CN108526450B

CN108526450B - Ferroalloy spheroidizing casting equipment

Info

Publication number: CN108526450B
Application number: CN201810540406.7A
Authority: CN
Inventors: 吕庆东; 吕家环; 常永婉
Original assignee: Shanxi Zhongde Tianhe Management Technology Co Ltd
Current assignee: Shanxi Zhongde Tianhe Management Technology Co ltd
Priority date: 2018-05-30
Filing date: 2018-05-30
Publication date: 2019-12-24
Anticipated expiration: 2038-05-30
Also published as: CN108526450A

Abstract

The invention discloses ferroalloy spheroidizing casting equipment which comprises a ladle system, a casting chute system, a head vibration groove system, a tail vibration groove system, a casting buffer system, a spheroidizing casting system, a finished product storage bin and a steel frame system, wherein all the systems are sequentially and fixedly arranged on the steel frame system according to the flow direction of molten iron. Through being provided with head vibration tank system and afterbody vibration tank system, can realize that the molten iron gets into the organic adjustment of the preceding state of casting, simultaneously through setting up casting buffer system and balling casting system to the purpose of quantitative casting, balling casting has been realized.

Description

Ferroalloy spheroidizing casting equipment

Technical Field

The invention relates to ferroalloy casting equipment, in particular to ferroalloy spheroidizing casting equipment, and belongs to the technical field of ferroalloy casting equipment.

Background

With the continuous development of industrial modernization and intellectualization, the ferroalloy production technology is also continuously advanced and updated,

the technology of ferroalloy production is improved in all aspects from raw material treatment and product smelting, but as the final link of ferroalloy production, the casting of finished molten iron is always the focus of attention. Various finished product processing methods are different aiming at a plurality of ferroalloy products, but the conditions of complex product casting process, uneven granularity and difficult granularity adjustment generally exist, which is extremely unfavorable for the subsequent steelmaking process.

Disclosure of Invention

Aiming at the problems, the invention provides the ferroalloy spheroidizing casting equipment which is reasonable in structure, strong in pertinence and high in production efficiency.

The technical scheme adopted by the invention is as follows: a ferroalloy spheroidizing casting device comprises a ladle system, a casting chute system, a head vibration groove system, a tail vibration groove system, a casting buffer system, a spheroidizing casting system, a finished product storage bin and a steel frame system, wherein the ladle system consists of a ladle, ladle shafts, a sliding gate and a tap hole, the two ladle shafts are fixedly arranged on two sides of the ladle, the sliding gate is fixedly arranged at the bottom of the ladle, and the tap hole is fixedly arranged on the sliding gate.

The casting chute system comprises a casting chute and a chute lining plate, wherein the casting chute is arranged below the tapping hole, and the chute lining plate is fixedly arranged at the top of the casting chute.

The head vibration groove system comprises a head vibration groove, a head vibration groove water-cooled tube, vibration springs and a vibration motor, wherein the head vibration groove is arranged below the casting chute, the head vibration groove water-cooled tube is fixedly arranged at the bottom of the head vibration groove, the four vibration springs are respectively and fixedly arranged around the lower part of the head vibration groove, and the vibration motor is fixedly arranged in the middle of the lower part of the head vibration groove.

The tail vibration groove system consists of a tail vibration groove, a tail vibration groove water-cooled tube, a tail vibration groove fixing frame, a middle connecting rod, a crank, a speed reducer and a motor, wherein the tail vibration groove is arranged below the head vibration groove, the tail vibration groove water-cooled tube is fixedly arranged at the bottom of the tail vibration groove, and the tail vibration groove fixing frame is hinged on the tail vibration groove; one end of the middle connecting rod is hinged with the tail vibration groove, the other end of the middle connecting rod is hinged with a crank, the crank is fixedly connected with an output shaft of the speed reducer through a key, and the motor is fixedly installed on the input shaft of the speed reducer.

