Non-metallic ore efficient purification equipment

By designing a high-efficiency purification device for non-metallic ores that includes a hopper, frame, purification box, magnetic separation shaft and screen, the problem of incomplete removal of iron filings in existing devices has been solved, and the high-efficiency purification and quality improvement of ores have been achieved.

CN224321858UActive Publication Date: 2026-06-05XIANGYANG CHENGNUO DEVELOPMENT MANUFACTURING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XIANGYANG CHENGNUO DEVELOPMENT MANUFACTURING CO LTD
Filing Date
2025-05-27
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing non-metallic ore purification equipment lacks iron filings removal devices, resulting in poor quality of purified ore.

Method used

A high-efficiency purification device for non-metallic ores was designed. It adopts components such as hopper, frame, purification box, motor, magnetic separation shaft, and screen. Iron filings are removed by magnetic adsorption and screening, and combined with water washing and air drying, the ore is purified efficiently.

Benefits of technology

It effectively removes iron filings and mud from the surface of the ore, improving the purity and quality of the ore and achieving a highly efficient purification effect for non-metallic ores.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to non -metallic ore production and processing equipment technical field discloses a kind of non -metallic ore high -efficient purification equipment, including hopper, the outside of frame is fixedly connected with purification tank, the upper surface of equipment bottom plate is fixedly connected with motor, the inside of purification tank is provided with first magnetic separation shaft, the inside of purification tank is provided with second magnetic separation shaft, the outside of collection basin is fixedly connected with cylinder machine.The utility model has following advantages and effects: worker simultaneously starts motor, cylinder machine and pump after being poured in the inside of hopper with broken ore, the magnetic attraction of the magnetic attraction of rotating first magnetic separation shaft and second magnetic separation shaft, iron filings on the surface of broken ore are adsorbed on the upper surface of first magnetic separation shaft and second magnetic separation shaft, again after slope drop in the upper surface of shaking screen, through the back and forth shaking of screen to make the mud and slag on the surface of broken ore drop, through the above operation, the effect that non -metallic ore purification effect is good is realized.
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Description

Technical Field

[0001] This utility model relates to the technical field of non-metallic mineral production and processing equipment, and in particular to a high-efficiency purification equipment for non-metallic ores. Background Technology

[0002] Naturally occurring non-metallic minerals contain varying degrees of other mineral impurities or associated minerals. For specific non-metallic mineral products, some of these mineral impurities are permissible, such as the small amounts of dolomite and wollastonite contained in calcite, and some pyrophyllite and chlorite contained in talc; however, some should be removed as much as possible, such as the various iron minerals and other metallic impurities contained in minerals such as kaolinite, quartz, diatomite, talc, diatomaceous earth, wollastonite, and calcite.

[0003] In existing technologies, such as the non-metallic ore purification device disclosed in Chinese Patent Publication No. CN220900671U, the device includes: a purification chamber; a washing spiral drum is installed at the upper end of the purification chamber, a spiral chute is rotatably connected to one end of the washing spiral drum, a water outlet gate is installed at one end of the washing spiral drum, a water storage tank is installed below the water outlet gate, a filter plate is slidably connected to one end of the water storage tank, a water pump is installed at one end of the water pump, and a water storage tank is installed at the other end of the water pump. In this invention, the water storage tank and water pump facilitate the centralized collection and recycling of clean wastewater, the filter plate simultaneously filters the clean wastewater, and the filter plate is slidably connected within the water storage tank for easy disassembly and treatment of filter residue or replacement of the filter plate. A strong magnetic drying box and a weak magnetic drying box facilitate timely classification and processing of magnetically separated ores, followed by drying for subsequent operations.

[0004] In actual production, although this type of non-metallic ore purification device can purify non-metallic ores, it lacks an iron filings removal device. As a result, the iron filings cannot be effectively removed during the purification process, leading to poor quality of the purified non-metallic ores and thus poor performance of the equipment. Therefore, improvements are needed. Utility Model Content

[0005] The purpose of this invention is to provide a high-efficiency purification device for non-metallic ores, which has excellent purification effect on non-metallic ores.

