Grading Discharge Module, and Continuous Wet Ball-Milling Separation Device and Separation Method

Abstract

A continuous wet ball-milling separation device has a cylinder, which has a feeding section, a shearing section, and a crushing section in sequence from top to bottom. The feeding section is located at the upper portion of the device, and is provided with a liquid inlet, a material inlet, and a material distributor. The shearing section is located in the middle of the device, and is internally provided with shearing blades. The crushing section is located at the lower portion of the device, and is internally provided with stirring rods and crushing balls, and a grading discharge module is provided at the bottom of the crushing section. A grading discharge module is used in the device and a continuous wet ball-milling separation method applying the device. The device implements continuous operations of material crushing and grading by means of the material distributor, wet shearing, wet crushing, and wet grading.

Claims

1. A grading discharge module, comprising a grading mesh plate and a grading wheel, wherein the grading mesh plate is sleeved outside the grading wheel; wherein the grading mesh plate has a cylinder structure, with a top cover arranged at a top end of the grading mesh plate and fixedly connected to a first rotating shaft; the cylinder wall of the grading mesh plate is provided with a plurality of first slits or holes; and the grading wheel has a cylinder structure, and the cylinder wall of the grading wheel is provided with a plurality of second slits or holes.

2. The grading discharge module of claim 1, wherein the width or diameter of the second slits or holes is increased from the inner side to the outer side of the cylinder wall.

3. The grading discharge module of claim 2, wherein the width or diameter of the second slits or holes at the inner side of the cylinder wall is 0.2-0.9 times that at the outer side of the cylinder wall.

4. The grading discharge module of claim 1, wherein a discharging outlet is arranged at the bottom of the grading wheel.

5. The grading discharge module of claim 1, wherein an area of the grading mesh plate where the first slits or holes are arranged is staggered from an area of the grading wheel where the second slits or holes are arranged in an axial direction.

6. The grading discharge module of claim 1, wherein the cylinder structure of the grading mesh plate comprises a feeding section of the grading mesh plate, a grading section of the grading mesh plate and a discharging section of the grading mesh plate, which are arranged from top to bottom sequentially, wherein the cylinder wall of the feeding section of the grading mesh plate and the cylinder wall of the discharging section of the grading mesh plate are provided with the first slits or holes, while the cylinder wall of the grading section of the grading mesh plate is not provided with the first slits or holes.

7. The grading discharge module of claim 6, wherein the grading wheel is divided into three sections from top to bottom, namely, an upper section of the grading wheel, a grading section and a lower section of the grading wheel; the cylinder wall of the upper section of the grading wheel and the cylinder wall of the lower section of the grading wheel are not provided with the second slits or holes, while the cylinder wall of the grading section is provided with the second slits or holes.

8. The grading discharge module of claim 6, wherein the three sections of the grading mesh plate correspond to the three sections of the grading wheel in the vertical direction respectively.

9. A continuous wet ball-milling separation device, comprising a cylinder, which comprises a feeding section, a shearing section and a crushing section arranged from top to bottom sequentially therein, and the grading discharge module of claim 1 is arranged inside the crushing section; the feeding section is located at the upper part of the ball-milling separation device; the feeding section is provided with a liquid inlet, a material inlet and a material distributor; the shearing section is located at the middle part of the ball-milling separation device and provided with shearing blades therein; and the crushing section is located at the lower part of the ball-milling separation device and provided with stirring rods and crushing balls therein, and the grading discharge module is arranged at the bottom of the crushing section.

10. The continuous wet ball-milling separation device of claim 9, wherein the ball-milling separation device has a cylinder structure.

11. The continuous wet ball-milling separation device of claim 9, wherein the liquid inlet and the material inlet are located in the top or upper cylinder wall of the ball-milling separation device, the material distributor is located inside the cylinder, and the material inlet is in communication with an inlet of the material distributor through a pipeline.

12. The continuous wet ball-milling separation device of claim 9, wherein a motor is arranged outside the top of the cylinder, and a first rotating shaft is arranged along a central axis of the cylinder structure of the ball-milling separation device and extends through the feeding section, the shearing section and the crushing section.

13. The continuous wet ball-milling separation device of claim 12, wherein the shearing blades and the stirring rods are evenly distributed on the first rotating shaft and fixedly connected to the first rotating shaft; the crushing balls are loaded in bulk in the crushing section, and the grading discharge module is located along the central axis of the crushing section.

14. The continuous wet ball-milling separation device of claim 12, wherein both the grading mesh plate and the grading wheel are coaxial with the first rotating shaft.

15. The continuous wet ball-milling separation device of claim 14, wherein the width or diameter of the first slits or holes is smaller than the diameter of the crushing balls, and/or, wherein the grading mesh plate forms the rotating shaft of the crushing section, and the stirring rods are evenly distributed on the outer wall of the cylinder structure of the grading mesh plate.