The casting buffer system consists of a buffer disc, a baffle bracket, a baffle, a splitter disc, splitter disc holes, splitter disc enclosing plates, a quantitative frame, a hydraulic push rod, a plug rod, quantitative holes, a buffer disc support and a splitter disc support, and is arranged below the tail vibration groove system; the buffer disc is fixedly arranged at the top of the buffer disc support, the baffle supports which are uniformly arranged are fixedly arranged at the top of the buffer disc, and the baffles are fixedly arranged on the baffle supports; the shunting plate is arranged at the lower part of the buffer plate, the shunting plate is fixedly arranged at the top of the shunting plate support, uniformly arranged shunting plate holes are formed in the upper part of the shunting plate, and shunting plate enclosing plates are fixedly arranged at the edge part of the shunting plate; the quantitative rack is uniformly arranged and fixedly installed on the dividing plate enclosing plate, the hydraulic push rod is fixedly installed at the top of the quantitative rack, the extending end of the hydraulic push rod is fixedly connected with the plug rod, and the plug rod is slidably installed on the quantitative rack.

The spheroidizing casting system consists of a finished product disc, a finished product hole, a spheroidizing casting disc, a spheroidizing cup, a curve disc fixing bracket, a jacking rod, a jacking cylinder and a jacking cylinder fixing seat, wherein the spheroidizing casting disc is arranged right below the casting buffer system, the finished product disc is obliquely arranged outside the spheroidizing casting disc, and the lowest part of the finished product disc is provided with the finished product hole; the curve disc is arranged at the upper part of the spheroidizing casting disc, the spheroidizing cups are respectively installed at the top of the curve disc in a sliding manner, one end of a curve disc fixing support is hinged with the curve disc, and the other end of the curve disc fixing support is fixedly installed on the spheroidizing casting disc; jacking rod one end and curve dish articulated, jacking rod other end slidable mounting is on the jacking jar, the jacking jar rotates to be installed on the jacking jar fixing base, jacking jar fixing base fixed mounting is on balling casting dish.

The steel frame system consists of a ladle support, a casting chute support, a head vibration groove water collector, a tail vibration groove water collector, a head vibration groove water collecting pipe, a tail vibration groove water collecting pipe, a self-cooling water tank, a two-layer platform support, a shunting buffer support, a spheroidizing casting support, a finished product tray support, a finished product storage bin support, a one-layer platform and a one-layer platform support, wherein the ladle, the casting chute and a vibration spring are respectively and fixedly arranged on the ladle support, the casting chute support and the head vibration groove support, a speed reducer, a tail vibration groove fixing frame, the ladle support, the casting chute support, the head vibration groove support and the self-cooling water tank are all fixedly arranged on the two-layer platform, and the two-layer platform is fixedly arranged on the two-layer platform; the head vibration groove water collector and the tail vibration groove water collector are respectively and fixedly arranged on the head vibration groove water-cooled tube and the tail vibration groove water-cooled tube, one end of the head vibration groove water collector tube and one end of the tail vibration groove water collector tube are fixedly arranged at the bottoms of the head vibration groove water collector and the tail vibration groove water collector, and the other ends of the head vibration groove water collector tube and the tail vibration groove water collector tube are fixedly arranged on the self-cooling water tank; buffer disc pillar and splitter disc pillar all rotate and install on reposition of redundant personnel buffering support, balling casting dish and finished product dish are fixed mounting respectively on balling casting support and finished product dish support, the storehouse is stored to the finished product and is arranged in finished product dish lower part, on the storehouse support is stored to finished product storehouse fixed mounting finished product. The two-layer platform support, the shunting buffer support, the spheroidizing casting support and the finished product disc support are all fixedly installed at the top of the first layer platform, and the first layer platform support is fixedly installed at the bottom of the first layer platform.

Furthermore, in order to better ensure the conveying of finished products, the dividing disc enclosing plate is provided with uniformly distributed quantitative holes.

Furthermore, in order to better ensure the spheroidizing casting of the ferroalloy, a curve track is processed on the curve disc.