[0006] The above-mentioned technical objective of this utility model is achieved through the following technical solution: a high-efficiency purification device for non-metallic ores, including a hopper, a frame fixedly connected to the outside of the hopper, a purification box fixedly connected to the outside of the frame, the hopper penetrating into the interior of the purification box, a base plate fixedly connected to the outside of the purification box, a motor fixedly connected to the upper surface of the base plate, a rotating hole opened inside the purification box, a first magnetic separation shaft and a second magnetic separation shaft arranged inside the purification box, a small gear disk rotatably connected inside the purification box, and the small gear disk being fixedly connected to one end of the second magnetic separation shaft. Next, a large gear disc is provided inside the purification box. The output end of the motor passes through the interior of the rotating hole and is fixedly connected to one end of the first magnetic separation shaft. The large gear disc is fixedly connected to the output end of the motor. A ramp is fixedly connected to the outside of the frame. A collection basin is provided at the bottom of the ramp. A spring is fixedly connected to the upper surface of the collection basin. A screen is fixedly connected to the upper surface of the spring. A cylinder is fixedly connected to the outside of the collection basin. A crank is fixedly connected to the outside of the screen. The output end of the cylinder is fixedly connected to the crank. A pump box is provided on one side of the outside of the collection basin. A water tank is fixedly connected to the outside of the purification box.

[0007] By adopting the above technical solution, the worker simultaneously starts the motor, cylinder, and pump. The motor, cylinder, and pump begin operating. The motor's output drives the first magnetic separation shaft to rotate, simultaneously rotating the large gear disc. Through the meshing connection between the large and small gear discs, the small gear disc also rotates. The rotating small gear disc drives the second magnetic separation shaft to rotate inside the purification chamber. After the cylinder operates, it drives the crank handle, causing the screen to sway back and forth through the action of the spring. The worker pours the crushed ore into the hopper, and the crushed ore falls from the hopper into the purification chamber. The crushed ore passes between the rotating first and second magnetic separation shafts. Due to the magnetic attraction of the rotating first and second magnetic separation shafts, the iron filings on the surface of the crushed ore are attracted to the upper surface of the first and second magnetic separation shafts. Then, the crushed ore after removing the iron filings falls onto the surface of the slope, and then falls onto the upper surface of the shaking screen. The back and forth shaking of the screen causes the mud and sludge on the surface of the crushed ore to fall off, thereby improving the quality of the crushed ore. Through the above operation, a good purification effect on non-metallic ores is achieved.

[0008] A further feature of this invention is that the water tank is provided with four nozzles on its exterior.

[0009] By adopting the above technical solution, the nozzle is turned on, and water is sprayed out from the water tank through the nozzle to clean the mud stains on the surface of the crushed ore.

[0010] A further feature of this invention is that a first circulation pipe is provided outside the slope, and a second circulation pipe is provided outside the slope. One end of the first circulation pipe extends into the interior of the collection basin, and the other end of the first circulation pipe extends into the interior of the pump box. One end of the second circulation pipe extends into the interior of the pump box, and the other end of the second circulation pipe extends into the interior of the water tank. A pump is fixedly connected inside the pump box.

[0011] By adopting the above technical solution, the pump is turned on and starts working. The water sprayed from the nozzle washes the crushed ore and flows into the collection basin. Through the combined action of the pump, the first circulation pipe and the second circulation pipe, the water flows back into the water tank, thus realizing the water circulation and cleaning.

[0012] A further feature of this invention is that a filter screen opening is provided inside the water tank, and a filter screen is provided inside the water tank.

[0013] By adopting the above technical solution, the filter screen filters the circulating water, reducing the turbidity of the circulating water.

[0014] A further feature of this invention is that two fans are fixedly connected to the outside of the frame.

[0015] By adopting the above technical solution, two fans are turned on to blow air onto the cleaned crushed ore surface, accelerating the drying of the crushed ore.

[0016] A further feature of this invention is that a magnetic mesh is fixedly connected to the upper surface of the slope, and the upper surface of the magnetic mesh is provided with a wear-resistant coating.

[0017] By adopting the above technical solution, when the crushed ore slides down the slope, the magnetic mesh once again adsorbs the iron filings on the surface of the crushed ore, further improving the purification effect of the crushed ore.

