A slicing plasma sedimentation and crushing machine

By designing a slicing-type plasma precipitation and crushing machine, which utilizes a pneumatic push rod to drive the cutter for vertical cutting and incorporates an anti-splash structure, the problem of low crushing efficiency and splash loss of human blood protein precipitation raw materials for blood products is solved, achieving efficient and safe crushing results.

CN224443181UActive Publication Date: 2026-07-03LANZHOU LANSHENG BLOOD PROD CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LANZHOU LANSHENG BLOOD PROD CO LTD
Filing Date
2025-06-11
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing technologies for the low-temperature precipitation of human blood protein raw materials for blood products have low crushing efficiency and suffer from splashing losses and high labor intensity.

Method used

A slicing-type plasma sedimentation and crushing machine is designed. It uses a pneumatic push rod to drive the installed cutter for vertical cutting. Combined with an upper sealing cover and splash guard to prevent splashing, the material slides out through an inclined discharge path, achieving efficient crushing and safe operation.

Benefits of technology

It improves crushing efficiency by 6-12 times, reduces splash loss rate to below 3%, increases material utilization rate to over 95%, and meets GMP hygiene standards.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses a slicing-type plasma sedimentation and crushing machine, comprising a main body, a main frame, a worktable, an inlet frame, a support frame, and a material. The worktable is installed at an angle on top of the main frame, and the inlet frame and support frame are installed on top of the worktable, with the support frame directly above the inlet frame. The material is placed inside the inlet frame. The worktable has a rectangular structure, with a first cutting edge on its surface. The first cutting edge is rectangular in shape, and a movable cover is welded to the bottom of the first cutting edge. The movable cover is rectangular in shape, with a through-type structure at the top and inside. A sliding seat is provided inside the movable cover, and a set of symmetrically distributed pneumatic push rods are installed at the bottom of the movable cover. This device improves work efficiency, protects product safety, minimizes losses, and ensures compliance with product operation regulations.
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Description

Technical Field

[0001] This invention relates to the field of plasma sedimentation and crushing technology, specifically a slicing plasma sedimentation and crushing machine. Background Technology

[0002] Currently, there are no specific methods or procedures in the industry for crushing raw materials for low-temperature precipitation of human blood protein in blood products. Most methods involve chopping with knives, shoveling, or hammering.

[0003] The current process for precipitating human blood protein at low temperatures involves splashing losses during raw material crushing, and is extremely inefficient and labor-intensive, consuming a large portion of the operator's energy and time in this dissolution stage.

[0004] Therefore, a solution is needed. Summary of the Invention

[0005] (a) Technical problems to be solved

[0006] To address the shortcomings of existing technologies, this invention provides a slicing plasma sedimentation and crushing machine to solve the problems mentioned in the background section.

[0007] (II) Technical Solution

[0008] To achieve the above objectives, the present invention provides the following technical solution: a slicing plasma sedimentation and crushing machine, comprising a device body, the device body including a main frame device, a workbench device, an inlet frame device, a frame device, and material; the workbench device is installed at an angle on top of the main frame device; the inlet frame device and the frame device are installed on top of the workbench device; the frame device is located directly above the inlet frame device; the material is placed inside the inlet frame device; the workbench device has a rectangular structure; a first cutting edge is provided on the surface of the workbench device; the first cutting edge has a rectangular structure; a movable cover is welded to the bottom of the first cutting edge; the movable cover has a rectangular structure, and its top and interior are a through structure; a sliding seat is provided inside the movable cover; a set of symmetrically distributed pneumatic push rods are installed at the bottom of the movable cover; the top driving end of the pneumatic push rod is fixed to the sliding seat by screws; and a cutting blade is installed on the top of the sliding seat.

[0009] Preferably, the workbench device has a discharge port at the top and a discharge cover at the bottom. The discharge cover is located at the bottom of the discharge port and has a funnel-shaped structure. The discharge port is located in front of the cutting edge.

[0010] Preferably, the entry frame device includes a main storage frame and an upper sealing cover. The upper sealing cover is welded to the top front end of the main storage frame. The upper sealing cover has a cutting blade opening at its top and a splash guard at its top. The splash guard is located in front of the cutting blade opening, and the upper sealing cover and the splash guard form an L-shaped structure.

[0011] Preferably, the main storage frame has a rectangular structure, a drop outlet is provided at the bottom front end of the main storage frame, and a set of baffles is installed inside the main storage frame.

[0012] Preferably, the main storage frame is provided with side mounting blocks on both the left and right sides. The side mounting blocks are rectangular in shape, and locking notches are provided on the surface of the side mounting blocks. Locking bolts are installed on the surface of the locking notches.

