Equipment and Method of Semi-Continuous Casting Optimized by Synergistic Action of Traveling Magnetic Field and Ultrasound Wave for Thin-Walled Alloy Casting with Equal Outer Diameter

Abstract

A semi-continuous casting equipment for thin-walled alloy castings with equal outer diameter, optimized by synergistic action of traveling magnetic fields and ultrasonic wave, includes: a melting and insulation device, a heat insulation panel, a traveling magnetic field generator and a water-cooled crystallizer sequentially positioned on a working platform; an outer mold positioned on the water-cooled crystallizer and sleeved the traveling magnetic field generator; a mold core inside the outer mold defining a casting cavity; a bottom plate below the mold core capable of sliding against and along an inner side of the outer mold; two position control units supported by the working platform; an ultrasonic limit baffle moveably engaged with the position control units; an ultrasonic wave generator affixed on the ultrasonic limit baffle and extended to the casting cavity; a motion system controlling up and down movement of the bottom plate and the position control units through a gear transmission mechanism.

Claims

1. A semi-continuous casting equipment for thin-walled alloy castings with equal outer diameter that is optimized by synergistic action of traveling magnetic field and ultrasonic wave, comprising: a melting and insulation device, a traveling magnetic field generator, an ultrasonic wave generator, a motion system, an ultrasonic limit baffle, two position control units, a mold core, an outer mold, a bottom plate, a working platform, a heat insulation panel, a water-cooled crystallizer, and a motor, wherein said melting and insulation device, said heat insulation panel, said traveling magnetic field generator and said water-cooled crystallizer are sequentially stacked from top to bottom on said working platform, said outer mold is sleeved at an inner portion of said traveling magnetic field generator and is positioned on said water-cooled crystallizer, and said mold core is provided inside said outer mold and is positioned on said bottom plate to define a casting cavity between said mold core and said outer mold, wherein each said position control unit has a T-shaped structure formed by a horizontal member and a vertical member below said horizontal member, said two position control units are arranged on top of said working platform at two opposite sides of said working platform respectively, said ultrasonic limit baffle is overlappingly connected on said horizontal member of said position control unit, and said ultrasonic wave generator is fixedly mounted on said ultrasonic limit baffle and extends downward into said casting cavity, said motion system comprises two screw nuts, two screw guiding rails, two push rods and two support rods at said two opposite sides of said working platform and a moving push plate, wherein said two screw guiding rails are connected to a lower surface of said working platform and extended vertically and downwardly, said two screw nuts are sleeved on said two screw guiding rails respectively to form two screw pairs, said moving push plate is fixedly connected to said two screw nuts to moveably connected to said two screw guiding rails, said two screw guiding rails are driven by synchronous rotational movement of said motor so that said moving push plate is driven to have an up and down movement through said two guiding rails, said two support rods and said two push rods are connected to said moving push plate and vertically extended, each said support rod is connected to said bottom plate at a top end of said support rod, each said push rod penetrates through said working platform and said position control unit, said ultrasonic limit baffle is pushed to move upward by said push rod when said push rod is driven to move upward.

2. The semi-continuous casting equipment for thin-walled alloy castings with equal outer diameter that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 1, wherein a height of said screw guiding rail is greater than two times of a total stroke of continuous casting.

3. The semi-continuous casting equipment for thin-walled alloy castings with equal outer diameter that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 1, wherein said water-cooled crystallizer has a hollow copper plate structure in such a manner that circulating water is introduced into said water-cooled crystallizer for forced cooling.

4. The semi-continuous casting equipment for thin-walled alloy castings with equal outer diameter that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 1, wherein said heat insulation board is made of mica plate or high temperature asbestos.

5. The semi-continuous casting equipment for thin-walled alloy castings with equal outer diameter that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 1, wherein a rotation movement is driven by said motor so that said screw guiding rails are controlled to rotate synchronously through a gear transmission.

