed gas two-shaft reflective type furnace for remelting aluminum scrap is highly efficient, has a long service life and a platform moving on rails with two rotary access chutes installed on it, which allows: to reduce heat loss to the environment due to thermal insulation, which allows the remelting process on natural and artificial traction with a dust and gas cleaning system, which makes it environmentally friendly.

The specified technical result is achieved due to the fact that in a two-shaft furnace for remelting aluminum scrap, containing a body formed by refractory outer side, front and rear end walls, two bathtubs (first and second), limited by hearths, arches and walls, drainage gates and duct , according to the invention, a welded frame is introduced, laid out inside with a lightweight brick ШЛ-1,0, two inclined platforms, the hearths of two bathtubs are made of MKP-72 mullite-corundum blocks laid on three layers of asphalt board and having dry quartz sand mix. Three layers of asbestos board, tamping made of dry quartz sand, a lightweight brick of the frame allow you to additionally maintain the temperature of the metal in the bathtubs of the furnace, reduce heat loss. MKP-72 mullite-corundum blocks have high refractoriness and resistance and allow to increase the furnace service life (service life according to practical data is 7-8 years). The use of MKP-72 mullite-corundum blocks instead of conventional piece products can reduce the number of joints, which reduces gas permeability and increases the lining resistance of the lining; get cost savings, because the process of pre-fabrication of piece refractories disappears, speed up the process of building a furnace and reduce the proportion of manual labor.

In addition, the two-shaft reflective furnace for remelting aluminum scrap (hereinafter the two-furnace) has three injection double-row six-mixing burners of medium pressure in each side wall, directed at an angle of 23 ° to the inclined platforms of the furnace, and at an angle of 25 ° to the axis of the furnace, with a two-row six-mixing the burner during combustion of the air-gas mixture has a long flame from the mixers of the upper row, the middle from the mixers of the lower row, and there is a mixture of two flares that heat the inclined platform of the furnace.

It should be noted that each mixer of the upper row of a two-row six-mixing medium pressure burner is a casting and is a pipe made of corrosion-resistant heat-resistant cast iron CHX22C with a diameter of 64 × 10 mm and a length of 315 mm, in which four nozzles are drilled along the periphery at an angle of 25 ° ± 1 ° to their axes with a countersink of the inlet part of 0.5 mm at an angle of 90 °, while in each mixer at the end on the inner surface there are 12 cast ribs, the cast ribs on the side of the movement of the air-gas mixture have a 5 mm long “sharpening” inlet, the angle “behind acute ”is 30 °, the height of the ribs is 4.5 mm, the torch length of the mixers of the upper row is 3.3 meters. Burners with mixers made of corrosion-resistant heat-resistant cast iron CHX22S have great reliability and a long service life.

Moreover, each mixer of the lower row is a casting of corrosion-resistant heat-resistant cast iron ChKh22S and is a pipe with an outer diameter of 64 mm and an inner ∅ 44 mm with a length of 315 mm, in which four nozzles are drilled along the periphery at an angle of 25 ° ± 1 ° to their axes with a countersink of the inlet part of 0.5 mm at an angle of 90 °, while the mixers of the lower row allow to obtain the length of the torch of the lower row up to 1.5 m. The location of the burners allows to achieve high melting speed, reduce fumes (according to practical data), as well as load contaminated charge through two working windows in the front wall into two inclined platforms and quickly melt it due to the heat of six double-row six-mixing burners.

Further, the twin-furnace in the rear wall has five injection double-row six-mixing medium-pressure burners directed at an angle of 23 ° to the first hearth, as well as five injection double-row six-mixing medium-pressure burners directed at an angle of 23 ° to the second hearth. This arrangement of the burners allows to achieve a high melting rate, reduce fumes (according to practical data), as well as load an uncontaminated charge through two working windows (they also act as slag windows) in the side walls on the bottom of the first and second baths and quickly melt it due to the heat generated during the burning of the torches of ten double-row six-mixing burners, and the heat output of all injection burners installed in the furnace is 13,400 kW, which makes the furnace highly efficient, allowing forcing new melting mode.

Moreover, the furnace is laid out in a steel box and has thermal insulation between it and each wall, consisting of fireclay chips, refractory wool, a triple layer of sheet asbestos board and asbestos chips. Such insulation can reduce heat loss and save gas.

It is significant to note that the arches above the sloping platforms, as well as above the first and second bathtubs of the furnace, have a layer with double heat-insulating coating and a double layer of refractory heat-insulating mats and a layer of diatom brick are laid on top of it. This design solution significantly reduces heat loss to the environment.

In addition, the furnace has four working windows, two of which can serve as a slag window and two slots made in the rear wall. Four working windows allow for quick loading of the furnace, and two tap holes to quickly drain the weld metal, which makes the furnace highly efficient.

