RU2539490C2 - Electromagnetic induction crucible melting furnace with u-like magnetic core and horizontal magnetic flux - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to metallurgy, particularly, to design peculiarities of electromagnetic induction crucible melting furnaces. Proposed furnace comprises body, crucible with bath, magnetic core made integral with said body with unlike opposed poles that face said crucible to develop a horizontal magnetic flux, inductor with coils around horizontal part of magnetic core between poles. Note here that said crucible with bath is located between said poles above the inductor.

EFFECT: lower losses from crucible wear and decreased amount of rejects, decreased overall dimensions, higher level of protection.

10 cl, 4 dwg

Description

The invention relates primarily to metallurgy and foundry, in particular to designs of induction crucible furnaces used for the smelting of various alloys, bringing the melt to the necessary properties and holding it for batch casting.

A transformer induction channel furnace with an O-shaped magnetic circuit and a vertical magnetic flux is known, comprising an inductor fastened together with coils covering one of the four rods of an O-shaped vertical magnetic circuit, a fixed vessel for melt in the form of a horizontal narrow annular channel made in a refractory ceramic lining and covering the inductor, a rotary device for draining the melt. The furnace is a kind of transformer, where the primary winding is an inductor, the secondary is a short-circuited melt ring (Farbman S.A. Induction furnaces for melting metals and alloys / S.A. Farbman, I.F. Kolobnev. - M .: Metallurgy, 1968. - S.20).

The described transformer induction channel furnace with a vertical magnetic flux has the following main disadvantages:

- a limited scope of use, since, firstly, it is not suitable for direct melting of pieces of a charge, but requires pouring melt from another furnace of a different kind into an annular channel, after which pieces of a charge can be added to the melt. This is due to the peculiarities of energy conversions in such a furnace. The alternating electric current passing through the inductor, excited by the electromotive force (emf) of the electric power source, creates an alternating magnetic flux, which, passing through the magnetic circuit, magnetizes it and amplifies. In this case, electric energy is converted according to the law of total current according to the first Maxwell equation to magnetic. The magnetic flux creates Foucault eddy currents in the magnetic circuit, and around each of the magnetic circuit rods it creates an alternating electric field both in air and in the electrically conductive short-circuited melt ring. An alternating electric field induces an emf in this ring, under the influence of which an electric current arises. In this case, the magnetic energy is converted again into induced electrical energy, which, according to the Joule-Lenz law, is converted into heat, heating the melt. However, despite the fact that the same alternating electric field acts on the electrically conductive pieces of the charge, the electric current does not appear in them, since there are non-conductive air gaps between the pieces and therefore a closed electric circuit is not formed. Thus, the furnace is built on the transformer principle of energy conversion: electric from the emf source - magnetic - electrical in a closed circuit from the induced emf - thermal; secondly, it increases the fumes of the chemical elements of the alloy, since part of it is constantly in the molten state at high temperature, which does not allow smelting alloys whose properties change sharply due to a small deviation from the required chemical composition, for example steel;

- increased operating costs, firstly, due to the need to use a second furnace of a different kind for smelting the melt from the lump charge and pouring it into the annular channel; secondly, due to the reduced resistance of the lining of the channel due to erosion or overgrowing and its often laborious cleaning or replacement, accompanied by disassembly of the magnetic circuit and removal of the inductor, especially when smelting high-temperature alloys; thirdly, due to the difficulty of switching from smelting one type of alloy to another due to the need to completely drain one melt from the channel and fill another, changing the design and section of the channel and the composition of the lining before.