Furthermore, in order to better realize the movement of the head vibration groove and the tail vibration groove, the head parts of the head vibration groove water-cooling pipe and the tail vibration groove water-cooling pipe are provided with soft rubber pipes.

Further, in order to better realize spheroidizing casting, the spheroidizing cup is internally provided with an annular channel and a coolant.

Due to the adoption of the technical scheme, the invention has the following advantages: (1) the purpose of organic adjustment of the molten iron before casting is achieved by arranging the head vibration groove system and the tail vibration groove system; (2) the purpose of quantitative casting is achieved by arranging the buffer disc and the splitter disc; (3) the spheroidizing cup and the curve disc are arranged, so that the aim of molten iron spheroidizing casting is fulfilled.

Drawings

Fig. 1 is a schematic perspective view of the overall assembly of the present invention.

Fig. 2 is a schematic view of another angle of the integral assembly of the present invention.

Fig. 3 is a schematic perspective view of a molten iron package assembly according to the present invention.

Fig. 4 is a perspective view of the casting spout assembly of the present invention.

Fig. 5 is a perspective view illustrating an assembly of the head vibration groove according to the present invention.

Fig. 6 is a schematic perspective view of the assembled structure of the tail vibration slot of the present invention.

Fig. 7 is a perspective view illustrating an assembly of the casting buffer tray according to the present invention.

Fig. 8 is a perspective view of another angle of the cast bumper plate assembly of the present invention.

FIG. 9 is a schematic perspective view of a spheroidizing casting assembly according to the present invention.

FIG. 10 is a schematic view of a spheroidized cast subassembly according to the present invention.

Fig. 11 is a perspective view of the bracket assembly of the present invention.

Reference numerals: 1-ladle system; 2-casting a chute system; 3-a head vibration tank system; 4-a tail vibrating trough system; 5-casting a buffer system; 6-spheroidizing a casting system; 7-finished product storage; 8-a steel frame system; 101-a ladle; 102-wrapping a shaft; 103-a sliding gate valve; 104-iron outlet; 201-casting chute; 202-chute liner plate; 301-head vibration groove; 302-head vibration groove water-cooling pipe; 303-vibrating spring; 304-a vibration motor; 401-tail vibration groove; 402-tail vibration groove water-cooling tube; 403-tail vibration groove fixing frame; 404-intermediate link; 405-a crank; 406-a reducer; 407-motor; 501-a buffer disc; 502-a baffle bracket; 503-a baffle; 504-diverter trays; 505-diverter tray holes; 506-diverter tray coaming; 507-a quantitative rack; 508-hydraulic push rod; 509-stopper rod; 510-a quantification aperture; 511-a buffer tray support; 512-diverter tray posts; 601-finished disc; 602-finished hole; 603-spheroidizing the casting disc; 604-a spheroidisation cup; 605-a curve disc; 606-a curvilinear disk fixed support; 607-jacking rod; 608-jacking cylinder; 609-jacking cylinder fixing seat; 610-curved track; 801-ladle holder; 802-casting a chute support; 803-head vibration slot support; 804-head shaking groove water collector; 805-tail vibratory trough water collector; 806-head vibration trough water collecting pipe; 807-tail vibration trough water collecting pipe; 808-self-cooling water tank; 809-two-tier platform; 810-two-tier platform support; 811-shunting buffer support; 812-spheroidizing the casting support; 813-finished disc support; 814-finished product storage bin support; 815-a layer of platform; 816-one layer of platform support.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

Referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 and 11, the casting apparatus for spheroidizing of iron alloy comprises a ladle system 1, a casting chute system 2, a head vibration chute system 3, a tail vibration chute system 4, a casting buffer system 5, a spheroidizing casting system 6, a finished product storage bin 7 and a steel frame system 8, wherein the ladle system comprises a ladle 101, ladle shafts 102, a sliding gate 103 and a tap hole 104, the two ladle shafts 102 are fixedly arranged at two sides of the ladle 101, the sliding gate 103 is fixedly arranged at the bottom of the ladle 101, and the tap hole 104 is fixedly arranged on the sliding gate 103.