Moreover, the device for raising and lowering the shutter of the worker, as well as the slag window of the furnace, contains an electric drive in the form of a geared motor containing a double roller block and two single roller blocks connected by a flexible link in the form of chains between each other and a counterweight, while the double shafts and single blocks of rollers are fixed in the longitudinal channels of the furnace with the shutter moving along the water-cooled box and with the possibility of regulating its position from the control panel, and the water-cooled box with a chain forms with a vertical angle of 1 degree, further, the damper contains a U-shaped box with internal ribs and a lid, made of cast heat-resistant cast iron CHX22C with ribs and T-cavities lined with a refractory packing mass. The design of the actuator and the damper ensures the tightness of the furnace, reduces the loss of metal and heat in the environment.

In this case, the two-shaft furnace has a platform moving along rails with two rotary attached steel gutters installed on it, a drive is fixed on the platform, which ensures its movement on rails, in addition, a movable plate is mounted on the top plate of the platform, on which the rotation mechanisms of two steel gutters with swivel bowls welded to them, each made in the form of two vertical posts welded to a cross member mounted on a steel gutter having a hinge rotary rollers, which ensure rolling along the movable plate during rotation, moreover, a mechanism for feeding steel gutters to stationary drain socks with rotary bowls, comprising a rack and pinion mechanism with a drive, and rotary bowls mounted on shafts that are rotatable in cylinders mounted on a movable plate having rotation limiters.

Finally, the two-chamber furnace is equipped with a two-stage dust and gas cleaning installation to achieve an environmentally friendly process, the first stage being a mixing chamber, a DN-15 smoke exhaust, a two-section gas cleaning unit, and a second battery cyclone and a centrifugal fan VTs 4-70-12.5R, while the installation dust and gas purification has the following characteristic: gas purification rate 49,000 m ³ / h, hydrogen fluoride purification degree 67%, copper oxide purification 86%, carbon monoxide 94%, purification o nitric oxide 86%, the degree of purification by alumina 82%, the degree of purification by dust 95%, the sound level is not more than 75 dBA.

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

The developed design of the two-shaft furnace allows the remelting of not subjected to cutting and magnetic separation of aluminum scrap, which is loaded into two working windows located in the front wall. Thus, alterations (cast iron and steel rings, bushings, bushings, studs, pushers, valves, etc.) remain on two inclined platforms and do not fall into the molten metal. It is necessary to load aluminum scrap subjected to cutting and magnetic separation into the side working windows in order to fulfill high requirements for the chemical composition of the alloy being smelted.

In FIG. 1. The view of the two-chamber furnace in plan.

In FIG. 2. A longitudinal section AA of a two-shaft furnace.

In FIG. 3. Cross section BB of a two-shaft furnace.

In FIG. 4. Cross-section B-B along the slag windows of a two-shaft furnace.

In FIG. 5. Top view Г of the platform with two rotary attached steel gutters installed on it.

In FIG. 6. Side view D of the platform with two rotary attached steel gutters mounted on it.

In FIG. 7. View E of the two-furnace from the end (from the front wall).

In FIG. 8. Two-row six-mixing injection burner.

In FIG. 9. Section Zh-Zh two-row six-mixing injection burner.

In FIG. 10. Two-section gas cleaning unit.

In FIG. 11. Battery cyclone.

In FIG. 12. A plan view of a two-chamber furnace with a two-stage dust and gas cleaning installation and filling equipment.

The proposed furnace comprises a housing mounted on a metal frame 1 of the furnace formed by brickwork of the outer side, front 2 and rear 3 end walls of FIG. 2.

Under the 4 first baths of the two-furnace furnace and under the 5 second baths of the two-furnace furnace, as well as the first 6 and second 7 inclined platforms, they are made of mullite-corundum blocks 8 of the MKP-72 grade laid on three layers of asphalt board 9 and having a pad 10 of dry quartz sand. The metal frame 1 is welded from I-beams No. 35 and No. 25 GOST 8239-89 and laid inside with a lightweight brick ШЛ-1,0 pos. 11. Three layers of asphalt board 9, lining 10 of dry quartz sand, lightweight brick ШЛ-1,0 pos. 11 of the frame 1 can additionally maintain the temperature of the metal on inclined platforms 6.7, on the hearths of 4.5 bathtubs of the furnace, to reduce the heat loss of FIG. 2, 3, 4. Mullite-corundum blocks 8 of the MKP-72 grade have high refractoriness and resistance and allow to increase the furnace service life (the service life is 7-8 years according to practical data). The use of mullite-corundum blocks 8 of the MKP-72 grade 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 pre-fabrication of piece refractories disappears, speed up the process of building a furnace and reduce the proportion of manual labor. Mullite-corundum blocks 8 MKP-72 (decoding of the MK mark - mullite-corundum; more than 72% Al ₂ O ₃ ). The prototype used conventional refractory bricks of grades ША-1 No. 5, in which the content of Al ₂ O _{3 is} 30%, in addition, they have a tensile strength of 20 N / mm ² and a softening onset temperature of 1400 ° C. In the proposed furnace, the mullite-corundum blocks 8 have a tensile strength of 80 N / mm ² , they have more than% Al ₂ O ₃ , and the softening start temperature is not less than 1550 ° C; therefore, the service life of the mullite-corundum blocks 8 MKP-72 according to practical data is 7-8 years .

