CN115194134B - Precision casting processing equipment for wear-resistant steel balls - Google Patents

Abstract

The invention relates to the technical field of wearable steel ball processing accessories, in particular to a wearable steel ball precision casting processing device which is simple in structure, can automatically unload a cast wearable steel ball, and reduces the use cost; comprises a metal solution generating mechanism, a rotary casting mechanism, a cooling mechanism and a steel ball collecting mechanism; the rotary casting mechanism comprises a support group with a fixed position, a disc is fixed at one end of the support group, a first annular groove is formed in the disc, and the first annular groove comprises a first U-shaped section with a gradually changed radius and a circular arc section with a constant radius; the rotary casting mechanism further comprises a door-shaped plate with a fixed position, a first rotating shaft is rotatably mounted on the door-shaped plate, a rotating table is fixed on the first rotating shaft, four groups of actuating mechanisms are arranged on the rotating table in a circumferential array at equal intervals, each actuating mechanism comprises an upper die and a lower die for casting wear-resistant steel balls, and a metal solution generating mechanism is used for injecting metal solution into the upper die and the lower die.

Description

Precision casting processing equipment for wear-resistant steel balls

Technical Field

The invention relates to the technical field of wearable steel ball processing accessories, in particular to a wearable steel ball precision casting processing device.

Background

The wear-resistant steel ball is also called as a wear-resistant medium for a grinder, is a consumable product, is mainly used for grinding materials to enable the materials to be ground more finely so as to reach the use standard, and is mainly used in the fields of mines, power plants, cement plants, steel plants, silica sand plants, coal chemical industry and the like.

The invention patent with application number of 201610380643.2 provides rotary type wear-resistant steel ball casting equipment, which comprises a first wear-resistant steel ball casting mould component, a second wear-resistant steel ball casting mould component, a third wear-resistant steel ball casting mould component, a fourth mounting rotary table, a support column, a motor reducer and a motor component, wherein the upper end of the motor component is connected with the motor reducer, the upper end of the motor reducer is provided with the support column, the upper end of the support column is assembled with the rotary table, the first wear-resistant steel ball casting mould component is arranged on the mounting rotary table, the second wear-resistant steel ball casting mould component is arranged on the mounting rotary table, the third wear-resistant steel ball casting mould component is arranged on the mounting rotary table, and the fourth wear-resistant steel ball casting mould component is arranged on the mounting rotary table.

The above-described device has the following disadvantages: the unloading process of the wear-resistant steel balls needs to be manually controlled, a large amount of power equipment is needed, and the use cost is high.

Disclosure of Invention

In order to solve the technical problem, the invention provides precision casting equipment for a wear-resistant steel ball, which is simple in structure, can automatically unload the cast wear-resistant steel ball, and reduces the use cost.

The invention discloses precision casting processing equipment for a wear-resistant steel ball, which comprises a metal solution generating mechanism, a rotary casting mechanism, a cooling mechanism and a steel ball collecting mechanism, wherein the metal solution generating mechanism is used for generating a metal solution; the rotary casting mechanism comprises a support group with a fixed position, a disc is fixed at one end of the support group, a first annular groove is formed in the disc, and the first annular groove comprises a first U-shaped section with gradually changed radius and an arc section with unchanged radius;

the rotary casting mechanism further comprises a door-shaped plate with a fixed position, a first rotating shaft is rotatably mounted on the door-shaped plate, a rotating table is fixed on the first rotating shaft, four groups of actuating mechanisms are circumferentially arranged on the rotating table at equal intervals and comprise an upper die and a lower die for casting wear-resistant steel balls, and a metal solution generating mechanism is used for injecting metal solution into the upper die and the lower die;

the action mechanism is driven by the first U-shaped section to enable the upper die and the lower die to be matched to complete the unloading process.

