CN212857737U - Casting system - Google Patents

Abstract

The utility model relates to a casting system. The casting system integrates smelting and casting molding, molten metal can directly enter the casting mold from the containing chamber of the furnace main body through the fluid communication channel, the temperature of the molten metal in the fluid communication channel and the cavity of the casting mold is maintained by the heating device, and the molten metal can be prevented from being cooled and filled or cooled and filled with large temperature difference. The method is suitable for casting wrought aluminum alloy products and wrought magnesium alloy products.

Description

Casting system

Technical Field

The utility model relates to a metal casting technical field specifically is to relate to a casting system.

Background

Aluminum (magnesium) alloys are classified into cast aluminum (magnesium) alloys and wrought aluminum (magnesium) alloys according to their molding methods. Among them, cast aluminum (magnesium) alloys are difficult to be formed by external forces such as extrusion force, forging force, and spinning force, and thus, liquid casting is generally used. However, the mechanical properties of the cast workpiece are still unsatisfactory even after heat treatment. However, because the cast aluminum (magnesium) alloy has excellent liquid fluidity, the cast aluminum (magnesium) alloy is directly formed into a workpiece by a casting process, so that a large amount of mechanical processing can be avoided, and the production cost is low.

The wrought aluminum (magnesium) alloys have poor liquid fluidity, solidify almost at millisecond-level speeds near the solidus temperature during solidification, and are difficult to cast and mold using current casting systems, and are therefore generally shaped by external forces. However, the external force forming requires a large amount of machining to obtain the final workpiece, which results in high production cost and low efficiency. But the workpiece has excellent mechanical property, and the mechanical property can be improved or strengthened by heat treatment under the same component condition.

Therefore, the industry is always seeking to realize the liquid casting of wrought aluminum (magnesium) alloys so as to achieve the advantages of both alloys.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention has been developed to provide a casting system and applications thereof that overcome or at least partially address the above-mentioned problems.

In a first aspect, the present application is directed to a casting system.

The casting system, comprising:

an induction melting furnace including a furnace body and a first induction coil; the furnace main body has a receiving chamber that receives metal; the first induction coil is used for generating alternating current in the metal in the accommodating chamber when the accommodating chamber is provided with the metal;

a casting mold having a cavity;

a fluid communication passage for communicating the receiving chamber of the furnace body and the cavity of the casting mold;

heating means for providing heat to the fluid communication channel and the metal in the mould cavity when the fluid communication channel and the mould cavity are provided with metal in a molten state.

Optionally, the heating means comprises a second induction coil for generating an alternating electrical current in the metal in the fluid communication channel and the mould cavity when the fluid communication channel and the mould cavity are provided with metal in a molten state.

Optionally, the casting system further comprises an ultrasonic source for delivering ultrasonic pulses into the mould cavity when the mould cavity is supplied with metal.

Optionally, the casting system further comprises a cooling device for reducing the temperature of the metal in the mould cavity when the mould cavity is supplied with metal in a molten state.

Optionally, the induction smelting furnace further comprises a spoiler, an outer circumferential wall of the spoiler including a first spiral-shaped protrusion for guiding the metal in the receiving chamber to turn upward or downward when the metal provided in the receiving chamber is in a molten state.

Optionally, the inner peripheral wall of the accommodating chamber comprises a second helical protrusion for guiding the metal in the accommodating chamber to turn over when the metal provided in the accommodating chamber is in a molten state; the second spiral protrusion is rotated in a direction opposite to that of the first spiral protrusion.

Optionally, the inside peripheral wall of the containment chamber comprises protrusions for dispersing agglomerates of fibers and/or particles in the metal flowing around it when the metal supplied to the containment chamber is in a molten state.

Optionally, the protrusions are staggered in the horizontal direction.

Optionally, the furnace body comprises a furnace bottom and a furnace wall, and the furnace wall is formed by stacking a plurality of furnace wall units; the space surrounded by the hearth and the furnace walls forms the containment chamber.

Optionally, the fluid communication channel comprises a liquid discharge channel disposed in the furnace body and communicating with the accommodating chamber, and a flow passage connecting an output end of the liquid discharge channel and an input end of the cavity; the induction smelting furnace further comprises a plug for regulating the flow of molten metal in the tapping channel and for exerting a force on the molten metal in the fluid communication channel.

Optionally, the drainage channel is arranged on the furnace bottom.