Thus, four walls are laid out on the metal frame 1 of the furnace, under 4 of the first bath, under 5 of the second bath of the two-furnace furnace, as well as the first 6 and second 7 inclined platforms, and the wall 12 of the furnace is laid in the center of the furnace between the inclined areas and the hearths. 3 The size of the hearths is 4, 5 3 × 4 m, and the size of the inclined platforms is 6, 7 3 × 3.3 m. The mullite-corundum blocks 8 of the MKP-72 brand are lined with direct fireclay bricks of the SHA-1 brand, item No. 5 and No. 12. The walls of the furnace are laid out of fireclay bricks TUTA - 1 No. 5 and No. 12 in a steel box 13, which is welded to the frame 1 of the furnace, having heat insulation 14 between it and each wall, consisting of fireclay chips, fire-resistant cotton wool, a triple layer of sheet asbestos board and asbestos chips FIG. 3. Such thermal insulation can reduce heat loss and save gas. The steel box 13 of the two-shaft furnace is fastened to the frame 1 of the furnace by vertical channels No. 16 pos. 15. To prevent the spread of masonry of a two-shaft furnace (hereinafter referred to as the furnace), the vertical channels have a bunch of horizontal channels No. 16 pos. 16 of FIG. 2, 3. It is important to note that the large arches 17 above the inclined platforms 6, 7, as well as above the first 4 and second 5 hearths of the furnace are made of the wedge of the end ША-1 No. 22, No. 23 and have a layer 18 with double heat-insulating coating and top a double layer of refractory heat-insulating mats 19 and a layer of diatom brick 20 of FIG. 3.

Heel beams 21 of large arches 17 are welded from channels No. 27U and rely on heel bricks 22 of FIG. 3. In addition, the furnace has four working 23 windows, two of which can act as a slag window and two slots 24, made in summer brick 25, placed at the rear wall 3 and blocked by hearth blocks 26. Four working 23 windows allow quick loading of the furnace and two years of 24 to quickly discharge the weld metal, which makes the furnace highly productive. At the same time, the working (slag) 23 windows have arches 27 laid out according to the patterns from the chamotte end wedge ША-1 No. 22 and No. 23, the arches 27 are based on heel bricks 28 of FIG. 2, 3. Chimneys 29 are made in the rear end wall 3 and have arches 30 based on the heel bricks 31 of FIG. four.

Further, the furnace has a device for raising and lowering the shutter 32 of the working (slag) window of the furnace. The damper 32 is cast from corrosion-resistant heat-resistant cast iron. The CHX22C is cooled by air, which is fed through the elastic inlet pipe 33, then through the connector 34 and the inlet pipe 35 enters a U-shaped box 36, cast at the same time with the damper 32, of FIG. 7. To improve air cooling of the shutter 32, the U-shaped duct 36 has cast ribs 37 inside, which increase the heat transfer area and which are closed by the welded lid 38 of FIG. 4. The T-grooves of the shutter 32 are lined with a refractory packing material 39. The device for raising and lowering the shutter 32 contains an electric drive in the form of a gear motor 40, containing two 41 roller blocks and two single 42 roller blocks connected by a flexible connection in the form of chains 43 between each other and the counterweight 44, while the shafts 45 of the twin 41 and single 42 blocks of rollers are fixed in the horizontal channels 16 of the furnace with the shutter 32 moving along the water-cooled duct 46 lined in the furnace of FIG. 1, 2, 7. The damper 32 has stiffeners 47, in the raised position, the damper 32 is located opposite the protective shield 48, and in the lower it rests on the stops 49. Water is supplied to the water-cooled box 46 through the inlet pipe 50, and leaves the outlet pipe 51 FIG. 7. The counterweights 44 according to safety regulations are located in metal boxes 52 of FIG. 2. The damper 32 has the ability to adjust its position from the control panel. The design of the actuator and the damper 32 ensures the tightness of the furnace, reduces the loss of metal and heat to the environment.