Furthermore, the action mechanism also comprises a long hole arranged on the rotary table along the radial direction, a first sliding block slides in the long hole, a driving shaft is fixed on the first sliding block, the driving shaft extends into the first annular groove, a vertical rod is fixed on the first sliding block, and a pushing shaft is fixed on the vertical rod;

the action mechanism also comprises a vertical track fixed on the turntable, a door-shaped sliding block II is slidably mounted on the track, an inclined hole is formed in the sliding block II, and two ends of the pushing shaft respectively penetrate through the two inclined holes;

a lifting shaft is fixed on the second sliding block;

the actuating mechanism further comprises a support rod fixed on the rotary table, a second rotating shaft is rotatably mounted on the support rod, the lower die is fixed at one end of the second rotating shaft, and a first bevel gear is fixed at the other end of the second rotating shaft;

the actuating mechanism also comprises a guide rod fixed on the rotary table, an L-shaped rod is fixed on the upper die, and the guide rod is in sliding fit with the L-shaped rod;

the action mechanism further comprises a hollow shaft fixed on the rotary table and a rotating shaft III rotatably installed on the rotary table, the rotating shaft III is coaxial with the hollow shaft, and a bevel gear II meshed with the bevel gear I is fixed on the rotating shaft III;

a spline shaft is fixed on the rotating shaft III, and a spline sleeve slides on the spline shaft;

the inner wall of the hollow shaft is provided with a limiting groove and a second annular groove, the limiting groove is axially arranged, the second annular groove is circumferentially arranged, and the limiting groove is communicated with the second annular groove;

a lifting plate is fixed on the outer ring of the spline housing, and a limiting block in sliding fit with the limiting groove is fixed on the lifting plate;

the actuating mechanism further comprises a first pipe fixed on one side of the lifting plate, a spiral hole is formed in the surface of the first pipe, a transition hole is formed in the surface of the hollow shaft, and the lifting shaft penetrates through the transition hole and the spiral hole;

the actuating mechanism further comprises a second pipe fixed on the other side of the lifting plate, and the second pipe is rotatably connected with the L-shaped rod.

Furthermore, the cooling mechanism comprises a water tank with a fixed position, a housing is fixed on the water tank, sprayers are uniformly arranged in the water tank and the housing, every two sprayers form a group, the spraying directions of the sprayers face the upper die and the lower die, and a power pump is arranged in the water tank to provide cooling liquid for the sprayers.

Furthermore, the steel ball collecting mechanism comprises a collecting tank with a fixed position, and a filter screen is transversely fixed in the collecting tank;

the steel ball collecting mechanism further comprises a slag groove located at the bottom of the collecting groove, and the slag groove is provided with a first universal wheel and a handle.

Furthermore, the first annular groove further comprises a second U-shaped section with gradually changed radius, and the distance between the second U-shaped section and the circle center of the rotary table is larger than the distance between the first U-shaped section and the circle center of the rotary table.

Furthermore, the motor with a fixed position is further included, a speed reducer is installed at the output end of the motor, and an output shaft of the speed reducer is connected with the first rotating shaft.

Furthermore, a plurality of universal wheels II are installed at the bottom of the rotary table.

Furthermore, the cooling mechanism also comprises in-place sensors which correspond to the power pumps one by one, and the in-place sensors are fixed in the housing.

Compared with the prior art, the invention has the beneficial effects that: in the rotating process of the upper die and the lower die, extra power is not needed, the processed wear-resistant steel balls can be automatically taken down, the use cost is reduced, and the automation degree is higher.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

FIG. 3 is a block diagram from the left side of FIG. 1;

FIG. 4 is a bottom view of FIG. 1;

FIG. 5 is a top view of the present invention;

FIG. 6 is an isometric cross-sectional view of section A-A of FIG. 5;

FIG. 7 is a partial enlarged view of portion A of FIG. 6;

FIG. 8 is an isometric cross-sectional view of section B-B of FIG. 5;

FIG. 9 is a partial enlarged view of portion A of FIG. 8;

FIG. 10 is a top view of the first shaft, disk, drive shaft, etc.;

FIG. 11 is a view of the hollow shaft and tube one with portions of the hollow shaft cut away;

in the drawings, the reference numbers: 1. a bracket set; 2. a disc; 3. a first U-shaped section; 4. a circular arc section; 5. a door profile; 6. a first rotating shaft; 7. a turntable; 8. an upper die; 9. a lower die; 10. a first sliding block; 11. a drive shaft; 12. a vertical rod; 13. pushing the shaft; 14. a track; 15. a second sliding block; 16. an inclined hole; 17. a lifting shaft; 18. a support bar; 19. a second rotating shaft; 20. a first bevel gear; 21. a guide bar; 22. an L-shaped rod; 23. a hollow shaft; 24. a rotating shaft III; 25. a second bevel gear; 26. a spline shaft; 27. a spline housing; 28. a limiting groove; 29. a second annular groove; 30. a lifting plate; 31. a limiting block; 32. a first pipe; 33. a helical bore; 34. a second pipe; 35. a water tank; 36. a sprayer; 37. a power pump; 38. collecting tank; 39. filtering with a screen; 40. a slag groove; 41. a U-shaped section II; 42. a motor; 43. an in-place sensor; 44. a metal solution generating mechanism.