[0018] A further feature of this invention is that the slope is externally fixedly connected with two inclined plates.

[0019] By adopting the above technical solution, the two inclined plates prevent crushed ore from falling off the slope.

[0020] A further feature of this invention is that two foot pads are fixedly connected to the bottom of the frame.

[0021] By adopting the above technical solution, the motor will cause the frame to vibrate when it is working, and the two foot pads will cushion the frame.

[0022] A further feature of this invention is that a first turntable is rotatably connected inside the purification box, a second turntable is rotatably connected inside the purification box, the other end of the first magnetic separation shaft is fixedly connected to the first turntable, and the other end of the second magnetic separation shaft is fixedly connected to the second turntable.

[0023] By adopting the above technical solution, when the first magnetic separation shaft and the second magnetic separation shaft are rotated under force, the first turntable and the second turntable make the first magnetic separation shaft and the second magnetic separation shaft rotate smoothly.

[0024] A further feature of this invention is that the purification box has a cleaning square hole inside, a storage box is fixedly connected to the outside of the purification box, and a scraper is provided inside the storage box.

[0025] By adopting the above technical solution, workers use scrapers to periodically scrape off the iron filings adsorbed on the upper surfaces of the first and second magnetic separation shafts, preventing the iron filings from clogging the inside of the purification box.

[0026] The beneficial effects of this utility model are:

[0027] This invention, through the arrangement of a hopper, frame, purification box, equipment base plate, motor, rotating hole, first magnetic separation shaft, second magnetic separation shaft, small gear disc, large gear disc, ramp, collection basin, spring, cylinder, crank handle, and water tank, allows the worker to simultaneously start the motor, cylinder, and pump. The motor's output drives the first magnetic separation shaft to rotate, simultaneously rotating the large gear disc. Through the meshing connection between the large and small gear discs, the small gear disc also rotates. The rotating small gear disc drives the second magnetic separation shaft to rotate inside the purification box. The cylinder's operation drives the crank handle, and the spring causes the screen to sway back and forth. Workers pour crushed ore into the hopper, where it falls into the purification chamber. The crushed ore passes between the rotating first and second magnetic separation shafts. Due to the magnetic attraction of the rotating first and second magnetic separation shafts, iron filings on the surface of the crushed ore are attracted to the upper surfaces of the first and second magnetic separation shafts. After the iron filings are removed, the crushed ore falls onto the surface of the ramp, and then onto the upper surface of the shaking screen. The back-and-forth shaking of the screen removes mud and sludge from the surface of the crushed ore, thereby improving its quality. Through the above operations, a good purification effect is achieved for non-metallic ores.

[0028] This utility model, through the arrangement of a nozzle, a first circulation pipe, a pump, a filter screen, a filter screen, a fan, a magnetic mesh, a wear-resistant coating, an inclined plate, foot pads, a first turntable, a second turntable, a cleaning square hole, a storage box, and a scraper, allows for water circulation and cleaning. When the nozzle is turned on, water from the water tank is sprayed through the nozzle to clean the mud off the surface of the crushed ore. Turning on the pump activates the water sprayed from the nozzle, which then flows into a collection basin after cleaning the crushed ore. The pump, along with the first and second circulation pipes, recirculates the water back into the water tank, thus achieving water circulation and cleaning. The filter screen filters the circulating water, reducing its turbidity. Two fans are turned on to... Air is blown onto the cleaned crushed ore surface to accelerate its drying. As the crushed ore slides down the slope, the magnetic mesh again attracts iron filings from its surface, further improving the purification effect. Two inclined plates prevent the crushed ore from falling off the slope. When the motor is working, it causes the frame to vibrate, and two foot pads cushion the frame. When the first and second magnetic separation shafts rotate under force, the first and second turntables ensure their smooth rotation. Workers use scrapers to periodically scrape off the iron filings attracted to the upper surface of the first and second magnetic separation shafts, preventing them from clogging the inside of the purification chamber. Attached Figure Description

[0029] To more clearly illustrate the technical solutions in the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0030] Figure 1 This is a schematic diagram of the structure of this utility model;

[0031] Figure 2 This is a schematic diagram of the motor and the first magnetic separation shaft structure of this utility model;

[0032] Figure 3 This is a schematic diagram of the pump and the first circulation pipe of this utility model;

[0033] Figure 4 This utility model Figure 1 A magnified structural diagram of point A in the middle.