In addition, the twin-furnace in each side wall has three medium-pressure injection double-row six-mixing six-burner 53 (hereinafter referred to as the burner), blocked by a hearth block 54 directed at an angle of 23 ° to the inclined platforms of the furnace, and at an angle of 25 ° to the axis of the furnace, with the burner burning gas-air mixture has a long flame from the mixers of the upper row, the middle from the mixers of the lower row, and there is a mixture of two flares that heat the inclined platform 6.7 of the furnace of FIG. 2. Each mixer 55 of the upper row (at the installation site) of burner 53 is a casting and is a pipe made of corrosion-resistant heat-resistant cast iron CHX22C with a diameter of 64 × 10 mm and a length of 315 mm, in which four nozzles 56 are drilled along the periphery at an angle of 25 ± 1 ° to their axes with a countersink of the input part of 0.5 mm at an angle of 90 °, while in each mixer 55 of the upper row at the end on the inner surface there are 12 cast ribs pos. 57, cast ribs 57 from the side of the movement of the air-gas mixture have a lead-in “sharpening” with a length of 5 mm. The “sharpening” angle is 30 °, the height of the ribs is 4.5 mm, the torch length of the mixers of the upper row is 3.3 m. Burners 53 with mixers made of corrosion-resistant heat-resistant cast iron ЧХ22С GOST 7769-82 (Ch-cast iron; chemical composition C = 0 , 6-1.0%; Si = 3.0-4.0%; Mn up to 1%; P up to 0.1%; S up to 0.08%; Cr = 19-25%; Fe the rest) have a large reliability and long service life.

Moreover, each mixer 58 of the lower row is a casting from heat-resistant cast iron ЧХ22С and is a pipe with an outer diameter of 64 mm and an inner ∅ 44 mm with a length of 315 mm, in which four nozzles 56 are drilled along the periphery at an angle of 25 ± 1 ° to their axes with a countersink the input part is 0.5 mm at an angle of 90 °, while the mixers 58 of the lower row allow you to get the length of the plume of the lower row up to 1.5 m. The location of the burners 53 allows to achieve high melting speed, reduce fumes (according to practical data), as well as load contaminated charge through two workers 23 ok on the front 2 wall into two inclined platforms 6, 7 and quickly melt it due to the heat of six burners.

Further, the furnace has five burners in the rear 3 wall, directed at an angle of 23 ° to under 4 of the first bath, as well as five burners directed at an angle of 23 ° at 5 of the second bath. This arrangement of burners 53 allows to achieve a high melting rate, reduce fumes (according to practical data), as well as load a contaminated charge through two working windows (they also act as slag windows) in the side walls on the heights 4, 5 of the first and second baths and quickly re-melt due to the heat generated during the burning of the torches of ten burners, and the thermal power of all burners installed in the furnace is 13,400 kW, which makes the furnace highly efficient, allowing forcing the forced melting mode, while the metal does not have time It oxidizes and, ultimately, the burnout is small.

So, each burner 53 consists of six mixers, united by a common welded gas distribution chamber 59, to which a fitting 60 is welded, through which the natural gas of FIG. 8, 9. A gas distribution chamber 59 having a rectangular shape is welded from milled channel channels No. 18. Two rows of holes with a diameter of 63 mm were drilled in the gas distribution chamber 59, into which six mixers were inserted and hermetically sealed, the three mixers 55 located in the upper row (for installing the burner in the furnace) have cast fins 57, and the three mixers 58 in the lower row without cast ribs. The casing 61, box-shaped, introduced into the design of the burner, is welded to the gas distribution chamber 59, allows filling the refractory packing mass 62 into the space between the mixers before installing the burner in a heat or melting unit, and also makes it possible to dry and calcine the burner outside the heat or melting unit, casing 61 prevents the process of shedding refractory packing mass 62 in the process of packing.

A stabilizing tunnel 63 cast from corrosion-resistant and heat-resistant cast iron CHX22C is put on the gas distribution chamber 59 and the casing 61 from the bottom and is welded around the perimeter to the gas distribution chamber 59 of FIG. 5, 6. The introduction of a stabilizing tunnel 63 into the burner increases the life of the burner 53, stabilizes the flame, improves the process of lining the burners 53 in a heat or smelting unit, and the lining time of the burners is significantly reduced. The design of the stabilizing tunnel 63 allows you to install the burner 53 in a thermal or melting unit with any wall thickness.

The lining of the burner and the packing of the space between the mixers is carried out by a refractory packing mass of 62, which was experimentally developed by the author and tested on existing gas melting furnaces. The refractory packing mass 62 for lining the burner and filling the space between the mixers has the following composition:

Chamotte mortar МШ 39 ТУ 14-199-119-200 40% Technical lignosulfonate TU 13-0281036-89 fourteen% Powder ground clay PGNU TU 1522-051-05802299-2005 22% Foscon 430 TU 2149-200-10964029-2003 four% Quartz sand grade T GOST 22551-77 8 Water 12%

The refractory packing material 62 after calcination has high hardness, high refractoriness, and considerable resistance to shedding at temperatures up to 1650 ° C. The life of the burner is significantly increased.