6. A semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave, comprising the steps of: (a) arranging a melting and insulation device, a heat insulation panel, a traveling magnetic field generator and a water-cooled crystallizer sequentially from top to bottom on a working platform, sleeving an outer mold at an inner portion of the traveling magnetic field generator which is positioned on the water-cooled crystallizer, providing a mold core inside the outer mold at a position on the bottom plate and defining a casting cavity between the mold core and the outer mold, and arranging an ultrasonic wave generator extending into the casting cavity; (b) at an initial state, fittingly aligning the bottom plate with a bottom surface of an inner cavity of the melting and insulation device, turning on the ultrasonic wave generator, putting the alloy material with large solidification intervals inside the melting and insulation device for melting, process heat preservation at a temperature 5060 C. higher than a melting point of the alloy material, carrying out ultrasonic treatment on the molten alloy through the ultrasonic wave generator in the process of heat preservation, then obtain the insulated and ultrasonic treated smelting alloy; (c) then processing pulling while the mold core and the ultrasonic wave generator are moving vertically downwards synchronously, and turning on the traveling magnetic field generator and the water-cooled crystallizer when the pulling process begins; (d) limiting and fixing a position of the ultrasonic wave generator when the ultrasonic wave generator is pulled to a position of the mushy zone of the alloy so as to ensure that the mushy zone is simultaneously subjected to a magnetic field treatment of the traveling magnetic field generator and an ultrasonic treatment of the ultrasonic wave generator, continuing the pulling of the mold core until the end of the casting process, thereby a semi-continuous casting for thin-walled alloy castings with equal outer diameter and large solidification intervals is completed.

7. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein a traveling magnetic field strength of the traveling magnetic field generator is 0.001 T to 2 T.

8. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein a power of the ultrasonic generator is 1 W to 2000 W.

9. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein a speed of a downward movement of the mold core driven by the bottom plate is 1 m/s to 500 m/s.

10. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein in the step (b), the alloy material with wide solidification interval is ZnAl alloy, AlCu alloy or AlPb alloy.

11. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein in the step (b), the alloy material with large solidification intervals is magnesium alloy MA2-1, uranium-niobium alloy U2Nb or aluminum alloy ZL205A.

12. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein in the step (b), process heat preservation at the temperature 5060 C. higher than the melting point of the alloy material for 10 minutes to 20 minutes.

13. The semi-continuous casting method for thin-walled alloy castings with equal outer diameter and large solidification intervals that is optimized by synergistic action of traveling magnetic field and ultrasonic wave according to claim 6, wherein in the step (d), limiting and fixing a position of the ultrasonic wave generator at a position corresponding to of a height of the traveling magnetic field generator from a top of the traveling magnetic field generator inside the traveling magnetic field generator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0024] FIG. 1 is a schematic diagram the semi-continuous casting equipment optimized by traveling magnetic field and ultrasonic wave for thin-walled alloy casting with equal outer diameter at a stable state of time according to a preferred embodiment of the present invention.

[0025] FIG. 2 is a schematic diagram of the semi-continuous casting equipment optimized by traveling magnetic field and ultrasonic wave for thin-walled alloy casting with equal outer diameter at an initial state of time according to the above preferred embodiment of the present invention.

[0026] FIG. 3 is a scanning electron micrograph of the casting structure prepared by the semi-continuous casting equipment optimized by traveling magnetic field and ultrasonic wave for thin-walled alloy casting with equal outer diameter according to the above preferred embodiment of the present invention.

[0027] FIG. 4 is a scanning electron micrograph of the casting structure prepared by the semi-continuous casting equipment without applying a traveling magnetic field and ultrasonic wave.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0028] The following detailed description of the preferred embodiment is the preferred mode of carrying out the invention. The description is not to be taken in any limiting sense. It is presented for the purpose of illustrating the general principles of the present invention.

Embodiment 1

[0029] According to this embodiment, a semi-continuous casting equipment that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy casting with equal outer diameter comprises: a melting and insulation device 1 for melting and keeping the temperature, a traveling magnetic field generator 3, a ultrasonic wave generator 4, a motion system 200, an ultrasonic limit baffle 11, a position control unit 12, a mold core 13 and an outer mold 14. On the working platform 15, the melting and insulation device 1, a heat insulation panel 2, the traveling magnetic field generator 3 and a water-cooled crystallizer 10 are sequentially stacked from top to bottom. The outer mold 14 is sleeved at an inner portion 31 of the traveling magnetic field generator 3 and is positioned on the water-cooled crystallizer 10. The mold core 13 is provided inside the outer mold 14 and is positioned on the bottom plate 16.