Optionally, the spoiler comprises a fluid channel through which the drain channel communicates with the receiving chamber; the flow disturbing piece further comprises an installation hole, and the plug piece is inserted into the installation hole and can move along the axial direction of the installation hole to adjust the flow of molten metal in the liquid drainage channel and exert acting force on the molten metal in the fluid communication channel.

Optionally, the lower end of the spoiler is connected to the bottom of the accommodating chamber.

Optionally, the induction smelting furnace further comprises a furnace cover for closing the upper end opening of the receiving chamber.

Optionally, a positioning hole is formed in the bottom of the accommodating chamber, and the spoiler penetrates through the through hole in the furnace cover and then is inserted into the positioning hole of the accommodating chamber.

Optionally, the spoiler is fixedly connected to the furnace cover.

Optionally, the induction smelting furnace further comprises a gas passage for communicating the receiving chamber with an external gas source.

Optionally, the gas passage is disposed within the plug and is capable of communicating with the fluid passage.

Optionally, the casting system further comprises means for delivering a non-reactive gas to the containment chamber.

Optionally, the casting system further comprises means for delivering a reactive gas to the containment chamber.

Optionally, the furnace body is an insulator furnace body; the spoiler is an insulator spoiler.

Optionally, the plug is an insulator plug.

In a second aspect, the present application proposes the use of the casting system of the first aspect.

Use of the casting system of the first aspect in casting a wrought aluminium alloy product or a wrought magnesium alloy product.

The utility model discloses possess following beneficial effect:

in this embodiment, the casting system integrates melting and casting, and when the molten metal directly enters the casting mold from the receiving chamber of the furnace body through the fluid communication channel and is maintained at the temperature of the molten metal in the fluid communication channel and the mold cavity by the heating device, the molten metal can be prevented from being cooled and filled, or cooled and filled with a large temperature difference. The method is suitable for casting wrought aluminum alloy products and wrought magnesium alloy products.

The plug is inserted in the liquid drainage channel communicated with the containing chamber, can move along the axial direction of the mounting hole to adjust the flow of molten metal in the liquid drainage channel, and can apply static pressure to the molten metal in the liquid communication channel and the casting mold cavity.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the application, are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the principles of the application. It is obvious that the drawings in the following description are only some embodiments of the application, and that for a person skilled in the art, other drawings can be derived from them without inventive effort. In the drawings:

FIG. 1 is a schematic block diagram of one embodiment of a furnace of the present casting system;

FIG. 2 is a schematic block diagram of another state of the casting system of FIG. 1;

FIG. 3 is a schematic cross-sectional view of the walls, spoilers and plugs of the induction melting furnace of FIG. 1;

FIG. 4 is a schematic view of another embodiment of an induction melting furnace of the present casting system;

fig. 5 is a schematic view of the induction melting furnace of fig. 4 in another state.

Description of reference numerals: 1. an induction melting furnace; 2. casting a mold; 3. a fluid communication channel; 4. a furnace main body; 5. a first induction coil; 6. a second induction coil; 7. a spoiler; 8. a first helical protrusion; 9. a protrusion; 10. a furnace bottom; 11. a furnace wall; 12. a liquid discharge channel; 13. a flow channel; 14. a plug member; 15. a fluid channel; 16. a cooling device; 17. an ultrasound source; 18. A furnace cover; 19. a turbulent flow action part; 20. a flange connection; 21. a second helical protrusion; 22. a gas channel.

Detailed Description

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings and examples.

The terms of orientation of upper, lower, left, right, front, rear, inner, outer, top, bottom, and the like, which are or may be referred to in this specification, are defined relative to the configuration shown in the drawings, and are relative terms, and thus may be changed correspondingly according to the position and the use state thereof. Therefore, these and other directional terms should not be construed as limiting terms.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. Furthermore, the terms "comprises," "comprising," and any variations thereof, are intended to cover non-exclusive inclusions.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring initially to fig. 1 and 2, an exemplary embodiment of a casting system according to the present invention is shown. The casting system comprises an induction smelting furnace 1, a casting mould 2, a fluid communication channel 3, and a heating device.

The induction melting furnace 1 includes a furnace main body 4, the furnace main body 4 is generally barrel-shaped, and a receiving chamber for receiving metal, such as wrought aluminum alloy, wrought magnesium alloy, and the like, is formed in the middle of the furnace main body 4. It should be understood that the furnace body 4 may also be designed in other suitable shapes.