16. (canceled)

17. The continuous wet ball-milling separation device of claim 13, wherein the discharging outlet also serves as a second rotating shaft.

18. The continuous wet ball-milling separation device of claim 17, wherein the grading mesh plate and the grading wheel can be driven by the first rotating shaft and the second rotating shaft to rotate respectively.

19. The continuous wet ball-milling separation device of claim 9, wherein there is a gap between a lower edge of the discharging section of the grading mesh plate and a bottom plate of the device, and the height of the gap is smaller than the diameter of the crushing balls.

20. The continuous wet ball-milling separation device of claim 19, wherein the width or diameter of the slits or holes in the cylinder wall of the grading mesh plate is 0.5-0.8 times the diameter of the crushing balls.

21. A continuous wet ball-milling separation method utilizing the continuous wet ball-milling separation device of claim 9, comprising the following steps: (1) feeding a liquid continuously into the ball-milling separation device through the liquid inlet, controlling the liquid level in the ball-milling separation device, while discharging the liquid continuously from the ball-milling separation device through the discharging outlet; (2) after the liquid level in the ball-milling separation device is controlled into a stable state, introducing a material into the material distributor through the material inlet and then into the ball-milling separation device, cooling or mixing the bulk material dispersed in the liquid, shearing the cooled or mixed bulk material in the shearing section of the ball-milling separation device, and milling the cooled or mixed bulk material in the crushing section of the ball-milling separation device; (3) in the milling process of the material, screening the material powder in size smaller than the width or diameter of the first slits or holes of the grading mesh plate into the grading mesh plate through the mesh plate, controlling the material powder and liquid in a particle size smaller than the target particle size to enter the grading wheel through the second slits or holes, and discharging the obtained material from the ball-milling separation device through the discharging outlet under the action of the rotating grading of the grading wheel; (4) in the grading process, throwing the material powder in a particle size greater than the target particle size out of the grading wheel under the action of rotation of the grading wheel, wherein the material powder thrown out of the grading wheel collides with the inner wall of the grading section of the grading mesh plate; and the material powder in a particle size greater than the target particle size is discharged under the action of gravity through the grading mesh plate to the interior of the ball-milling separation device for further ball-milling.

22. (canceled)

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0048] FIG. 1 is a schematic structural diagram of the continuous wet ball-milling separation device according to the present disclosure;

[0049] FIG. 2 is a schematic structural diagram of the grading mesh plate in the continuous wet ball-milling separation device according to the present disclosure;

[0050] FIG. 3 is a schematic structural diagram of the grading wheel in the continuous wet ball-milling separation device according to the present disclosure;

[0051] FIG. 4 is an isometric diagram of the second slits of the grading wheel in the continuous wet ball-milling separation device according to the present disclosure.

[0052] In the figures, the reference signs represent the following components:1material feeding pipeline, 2material inlet, 3liquid feeding pipeline, 4liquid inlet, 5motor, 6material distributor, 7ball-milling separation device, 8first rotating shaft, 9shearing blade, 10stirring rod, 11crushing ball, 12grading mesh plate, 13grading wheel, 14discharging pipe, 15rotary quick connector, 16discharging port, 17second slit or hole, 18first slit or hole, 19second rotating shaft, 20top cover of the mesh plate, 21feeding section of the mesh plate, 22grading section of the mesh plate, 23discharging section of the mesh plate, 24grading motor, 25rotating belt, Afeeding section of the ball-milling separation device, Bshearing section of the ball-milling separation device, Ccrushing section of the ball-milling separation device, Dgrading section of the grading wheel, Eupper section of the grading wheel, Flower section of the grading wheel.

DETAILED DESCRIPTION

[0053] Hereunder the present disclosure will be further detailed in embodiments, but the present disclosure is not limited to those embodiments.

Embodiment 1

[0054] As shown in FIG. 1, the continuous wet ball-milling separation device in the present disclosure comprises a cylinder, for example, a cylindrical cylinder structure. The cylinder comprises a feeding section A, a shearing section B and a crushing section C arranged sequentially from top to bottom therein, and a grading discharge module is arranged in the crushing section C. The feeding section A is located at the upper part of the ball-milling separation device 7. The feeding section A is provided with a liquid inlet 4, a material inlet 2 and a material distributor 6. The shearing section B is located at the middle part of the ball-milling separation device 7 and provided with shearing blades 9 therein.

[0055] The crushing section C is located at the lower part of the ball-milling separation device 7 and provided with stirring rods 10 and crushing balls 11 therein, and the grading discharge module is arranged at the bottom of the crushing section C.