Detailed Description

The following detailed description of the present invention is provided in connection with the accompanying drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as being either 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 meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1 to 11, the precise casting and processing equipment for the wearable steel ball comprises a metal solution generating mechanism 44, a rotary casting mechanism, a cooling mechanism and a steel ball collecting mechanism; the rotary casting mechanism comprises a support group 1 with a fixed position, a disc 2 is fixed at one end of the support group 1, a first annular groove is formed in the disc 2, and the first annular groove comprises a U-shaped section 3 with a gradually changed radius and an arc section 4 with a constant radius;

the rotary casting mechanism further comprises a door-shaped plate 5 with a fixed position, a first rotating shaft 6 is rotatably mounted on the door-shaped plate 5, a rotary table 7 is fixed on the first rotating shaft 6, four groups of actuating mechanisms are arranged on the rotary table 7 in a circumferential array at equal intervals, each actuating mechanism comprises an upper die 8 and a lower die 9 for casting wear-resistant steel balls, and a metal solution generating mechanism 44 is used for injecting metal solution into the upper die 8 and the lower die 9;

the actuating mechanism is driven by the U-shaped section I3 to enable the upper die 8 and the lower die 9 to be matched to complete the unloading process;

in this embodiment, during normal use, the first rotating shaft 6, the turntable 7 and the actuating mechanisms on the turntable 7 rotate simultaneously, when the actuating mechanisms pass through the arc section 4, the actuating mechanisms do not act, the upper die 8 and the lower die 9 are kept in a closed state, when the arc section 4 moves, the following processes are completed, molten metal is injected into the upper die 8 and the lower die 9 through the molten metal generating mechanism 44, then the upper die 8 and the lower die 9 rotate by taking the first rotating shaft 6 as an axis, the upper die 8, the lower die 9 and the molten metal inside the upper die 8 and the lower die 9 are cooled through the cooling mechanism to form wear-resistant steel balls, then the wear-resistant steel balls pass through the radius decreasing section of the first U-shaped section 3, the upper die 8 moves upwards firstly, then the lower die 9 turns over, the wear-resistant steel balls are collected by the steel ball collecting mechanism, then pass through the radius increasing section of the first U-shaped section 3, each component returns to the initial position, and then the processes of liquid injection, cooling and discharging are performed.

Furthermore, the action mechanism also comprises a long hole arranged on the rotary table 7 along the radial direction, a first sliding block 10 slides in the long hole, a driving shaft 11 is fixed on the first sliding block 10, the driving shaft 11 extends into the first annular groove, a vertical rod 12 is fixed on the first sliding block 10, and a pushing shaft 13 is fixed on the vertical rod 12;

the action mechanism further comprises a vertical track 14 fixed on the rotary table 7, a door-shaped sliding block II 15 is slidably mounted on the track 14, an inclined hole 16 is formed in the sliding block II 15, and two ends of the pushing shaft 13 respectively penetrate through the two inclined holes 16;

a lifting shaft 17 is fixed on the second sliding block 15;

the action mechanism further comprises a supporting rod 18 fixed on the rotary table 7, a second rotating shaft 19 is rotatably mounted on the supporting rod 18, the lower die 9 is fixed at one end of the second rotating shaft 19, and a first bevel gear 20 is fixed at the other end of the second rotating shaft 19;

the actuating mechanism further comprises a guide rod 21 fixed on the rotary table 7, an L-shaped rod 22 is fixed on the upper die 8, and the guide rod 21 is in sliding fit with the L-shaped rod 22;

the action mechanism further comprises a hollow shaft 23 fixed on the rotary table 7 and a rotating shaft III 24 rotatably installed on the rotary table 7, the rotating shaft III 24 is coaxial with the hollow shaft 23, and a bevel gear II 25 meshed with the bevel gear I20 is fixed on the rotating shaft III 24;