Known induction induction crucible melting furnace with a vertical magnetic flux, containing the body fastened together, a fixed steel or lined refractory crucible with a bath for the melt, an inductor with turns. The turns of the inductor, covering a cylindrical crucible with a bath, are located as close as possible to the crucible, mainly in the horizontal plane, coaxially with the vertical axis of the bath and are a support for the crucible. The turns are made hollow from a copper tube, inside which under pressure up to 0.2-0.7 MPa flows cooling air at a speed of 1-1.5 m / s: distilled or with a content of mechanical impurities up to 80 g / m ³ , a certain hardness up to 7 g-eq / m ³ , temperature 35-40 ° C and a pH value of pH 7. An insulating layer is applied on top of the tube. The crucible and bath have a circle configuration in terms of. The height of the inductor is less than the height of the bath and crucible. A device in the form of electric hoist, designed to drain the melt, is installed with the ability to rotate the entire furnace and attach to the furnace only for the duration of the drain. The electric hoist is also used to load the charge in furnaces with a capacity of up to 1 t. The alternating electric current passing through the coils of the inductor, excited by the emf source of electricity, creates a variable magnetic flux. In this case, electric energy is converted into magnetic energy according to the law of total current according to the first Maxwell equation. The magnetic flux acts on the electrically conductive pieces of the charge, and in each of them a direct alternating vortex electric field and emf are induced, and under the influence of this emf - Foucault eddy current. In this case, the magnetic energy is converted according to the Faraday law of electromagnetic induction according to the second Maxwell equation again into electrical energy, which according to the Joule-Lenz law is converted into heat, heating the melt. Thus, the furnace is built on other principles of energy conversion: electric from emf source - magnetic - electric eddy current Foucault - thermal. Since the working magnetic flux is created only by an inductor, the furnace is an induction induction furnace (Farbman S.A. Induction furnaces for melting metals and alloys / S.A. Farbman, I.F. Kolobnev. - M .: Metallurgy, 1968. - P.314 )

The main disadvantage of the induction induction crucible melting furnace with a vertical magnetic flux is the limited scope of use, due to the following reasons:

- increased rejects of castings on non-metallic inclusions - air shells, particles of foam, lining, slag - or an increase in the duration of melting due to the need to settle the melt in the furnace to float these inclusions. The latter increases energy consumption. The first is due to the fact that the magnetic field generated by a low inductor is very inhomogeneous and has a close to toroidal shape with different directions of the induction vector relative to the center of the inductor and an uneven distribution of the magnitude of the induction in its working cavity, namely: in height - at the ends it is almost 2 times less than in the middle; cross-section - at turns it is noticeably larger than in the center. This leads to the appearance of significant multidirectional gradients of induction and electromagnetic forces in the melt and its intensive mixing in different directions, which is the reason for the increased wear of the crucible walls and the mixing of wear products, air and slag into the melt, especially with a decrease in the field frequency;

- increased energy consumption, since despite the requirement of placing the crucible walls as close as possible to the turns of the inductor, a significant part of the working magnetic flux with the highest induction value is not used, since it passes along the non-conductive walls of the crucible, and not along the charge or melt. In addition to the working magnetic flux, the inductor also creates a scattering magnetic flux of the same magnitude, which is not involved in heating the charge and melt. All this reduces the useful use of magnetic flux to almost 40%, and the natural power factor cosφ - to 0.03-0.10 and increases energy consumption and suggests the availability of devices for reactive power compensation. Magnetic flux scattering harms the health of workers;

- increased dimensions of the furnace and increased occupied production area, since the magnetic flux of scattering causes heating of the nearby electrically conductive parts of the frame, so these parts are removed from the inductor or an electrically conductive screen is installed around the inductor;

- increased costs for ensuring trouble-free operation of the furnace due to leakage of the melt to the inductor during the formation of cracks in the crucible, and the rotation of the entire heavy and bulky furnace increases the energy consumption, dimensions and cost of the device for draining the melt;

- increased costs for water conditioning and the creation of high pressure due to the cooling of hollow turns of conditioned water.