[0056] The liquid inlet 4 and the material inlet 2 are located in the top or upper cylinder wall of the ball-milling separation device 7, and the material distributor 6 is located inside the cylinder. The material inlet 2 is in communication with an inlet of the material distributor 6 through a pipeline.

[0057] Furthermore, the shearing blades 9 may be conventional ones in the art. Two to eight shearing blades 9 may be arranged.

[0058] Furthermore, a motor 5 is arranged outside the top of the cylinder, and a first rotating shaft 8 is arranged along a central axis of the cylinder structure of the ball-milling separation device 7 and extends through the feeding section A, the shearing section B and the crushing section C. The shearing blades 9 and the stirring rods 10 are evenly distributed on the first rotating shaft 8 and fixedly connected to the first rotating shaft 8. The crushing balls 11 are loaded in bulk in the crushing section C. The grading discharge module is arranged along the central axis of the crushing section C.

[0059] As shown in FIGS. 2-3, the grading discharge module comprises a grading mesh plate 12 and a grading wheel 13. The grading mesh plate 12 is sleeved outside the grading wheel 13, and both the grading mesh plate 12 and the grading wheel 13 are coaxial (concentric) with the first rotating shaft 8. The grading mesh plate 12 has a cylinder structure, with a top cover 20 arranged at a top end of the grading mesh plate 12 and fixedly connected to a first rotating shaft 8. The cylinder wall of the grading mesh plate 12 is provided with a plurality of first slits or holes 18, and the width or diameter of the slits or holes is smaller than the diameter of the crushing balls 11. Stirring rods 10 are evenly distributed on the outer wall of the cylinder structure of the grading mesh plate 12. The grading wheel 13 also has a cylinder structure, and the cylinder wall of the grading wheel 13 is provided with a plurality of second slits or holes 17. The width or diameter of the second slits or holes 17 in the cylinder wall of the grading wheel 13 is increased from the inner side to the outer side, and the width or diameter of the second slits or holes in the cylinder wall at the inner side is 0.2-0.9 times that at the outer side, and is usually 2 mm-15 mm. The lower section F of the grading wheel is fixedly connected to the second rotating shaft 19, and a discharging port 16 is arranged at the bottom of the grading wheel 13. The grading mesh plate 12 and the grading wheel 13 can be driven by the first rotating shaft 8 and the second rotating shaft 9 to rotate respectively.

[0060] Furthermore, the lower end of the discharging port 16 of the grading wheel 12 is provided with a rotary quick connector 15, and the other end of the rotary quick connector 15 is in communication with a discharging pipe 14. The second rotating shaft 19 penetrates the bottom plate of the device 7 and can be connected to the grading motor 24 through a rotating belt (e.g., a pulley belt) 25.

[0061] In the present disclosure, the grading mesh plate 12 is used to isolate the crushing balls 11 to prevent them from entering the grading discharge module, and the grading wheel 13 is used to separate the material powder meeting the particle size requirement.

[0062] The material entering the ball-milling separation device 7 through the material inlet 2 may be a solid material or hot liquid material. The particle size of the solid material should be smaller than 50 mm.

[0063] The material distributor 6 may be a conventional structure such as a pelletizer, extruder or atomizer, and is used to disperse the material in the ball-milling separation device 7.

Embodiment 2

[0064] As shown in FIG. 2, in an embodiment of the present disclosure, the cylinder structure of the grading mesh plate 12 comprises a feeding section 21 of the grading mesh plate, a grading section 22 of the grading mesh plate and a discharging section 23 of the grading mesh plate, which are arranged from top to bottom sequentially, wherein the cylinder wall of the feeding section 21 of the grading mesh plate and the cylinder wall of the discharging section 23 of the grading mesh plate are provided with the first slits or holes 18, while the cylinder wall of the grading section 22 of the grading mesh plate is not provided with the first slits or holes. There is a gap between the lower edge of the discharging section 23 of the grading mesh plate and the bottom plate of the device 7, and the height of the gap should be smaller than the diameter of the crushing balls 11, usually 0.5-0.8 times the diameter of the crushing balls 11.

[0065] As shown in FIGS. 3-4, the grading wheel can also be divided into three sections from top to bottom, namely, an upper section E, a grading section D and a lower section F of the grading wheel. The cylinder wall of the upper section E and the cylinder wall of the lower section F of the grading wheel are not provided with the second slits or holes 17, while the grading section D is provided with the second slits or holes 17. The width of the second slits in the cylinder wall of the grading wheel 12 is increased from the inner to the outer side; specifically, the width of the slits at the inner side is 0.2-0.9 times that at the outer side, and usually is 2 mm-15 mm. The slits of the grading section D are used to separate the material in different particle sizes. Further preferably, the three sections of the grading mesh plate 12 correspond to the three sections of the grading wheel 13 in the vertical direction respectively, which is to say, the feeding section 21, the grading section 22 and the discharging section 23 of the grading mesh plate 12 are in one-to-one correspondence with the upper section E, the grading section D and the lower section F of the grading wheel 12 in the vertical direction respectively.