[0034] In the diagram, 1. Hopper; 2. Frame; 3. Purification box; 4. Equipment base plate; 5. Motor; 6. Rotary hole; 7. First magnetic separation shaft; 8. Second magnetic separation shaft; 9. Small gear disc; 10. Large gear disc; 11. Inclined plate; 12. Collection basin; 13. Screen; 14. Cylinder; 15. Handle; 16. Water tank; 17. Nozzle; 18. Second circulation pipe; 19. Pump; 20. Filter port; 21. Filter screen; 22. Fan; 23. Magnetic suction screen; 24. Wear-resistant coating; 25. Inclined plate; 26. Foot pad; 27. First turntable; 28. Second turntable; 29. ​​Cleaning square hole; 30. Storage box; 31. Scraper; 32. Spring; 33. First circulation pipe; 34. Pump box. Detailed Implementation

[0035] The technical solution of this utility model will now be clearly and completely described with reference to specific embodiments. Obviously, the described embodiments are only a part of the embodiments of this utility model, and not all of them. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the scope of protection of this utility model.

[0036] Reference Figure 1-4A high-efficiency purification device for non-metallic ores includes a hopper 1, a frame 2 fixedly connected to the outside of the hopper 1, a purification box 3 fixedly connected to the outside of the frame 2, the hopper 1 extending into the interior of the purification box 3, a base plate 4 fixedly connected to the outside of the purification box 3, a motor 5 fixedly connected to the upper surface of the base plate 4, a rotating hole 6 inside the purification box 3, a first magnetic separation shaft 7 inside the purification box 3, a second magnetic separation shaft 8 inside the purification box 3, a small gear disk 9 rotatably connected inside the purification box 3, the small gear disk 9 being fixedly connected to one end of the second magnetic separation shaft 8, a large gear disk 10 inside the purification box 3, the output end of the motor 5 extending into the rotating hole 6 and fixedly connected to one end of the first magnetic separation shaft 7, and the large gear disk 10 being fixedly connected to the output end of the motor 5. A ramp 11 is fixedly connected to the outside of frame 2. A collection basin 12 is installed at the bottom of ramp 11. A spring 32 is fixedly connected to the upper surface of collection basin 12. A screen 13 is fixedly connected to the upper surface of spring 32. A cylinder 14 is fixedly connected to the outside of collection basin 12. A crank handle 15 is fixedly connected to the outside of screen 13. The output end of cylinder 14 is fixedly connected to crank handle 15. A pump box 34 is installed on one side of the outside of collection basin 12. A water tank 16 is fixedly connected to the outside of purification box 3. When the worker starts motor 5, cylinder 14, and pump 19 simultaneously, motor 5, cylinder 14, and pump 19 begin to work. The output end of motor 5 drives the first magnetic separation shaft 7 to rotate, and at the same time drives the large gear disk 10 to rotate. Through the interaction between the large gear disk 10 and the small gear disk 9... The meshing connection causes the small gear disc 9 to rotate as well. The rotating small gear disc 9 drives the second magnetic separation shaft 8 to rotate inside the purification box 3. After the cylinder 14 starts working, it drives the crank handle 15 to move. Through the action of the spring 32, the screen 13 shakes back and forth. The worker pours the crushed ore into the hopper 1. The crushed ore falls from the hopper 1 into the purification box 3. The crushed ore passes between the rotating first magnetic separation shaft 7 and the second magnetic separation shaft 8. Under the magnetic attraction of the rotating first magnetic separation shaft 7 and the second magnetic separation shaft 8, the iron filings on the surface of the crushed ore are attracted to the upper surface of the first magnetic separation shaft 7 and the second magnetic separation shaft 8. Then, the crushed ore after removing the iron filings falls onto the surface of the ramp 11, and then falls onto the upper surface of the shaking screen 13 through the back and forth shaking of the screen 13. This process removes mud and slag from the surface of the crushed ore, thereby improving its quality. Through this operation, a high-quality purification effect on non-metallic ores is achieved. Four nozzles 17 are installed on the outside of the water tank 16. When the nozzles 17 are turned on, water flows from the water tank 16 through the nozzles 17, cleaning the mud off the surface of the crushed ore. A first circulation pipe 33 and a second circulation pipe 18 are installed on the outside of the slope 11. One end of the first circulation pipe 33 extends into the inside of the collection basin 12, and the other end extends into the inside of the pump box 134. One end of the second circulation pipe 18 extends into the inside of the pump box 134, and the other end extends into the inside of the water tank 16. A pump 19 is fixedly connected inside the pump box 34.The water tank 16 has a filter screen 20 inside and a filter screen 21 inside. The filter screen 21 filters the circulating water, reducing its turbidity. Two fans 22 are fixedly connected to the outside of the frame 2. When the two fans 22 are turned on, they blow air onto the cleaned crushed ore surface, accelerating the drying of the crushed ore. A magnetic mesh 23 is fixedly connected to the upper surface of the ramp 11. The upper surface of the magnetic mesh 23 is coated with a wear-resistant coating 24. When the crushed ore slides down the ramp 11, the magnetic mesh 23 again attracts iron filings from the surface of the crushed ore, further improving the purification effect of the crushed ore. Two inclined plates 25 are fixedly connected to the outside of the ramp 11 to prevent the crushed ore from falling off when sliding down the ramp 11. Two foot pads 26 are fixedly connected to the bottom of the frame 2. When motor 5 operates, it causes frame 2 to vibrate. Two foot pads 26 cushion the frame 2. A first turntable 27 and a second turntable 28 are rotatably connected inside the purification chamber 3. The other end of the first magnetic separation shaft 7 is fixedly connected to the first turntable 27, and the other end of the second magnetic separation shaft 8 is fixedly connected to the second turntable 28. When the first and second magnetic separation shafts 7 and 8 rotate under force, the first and second turntables 27 and 28 ensure smooth rotation. Workers use a scraper 31 to periodically scrape off the iron filings adsorbed on the upper surfaces of the first and second magnetic separation shafts 7 and 8, preventing them from clogging the inside of the purification chamber 3.