The closest in technical essence and the achieved result (prototype) is an induction induction crucible melting furnace with I-shaped magnetic circuits and vertical magnetic flux, comprising a housing, a stationary refractory lined crucible with a bath, an inductor with turns, several vertical rod I-shaped magnetic circuits, a device to drain the melt bonded together. Water-cooled coils of the inductor, covering the crucible with a bath for the melt, are located as close as possible to the crucible, mainly in the horizontal plane, coaxially with the vertical axis of the bath and are a support for the crucible. The crucible and bath have a circle configuration in terms of. The height of the inductor is less than the height of the bath and crucible. Vertical rod-shaped I-shaped magnetic circuits are located on the outside of the inductor with a given circumferential pitch, their poles are horizontal, placed on the lower and upper ends of the magnetic circuit and face in opposite directions. This partially reduces the scattering flux, but increases the mass and dimensions of the furnace. A device for draining the melt with a hydraulic drive is installed with the ability to rotate the entire furnace. The principle of operation of the furnace is the same as that of the previous analogue, therefore it is also an induction induction furnace (S. A. Farbman. Induction furnaces for melting metals and alloys / S. A. Farbman, I. F. Kolobnev. - M .: Metallurgy, 1968. - P.313).

The main disadvantage of the induction induction crucible melting furnace with I-shaped magnetic circuits and vertical magnetic flux is the limited scope of use, due to the following reasons:

- increased rejects of castings on non-metallic inclusions - air shells, particles of foam, lining, slag - or an increase in the duration of melting due to the need to settle the melt in the furnace to float these inclusions. The latter increases energy consumption. The first is due to the fact that the magnetic field generated by a low inductor is very inhomogeneous and has a close to toroidal shape with different directions of the induction vector relative to the center of the inductor and an uneven distribution of the magnitude of the induction in its working cavity, namely: in height - at the ends it is almost 2 times less than in the middle; cross-section - at turns it is noticeably larger than in the center. This leads to the appearance of significant multidirectional gradients of induction and electromagnetic forces in the melt and its intensive mixing in different directions, which is the reason for the increased wear of the crucible walls and the mixing of wear products, air and slag into the melt, especially with a decrease in the field frequency;

- increased energy consumption, since despite the requirement of placing the crucible walls as close as possible to the turns of the inductor, a significant part of the working magnetic flux with the highest induction value is not used, since it passes along the non-conductive walls of the crucible, and not along the charge or melt. In addition to the working magnetic flux, the inductor also creates a scattering magnetic flux of the same magnitude, which is not involved in heating the charge and melt. All this reduces the useful use of magnetic flux to almost 40%, and the natural power factor cosφ - to 0.03-0.10 and increases energy consumption and suggests the availability of devices for reactive power compensation. Magnetic flux scattering harms the health of workers;

- increased dimensions of the furnace and increased occupied production area, since the magnetic flux of scattering causes heating of the nearby electrically conductive parts of the frame, so these parts are removed from the inductor, and vertical magnetic circuits are installed around the inductor;

- increased costs for ensuring trouble-free operation of the furnace due to leakage of the melt to the inductor during the formation of cracks in the crucible, and the rotation of the entire heavy and bulky furnace increases the energy consumption, dimensions and cost of the device for draining the melt;

- increased costs for water conditioning and the creation of increased pressure due to cooling of the hollow turns with conditioned water;

- low security and reliability of the furnace due to the placement of the inductor around the crucible.

The problem solved by the invention is to expand the scope of use of a crucible melting furnace by reducing losses from wear of the crucible and marriage of castings for non-metallic inclusions, the energy consumption of melting and casting, reducing the occupied area, increasing security and reliability.

The problem is solved in that in an induction crucible melting furnace with a U-shaped magnetic circuit and a horizontal magnetic flux containing a housing, a crucible with a bathtub, an inductor with turns, a magnetic circuit with poles, according to the invention, the magnetic circuit is made U-shaped integral with the housing, its poles facing to each other, the turns of the inductor, covering its horizontal part between the poles, are located mainly in the vertical plane, and the crucible with a bath is placed between the poles above the inductor.

The horizontal size of the poles of the magnetic circuit does not exceed the corresponding horizontal size of the crucible bath.

In addition, the inductor is closed by a sealed casing with holes for supplying refrigerant to its electrically insulated coils and removal.