The induction melting furnace 1 further comprises a first induction coil 5, the first induction coil 5 surrounding an outer periphery of a furnace wall 11 of the furnace body 4, the first induction coil 5 turning on an external power supply when the accommodating chamber is supplied with metal, and generating an alternating current in the metal in the accommodating chamber so that the metal is heated and melted. After the metal in the accommodating chamber is heated and melted, the first induction coil 5 is continuously connected with an external power supply, and the molten metal (namely the metal in the molten state) is in the magnetic field generated by the first induction coil 5 and rotates under the action of Lorentz force, so that some components in the molten metal, such as flocculent fibers and particle agglomerates, are dispersed, and the components of the molten metal are homogenized.

Preferably, the current input by the external power source to the first induction coil 5 is adjustable, such as turning on and off the power source, changing the direction of the current, changing the frequency of the current, changing the magnitude of the current, and the like. The current input to the first induction coil 5 by an external power supply is regulated by a controller, for example. The change of the current can cause the corresponding change of the Lorentz force borne by the molten metal, and the sudden disappearance, the change of the direction, the change of the size and the like of the Lorentz force can influence the flow of the molten metal in the accommodating chamber, so that the fiber and particle lumps in the molten metal can be scattered, and the components of the molten metal tend to be uniform.

After the components of the molten metal in the accommodating chamber are homogenized to meet the requirement, the molten metal flows from the accommodating chamber of the furnace main body 4 to the cavity of the casting mold 2 through the fluid communication channel 3, and the temperature of the molten metal in the fluid communication channel 3 and the cavity of the casting mold 2 is maintained by a heating device in the mold filling process, so that the molten metal is prevented from being cooled and filled, or the molten metal is cooled and filled with a large temperature difference. Of course, it is also possible to heat the fluid communication channel 3 and the casting mold 2 to increase the temperature thereof before filling, and to reduce or avoid the temperature change of the molten metal due to contact with the inner wall of the fluid communication channel 3 and the inner wall of the casting mold 2.

Specifically, the heating device includes a second induction coil 6, and the second induction coil 6 surrounds an outer peripheral side of the fluid communication passage 3 and an outer peripheral side of the casting mold 2. During the process of filling the molten metal of the containment chamber through the fluid communication channel 3, the second induction coil 6 is connected to an external power source and generates an alternating current in the fluid communication channel 3 and in the molten metal of the mould cavity to provide heat to the molten metal and maintain the temperature of the molten metal. Meanwhile, since the molten metal is in the magnetic field generated by the second induction coil 6 and is rotated by the lorentz force, it is possible to better homogenize the composition of the molten metal and to facilitate the mold filling.

In alternative embodiments, the heating device may also be a device that provides heat to the molten metal in the fluid communication channel 3 and the mold cavity by heat transfer, radiation heating, or the like, or a device that provides heat to the molten metal in the fluid communication channel 3 and the mold cavity by a combination of two or more of heat transfer, radiation heating, electromagnetic induction heating, or the like.

In this embodiment, the induction smelting furnace 1 further comprises a spoiler 7. The spoiler 7 is arranged in the middle of the accommodating chamber, the outer peripheral wall of the spoiler comprises a first spiral protrusion 8, molten metal in the accommodating chamber rotates under the action of Lorentz force and is guided by the first spiral protrusion 8 to turn upwards or downwards, so that the molten metal forms annular longitudinal turbulence, fiber and particle lumps in the molten metal can be scattered, and the components of the molten metal tend to be uniform. It should be understood that the first helical protrusion 8 may be a continuous helical protrusion or may be formed by several separate protrusions in common.

In this embodiment, the inner peripheral wall of the accommodating chamber includes the protrusions 9, the molten metal can rotate in a turbulent flow under the action of the lorentz force, and the molten metal flowing through the protrusions 9 of the inner peripheral wall collides with the protrusions 9, thereby forming a turbulent flow, promoting further scattering of fibers and particle agglomerates in the molten metal, and making the composition of the molten metal uniform. The protrusions 9 of the inner peripheral wall may be regularly or irregularly distributed. In this embodiment, the protrusions 9 of the inner peripheral wall are regularly distributed.

Specifically, the furnace body 4 includes a furnace bottom 10 and a furnace wall 11, and the furnace wall 11 is formed by stacking a plurality of furnace wall 11 units. The space enclosed by the hearth 10 and the furnace walls 11 forms the receiving chamber. The protrusions 9 of the inner circumferential wall are arranged on the inner wall of the furnace wall 11 units, and the protrusions 9 between adjacent furnace wall 11 units are distributed in a staggered manner, as shown in fig. 3.