[0037] In this invention, the worker simultaneously starts the motor 5, the cylinder 14, and the pump 19. The motor 5, cylinder 14, and pump 19 begin operation. The output of the motor 5 drives the first magnetic separation shaft 7 to rotate, simultaneously driving the large gear disc 10 to rotate. Through the meshing connection between the large gear disc 10 and the small gear disc 9, the small gear disc 9 also rotates. The rotating small gear disc 9 drives the second magnetic separation shaft 8 to rotate inside the purification chamber 3. After the cylinder 14 starts working, it drives the crank handle 15 to move, causing the screen 13 to shake back and forth through the action of the spring 32. The worker pours the crushed ore into the hopper 1, and the crushed ore falls from the hopper 1 into the purification chamber 3. The crushed ore passes between the rotating first magnetic separation shaft 7 and the second magnetic separation shaft 8. Due to the magnetic attraction of the rotating first magnetic separation shaft 7 and the second magnetic separation shaft 8, iron filings on the surface of the crushed ore are attracted to the upper surfaces of the first magnetic separation shaft 7 and the second magnetic separation shaft 8. Then, the crushed ore, after the iron filings are removed, falls onto the surface of the inclined slope 11, and then onto the upper surface of the shaking screen 13. The back-and-forth shaking of the screen 13 causes the mud and sludge on the surface of the crushed ore to fall off, thereby improving the quality of the crushed ore. Through the above operation, a good purification effect is achieved for non-metallic ores. The nozzle 17 is turned on, and water flows from the water tank 16. The nozzle 17 sprays water to clean the mud off the surface of the crushed ore. Pump 19 is then turned on, and the water sprayed from the nozzle 17 washes the crushed ore before flowing into the collection basin 12. Through the combined action of pump 19, the first circulation pipe 33, and the second circulation pipe 18, the water flows back into the water tank 16, thus achieving water circulation cleaning. The filter screen 21 filters the circulating water, reducing its turbidity. Two fans 22 are turned on, blowing air onto the cleaned surface of the crushed ore to accelerate its drying. As the crushed ore slides down the slope 11, the magnetic net 23 further cleans it. The iron filings on the surface are adsorbed, which further improves the purification effect of the crushed ore. Two inclined plates 25 prevent the crushed ore from falling when it slides down the slope 11. When the motor 5 is working, it will drive the frame 2 to vibrate. Two foot pads 26 play a buffering role for the frame 2. When the first magnetic separation shaft 7 and the second magnetic separation shaft 8 are rotated under force, the first turntable 27 and the second turntable 28 make the first magnetic separation shaft 7 and the second magnetic separation shaft 8 rotate smoothly. The worker holds a scraper 31 and extends it into the cleaning square hole 29 to periodically scrape off the iron filings adsorbed on the upper surface of the first magnetic separation shaft 7 and the second magnetic separation shaft 8 to prevent the iron filings from clogging the inside of the purification box 3.