The burner operates as follows. Gas under pressure is supplied through the channel of the nozzle 60 to the gas distribution chamber 59. The gas jets emerging from the gas nozzles 56 inject air from the atmosphere that is needed for combustion, which enters the pre-mixing chamber 65 through the channel 64 of each burner mixer, where the gas is pre-mixed with the gas sucked in air. The combustion of the main part of the gas-air mixture takes place in a refractory stabilizing tunnel 63, and the rest in the combustion chamber of the furnace.

A necessary condition for the normal operation of the burner is the presence of a vacuum in the combustion chamber within 3 ÷ 20 daPa (mm water column). The nominal gas pressure in front of the burner is 0.09 MPa.

Moreover, the corrosion-resistant and heat-resistant cast iron CHX22C used as a material for the manufacture of mixers 55, 58 of the cast flame-stabilizing tunnel 63 allows to increase the life of the burner 53 and the furnace, and therefore the furnace.

In this case, the two-shaft furnace has a device for casting metal deposited in the furnace: a platform 66 moving along rails with two rotary attached steel gutters installed on it 67. In a conventional industrial furnace there is a stationary or rotary trough, in large furnaces there can be two, in the proposed furnace it is a device for casting metal deposited in a furnace. A mobile platform 66 is introduced into the liquid metal casting device with the rotation mechanisms of two steel troughs 67 and a drive for moving the mobile platform 66 along the rails 68 mounted thereon.

One of the main elements of the device for casting metal deposited in the furnace is a mobile platform 66, which consists of a steel bottom plate 69 and a steel top plate 70, between which are channels 71 longitudinal and transverse No. 22 of FIG. 5, 6. The channels 71 are fixed to the bottom plate 69 and the top plate 70 by bolts, nuts and spring washers (not shown). The mobile platform has two axles 72, at the ends of which there are four rollers 73 with a diameter of 200 mm, which are supported by rails 68 (Fig. 6). In the brackets 74 are two rolling bearings, so the mobile platform rolls along the rails 68 easily.

The brackets 74 are attached to the bottom plate 69 of the movable platform 66 with nuts, bolts and spring washers (not shown). The mobile platform 66 is moved along rails 68 by means of a drive that consists of a reversible motor 75, a coupling 76, a gearbox 77 and a V-belt drive 78. The drive of the movable platform 66 uses a 1.6 kW reversible motor 75 of the MT-4 type, as well as a two-stage a cylindrical gearbox 77 with a gear ratio of 40. A movable plate 79 with three ribs 80 welded to it for stiffness slides along the upper plate 70. Two mechanisms for turning the gutters are placed on the moving plate 79, each of which consists of a rotary bowl 81 s rivarennym thereto steel trough 67, the trough 67 is fastened to the cross member 82 welded to the two vertical uprights 83 are pivotally-rotating rollers 84, which in turn roll on the movable plate 79 (Figs. 5, 6). Further, the rotary cup 81 has a shaft 85 fixed at the bottom center, rotating in two bearings 86 located in the cylinder 87, which is mounted on the movable plate 79, and two rotation limiters 88 are attached to it. Introduction to the design of the rotary cup 81 with welded to it steel groove 67 makes it possible to rotate up to 170 ° around its axis of the rotary bowl 81 with a steel groove 67 welded to it for pouring molten metal, increasing the service area, i.e. without readjustment, for example, pour molten metal into a casting conveyor, carousel, ladle. The articulated-rotary rollers 84 and bearings 86 make it very easy to rotate around their axis to the rotary bowl 81 with a steel groove 67 welded to it, thereby facilitating the work of maintenance personnel.

At the same time, the rotary bowl 81 and the steel groove 67 welded to it with a handle 89 have a lining (not shown) of the mullite-corundum packing mass and a heat-insulating layer (not shown), consisting of a flexible heat-insulating fiberglass mullite-siliceous cardboard, which improves the thermal insulation of the metal structure of the steel gutter 67 from molten metal. The mullite-corundum packing mass used for lining the rotary bowl 81 and the steel groove 67 welded to it increases the durability of the lining and increases the service life of the rotary cup 81 and the steel groove 67 welded to it.

A movable platform with a pivoting bowl 81 mounted on it with a steel chute 67 welded to it makes it possible to drive up to the stationary drain toe 90 for casting and to move away from it after pouring liquid metal (rough feed).

In addition, a mechanism for accurately feeding rotary bowls 81 with steel grooves 67 welded to it to a stationary drain toe 90, which includes a rack and pinion mechanism with a drive, has been introduced into the design of a device for casting liquid metal. The rack and pinion mechanism is mounted on a movable platform 66 and consists of two rails 91, mounted on a slide 92, moving along rails (not shown), moreover, on the slide 92 two brackets 93 are fixed, inside of which a pusher is mounted, consisting of a shaft 94 with a welded end movable plate 79.