Returning now to fig. 1 and 2, the fluid communication channel 3 includes a drain channel 12 communicating with the receiving chamber and provided in the furnace bottom 10 for draining molten metal in the receiving chamber. The fluid communication channel 3 further comprises a flow channel 13 connecting the outlet end of the liquid discharge channel 12 and the inlet end of the mould cavity. The induction smelting furnace 1 further comprises a plug 14 for regulating the flow of molten metal into the tapping channel 12, blocking the flow of molten metal from the tapping channel 12 as shown in fig. 1, and letting molten metal flow from the tapping channel 12 as shown in fig. 2, although it is also possible to regulate the flow rate of molten metal flowing from the tapping channel 12. In this embodiment, the lower end of the plug 14 can move up and down in the drainage channel 12, so that the plug 14 can also apply acting force to the molten metal in the fluid communication channel 3, and the molten metal can be subjected to gravity continuous casting and filling under isostatic pressure and isothermal conditions, thereby providing good thermodynamic and kinetic conditions for feeding and exhausting.

Specifically, the spoiler 7 further includes a fluid passage 15 and a mounting hole. The drainage channel 12 communicates with the receiving chamber via a fluid channel 15. The mounting hole is located on the same vertical axis as the liquid discharge passage 12, and the stopper 14 is inserted into the mounting hole and is capable of moving up and down in the axial direction of the mounting hole to regulate the flow of the molten metal in the liquid discharge passage 12 and to apply a force to the molten metal in the fluid communication passage 3.

In this embodiment, the furnace main body 4, the spoiler 7, and the plug 14 are made of an insulating material or a material having a low electrical conductivity at a temperature below the melting point of the metal to be supplied, such as a zirconium ceramic material, an aluminum titanate ceramic material, a corundum ceramic material, or the like. The eddy current generated by the current introduced into the first induction coil 5 can be completely acted on the metal provided in the accommodating chamber, so that the heating efficiency is high, the stirring effect of the Lorentz force on the molten metal in the accommodating chamber can be strengthened, and the uniformity of the components of the molten metal is improved.

The casting system further comprises a cooling device 16, wherein the cooling device 16 comprises a plurality of nozzles (not shown), and a cooling fluid, such as air, steam, nitrogen, etc., is directly sprayed on the casting mold 2 to reduce the temperature of the metal in the cavity and promote condensation. In alternative embodiments, the cooling device 16 may also be a device that uses water cooling, a combination of water cooling and air cooling, or other cooling means.

The casting system further comprises an ultrasonic source 17, which ultrasonic source 17 is on the outside of the casting mould 2 or in contact with the bottom of the casting mould 2. The ultrasound source 17 is a transducer that converts electrical signals into ultrasound waves. The ultrasonic source 17 transmits ultrasonic waves to the metal in the cavity to promote grain refinement.

In this embodiment, the casting system integrates melting and casting, the molten metal directly enters the casting mold from the receiving chamber of the furnace body through the fluid communication channel, and the temperature of the molten metal in the fluid communication channel and the cavity is maintained by a heating device, and the molten metal can be gravity-continuously cast and filled under isostatic isothermal conditions. Moreover, the centrifugal continuous casting can be realized by adopting the casting system. The casting system can solve the problem of cooling and mold filling during the casting of aluminum (magnesium) alloy at home and abroad at present, and is suitable for casting wrought aluminum alloy products and wrought magnesium alloy products.

In another embodiment, the induction melting furnace 1 may also adopt a structure as shown in fig. 4 and 5. The induction melting furnace 1 structurally includes a furnace main body 4, a first induction coil 5, and a spoiler 7.

The furnace main body 4 has a generally barrel-like shape, and includes a furnace bottom 10 and a furnace wall 11, and a space surrounded by the furnace bottom 10 and the furnace wall 11 forms a containing chamber for containing a metal such as a wrought aluminum alloy, a wrought magnesium alloy, or the like. In this embodiment, the induction melting furnace 1 further comprises a furnace cover 18, wherein the furnace cover 18 can close the upper opening of the receiving chamber, so that the receiving chamber becomes a closed or correspondingly closed space. It should be understood that the furnace body 4 may also be designed in other suitable shapes.

The first induction coil 5 surrounds the outer periphery of the furnace wall 11 of the furnace body 4, and when the accommodating chamber is supplied with metal, the first induction coil 5 is energized by an external power supply and generates an alternating current in the metal in the accommodating chamber, so that the metal is heated and melted. The molten metal is turbulently rotated by the Lorentz force in the magnetic field generated by the first induction coil 5 to disperse some components such as flocculent fibers and particle agglomerates in the molten metal and homogenize the components of the molten metal.