a spline shaft 26 is fixed on the third rotating shaft 24, and a spline sleeve 27 slides on the spline shaft 26;

the inner wall of the hollow shaft 23 is provided with a limiting groove 28 and a second annular groove 29, the limiting groove 28 is arranged along the axial direction, the second annular groove 29 is arranged along the circumferential direction, and the limiting groove 28 is communicated with the second annular groove 29;

a lifting plate 30 is fixed on the outer ring of the spline housing 27, and a limiting block 31 in sliding fit with the limiting groove 28 is fixed on the lifting plate 30;

the actuating mechanism further comprises a first pipe 32 fixed on one side of the lifting plate 30, a spiral hole 33 is formed in the surface of the first pipe 32, a transition hole is formed in the surface of the hollow shaft 23, and the lifting shaft 17 penetrates through the transition hole and the spiral hole 33;

the actuating mechanism further comprises a second pipe 34 fixed on the other side of the lifting plate 30, and the second pipe 34 is rotatably connected with the L-shaped rod 22;

in the embodiment, when the rotary table 7 rotates, the driving shaft 11, the first slider 10 and other components are driven to rotate, the position of the disc 2 is fixed, and when the driving shaft 11 passes through the decreasing radius section of the first U-shaped section 3, the first slider 10, the vertical rod 12 and the pushing shaft 13 on the vertical rod are all close to the circle center of the rotary table 7, because the pushing shaft 13 passes through the inclined hole 16 on the second slider 15, and the second slider 15 is in sliding fit with the track 14, the moving pushing shaft 13 enables the second slider 15 and the lifting shaft 17 to simultaneously move upwards;

in the upward movement process of the lifting shaft 17, the hollow shaft 23 cannot influence the movement of the lifting shaft 17 due to the arranged transition holes;

when the lifting shaft 17 moves upwards, the lifting shaft 17 penetrates through the spiral hole 33 in the first pipe 32, the lifting plate 30, the spline housing 27, the second pipe 34 and the limiting block 31 are fixedly connected, but at the moment, the limiting block 31 extends into the limiting groove 28, so that the first pipe 32, the lifting plate 30, the spline housing 27, the second pipe 34 and the limiting block 31 move upwards along the limiting groove 28 by the lifting shaft 17 moving upwards, the L-shaped rod 22 and the second pipe 34 are connected by a bearing, so that the L-shaped rod 22 and the upper mold 8 both move upwards, the upper mold 8 moves upwards due to the arranged guide rod 21, when the limiting block 31 moves to the second annular groove 29, the limiting block 31 cannot move upwards continuously, the upper mold 8 also reaches the highest position, the lifting shaft 17 penetrates through the spiral hole 33 in the first pipe 32, the lifting plate 30, the spline housing 27, the second pipe 34 and the limiting block 31 all rotate, the limiting block 31 and the second annular groove 29 change in relative positions, the second pipe 34 and the lifting shaft 17, so that the lifting shaft 17 and the lifting shaft 17 continuously moves upwards, the lifting shaft 22 and the lower mold section of the bevel gear 22 do not rotate, the bevel gear 21, the rotating shaft 24, and the lower mold 22 rotates, the bevel gear collecting mechanism 20, the shaft 24, and the bevel gear 21, and the lower mold 21 rotate, and the bevel gear collecting mechanism, and the bevel gear 21, and the lower mold 24 rotate, and the shaft 24, and the bevel gear 21, and the shaft 24 rotate, and the lower mold 24, and the shaft 24 rotate, and the shaft 24, and the bevel gear 21, and the lower mold 24, and the bevel gear, and the lower mold 24 rotate;

then the driving shaft 11 passes through the radius increasing section of the second U-shaped section 41, and contrary to the above process, the lower mold 9 is rotated to be horizontal, and then the upper mold 8 is lowered to be attached to the lower mold 9.

Further, the cooling mechanism comprises a water tank 35 with a fixed position, a housing is fixed on the water tank 35, sprayers 36 are uniformly arranged in the water tank 35 and the housing, every two sprayers 36 form a group, the spraying direction faces to the upper die 8 and the lower die 9, and a power pump 37 is arranged in the water tank 35 to provide cooling liquid for the sprayers 36;

in this embodiment, after the molten metal is poured into the upper mold 8 and the lower mold 9, the upper mold 8 and the lower mold 9 are rotated to a position between the water tank 35 and the housing, the power pump 37 is turned on, and the shower 36 sprays the cooling liquid to the upper mold 8 and the lower mold 9 to cool them.