To slowly move the rotary bowl 81 with a steel groove 67 welded to it to or from the stationary drain toe 90, the rack and pinion drive is turned on. The gear rack drive consists of a reversing motor 95, a clutch 96, a gearbox 97, a clutch 98, a shaft 99 with two gear wheels mounted on it ∅ 230 mm pos. 100. The platform gear rack drive uses a 1.6 kW reversible motor 95, as well as a two-stage cylindrical gearbox 97 with a gear ratio of 30. It is important to note once again that the rack gear shaft 94 is welded to the movable plate 79, therefore, during the slow movement of the rotary bowls 81 with steel gutters 67 welded to them to or from stationary drain socks 90, a movable plate 79 welded to the shaft 94 slides along the upper plate 70 of the movable platform 66. The mechanism for accurately feeding the rotary bowls 81 from the weld steel gutters 67 attached to them to stationary drain socks 90 ensures accurate installation of the rotary bowls 81 with steel gutters 67 welded to them relative to stationary drain socks 90, and also provides the necessary manipulations in case of pouring different casting devices with liquid metal (except for pouring operations associated with by turning the gutter). To protect the melting furnace from damage by the mobile platform, there are two stops 101 with limit switches on the frame 1 of the melting furnace.

Finally, the two-chamber furnace is equipped with a two-stage dust and gas cleaning installation to achieve an environmentally friendly process, and the first stage is a mixing chamber 102, smoke exhauster DN-15 pos. 103, a two-section gas cleaning unit 104, and a second battery cyclone 105 and a centrifugal fan VTs 4-70-12.5P pos. 106 of FIG. 12. Purification of flue gases from harmful substances occurs in a two-section gas cleaning unit 104, developed by the author and depicted in FIG. 10, which has a wide range of purified harmful substances in flue gases. Each section of the two-section gas treatment unit 104 is a prefabricated steel body round in cross section 107, in the lower part of which there is a lower rotary loading grill 108 with holes. Above the lower rotary loading grill 108, a lower loading nozzle 109 of FIG. 10. In the middle of the steel casing 107, there is an upper rotatable loading grill 110 with openings. The rotation of the gratings around the axes is carried out using the handles 111, mounted on the axes of the gratings. Above the upper rotary loading grill 110 is the upper loading nozzle 112. The cover 113 opens and closes the housing 107 and is intended for maintenance and repair of the gas cleaning unit. The steel casing 107 is supported by four supports 114, in the upper part a service platform 115 is attached to it. Spent adsorbent and dust are collected in the conical part 116 of the steel casing 107. The gases to be cleaned are fed to the dust and gas cleaning unit through a common inlet pipe 117. A frame is fixed to the service platform 115 118, on which a blower 119 with an electric motor 120 is mounted. Spent adsorbent contaminated with dust from the lower rotary loading grill 108 and from the upper rotary loading grill 110 using the dump handles 111 is inserted into the cone portion 116 of the steel body 107, and then, by turning the handle 121, the spent adsorbent is poured through the lower neck 122 of the steel body 107 into a container (not shown) and transported to a dump. The cleaned flue gases are passed through a pipe 123 to the blower 119 and then to the battery cyclone 105. To monitor the progress of the flue gas cleaning process, two eyes 124 are made in the steel casing 107. Since the flue gases leaving the furnace have a temperature of more than 750 ° C, usually, before the exhaust fan 103, a mixing chamber 102 is installed in which the flue gases are diluted with the air of the workshop, while their temperature drops to 140-170 ° C. Two gates are installed in the mixing chamber 102: one of which 125 closes or opens the supply of exhaust gases to the exhaust fan 103, the other 126 regulates the supply of fresh air to dilute the combustion products (Fig. 12). As a smoke exhaust, a smoke exhaust mod is adopted. DN-15, which has an operating temperature of up to 250 ° C. The two-section gas cleaning unit 104 has a guard 127 and a ladder 128.

The battery cyclone 105 consists, as it were, of two single cyclones arranged in a battery, where they operate in parallel (Fig. 12). Flue gases to be cleaned from dust are introduced through the inlet pipe 129 into a common distribution chamber 130, from where they are distributed over two unit cyclones. To give flue gases rotational motion in each unit cyclone there is a device that is a "socket" consisting of blades 131 mounted at an angle of 30 ° to the axis. As a result of the action of centrifugal forces, dust particles suspended in the flue gas stream are thrown onto the walls of the housing 132 and fall out of the flue gas stream into two bins 133. Dust-free flue gases change direction and are removed through the outlet pipe 134. Two bins 133 are equipped with shutters with electric drives 135, with which the shutters open the neck of the bins 133, while the dust is poured into the tank 136 and taken to the dump. The battery cyclone 105 is supported by four supports 137, is equipped with a ladder 138 and a service platform 139, which has a guard 140. The battery cyclone 105 at the top has two valves 141. The purified gases after passing through the battery cyclone 105 are fed through a pipe 142 by a centrifugal fan VTs 4-70-12 , 5P pos. 106 into the chimney 143 and are discharged into the atmosphere.