The casting chute system 2 is composed of a casting chute 201 and a chute lining plate 202, wherein the casting chute 201 is arranged below the taphole 104, and the chute lining plate 202 is fixedly installed at the top of the casting chute 201.

Head vibration groove system 3 comprises head vibration groove 301, head vibration groove water-cooled tube 302, vibration spring 303 and vibrating motor 304, and head vibration groove 301 arranges in casting chute 201 below, and head vibration groove 301 bottom fixed mounting has head vibration groove water-cooled tube 302, and four vibration springs 303 are fixed mounting respectively around head vibration groove 301 lower part, and vibrating motor 304 fixed mounting is in the middle of head vibration groove 301 lower part.

The tail vibration groove system 4 is composed of a tail vibration groove 401, a tail vibration groove water-cooling pipe 402, a tail vibration groove fixing frame 403, a middle connecting rod 404, a crank 405, a speed reducer 406 and a motor 407, wherein the tail vibration groove 401 is arranged below the head vibration groove 301, the tail vibration groove water-cooling pipe 402 is fixedly installed at the bottom of the tail vibration groove 401, and the tail vibration groove fixing frame 403 is hinged to the tail vibration groove 401. One end of the middle connecting rod 404 is hinged with the tail vibration groove 401, the other end of the middle connecting rod 404 is hinged with the crank 405, the crank 405 is fixedly connected with an output shaft of the speed reducer 406 through a key, and the motor 407 is fixedly arranged on an input shaft of the speed reducer 406.

The casting buffer system 5 is composed of a buffer disc 501, a baffle bracket 502, a baffle 503, a diversion disc 504, a diversion disc hole 505, a diversion disc coaming 506, a quantitative frame 507, a hydraulic push rod 508, a plug rod 509, a quantitative hole 510, a buffer disc support 511 and a diversion disc support 512, and the casting buffer system 5 is arranged below the tail vibration trough system 4. The buffer disc 501 is fixedly arranged at the top of the buffer disc support 511, the baffle supports 502 which are uniformly arranged are fixedly arranged at the top of the buffer disc 501, and the baffle 503 is fixedly arranged on the baffle supports 502. The diversion tray 504 is arranged at the lower part of the buffer tray 501, the diversion tray 504 is fixedly arranged at the top of the diversion tray support 512, the diversion tray holes 505 which are uniformly arranged are arranged at the upper part of the diversion tray 504, and the diversion tray enclosure 506 is fixedly arranged at the edge part of the diversion tray 504. The quantitative shelf 507 is uniformly arranged and fixedly arranged on the dividing plate enclosing plate 506, the hydraulic push rod 508 is fixedly arranged at the top of the quantitative shelf 507, the extending end of the hydraulic push rod 508 is fixedly connected with the plug rod 509, and the plug rod 509 is slidably arranged on the quantitative shelf 507.

The spheroidizing casting system 6 consists of a finished product disc 601, a finished product hole 602, a spheroidizing casting disc 603, a spheroidizing cup 604, a curved disc 605, a curved disc fixing bracket 606, a jacking rod 607, a jacking cylinder 608 and a jacking cylinder fixing seat 609, wherein the spheroidizing casting disc 603 is arranged right below the casting buffer system 5, the finished product disc 601 is obliquely arranged outside the spheroidizing casting disc 603, and the finished product hole 602 is processed at the lowest part of the finished product disc 601. The curve disc 605 is arranged on the upper part of the spheroidizing casting disc 603, the spheroidizing cups 604 are respectively and slidably mounted on the top of the curve disc 605, one end of the curve disc fixing bracket 606 is hinged with the curve disc 605, and the other end of the curve disc fixing bracket 606 is fixedly mounted on the spheroidizing casting disc 603. One end of the jacking rod 607 is hinged with the curved plate 605, the other end of the jacking rod 607 is slidably mounted on the jacking cylinder 608, the jacking cylinder 608 is rotatably mounted on a jacking cylinder fixing seat 609, and the jacking cylinder fixing seat 609 is fixedly mounted on the spheroidizing casting plate 603.