Further, the steel ball collecting mechanism comprises a fixed position collecting tank 38, and a filter screen 39 is transversely fixed in the collecting tank 38;

the steel ball collecting mechanism also comprises a slag groove 40 positioned at the bottom of the collecting groove 38, and the slag groove 40 is provided with a first universal wheel and a handle;

in this embodiment, the rotating lower die 9 dumps the wear-resistant steel balls and other waste materials inside the collecting tank 38, the filter screen 39 intercepts the wear-resistant steel balls, the waste materials fall into the slag groove 40, the handle is held periodically to pull out the slag groove 40, and the waste materials inside the slag groove 40 are cleaned.

Furthermore, the first annular groove also comprises a U-shaped section II 41 with gradually changed radius, and the distance between the U-shaped section II 41 and the circle center of the rotary table 7 is greater than the distance between the U-shaped section I3 and the circle center of the rotary table 7;

in this embodiment, the distance between the second U-shaped section 41 and the center of the turntable 7 is greater than the distance between the first U-shaped section 3 and the center of the turntable 7, that is, the displacement of the driving shaft 11 passing through the second U-shaped section 41 is smaller than the displacement of the driving shaft 11 passing through the first U-shaped section 3, so that the highest point of the lifting shaft 17 is reduced when passing through the first U-shaped section 3 relative to the driving shaft 11, when the driving shaft 11 reaches the end point of the decreasing radius section of the second U-shaped section 41, the lifting shaft 17 reaches the highest point, at this time, the lower mold 9 does not rotate, and when the position is reached, the upper mold 8 is opened relative to the lower mold 9, so that the upper mold 8 and the lower mold 9 can be conveniently maintained or otherwise operated, and the practicability is high.

Furthermore, the device also comprises a motor 42 with a fixed position, wherein the output end of the motor 42 is provided with a speed reducer, and the output shaft of the speed reducer is connected with the first rotating shaft 6;

in this embodiment, when the motor 42 is turned on, the first speed reducer drives the first rotating shaft 6 to rotate, and drives the first rotating shaft 6 and the turntable 7 to rotate.

Furthermore, a plurality of universal wheels II are arranged at the bottom of the rotary table 7;

in this embodiment, when the turntable 7 rotates, the second universal wheel rotates at the same time, and the second universal wheel makes the turntable 7 rotate more stably.

Further, the cooling mechanism further comprises in-place sensors 43 corresponding to the power pumps 37 one to one, and the in-place sensors 43 are fixed in the housing;

in the present embodiment, when a certain in-place sensor 43 detects the upper mold 8 and the lower mold 9, the power pump 37 is controlled to be turned on to spray the cooling liquid onto the upper mold 8 and the lower mold 9, and when the upper mold 8 and the lower mold 9 move out of the detection range of the in-place sensor 43, the corresponding power pump 37 is turned off, so that the usage amount of the cooling liquid is reduced.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (7)

1. A precision casting processing device for wear-resistant steel balls comprises a metal solution generating mechanism (44), a rotary casting mechanism, a cooling mechanism and a steel ball collecting mechanism; the device is characterized in that the rotary casting mechanism comprises a fixed support group (1), a disc (2) is fixed at one end of the support group (1), a first annular groove is formed in the disc (2), and the first annular groove comprises a first U-shaped section (3) with gradually changed radius and a circular arc section (4) with unchanged radius;

the rotary casting mechanism further comprises a door-shaped plate (5) with a fixed position, a first rotating shaft (6) is rotatably mounted on the door-shaped plate (5), a rotary table (7) is fixed on the first rotating shaft (6), four groups of actuating mechanisms are arranged on the rotary table (7) in a circumferential array at equal intervals, each actuating mechanism comprises an upper die (8) and a lower die (9) for casting wear-resistant steel balls, and a metal solution generating mechanism (44) is used for injecting metal solution into the upper die (8) and the lower die (9);