In this case, the dust and gas cleaning installation has the following characteristic: the gas purification capacity is 49,000 m ³ / h, the hydrogen fluoride purification rate is 67%, the copper oxide purification degree is 86%, the carbon monoxide purification degree is 94%, the nitric oxide purification degree is 86%, the degree of purification by alumina is 82%, the degree of purification by dust is 95%, the sound level is not more than 75 DBA.

It is important to note that the furnace can operate both on artificial draft and on natural draft. The furnace operates on natural draft as follows. The smelter of metal and alloys opens the gate 144 while the draft in the furnace should be at least 5-20 daPa. It is important to note that at the beginning, two gates 125 and 126 in the mixing chamber 102 are necessarily closed. Gas is supplied, burners 53 are ignited, after the calcination process two doors 24 are closed, the shutters 32 are opened 23 and the metal and alloy smelters are loaded into the calcined furnace using loaders equipped with troughs 6, 7 aluminum scrap with ambient temperature . The flame of six burners 53 heats the scrap to the melting temperature on inclined platforms 6, 7. The metal melts and flows down to the heights 4, 5 of the furnace baths. After filling the baths with liquid metal, 1/5 of the volume is loaded through two side working windows 23 onto the molten metal prepared aluminum scrap. After filling the baths with liquid metal (23-25 tons), the flux is treated with liquid metal in the baths, then the liquid metal is thoroughly mixed, a sample is taken and delivered to the spectral analysis laboratory. When the laboratory confirms the spectral analysis of the grade of the alloy obtained, the metal castors bring the casting device to the stationary drain socks 90, grasping the handles 89 of the steel grooves 67, bring the socks of the steel grooves 67 to the casting equipment, for example, to conveyor 145, molds for sauces 146, open slots 24 and deposited metal is drained from the furnace. After casting the liquid metal, the inclined areas 6, 7 and the bottoms 4, 5 of the furnace baths are cleaned of slag, the plugs 24 are plugged and the cycle repeats. When loading the mixture, melting, casting, flue gases enter the chimney 29, pass through the gas pipe 147 into the chimney 143 and are discharged into the atmosphere. The operation of the furnace on natural traction is carried out if the size of the sanitary protection zone of the enterprise allows, during calcination after repair, casting of deposited metal.

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

The smelter of metal and alloys closes the gate 144, and opens the gates 125 and 126. 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 (lime "cannon", activated carbon, silica gel) is loaded into the two-section gas treatment unit 104 of FIG. 12 and its inclusion is made. In addition, the exhaust fan 103 and the centrifugal fan VTs 4-70-12.5R are turned on. Flue gases enter the mixing chamber 102, are diluted in it by the workshop air, are pumped by the exhaust fan 103 into a two-section gas cleaning unit 104, where they are cleaned of harmful substances in a "fluidized bed", then they enter the battery cyclone 105 and are cleaned from dust by a centrifugal fan 106 and the cleaned smoke the gases are pumped into the chimney 143. The two-section gas purification unit 104 developed by the author cleans the flue gases of harmful substances well. Flue gas cleaning makes the process of smelting aluminum scrap environmentally friendly. After pouring liquid metal from the furnace, metal and alloy smelters open the shutters 32 of the working windows 23 of the furnace and clean the inclined platforms 6, 7, as well as the heights 4, 5 from the slag. Next, the tap holes 24 are plugged and the cycle repeats.

So, the proposed gas two-shaft reflective type furnace for remelting aluminum scrap furnace is a high-performance furnace with a long service life, low heat loss to the environment due to thermal insulation, allowing the remelting process to be carried out on natural and artificial draft with a dust and gas cleaning system.