The steel frame system 8 is composed of a ladle support 801, a casting chute support 802, a head vibration chute support 803, a head vibration chute water collector 804, a tail vibration chute water collector 805, a head vibration chute water collector 806, a tail vibration chute water collector 807, a self-cooling water tank 808, a two-layer platform 809, a two-layer platform support 810, a diversion buffer support 811, a spheroidizing casting support 812, a finished product tray support 813, a finished product storage bin support 814, a one-layer platform 815 and a one-layer platform support 816, wherein the ladle 101, the casting chute 201 and the vibration spring 303 are respectively and fixedly installed on the ladle support 801, the casting chute support 802 and the head vibration chute support 803, a speed reducer 406, a tail vibration chute fixing frame 403, the ladle support 801, the casting chute support 802, the head vibration chute support 803 and the self-cooling water tank 808 are all and fixedly installed on the two-layer platform support 810. The head vibration groove water collector 804 and the tail vibration groove water collector 805 are respectively and fixedly arranged on the head vibration groove water-cooled tube 302 and the tail vibration groove water-cooled tube 402, one end of the head vibration groove water collector 806 and one end of the tail vibration groove water collector 807 are fixedly arranged at the bottoms of the head vibration groove water collector 804 and the tail vibration groove water collector 805, and the other end of the head vibration groove water collector 806 and the tail vibration groove water collector 807 are fixedly arranged on the self-cooling water tank 808. The buffer disc support 511 and the diversion disc support 512 are rotatably mounted on the diversion buffer support 811, the spheroidizing casting disc 603 and the finished product disc 601 are fixedly mounted on the spheroidizing casting support 812 and the finished product disc support 813 respectively, the finished product storage bin 7 is arranged at the lower part of the finished product disc 601, and the finished product storage bin 7 is fixedly mounted on the finished product storage bin support 814. The two-layer platform bracket 810, the flow distribution buffer bracket 811, the spheroidizing casting bracket 812 and the finished disc bracket 813 are all fixedly arranged at the top of the one-layer platform 815, and the one-layer platform bracket 816 is fixedly arranged at the bottom of the one-layer platform 815.

To better ensure product delivery, the diverter tray shroud 506 is machined with uniformly arranged dosing holes 510.

In order to better ensure the spheroidizing casting of the ferroalloy, the curve disk 605 is provided with a curve track 610.

In order to better realize the movement of the head vibration groove 301 and the tail vibration groove 401, the head parts of the head vibration groove water-cooling pipe 302 and the tail vibration groove water-cooling pipe 402 are provided with soft rubber pipes.

To better achieve the spheroidizing casting, the spheroidizing cup 604 is provided with an annular channel therein and with a coolant.

The working principle of the invention is as follows: molten iron flows out of the casting chute 201 through the sliding water gap 103 at the lower part of the ladle 101, and sequentially falls onto the buffer disc 501 of the buffer casting system 5 through the head vibration groove system 3 and the tail vibration groove system 4, the buffer disc 501 rotates to discharge the molten iron onto the diverter disc 504, the molten iron enters the edge of the diverter disc 504 through the diverter disc hole 505, after the molten iron is gradually paved on the edge of the diverter disc 504, the diverter disc 504 is controlled to rotate for a circle, the hydraulic push rod 508 is controlled to act, the plug rod 509 is driven to slide in the quantitative frame 507, the semi-cooled molten iron falls into the corresponding spheroidizing cup 604, the spheroidizing cup 604 is controlled to move along the curved track 610 on the curved disc 605, and after the molten iron is cooled into spheres, the jacking rod 607 is controlled to jack up, so that the curved disc 605 is tilted, and the finished iron spheres fall into the finished product storage disc 601 and enter the finished product storage bin 7 through the.