[0030] The position control unit 12 has a T-shaped structure formed by a horizontal member 121 and a vertical member 122. Two position control units 12 are arranged on the left and right sides and on top of the working platform 15 respectively. The ultrasonic limit baffle 11 is overlapped and positioned on the horizontal member 121 of the position control unit 12. The ultrasonic wave generator 4 is affixed on the ultrasonic limit baffle 11. The position control unit 12 control the lowest position of the ultrasonic baffle 11 along a vertical direction. When the ultrasonic baffle 11 is guided to move vertically downward, the position control unit 12 can stop the ultrasonic baffle 11 from further movement when reaching the position control unit 12.

[0031] The motion system 200 comprises a screw nut 5, a screw guiding rail 6, a moving push plate 7, a push rod 8 and a support rod 9. Two screw guiding rails 6 are vertically arranged on a lower surface of the working platform 15 and extended downwardly. One screw nut 5 is sleeved on one screw guiding rail 6 to form a screw pair. The moving push plate 7 is fixedly connected with the screw nut 5. The two screw guiding rails 6 are driven by a gear 18 and the motor 17 to rotate synchronously to drive the moving push plate 7 on the screw guiding rails 6 to move up and down. Two support rods 9 and two push rods 8 are vertically arranged on the moving push plate 7 and extended upwardly, and the tops of the two support rods 9 are connected with a bottom plate 16. The push rod 8 penetrates through the working platform 15 and the position control unit 12, and the ultrasonic limit baffle 11 is pushed to move upward when the push rod 8 is moving upward. The ultrasonic wave generator 4 on the ultrasonic limit baffle 11 extends downward into a casting cavity 19 between the mold core 13 and the outer mold 14.

[0032] According to the semi-continuous casting equipment that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy castings with equal outer diameter of this embodiment of the present invention, the ultrasonic wave generator and the mold core are synchronized

Embodiment 2

[0033] The difference between this embodiment and the embodiment 1 is that a height of the screw guiding rail 6 is greater than twice a total stroke of the continuous casting.

[0034] In this embodiment, the height of the screw guiding rail 6 and the working platform 15 are the same, and the two guiding rails 6 are parallel to each other and perpendicular to the ground.

Embodiment 3

[0035] The difference between this embodiment and the embodiment 1 or embodiment 2 is that the water-cooled crystallizer 10 adopts a hollow copper plate structure, and circulating water is introduced into the water-cooled crystallizer 10 for forced cooling.

[0036] This embodiment ensures that the ultrasonic generator 4 can effectively act on the mushy zone during the alloy solidification process.

Embodiment 4

[0037] The difference between this embodiment and one of the embodiments 1-3 is that the material of the heat insulation board 2 is mica plate or high temperature asbestos.

Embodiment 5

[0038] The difference between this embodiment and one of the embodiments 1-4 is that a rotation of a gear 18 is driven by a motor 17 so that the screw guiding rails 6 is controlled to rotate synchronously through a gear transmission.

Embodiment 6

[0039] According to this embodiment, a semi-continuous casting method that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy castings with equal outer diameter and large solidification intervals is implemented according to the following steps:

[0040] 1. Arranging a melting and insulation device 1, a heat insulation panel 2, a traveling magnetic field generator 3 and a water-cooled crystallizer 10 sequentially from top to bottom on a working platform 15, sleeving an outer mold 14 at an inner portion 31 of the traveling magnetic field generator 3 which is positioned on the water-cooled crystallizer 10, providing a mold core 13 inside the outer mold 14 at a position on the bottom plate 16, defining a casting cavity 19 between the mold core 13 and the outer mold 14 and arranging an ultrasonic wave generator 4 extending into the casting cavity 19.

[0041] 2. At an initial state, fittingly aligning the bottom plate 16 with a bottom surface of an inner cavity of the melting and insulation device 1, turning on the ultrasonic wave generator 4, putting the alloy material with large solidification intervals inside the melting and insulation device 1 for melting, performing heat preservation at a temperature 5060 C. higher than the melting point of the alloy material, carrying out ultrasonic treatment on the molten alloy through the ultrasonic wave generator 4 in the process of heat preservation, then obtaining the insulated and ultrasonic treated smelting alloy.

[0042] 3. Then pulling downwards the mold core 13 and the ultrasonic wave generator 4 vertically and synchronously, and turning on the traveling magnetic field generator 3 and the water-cooled crystallizer 10 when the pulling process begins.