The current input by the external power supply to the first induction coil 5 is adjustable, such as switching on and off the power supply, changing the direction of the current, changing the frequency of the current, changing the magnitude of the current, and the like. The current input to the first induction coil 5 by an external power supply is regulated by a controller, for example. The change of the current can cause the corresponding change of the Lorentz force borne by the molten metal, and the sudden disappearance, the turning, the size change and the like of the Lorentz force can influence the flow of the molten metal in the accommodating chamber, so that the fiber and particle lumps in the molten metal can be scattered, and the components of the molten metal tend to be uniform.

The spoiler 7 is arranged in the middle of the accommodating chamber, the outer peripheral wall of the spoiler comprises a first spiral protrusion 8, the molten metal rotates under the action of Lorentz force and is guided by the first spiral protrusion 8 to turn upwards or downwards, so that the molten metal forms annular longitudinal turbulence, fibers and particle lumps in the molten metal can be scattered, and the components of the molten metal tend to be uniform. It should be understood that the first helical protrusion 8 may be a continuous helical protrusion or may be formed by several separate protrusions in common.

Specifically, the spoiler 7 includes a spoiler-acting portion 19, and the first helical protrusion 8 is disposed on an outer peripheral wall of the spoiler-acting portion 19; the turbulence action part 19 penetrates through a through hole on the furnace cover 18 and then is inserted into a positioning hole in the center of the bottom of the accommodating chamber. The spoiler 7 further comprises a flange connecting portion 20, and the upper end of the spoiler acting portion 19 is connected with the flange connecting portion 20 and fixedly connected with the furnace cover 18 through the flange connecting portion 20.

In this embodiment, the inner peripheral wall of the accommodating chamber includes a second spiral protrusion 21, and the molten metal is turbulently rotated under the action of the lorentz force and is guided by the second spiral protrusion 21 to turn upwards or downwards, so that the molten metal forms an annular longitudinal turbulence, and the fibers and the particle lumps in the molten metal can be scattered, so that the components of the molten metal tend to be uniform. Preferably, the second spiral protrusion is opposite to the first spiral protrusion in rotation direction, and the second spiral protrusion 21 guides the molten metal to turn downward while the first spiral protrusion 8 guides the molten metal to turn upward; the second helical projection 21 directs the molten metal to turn upward while the first helical projection 8 directs the molten metal to turn downward. Thus, the annular longitudinal turbulence promoted by the first helical projections 8 and the annular longitudinal turbulence promoted by the second helical projections 21 are brought into longitudinal intersection, while under the action of the lorentz force the molten metal at the intersection is able to form a complex turbulence which further homogenizes the fiber and particle agglomerates in the molten metal. Similarly, the second spiral protrusion 21 may be a continuous spiral protrusion, or may be formed by sharing a plurality of separate protrusions.

The hearth 10 is provided with a liquid discharge passage 12 communicating with the receiving chamber for discharging molten metal in the receiving chamber. The induction smelting furnace 1 further comprises a plug 14 for regulating the flow of molten metal into the tapping channel 12, blocking the flow of molten metal from the tapping channel 12 as shown in fig. 4, and letting molten metal flow from the tapping channel 12 as shown in fig. 5, although it is also possible to regulate the flow rate of molten metal flowing from the tapping channel 12. In this embodiment, the lower end of the plug 14 can move up and down in the drainage channel 12, so that the plug 14 can also apply acting force to the molten metal in the fluid communication channel 3, and the molten metal can be subjected to gravity continuous casting and filling under isostatic pressure and isothermal conditions, thereby providing good thermodynamic and kinetic conditions for feeding and exhausting.

Specifically, the spoiler 7 further includes a fluid passage 15 and a mounting hole. The drainage channel 12 communicates with the receiving chamber via a fluid channel 15. The mounting hole is located on the same vertical axis as the liquid discharge passage 12, and the stopper 14 is inserted into the mounting hole and is capable of moving up and down in the axial direction of the mounting hole to regulate the flow of the molten metal in the liquid discharge passage 12 and to apply a force to the molten metal in the fluid communication passage 3.