In addition, the crucible and the bath are predominantly rectangular in plan and the large walls of the crucible are facing the poles.

In addition, the crucible is removable.

In addition, the removable crucible is equipped with at least two trunnions located on opposite sides of the crucible at its end.

In addition, the removable crucible is suspended on the magnetic circuit through the pins.

In addition, a removable lined crucible is made with a metal lattice frame located on the outer surface of the lining and fastened with at least two pins.

In addition, when melting alloys with temperatures up to 1100 ° C, the removable crucible is made of refractory electrically conductive material.

In addition, the bottom of the crucible is made curved with the possibility of rotation of the crucible relative to the inductor.

The decrease in losses from wear of the crucible and marriage of castings from non-metallic inclusions is due to a decrease in the intensity of melt mixing by the horizontal magnetic flux generated by the inductor and guided by a U-shaped magnetic circuit.

The decrease in the energy consumption of melting and casting is due to the increase in the magnetic flux of the inductor’s magnetic circuit, the more complete use of the magnetic flux reinforced by the magnetic circuit as a working one, and to a decrease in the scattering flux, since the magnetic circuit is horizontal and U-shaped in combination with the horizontal coils between the poles covering the inductor, it is possible to create a horizontal magnetic flux and provide conditions for the location of the inductor under the crucible and the direction of the magnetic flux generated inductor to the crucible.

The reduction in the dimensions of the furnace and, accordingly, the occupied production area is due to the implementation of the magnetic circuit at the same time with the body.

Improving the safety and reliability of the device is due to the placement of the inductor only at the bottom of the crucible, that is, installing a crucible with a bath between the poles above the inductor is a necessary condition for melting and increases the reliability of the furnace by significantly reducing the risk of melt entering the inductor through cracks only in the bottom of the crucible, which can be very thick, and the inductor can be additionally protected by a casing.

If the horizontal size of the poles of the magnetic circuit does not exceed the horizontal size of the crucible bath, then the contents of the bath are affected by the working magnetic flux, and the two side walls of the crucible are affected by the magnetic flux of scattering, which reduces the dimensions of the magnetic circuit and, in addition, the energy consumption for melting. If the horizontal size of the poles of the magnetic circuit exceeds the horizontal size of the crucible bath, then this size of the magnetic circuit, the consumption of material and energy, and the scattering flux will increase.

To further increase the reliability of the furnace, the inductor is equipped with a sealed casing that covers and protects the inductor from any negative external influences.

To increase the cooling efficiency of the furnace, reduce the requirements for the parameters of the refrigerant and the costs of its preparation, openings were made in the sealed enclosure for supplying refrigerant to its electrically insulated coils and for removing the refrigerant.

To further reduce the energy consumption of the furnace, the crucible and the bath are made predominantly of a rectangular configuration in plan and the large walls of the crucible are facing the poles, which reduces the path of the working magnetic flux between the poles and the magnetic flux of scattering.

To increase the efficiency of operation of the furnace by ensuring the removal of the crucible after melting and transfer to the place of casting, the crucible is removable. This embodiment of the crucible also significantly speeds up and facilitates the replacement of a worn crucible with a new one.

To increase the efficiency of operation of the furnace by facilitating the removal of the crucible from the furnace and transferring it to the place of casting, by making it possible to hang the crucible on the magnetic circuit without installing only the crucible, and not the entire furnace, on the base of the furnace, the removable crucible is equipped with at least two trunnions during the discharge of the melt .

To increase the efficiency of operation of the furnace by strengthening the crucible when transferring the melt to the casting site, the removable lined crucible is equipped with a metal lattice frame located on the outer surface of the lining and fastened with at least two pins. Moreover, the execution of the lattice frame allows a significant part of the working magnetic flux to penetrate the contents of the bath and to carry out the necessary effect.