[0043] 4. Limiting and fixing a position of the ultrasonic wave generator 4 when the ultrasonic wave generator 4 is pulled to the position of the mushy zone of the alloy so as to ensure that the mushy zone can be simultaneously subjected to magnetic fields treatment of the traveling magnetic field generator 3 and an ultrasonic treatments of the ultrasonic generator 4, continue pulling of the mold core 13 until the end of the casting process, thereby a semi-continuous casting for thin-walled alloy castings with equal outer diameter and large solidification intervals is completed.

Embodiment 7

[0044] The difference between this embodiment and the embodiment 6 is that a traveling magnetic field strength of the traveling magnetic field generator 3 is controlled to approximately 0.001 T to 2 T.

[0045] In this embodiment, an axial direction of the traveling magnetic field is adjusted to be upward or downward.

Embodiment 8

[0046] The difference between this embodiment and the embodiment 6 or embodiment 7 is that a power of the ultrasonic generator 4 is controlled to approximately 1 W to 2000 W.

Embodiment 9

[0047] The difference between this embodiment and one of the embodiments 6-8 is that the lowering speed of the mold core 13 driven by the bottom plate 16 is approximately 1 s to 500 m/s.

Embodiment 10

[0048] The difference between this embodiment and one of the embodiments 6-9 is that in the step 2, the alloy material with large solidification intervals is ZnAl alloy, AlCu alloy or AlPb alloy. ZnAl alloy refers to alloys whose main constituents are zine and aluminum, AlCu alloy refers to alloys whose main constituents are aluminum and copper, and AlPb alloy refers to alloys whose main constituents are aluminum and lead.

Embodiment 11

[0049] The difference between this embodiment and one of the embodiments 6-10 is that in the step 2, the alloy material with large solidification intervals is magnesium alloy MA2-1, uranium-niobium alloy U2Nb or aluminum alloy ZL205A.

Embodiment 12

[0050] The difference between this embodiment and one of the embodiments 6-11 is that in the step 2, process heat preservation at the temperature 5060 C. higher than the melting point of the alloy material for approximately 10 minutes to 20 minutes.

Embodiment 13

[0051] The difference between this embodiment and one of the embodiments 6-12 is that in the step 4, limiting and fixing a position of the ultrasonic wave generator 4 at a position corresponding to inside the traveling magnetic field generator 3.

[0052] The position of the alloy mushy zone in this embodiment can be determined through experiments. The position of the mushy zone of the alloy material with large solidification intervals is (mostly) within the range of after entering inside the traveling magnetic field generator 3.

Preferred Embodiment

[0053] According to this embodiment, a semi-continuous casting equipment that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy castings with equal outer diameter comprises: a melting and insulation device 1 for melting and keeping the temperature, a traveling magnetic field generator 3, a ultrasonic wave generator 4, a motion system 200, an ultrasonic limit baffle 11, a position control unit 12, a mold core 13 and an outer mold 14. On the working platform 15, the melting and insulation device 1, a heat insulation panel 2, the traveling magnetic field generator 3 and a water-cooled crystallizer 10 are sequentially stacked from top to bottom. The working platform 15 is supported by two supporting legs 20. The outer mold 14 is sleeved at an inner portion 31 of the traveling magnetic field generator 3 and is positioned on the water-cooled crystallizer 10. The mold core 13 is provided inside the outer mold 14. The mold core 13 is positioned on the bottom plate 16.

[0054] The position control unit 12 has a T-shaped structure formed by a horizontal member 121 and a vertical member 122. Two position control units 12 are arranged on the left and right sides and on top of the working platform 15 respectively. The ultrasonic limit baffle 11 is overlapped and positioned on the horizontal member 121 of the position control unit 12. The ultrasonic wave generator 4 is affixed on the ultrasonic limit baffle 11.

[0055] The motion system 200 comprises a screw nut 5, a screw guiding rail 6, a moving push plate 7, a push rod 8 and a support rod 9. Two screw guiding rails 6 are vertically arranged on a lower surface of the working platform 15 and extended downwardly. One screw nut 5 is sleeved on one screw guiding rail 6 to form a screw pair. The moving push plate 7 is fixedly connected with the screw nut 5. The two screw guiding rails 6 are driven by the motor 17 and a gear 18 to rotate synchronously to drive the moving push plate 7 on the screw guiding rails 6 to move up and down. Two support rods 9 and two push rods 8 are vertically arranged on the moving push plate 7 and extended upwardly, and the tops of the two support rods 9 are connected with a bottom plate 16. The mold core 13 on the bottom plate 16 is driven by the moving push plate 7 to have a downward pulling movement inside the outer mold 14. The push rod 8 penetrates through the working platform 15 and the position control unit 12, and the ultrasonic limit baffle 11 is pushed to move upward by a top portion of the push rod 8 during upstroke movement. The ultrasonic wave generator 4 on the ultrasonic limit baffle 11 extends into a casting cavity 19 between the mold core 13 and the outer mold 14.