In this embodiment, the induction smelting furnace 1 further comprises a gas channel 22 for communicating the receiving chamber with an external gas source. In particular, said gas passage 22 is provided in the plug 14 and can communicate with the fluid passage 15, as shown in fig. 4. The output end of the external gas source is connected to the inlet of the gas passage 22 at the upper end of the plug 14, and when the gas passage 22 is in the state of being communicated with the fluid passage 15 as shown in fig. 4, a non-reactive gas such as an inert gas, or a reactive gas such as oxygen, or a gas together with nano-metal powder, etc. may be supplied into the accommodating chamber.

Preferably, the fluid channel 15 is arranged close to the bottom wall of the containment chamber. On one hand, the input gas can promote the molten metal to form turbulent flow at the bottom of the containing chamber, and further homogenize fiber and particle agglomerates in the molten metal; on the other hand, bubbles generated by the input gas meet suspended slag inclusions in the floating process, and the slag inclusions are adsorbed on the surfaces of the bubbles and are brought to the liquid level of the molten metal, so that the slag inclusions can be effectively removed; on the other hand, when the gas to be supplied is an inert gas, oxygen, water molecules, etc. above the molten metal surface can be effectively removed.

In this embodiment, the furnace main body 4, the spoiler 7, the plug 14, and the furnace cover 18 are made of an insulating material or a material having a low electrical conductivity at a temperature below the melting point of the metal to be supplied, such as a zirconium ceramic material, an aluminum titanate ceramic material, a corundum ceramic material, or the like. Eddy current generated by the current introduced into the first induction coil 5 can be completely acted on the metal provided in the accommodating chamber, so that the heating efficiency is high, the stirring effect of the Lorentz force on the molten metal can be enhanced, and the uniformity of the components of the molten metal is improved.

In an alternative embodiment, the casting system further comprises means for delivering a non-reactive gas to the containment chamber, the output of which is connected to the inlet of the gas passage 22 at the upper end of the plug 14.

In another alternative embodiment, the casting system further comprises means for delivering a reactive gas to the containment chamber, the output of which is connected to the inlet of the gas passage 22 at the upper end of the plug 14.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (9)

1. A casting system, comprising:

an induction melting furnace including a furnace body and a first induction coil; the furnace main body has a receiving chamber that receives metal; the first induction coil is used for generating alternating current in the metal in the accommodating chamber when the accommodating chamber is provided with the metal;

a casting mold having a cavity;

a fluid communication passage for communicating the receiving chamber of the furnace body and the cavity of the casting mold;

heating means for providing heat to the fluid communication channel and the metal in the mould cavity when the fluid communication channel and the mould cavity are provided with metal in a molten state.

2. The casting system of claim 1, wherein: the heating means comprises a second induction coil for generating an alternating electrical current in the metal in the fluid communication channel and the mould cavity when the fluid communication channel and the mould cavity are provided with metal in a molten state.

3. The casting system of claim 1, wherein: also included is an ultrasonic source for delivering ultrasonic pulses into the cavity when the cavity is provided with metal.

4. The casting system of claim 1, wherein: further comprising cooling means for reducing the temperature of the metal in the mould cavity when the mould cavity is supplied with metal in a molten state.

5. The casting system according to any one of claims 1 to 4, wherein: the induction melting furnace further includes a spoiler, an outer peripheral wall of which includes a first spiral protrusion for guiding the metal in the receiving chamber to turn upward or downward when the metal supplied to the receiving chamber is in a molten state.

6. The casting system of claim 5, wherein: the inner peripheral wall of the accommodating chamber comprises a second spiral protrusion for guiding the metal in the accommodating chamber to turn over when the metal provided in the accommodating chamber is in a molten state; the second spiral protrusion is rotated in a direction opposite to that of the first spiral protrusion.

7. The casting system of claim 5, wherein: the inside peripheral wall of the containing chamber contains protrusions for dispersing fiber and/or particle agglomerates in the metal flowing therethrough when the metal supplied to the containing chamber is in a molten state.

8. The casting system of claim 5, wherein: the fluid communication channel comprises a liquid drainage channel which is arranged on the furnace main body and communicated with the containing chamber, and a flow passage which is connected with the output end of the liquid drainage channel and the input end of the cavity; the induction smelting furnace further comprises a plug for regulating the flow of molten metal in the tapping channel and for exerting a force on the molten metal in the fluid communication channel.

9. The casting system of claim 8, wherein: the spoiler comprises a fluid channel, and the liquid discharge channel is communicated with the accommodating chamber through the fluid channel; the flow disturbing piece further comprises an installation hole, and the plug piece is inserted into the installation hole and can move along the axial direction of the installation hole to adjust the flow of molten metal in the liquid drainage channel and exert acting force on the molten metal in the fluid communication channel.

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