To reduce the complexity of manufacturing a furnace by facilitating the manufacture of a crucible in accordance with the invention in comparison with the manufacture of a lined fixed crucible, which requires quite a long drying and sintering process, the removable crucible is made of refractory electrically conductive material when melting alloys with temperatures up to 1100 ° C. In addition, such a crucible reduces the contamination of some alloys by the products of the interaction of the melt with the lining.

To further reduce the energy consumption of the furnace compared to the flat bottom of the rotary crucible, the bottom of the removable crucible is made curved with the possibility of rotation of the crucible relative to the inductor, which brings the bottom of the bath to the inductor and allows you to place a larger volume of the bath in the working volume of the magnetic circuit.

The invention is illustrated by drawings, where Fig. 1 shows an electromagnetic crucible melting furnace with a U-shaped magnetic circuit and horizontal magnetic flux, equipped with a stationary casing made integrally with the magnetic circuit, and a rectangular removable crucible, cross section; figure 2 is the same, a top view; figure 3 is the same, a longitudinal section; figure 4 - furnace with a rotary housing, made integral with the magnetic circuit, and a rectangular fixed crucible.

The proposed electromagnetic induction crucible melting furnace with a U-shaped magnetic circuit and horizontal magnetic flux contains a horizontal U-shaped magnetic circuit 1, made integral with the body, a refractory crucible 2 with a bath 3, an inductor 4 with turns. It is possible to use the device 5 for draining the melt from the bath in the form of electric hoists, or hydraulic cylinders, or an electromechanical transmission, or a winch. The furnace is additionally equipped with a source of adjustable AC voltage with a capacitor bank (not shown).

The implementation of the magnetic circuit 1 at the same time with the housing allows to reduce the dimensions of the furnace and the occupied area. In the latter case, its installation on the base 6 and the rotation are carried out in a known manner, in particular hydraulic cylinders or electric hoists. The implementation of the U-shaped magnetic circuit 1 at the same time with the body allows you to combine the support function for the crucible 2 and inductor 4 with the function of the magnetic induction amplifier and a good conductor of magnetic flux. The U-shaped magnetic circuit 1 has two opposite poles N and S with vertical flat surfaces facing each other and the crucible 2, and the middle horizontal part. To reduce the heating of the U-shaped magnetic circuit 1 by Foucault induction eddy currents, it can be made of plates of electrical transformer steel with a thickness of 0.25-0.5 mm at an industrial frequency of 50 Hz; 0.08-0.15 mm thick - at an increased frequency of up to 500-2500 Hz. With increasing frequency, the thickness of the plate decreases. It is possible to manufacture small magnetic cores for laboratory furnaces and from soft magnetic ferrites, especially at a frequency of more than 2000 Hz. A U-shaped magnetic core 1 mounted on a low or non-conductive base 6 can be fixed and / or rotatable relative to this base. The base 6 can be made of separate elements to create a space under the furnace through which the melt from the cracked or burnt crucible can drain into the emergency tank. The base 6 also contributes to the cooling of the U-shaped magnetic core 1.

The turns of the inductor 4 cover the horizontal part of the U-shaped magnetic circuit 1 between the poles and are located mainly in a vertical plane in one, two or more layers. The crucible 2 with a bath 3 is placed above the inductor 4 between the poles N and S of the U-shaped magnetic circuit 1 with or without the smallest possible gap.

The horizontal size of the poles N and S of the magnetic circuit 1 does not exceed the horizontal size of the bath 3 of the crucible 2.

The inductor 4 can be protected from external influences, especially when the melt leaks from the cracked crucible, with the nonelectrically conductive casing 7 on all sides or partially, for example, only on top of the crucible 2. In the interpolar space of the U-shaped magnetic circuit 1, the inductor 4 with the casing 7 occupy its lower part . The remaining upper part of this space is the working volume and is designed to accommodate the crucible 2. The casing 7 can be single or multi-layer, for example, the outer layer of asbestos cement, and the inner layers of different plastics.