the actuating mechanism is driven by the U-shaped section I (3) to enable the upper die (8) and the lower die (9) to be matched to complete the unloading process;

the action mechanism further comprises a long hole formed in the rotary table (7) along the radial direction, a first sliding block (10) slides in the long hole, a driving shaft (11) is fixed on the first sliding block (10), the driving shaft (11) extends into the first annular groove, a vertical rod (12) is fixed on the first sliding block (10), and a pushing shaft (13) is fixed on the vertical rod (12);

the action mechanism further comprises a vertical track (14) fixed on the rotary table (7), a door-shaped second sliding block (15) is slidably mounted on the track (14), an inclined hole (16) is formed in the second sliding block (15), and two ends of the pushing shaft (13) respectively penetrate through the two inclined holes (16);

a lifting shaft (17) is fixed on the second sliding block (15);

the actuating mechanism further comprises a supporting rod (18) fixed on the rotary table (7), a second rotating shaft (19) is rotatably mounted on the supporting rod (18), the lower die (9) is fixed at one end of the second rotating shaft (19), and a first bevel gear (20) is fixed at the other end of the second rotating shaft (19);

the actuating mechanism further comprises a guide rod (21) fixed on the rotary table (7), an L-shaped rod (22) is fixed on the upper die (8), and the guide rod (21) is in sliding fit with the L-shaped rod (22);

the actuating mechanism further comprises a hollow shaft (23) fixed on the rotary table (7) and a rotating shaft III (24) rotatably mounted on the rotary table (7), the rotating shaft III (24) is coaxial with the hollow shaft (23), and a bevel gear II (25) meshed with the bevel gear I (20) is fixed on the rotating shaft III (24);

a spline shaft (26) is fixed on the third rotating shaft (24), and a spline sleeve (27) slides on the spline shaft (26);

a limiting groove (28) and a second annular groove (29) are formed in the inner wall of the hollow shaft (23), the limiting groove (28) is axially arranged, the second annular groove (29) is circumferentially arranged, and the limiting groove (28) is communicated with the second annular groove (29);

a lifting plate (30) is fixed on the outer ring of the spline housing (27), and a limiting block (31) in sliding fit with the limiting groove (28) is fixed on the lifting plate (30);

the actuating mechanism further comprises a first pipe (32) fixed on one side of the lifting plate (30), a spiral hole (33) is formed in the surface of the first pipe (32), a transition hole is formed in the surface of the hollow shaft (23), and the lifting shaft (17) penetrates through the transition hole and the spiral hole (33);

the actuating mechanism further comprises a second pipe (34) fixed to the other side of the lifting plate (30), and the second pipe (34) is rotatably connected with the L-shaped rod (22).

2. The precision casting processing equipment for the wear-resistant steel ball as claimed in claim 1, wherein the cooling mechanism comprises a fixed water tank (35), a housing is fixed on the water tank (35), sprayers (36) are uniformly arranged in the water tank (35) and the housing, every two sprayers (36) form a group, the spraying direction faces to the upper die (8) and the lower die (9), and a power pump (37) is arranged in the water tank (35) to provide cooling liquid for the sprayers (36).

3. Precision casting processing equipment for steel balls, which is wear resistant, according to claim 2, characterized in that the ball collecting means comprises a fixed collecting trough (38), inside which collecting trough (38) a sieve (39) is fixed transversely;

the steel ball collecting mechanism also comprises a slag groove (40) positioned at the bottom of the collecting groove (38), and the slag groove (40) is provided with a first universal wheel and a handle.

4. The precise casting and machining equipment for the wearable steel ball as claimed in claim 3, characterized in that the first annular groove further comprises a second U-shaped section (41) with gradually changed radius.

5. The precision casting processing equipment for the wear-resistant steel balls as claimed in claim 4, further comprising a motor (42) with a fixed position, wherein a speed reducer is installed at the output end of the motor (42), and the output shaft of the speed reducer is connected with the first rotating shaft (6).

6. The precise casting and processing equipment for the wearable steel ball as claimed in claim 5, characterized in that a plurality of second universal wheels are arranged at the bottom of the rotary table (7).

7. The apparatus for precision casting of wearable steel balls as claimed in claim 6, characterized in that the cooling mechanism further comprises a position sensor (43) corresponding to the power pump (37), the position sensor (43) being fixed in the housing.

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