[0038] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A high-efficiency purification device for non-metallic ores, comprising a hopper (1), characterized in that: A frame (2) is fixedly connected to the outside of the hopper (1), and a purification box (3) is fixedly connected to the outside of the frame (2). The hopper (1) extends into the interior of the purification box (3). A base plate (4) is fixedly connected to the outside of the purification box (3), and a motor (5) is fixedly connected to the upper surface of the base plate (4). A rotating hole (6) is provided inside the purification box (3). A first magnetic separation shaft (7) is provided inside the purification box (3), and a second magnetic separation shaft (8) is provided inside the purification box (3). A small gear disk (9) is rotatably connected inside the purification box (3), and one end of the small gear disk (9) is fixedly connected to the second magnetic separation shaft (8). A large gear disk (10) is provided inside the purification box (3), and the output end of the motor (5) extends into the rotating hole. (6) is fixedly connected to one end of the first magnetic separation shaft (7), the large gear plate (10) is fixedly connected to the output end of the motor (5), the frame (2) is fixedly connected to the outside of the slope (11), the bottom of the slope (11) is provided with a collection basin (12), the upper surface of the collection basin (12) is fixedly connected with a spring (32), the upper surface of the spring (32) is fixedly connected with a screen (13), the outside of the collection basin (12) is fixedly connected with a cylinder (14), the outside of the screen (13) is fixedly connected with a crank (15), the output end of the cylinder (14) is fixedly connected to the crank (15), the outside side of the collection basin (12) is provided with a pump box (34), and the outside of the purification box (3) is fixedly connected with a water tank (16).

2. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The water tank (16) is provided with four nozzles (17) on its exterior.

3. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: A first circulation pipe (33) is provided on the outside of the slope (11), and a second circulation pipe (18) is provided on the outside of the slope (11). One end of the first circulation pipe (33) extends into the inside of the collection basin (12), and the other end of the first circulation pipe (33) extends into the inside of the pump box (34). One end of the second circulation pipe (18) extends into the inside of the pump box (34), and the other end of the second circulation pipe (18) extends into the inside of the water tank (16). A pump (19) is fixedly connected inside the pump box (34).

4. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The water tank (16) has a filter opening (20) inside and a filter screen (21) inside.

5. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The frame (2) is externally fixedly connected to a fan (22), and there are two fans (22).

6. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: A magnetic mesh (23) is fixedly connected to the upper surface of the slope (11), and a wear-resistant coating (24) is provided on the upper surface of the magnetic mesh (23).

7. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The ramp (11) is externally fixedly connected to an inclined plate (25), and there are two inclined plates (25).

8. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The bottom of the frame (2) is fixedly connected with two foot pads (26).

9. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The purification box (3) is rotatably connected to a first turntable (27) and a second turntable (28). The other end of the first magnetic separation shaft (7) is fixedly connected to the first turntable (27), and the other end of the second magnetic separation shaft (8) is fixedly connected to the second turntable (28).

10. The high-efficiency purification equipment for non-metallic ores according to claim 1, characterized in that: The purification box (3) has a cleaning square hole (29) inside, and a storage box (30) is fixedly connected to the outside of the purification box (3). A scraper (31) is provided inside the storage box (30).