The turns of the inductor 4 can be made of a copper tube, as in analogs, with the same cooling with running water, or of solid copper conductors: a flexible cable, wire or busbar. When using non-insulated conductors, it is possible to isolate them after manufacturing the inductor 4 by impregnating it or filling it with a compound, for example epoxy. On the turns of the inductor 4, it is advisable to have an electrical insulating layer, especially when cooled by supplying liquid or gaseous refrigerant to the cavity of the sealed casing 7. The presence of the magnetic circuit 1 reduces the supply voltage of the inductor 4 and, as a consequence, the risk of breakdown of insulation. Emulsions, transformer oil, non-combustible silicone fluids, distilled or tap water, liquid nitrogen, carbon dioxide, cooled compressed air can be refrigerants. The supply of refrigerant, including tap water, into the casing 7 directly on the outer surface of the insulated turns of the inductor 4, and not inside them, reduces its consumption, supply pressure and requirements for its preparation, and also helps to cool the magnetic circuit 1. The furnace can be additionally equipped refrigerant supply source (not shown).

The crucible 2 with a bath 3 is placed above the inductor 4 between the poles N and S of the U-shaped magnetic circuit 1. The crucible 2 and the bath 3 can be cylindrical, that is, have a circle configuration in plan, or a parallelepiped, that is, have a configuration in plan square or rectangle. The shape of the crucible 2 and the bath 3, especially in the form of a rectangle, in comparison with the cylindrical shape increases the useful use of the magnetic flux generated by the inductor 4, and is suitable for furnaces of increased capacity. The horizontal size of the bath 3 along the pole, it is advisable to perform at least the corresponding size of the pole. The height of the bath is also advisable not less than the upper level of the magnetic circuit 1. In this case, the bath 3 occupies almost the entire working volume of the interpolar space of the U-shaped magnetic circuit 1, with the exception of the thickness of its bottom and two side walls facing the poles, and is pierced by the working magnetic flux. The ratio between the height, length and width of the bath 3 of the crucible 2 is determined by the convenience of loading the mixture and draining the melt, as well as minimizing the energy consumption for melting the mixture. The lining of the bath 3 can be made stacked from refractory products, in particular brick, or printed from bulk refractory materials. Its thickness depends on the temperature of the melt. So, for aluminum alloys, the thickness of the lining is more than 75 mm, and for steel is equal to or more than 150 mm.

The crucible 2 can be installed on the supports 8, mounted on the poles of the magnetic circuit 1, or on the protrusions (not shown) of the magnetic circuit 1. The supports 8 and the protrusions can protect the casing 7 and the inductor 4 from the melt leaking through cracks in the side walls of the crucible 2. In this case, the crucible 2 may not be removable, since it is fastened to the magnetic circuit 1, including by performing a printed lining of the walls of the crucible 2, eliminating the gap between it and the pole. When this device 5 for draining the melt turns the entire furnace.

The crucible 2 can be suspended on loops or pins 9 located on opposite sides of the crucible and resting on the upper ends of the magnetic circuit 1 directly or using intermediate parts, for example gaskets, consoles (not shown). Moreover, the crucible 2 in this case is not bonded to the magnetic circuit 1, has the smallest possible gaps relative to it and the casing 7, which allows only the crucible 2 to be rotated by the device 5 for draining the melt or to remove the crucible 2 from the working volume of the magnetic circuit 1 by another device, for example, a lift (not shown ) To minimize the gap between the crucible 2 and the inductor 4 with the casing 7 and ensure rotation in the case of a central arrangement in the plane of symmetry of the pins 9, the bottom of the crucible 2 and the bath 3 can be made curved. The pins 9 can also be located near the free side walls of a rectangular crucible 2 and used to rotate the crucible 2 or to remove it from the working volume of the magnetic circuit 1 and transfer it to a casting stand or machine (not shown). Turning only crucible 2 provides much lower energy costs than the entire furnace. To rotate the crucible 2 when draining and hanging its trunnion 9 is preferable to the loops.