Claims

1. A ferroalloy spheroidizing casting device comprises a foundry ladle system (1), a casting chute system (2), a head vibration groove system (3), a tail vibration groove system (4), a casting buffer system (5), a spheroidizing casting system (6), a finished product storage bin (7) and a steel frame system (8), wherein the foundry ladle system (1) consists of a foundry ladle (101), ladle shafts (102), a sliding water gap (103) and a taphole (104), the two ladle shafts (102) are fixedly arranged on two sides of the foundry ladle (101), the sliding water gap (103) is fixedly arranged at the bottom of the foundry ladle (101), and the taphole (104) is fixedly arranged on the sliding water gap (103);

the casting chute system (2) is composed of a casting chute (201) and a chute lining plate (202), the casting chute (201) is arranged below the tapping hole (104), and the chute lining plate (202) is fixedly arranged at the top of the casting chute (201);

the head vibration groove system (3) is composed of a head vibration groove (301), a head vibration groove water-cooling pipe (302), vibration springs (303) and a vibration motor (304), the head vibration groove (301) is arranged below the casting chute (201), the head vibration groove water-cooling pipe (302) is fixedly installed at the bottom of the head vibration groove (301), the four vibration springs (303) are respectively and fixedly installed on the periphery of the lower part of the head vibration groove (301), and the vibration motor (304) is fixedly installed in the middle of the lower part of the head vibration groove (301);

the tail vibration groove system (4) consists of a tail vibration groove (401), a tail vibration groove water-cooling pipe (402), a tail vibration groove fixing frame (403), a middle connecting rod (404), a crank (405), a speed reducer (406) and a motor (407), wherein the tail vibration groove (401) is arranged below the head vibration groove (301), the tail vibration groove water-cooling pipe (402) is fixedly installed at the bottom of the tail vibration groove (401), and the tail vibration groove fixing frame (403) is hinged to the tail vibration groove (401); one end of the middle connecting rod (404) is hinged with the tail vibration groove (401), the other end of the middle connecting rod (404) is hinged with a crank (405), the crank (405) is fixedly connected with an output shaft of the speed reducer (406) through a key, and the motor (407) is fixedly arranged on an input shaft of the speed reducer (406);

the casting buffer system (5) consists of a buffer disc (501), a baffle bracket (502), a baffle (503), a diverter disc (504), a diverter disc hole (505), a diverter disc coaming plate (506), a quantitative frame (507), a hydraulic push rod (508), a stopper rod (509), a quantitative hole (510), a buffer disc support column (511) and a diverter disc support column (512), and the casting buffer system (5) is arranged below the tail vibration groove system (4); the buffer disc (501) is fixedly arranged at the top of the buffer disc support column (511), baffle supports (502) which are uniformly arranged are fixedly arranged at the top of the buffer disc (501), and the baffles (503) are fixedly arranged on the baffle supports (502); the distributing tray (504) is arranged at the lower part of the buffer tray (501), the distributing tray (504) is fixedly arranged at the top of the distributing tray strut (512), distributing tray holes (505) which are uniformly arranged are formed in the upper part of the distributing tray (504), and a distributing tray enclosing plate (506) is fixedly arranged at the edge part of the distributing tray (504); the quantitative frame (507) is uniformly arranged and fixedly installed on the dividing plate enclosing plate (506), the hydraulic push rod (508) is fixedly installed at the top of the quantitative frame (507), the extending end of the hydraulic push rod (508) is fixedly connected with the plug rod (509), and the plug rod (509) is installed on the quantitative frame (507) in a sliding mode;