[0066] Furthermore, in the grading mesh plate 12, the feeding section 21 and the discharging section 23 of the grading mesh plate are provided with a plurality of first slits or holes 18, and the width or diameter of the first slits or holes is usually 0.5-0.8 times the diameter of the crushing balls 11, and the second slits or holes 18 are used as channels for the milled slurry.

Embodiment 3

[0067] As shown in the accompanying drawings, the present disclosure provides a continuous wet ball-milling separation method.

[0068] Specifically, the continuous wet ball-milling separation method comprises the following steps: feeding a liquid continuously into the ball-milling separation device 7 through the liquid inlet 4, controlling the liquid level in the ball-milling separation device 7, while discharging the liquid continuously from the ball-milling separation device 7 through the discharging outlet 16; after the liquid level in the ball-milling separation device 7 is controlled into a stable state, feeding the material into the material distributor 6 through the material inlet 2 then into the ball-milling separation device 7, and cooling or mixing the dispersed materials in the liquid; shearing the cooled and mixed dispersed material in the shearing section B, and then milling the material in the crushing section C. In the milling process of the material, the material powder in a particle size smaller than the width or diameter of the first slits or holes enters the grading mesh plate 12 through the first slits or holes, and the material powder in a particle size smaller than 100 meshes per inch (mpi) enters the grading wheel 13 through the second slits or holes 17 and is discharged out of the ball-milling separation device 7 through the discharge port 16, the rotary quick connector 15 and the discharge pipe 14 under the rotating and grading action of the grading wheel 13; in the grading process, the material powder in a particle size greater than 100 meshes per inch (mpi) is thrown out of the grading wheel 13 by the centrifugal force under the rotating action of the grading wheel 13 and collides with the inner wall of the grading section 22 of the grading mesh plate, and, under the action of gravity, is discharged through the discharging section 23 of the grading mesh plate into the ball-milling separation device 7 for further ball-milling.

Embodiment 4

[0069] As shown in the accompanying drawings, the present disclosure provides a method for continuous ball-milling separation of insoluble sulfur. A quenching liquid continuously enters the ball-milling separation device 7 through the liquid inlet 4. The liquid level of the quenching liquid in the ball-milling separation device 7 is controlled, while the quenching liquid is continuously discharged from the ball-milling separation device 7 through the discharging port 16. After the level of quenching liquid in the ball-milling separation device 7 is controlled into a stable state, high-temperature (molten) sulfur at 250 C.-300 C. is fed into the ball-milling separation device 7 through the material distributor 6.

[0070] The dispersed sulfur enters the quenching liquid and is quenched. The quenched dispersed sulfur is sheared in the shearing section B of the ball-milling separation device and then milled in the crushing section C of the ball-milling separation device 7. In the milling process of the sulfur, sulfur powder in a particle size smaller than the aperture of the slits (holes) of the grading mesh plate enters the grading mesh plate 12 through the first slits (or holes). Under the rotating grading action of the grading wheel 13, the sulfur powder in a particle size smaller than 100 meshes per inch (mpi) enters the grading wheel 13 through the second slits, and is discharged out of the ball-milling separation device 7 through the discharging port 16, the rotating quick connector 15 and the discharging pipe 14. In the grading process, the material powder in a particle size greater than 100 meshes per inch (mpi) is thrown out of the grading wheel 13 under the action of rotation of the grading wheel 13, and collides with the inner wall of the grading section 22 of the grading mesh plate; while the material powder in a particle size greater than 100 meshes per inch (mpi) is discharged under the action of gravity through the discharging section 23 of the grading mesh plate to the interior of the ball-milling separation device 7 for further ball-milling. With the device provided by the present disclosure, high-temperature sulfur and quenching liquid can be continuously fed and discharged, the insoluble sulfur can be continuously quenched and milled, and sulfur powder meeting the particle size requirement of 100 meshes per inch (mpi) can be obtained.

[0071] The following table shows the particle size distribution of sulfur powder prepared with the continuous wet ball-milling separation device in the technical scheme of the present disclosure. In the prepared sulfur powder, particles in a particle size smaller than 150 m accounts for 98.21 vol. %, and particles in a particle size between 140 m and 150 m accounts for 70.32 vol. %, which is to say, the uniformity of particle size is high.

TABLE-US-00001 Particle Size (m) Vol. % or lower 100 0.08 105 0.18 110 0.31 115 0.49 120 1.38 125 2.51 130 8.55 135 15.65 140 27.89 145 89.23 150 98.21 155 100 160 100 165 100 170 100 175 100