Removable, including portable, crucible 2 is the most convenient all-metal of refractory conductive material, such as steel, titanium. It can be used for smelting alloys with a melting point up to 1100 ° C, which are heated mainly by the heat of crucible 2 heated by eddy currents of Foucault. However, a removable, including portable, crucible 2 can be lined, including stuffed with a molding slope of up to 5- 10 °.

To strengthen the removable lined crucible 2, a metal lattice frame fastened with at least two trunnions 9 is placed near the outer surface of the lining. The frame can be made of mesh in the form of a basket, perforated sheet, thick wire, rod, tubes, narrow plates. The discrete metal elements of the lattice frame, it is desirable to perform the smallest possible thickness or diameter of low-conductivity alloys and to arrange with the greatest possible distance from each other. At the same time, they heat up little and “pass” most of the magnetic flux to the pieces of the charge.

The device 5 for draining the melt can be selected from the most suitable for the accepted dimensions and weight of the entire furnace of known designs. The most convenient for this is the electric hoist with a carrying capacity of up to 10 tons with a flexible monorail suspension, which allows you to divert the electric hoist 700-800 mm from the nominal axis of the suspension and serve an area of up to 1600 mm wide.

The proposed electromagnetic induction crucible melting furnace with a U-shaped magnetic circuit and horizontal magnetic flux operates as follows.

After loading the electrically conductive components of the charge into the bath 3 to the upper level of the crucible 2, the inductor 4 is connected to the sources of refrigerant supply and regulated alternating electric voltage with a capacitor bank (not shown). In this case, the magnetic circuit 1 and the inductor 4 formed a kind of electromagnet, and therefore the furnace is electromagnetic. The number of turns of the inductor, the magnitude and frequency of voltage and current are determined by calculation. When electric current passes through the inductor 4, an electromagnetic field is created that magnetizes the U-shaped magnetic circuit 1. It increases the value of the induction of this field to 500-1000 or more times and directs the U-shaped magnetic circuit 1 into the interpolar working space in the form of a horizontal magnetic flux. The degree of increase in the value of induction depends mainly on the magnetic permeability of the material of the magnetic circuit 1, the magnitude of the induction of the field created by the inductor 4, its frequency and the distance between the poles. With an increase in permeability and induction, it increases, and with an increase in the frequency and distance between the poles, it decreases. Therefore, the rectangular shape of the crucible 2 is advisable, reducing this distance when the large sides of the crucible 2 are facing the poles.

The boundaries of the working magnetic flux are determined by the height and width of the poles. Beyond their limits, a magnetic flux of scattering spreads, mainly between the ends of the magnetic circuit 1. For its useful use and a significant reduction in the distribution outside the magnetic circuit 1, it is advisable that the corresponding sizes of the bath 3 exceed or exceed the indicated pole sizes. This is especially noticeable when using a ferromagnetic charge. Before loading the mixture into the bath 3, the working electromagnetic field is practically plane-parallel and inhomogeneous. The magnitude of the induction near the poles is greater than in the middle of the distance between the poles. On the surface of the poles, it is almost the same. When the charge is loaded, especially ferromagnetic, a slight violation of plane parallelism and heterogeneity is possible. After its melting, these properties are practically restored. This significantly reduces the intensity of melt mixing, wear of the lining of the crucible, and kneading of non-metallic inclusions — air shells, foam particles, lining, and slag — into the melt. Therefore, castings rejected by non-metallic inclusions are reduced.

The magnetic component of the electromagnetic field induces induction eddy currents in the electrically conductive components of the charge, which heat them until they melt. Eddy currents are induced in the magnetic circuit 1. However, to reduce them, down to zero, the magnetic circuit 1 is drawn from thin plates of electrical steel. Thus, in the prototype and the proposed technical solution, the magnetic flux first acts on the pieces of the charge, which induces electric eddy currents in them. In a transformer furnace, only an electric field acts on the pieces of the charge, which cannot create eddy currents in the piece of the charge, but can turn into a directed current only in a closed conductor.