APPLICATION EXAMPLES

[0056] According to this embodiment, a semi-continuous casting method that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy castings with equal outer diameter and large solidification intervals is implemented according to the following steps:

[0057] 1. Arranging a melting and insulation device 1, a heat insulation panel 2, a traveling magnetic field generator 3 and a water-cooled crystallizer 10 sequentially from top to bottom on a working platform 15, sleeving an outer mold 14 at an inner portion 31 of the traveling magnetic field generator 3 which is positioned on the water-cooled crystallizer 10, providing a mold core 13 inside the outer mold 14 at a position on the bottom plate 16, defining a casting cavity 19 between the mold core 13 and the outer mold 14 and arranging an ultrasonic wave generator 4 extending into the casting cavity 19. The bottom of the casting cavity 19 is the bottom plate 16.

[0058] 2. At an initial state, fittingly aligning the bottom plate 16 with a bottom surface of an inner cavity of the melting and insulation device 1, turning on the ultrasonic wave generator 4, putting Al-5Cu alloy material inside the melting and insulation device 1 for melting, performing heat preservation at a temperature 50 C. higher than the melting point of the alloy material for 15 minutes, carrying out ultrasonic treatment on the molten alloy through the ultrasonic wave generator 4 at a power of 1600 W in the process of heat preservation, then obtaining the insulated and ultrasonic treated smelting alloy.

[0059] 3. Then processing pulling by moving the mold core 13 and the ultrasonic wave generator 4 vertically downwards synchronously and controlling a pulling speed at 150 m/s turning on the traveling magnetic field generator 3 and the water-cooled crystallizer 10 when the pulling process begins, controlling a magnetic field strength to 1.2 T for continuous casting of the insulated and ultrasonic treated smelting alloy.

[0060] 4. Limiting and fixing a position of the ultrasonic wave generator 4 when the ultrasonic wave generator 4 is pulled to the position of the mushy zone of the alloy (that is when moving downward along a vertical direction to the inside of the traveling magnetic field generator 3, a position corresponding to of a height the traveling magnetic field generator 3 from the top of the traveling magnetic field generator 3) so as to ensure that the mushy zone is simultaneously subjected to magnetic fields treatment of the traveling magnetic field generator 3 and an ultrasonic treatment of the ultrasonic generator 4, continuing pulling of the mold core 13 until the end of the casting process, thereby a semi-continuous casting for thin-walled alloy castings with equal outer diameter and large solidification intervals is completed.

[0061] Referring to FIG. 1 and FIG. 2 of the drawings, the semi-continuous casting equipment that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy castings with equal outer diameter comprises: a melting and insulation device 1, a heat insulation panel 2, a traveling magnetic field generator 3, and a water-cooled crystallizer 10 sequentially positioned at a top-down direction on the working platform 15. A height of the screw guiding rail 6 is the same as a height of the working platform 15 and is greater than twice a total stroke of the continuous casting. The screw guiding rail 6 consists of two rail members parallel to each other and perpendicular to the ground. The motor 17 controls the moving push plate 7 to move. The moving push plate 7 is assembled with the screw guiding rail 6 and moves up and down along the screw guiding rail 6. The support rod 9 and the push rod 8 are fixedly connected on the moving push plate 7. The mold core 13 is fixedly mounted on the support rods 9. The ultrasonic limit baffle 11 and the push rods 8 is moveably engaged with each other. The push rod 8 acts as a support for the ultrasonic limit baffle 11 is capable of lifting up the ultrasonic limit baffle 11. When the push rod 8 is moving upwards, the ultrasonic limit baffle 11 is lifted upwardly to move at an upward direction. When the push rod 8 is moving upwards, the ultrasonic limit baffle 11 is supported by the push rod 8 to move at a downward direction until reaching the position control unit 12, then the ultrasonic limit baffle 11 and the push rods 8 are separated, the ultrasonic limit baffle 11 and the ultrasonic wave generator 4 are positioned on the position control unit 12. The position control unit 12 can be adjusted in height according to the actual distance requirements. The outer diameter of the outer mold 14 is the same as the inner diameter of the traveling magnetic field generator 3, and the inner diameter of the outer mold 14 is the same as the inner diameter of the water-cooled crystallizer 10. The outer mold 14 is positioned on top of the water-cooled crystallizer 10 and is fittingly and tightly placed face-to-face to each other. The water-cooled crystallizer 10 adopts a water-cooled hollow copper plate structure, and circulating water is introduced into the water-cooled crystallizer 10 for forced cooling.