the spheroidizing casting system (6) consists of a finished product disc (601), a finished product hole (602), a spheroidizing casting disc (603), a spheroidizing cup (604), a curved disc (605), a curved disc fixing support (606), a jacking rod (607), a jacking cylinder (608) and a jacking cylinder fixing seat (609), wherein the spheroidizing casting disc (603) is arranged under the casting buffer system (5), the finished product disc (601) is obliquely arranged outside the spheroidizing casting disc (603), and the finished product hole (602) is processed at the lowest part of the finished product disc (601); the curve disc (605) is arranged on the upper part of the spheroidizing casting disc (603), the spheroidizing cups (604) are respectively and slidably mounted on the top of the curve disc (605), one end of a curve disc fixing support (606) is hinged with the curve disc (605), and the other end of the curve disc fixing support (606) is fixedly mounted on the spheroidizing casting disc (603); one end of the jacking rod (607) is hinged with the curve disc (605), the other end of the jacking rod (607) is slidably mounted on a jacking cylinder (608), the jacking cylinder (608) is rotatably mounted on a jacking cylinder fixing seat (609), and the jacking cylinder fixing seat (609) is fixedly mounted on the spheroidizing casting disc (603);

the steel frame system (8) is composed of a ladle support (801), a casting chute support (802), a head vibration groove support (803), a head vibration groove water collector (804), a tail vibration groove water collector (805), a head vibration groove water collecting pipe (806), a tail vibration groove water collecting pipe (807), a self-cooling water tank (808), a two-layer platform (809), a two-layer platform support (810), a shunting buffering support (811), a spheroidizing casting support (812), a finished product tray support (813), a finished product storage bin support (814), a one-layer platform (815) and a one-layer platform support (816), wherein the ladle (101), the casting chute (201) and the vibration spring (303) are respectively and fixedly installed on the ladle support (801), the casting chute support (802) and the head vibration groove support (803), a speed reducer (406), a tail vibration groove fixing frame (403), the ladle support (801), the casting chute support (802), The head vibration groove support (803) and the self-cooling water tank (808) are both fixedly arranged on a two-layer platform (809), and the two-layer platform (809) is fixedly arranged on a two-layer platform support (810); the head vibration groove water collector (804) and the tail vibration groove water collector (805) are respectively and fixedly arranged on the head vibration groove water-cooled tube (302) and the tail vibration groove water-cooled tube (402), one ends of the head vibration groove water collector tube (806) and the tail vibration groove water collector tube (807) are respectively and fixedly arranged at the bottoms of the head vibration groove water collector (804) and the tail vibration groove water collector (805), and the other ends of the head vibration groove water collector tube (806) and the tail vibration groove water collector tube (807) are respectively and fixedly arranged on the self-cooling water tank (808); the buffering disc support column (511) and the diversion disc support column (512) are rotatably mounted on a diversion buffering support seat (811), the spheroidizing casting disc (603) and the finished product disc (601) are respectively and fixedly mounted on a spheroidizing casting support seat (812) and a finished product disc support seat (813), the finished product storage bin (7) is arranged at the lower part of the finished product disc (601), and the finished product storage bin (7) is fixedly mounted on a finished product storage bin support (814); the two-layer platform support (810), the flow distribution buffer support (811), the spheroidizing casting support (812) and the finished product tray support (813) are fixedly arranged at the top of the first layer platform (815), and the first layer platform support (816) is fixedly arranged at the bottom of the first layer platform (815).

2. The ferroalloy spheroidizing casting apparatus according to claim 1, wherein: quantitative holes (510) which are uniformly distributed are machined in the dividing disc enclosing plate (506).

3. The ferroalloy spheroidizing casting apparatus according to claim 1, wherein: the curve disc (605) is provided with a curve track (610).

4. The ferroalloy spheroidizing casting apparatus according to claim 1, wherein: the head parts of the head vibration groove water-cooling pipe (302) and the tail vibration groove water-cooling pipe (402) are provided with soft rubber pipes.

5. The ferroalloy spheroidizing casting apparatus according to claim 1, wherein: an annular channel is arranged in the spheroidizing cup (604), and a coolant is arranged in the spheroidizing cup.