The first to melt are the components located in the middle-high part of the bath 3 and closer to its bottom, since heat removal is difficult from them. Therefore, it is possible to use forced settling of the charge. After the mixture is completely melted and the necessary metallurgical operations are carried out (removing undesirable and harmful impurities, introducing alloying components and modifiers, downloading slag, etc.), which depend on the type and grade of alloy, the furnace is disconnected from the electric power source. It is also possible to bring the melt to the required properties and hold it for batch casting.

The electric current passing through the turns of the inductor 4 heats them with Joule heat, which must be removed in a known manner or by the proposed invention, namely by supplying refrigerant directly to the insulated turns located in the sealed casing 7, where it is supplied with lower speed, pressure and flow rate at least through one hole, and removed through another.

The melt is drained from the bath 3 of the crucible 2 using the device 5 according to one of two options, characterized by the installation of a U-shaped magnetic circuit 1 on the base 6:

- when the movable installation and fastening of the crucible 2 with the magnetic circuit 1, the device 5 rotates the entire furnace by 95-100 ° together with the crucible 2;

- with a stationary installation and a suspended crucible 3 on the magnetic circuit 1, device 5 rotates only one crucible 2 by 95-100 °.

If the crucible 2 is removed from the working volume of the magnetic circuit 1 by loops or pins 9 or by any other known method and device, it is delivered to a casting stand or machine (not shown), where the melt is poured from it, in particular, into small ladles or into casting molds .

Compared with the prototype, the proposed solution allows you to expand the scope of use of induction melting by using the following advantages:

- reducing losses from wear of the crucible and marriage of castings for non-metallic inclusions due to a decrease in the intensity of mixing of the melt with a horizontal magnetic flux;

- reducing the energy intensity of the melting due to the magnetic circuit reinforcing the magnetic flux of the inductor, more complete use of the magnetic flux reinforced by the magnetic flux as a working one and reducing the scattering flux;

- reducing the occupied production area and simplifying the design of the furnace by performing a magnetic circuit integral with the housing;

- increase the security and reliability of the inductor by placing it only at the bottom of the crucible, and not on four sides, installing a protective casing between it and the crucible, cooling its coils from their outer surface;

- reduce the requirements and costs for the preparation of conditioned refrigerant by feeding it to the outer surface of the turns of the inductor in a sealed enclosure;

- reducing the cost of draining the melt due to the transfer or rotation of only the removable crucible.

Claims (10)

1. Electromagnetic induction crucible melting furnace with a U-shaped magnetic circuit and horizontal magnetic flux, characterized in that it contains a housing, a crucible with a bath, the magnetic circuit is integral with the housing, its poles are facing each other and the crucible, the turns of the inductor cover the horizontal part of the magnetic circuit between the poles, and a crucible with a bath is placed between the poles above the inductor. 2. The furnace according to claim 1, in which the horizontal size of the bath along the pole of the magnetic circuit is made at least the corresponding size of the pole. 3. The furnace according to claim 1, in which the inductor is closed by a sealed casing with holes for supplying refrigerant to its electrically insulated coils and removing refrigerant. 4. The furnace according to claim 1, in which the crucible and the bath are made predominantly of a rectangular configuration in plan and the large walls of the crucible are facing the poles. 5. The furnace according to claim 1, in which the crucible is removable. 6. The furnace according to claim 5, in which the removable crucible is equipped with at least two trunnions located on opposite sides of the crucible. 7. The furnace according to claim 5, in which the removable crucible is suspended on the magnetic circuit through the pins. 8. The furnace according to claim 5, in which the removable crucible is lined with a metal lattice frame, placed on the outer surface of the lining and fastened with at least two pins. 9. The furnace according to claim 5, in which the removable crucible is made of refractory electrically conductive material during the smelting of alloys with a temperature of up to 1100 ° C. 10. The furnace according to claim 5, in which the bottom of the removable crucible is made curved with the possibility of rotation of the crucible relative to the inductor.

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