[0062] Preferably, as shown in FIGS. 1 and 2 of the drawings, the mold core 13 has a cylindrical structure defining an outer surface. The outer mold 14 has a hollow cylindrical structure defining an outer side and an inner side and is co-axially aligned with the mold core 13. The traveling magnetic field generator 3 surrounds the outer side of the outer mold 14 from the bottommost of the outer side of the outer mold 14 to extend upwardly and has a height shorter than a height of the outer mold 14. The bottom plate 16 is a circular plate coaxially arranged below the mold core 13 and has a diameter slightly smaller than a diameter of the inner side of the outer mold 14 to fit inside the outer mold 14 capable of sliding along the outer mold 14 in the vertical direction. The outer mold 14 and the traveling magnetic field generator 3 are fittingly positioned on top of the water-cooled crystallizer 10 such that a top of the water-cooled crystallizer 10 is fully overlapped by the outer mold 14 and the traveling magnetic field generator 3. At an initial state of the casting process, the mold core 13 and the ultrasonic wave generator 4 are both at a higher level than the outer mold 14 and are guided to move downward in the vertical direction. At the stable state of the casting process, the ultrasonic wave generator 4 extends along a vertical direction along the traveling magnetic field generator 3 from the top to of the height of the traveling magnetic field generator 3 so as to ensure that the mushy zone of the alloy melt is simultaneously subjected to magnetic field treatment of the traveling magnetic field generator 3 and an ultrasonic treatment of the ultrasonic generator 4 while the mold core 13 reaches the same level as the outer mold 14.The semi-continuous casting equipment that is optimized by synergistic action of traveling magnetic field and ultrasonic wave for thin-walled alloy castings with equal outer diameter according to this embodiment of the present invention has the following advantageous effect:

[0063] The ultrasonic treatment in this embodiment can effectively promote the nucleation of gas and impurities in the cylindrical thin-walled alloy melt, effectively purify the alloy melt, avoid the subsequent secondary treatment process, save costs, and reduce resource consumption.

[0064] The traveling magnetic field in this embodiment can effectively feed the cylindrical thin-walled alloy solidification process, and promote the separation of impurities and gases in the melt, eliminate segregation, obtain the overall uniform structure of the cylindrical thin-walled alloy casting, and improve the mechanical properties.

[0065] Through this embodiment, the synergistic effect of traveling magnetic field and ultrasound wave is realized, which promotes the effective nucleation and separation of gas and impurities in the cylindrical thin-walled alloy melt, improves the alloy structure, promotes the formation of equiaxed grains, and improves the mechanical properties.

[0066] According to this embodiment, the traveling magnetic field and ultrasonic wave are applied together for providing synergistic action. FIG. 3 is a scanning electron microscope image of the Al-5Cu alloy casting structure prepared by this equipment, and FIG. 4 is a scanning electron microscope image of the casting structure prepared without applying traveling magnetic fields. It can be seen that this embodiment promotes the effective nucleation and separation of gases and impurities in the cylindrical thin-walled alloy melt, improves the alloy structure, and improves the mechanical properties. At the same time, it can improve the defects such as segregation, shrinkage porosity and shrinkage of the cylindrical thin-walled alloy, thereby promoting the overall uniformity of the castings, eliminating the cost and waste of secondary treatment after semi-continuous casting, and achieving the near-net shape process of real-time optimization of the melt in the semi-continuous casting process.

[0067] The present invention, while illustrated and described in terms of a preferred embodiment and several alternatives, is not limited to the particular description contained in this specification. Additional alternative or equivalent components could also be used to practice the present invention.