Claims (6)

1. Two-shaft reflective furnace for remelting aluminum scrap, comprising a body formed by refractory outer side, front and rear end walls, two bathtubs bounded by hearths, a vault and walls, drain gaps and flues, characterized in that the furnace body is placed on a frame laid out inside with lightweight brick ШЛ-1,0, two inclined platforms, the bottom of two bathtubs are made of mullite-corundum blocks of the MKP-72 brand, laid on three layers of asbestos board with a pad of dry quartz sand, while inclined platforms and under the two bathtubs are separated by a wall, a steel box is welded to the furnace frame, which has heat insulation between it and each wall, consisting of fireclay chips, refractory wool, a triple layer of sheet asbestos board and asbestos chips, the arches above inclined platforms and above the first and second bathtubs of the furnace have a layer with double heat-insulating coating with a double layer of refractory heat-insulating mats laid on top of it and a layer of diatom brick, the chimney is made in the rear wall, with three double-row injection nozzles placed in each side wall six-mixing burners of medium pressure directed at an angle to the inclined platforms of the furnace and at an angle to the axis of the furnace, the two-row six-mixing burner during combustion of the air-gas mixture provides a long flame from the mixers of the upper row and the middle from mixers of the lower row, five injection double-row are placed in the rear end wall six mixing burners of medium pressure, directed at an angle to the bottom of the first bath, and five injection double-row six mixing burners of medium pressure, directed along d angle to the bottom of the second bath, the furnace has four working windows, two of which are slag windows, and the device for raising and lowering the shutters of the working and slag window of the furnace has an electric drive, two slots are made in the rear end wall, the furnace is equipped with a platform moving on rails with two rotary attached steel gutters installed on it and a two-stage dust and gas cleaning installation, which provides an environmentally friendly process. 2. The furnace according to claim 1, characterized in that each side wall contains three injection double-row six-mixing medium-pressure burners directed at an angle of 23 ° to inclined platforms of the furnace and at an angle of 25 ° to the axis of the furnace, each mixer of the upper row of a two-row six-mixing burner medium pressure is a casting in the form of a pipe made of heat-resistant cast iron CHKH28NDZYu2 with a diameter of 64 × 10 mm and a length of 315 mm, in which four nozzles are made at the periphery at an angle of 25 ± 1 ° to their axes with a countersink of the inlet part of 0.5 mm at an angle of 90 °, at this in every mixer at the end, on the inner surface there are 12 cast ribs, the cast ribs on the side of the gas-air mixture have an inlet in the form of a taper 5 mm long, the taper angle is 30 °, the height of the ribs is 4.5 mm and the torch length of the mixers of the upper row is 3.3 m. 3. The furnace according to claim 1, characterized in that in the rear end wall there are five injection double-row six-mixing burners of medium pressure directed at an angle of 23 ° to the bottom of the first bath, and five injection double-row six-mixing burners of medium pressure directed at an angle of 23 ° at the bottom of the second bath, each mixer of the lower row is a casting of heat-resistant cast iron CHKH28NDZYu2 in the form of a pipe with an outer diameter of 64 mm and an inner diameter of 44 mm and a length of 315 mm, in which four nozzles are made at the periphery at an angle of 25 ± 1 ° with their axes counterbored entrance portion of 0.5 mm at an angle of 90 °, while the lower row of mixers are arranged to receive the lower row of flame length and 1.5 m. 4. The furnace according to claim 1, characterized in that the device for raising and lowering the shutters of the working and slag window of the furnace has an electric drive in the form of a gear motor containing a double roller block and two single roller blocks connected by a flexible connection in the form of chains between each other and a counterweight, while the shafts of the twin and single blocks of rollers are fixed in the longitudinal channels of the furnace with the shutter moving along the water-cooled box and with the possibility of regulating its position from the control panel, and the water-cooled box with It forms a 1 ° angle with the vertical, the damper contains a U-shaped box with inner ribs and a lid and is cast from heat-resistant cast iron CHX22C with ribs and T-cavities lined with a refractory packing mass. 5. The furnace according to claim 1, characterized in that it has a platform moving along rails with two rotary attached steel gutters mounted on it, a drive is mounted on the platform for moving it on rails, a movable plate is mounted on the top plate of the platform to slide, on which rotational mechanisms of two steel troughs with rotary bowls welded to them are placed, each of which is made in the form of two vertical posts welded to a cross member mounted on a steel trough, having a pivot-turning In order to provide roller rollers that ensure rolling along the movable plate during rotation, a mechanism for feeding steel gutters to the stationary drain socks with rotary bowls is installed on the mobile platform, comprising a rack and pinion mechanism with a drive, and rotary bowls are mounted on shafts that are rotatably mounted in cylinders mounted on a movable plate having rotation limiters. 6. The furnace according to claim 1, characterized in that it is equipped with a two-stage dust and gas cleaning installation, the first stage comprising a mixing chamber, a DN-15 smoke exhaust, a two-section gas cleaning unit, and the second one - a battery cyclone and a centrifugal fan VTs 4-70-12,5R moreover, the dust and gas cleaning installation was performed with a gas purification capacity of 49,000 m ³ / h, and at the same time it has a hydrogen fluoride purification rate of 67%, a copper oxide purification rate of 86%, a carbon monoxide purification degree of 94%, a nitrous oxide purification degree 86%, purification by alumina oxide ia 82% and a degree of dust cleaning of 95% at a sound level of not more than 75 dBA.

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