[0013] Preferably, the frame device includes an upper frame block, support columns, and load-bearing bases. The upper frame block has a rectangular structure with arc-shaped ends. A set of load-bearing bases is provided, and the set of load-bearing bases is symmetrically installed on the top of the upper frame block by screws. A load-bearing block is welded to the top of the load-bearing base, and a fixing hole is opened on the top of the load-bearing base. A main frame is provided at the bottom of the upper frame block. A set of support columns is provided, and the set of support columns is symmetrically installed at the bottom of the upper frame block. A column fixing block is provided at the bottom of the support column, and a fixing hole is also opened on the surface of the column fixing block. A second cutting edge is opened at the bottom of the upper frame block.

[0014] Preferably, the main frame device includes a main frame, a front sealing plate, a bottom plate, maintenance doors, and a rear sealing plate. The top of the main frame has an inclined structure. The front sealing plate is welded and installed at the front end of the main frame, and the rear sealing plate is welded and installed at the rear end of the main frame. A set of maintenance doors is provided, and the set of maintenance doors is respectively installed on the left and right sides of the main frame by hinges. The bottom plate is installed at the bottom of the main frame.

[0015] Preferably, the front sealing plate has a rectangular structure, and an outlet is provided above the surface of the front sealing plate, the outlet having a rectangular structure.

[0016] Preferably, an installation beam is welded to the front end of the main frame, and a discharge plate is welded to the top of the installation beam. The discharge plate has an inclined structure, and a large discharge frame passes through the top of the discharge plate. The large discharge frame is located directly below the discharge hood, and a small discharge frame is provided at the front end of the large discharge frame.

[0017] Preferably, threaded support bolts and movable wheels are installed at the four corners of the bottom of the base plate, and support feet are installed at the bottom of the threaded support bolts, with the support feet having a suction cup-like structure.

[0018] (III) Beneficial Effects

[0019] This invention provides a slicing-type plasma sedimentation and disruption machine. It has the following beneficial effects:

[0020] This solution presents a slicing-type plasma sedimentation and crushing machine that improves work efficiency, protects product safety, minimizes waste, and ensures compliance with operational regulations, filling a gap in industry applications. The device is equipped with a cutter that shreds the material before it slides out through a discharge frame, where workers can collect the material. Furthermore, the upper sealing cover effectively prevents material splashing during the shredding process, thus improving the cleanliness of the cutting process. Attached Figure Description

[0021] Figure 1 This is a schematic diagram of the overall structure of the present invention;

[0022] Figure 2 This is a schematic diagram of the overall internal structure of the present invention;

[0023] Figure 3 This is a schematic diagram of the structure of the workbench device of the present invention;

[0024] Figure 4 This is a schematic diagram of the structure of the entry frame device of the present invention.

[0025] Figure 5 This is a schematic diagram of the frame device of the present invention.

[0026] In the diagram: 1. Device body; 2. Main frame assembly; 3. Workbench assembly; 4. Inlet frame assembly; 5. Frame assembly; 6. Material; 7. Movable cover; 8. Sliding seat; 9. Cutter mounting; 10. Pneumatic push rod; 11. Discharge port; 12. Discharge cover; 13. First cutter opening; 14. Main storage frame; 15. Upper sealing cover; 16. Cutter movable opening; 17. Splash guard; 18. Stop bar; 19. Side mounting block; 20. Locking notch; 21. Locking bolt. 22. Upper frame block; 23. Support column; 24. Load-bearing base; 25. Load-bearing block; 26. Fixing hole; 27. Column fixing block; 28. Main frame; 29. ​​Front sealing plate; 30. Base plate; 31. Maintenance door; 32. Outlet; 33. Discharge plate; 34. Large discharge frame; 35. Small discharge frame; 36. Threaded support bolt; 37. Support foot; 38. Moving wheel; 39. Mounting beam; 40. Drop outlet; 41. Rear sealing plate; 42. Second cutting edge. Detailed Implementation

[0027] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0028] Please see Figure 1-5 The present invention provides a technical solution:

[0029] Example 1

[0030] Regarding the aforementioned problems: the existing low-temperature precipitation process for human blood protein in blood products involves splashing losses during raw material crushing, and is extremely inefficient and labor-intensive, consuming most of the operator's energy and time in this dissolution stage.

[0031] The solution is as follows: A slicing plasma sedimentation and crushing machine includes a device body 1, which includes a main frame device 2, a workbench device 3, an inlet frame device 4, a frame device 5, and a material 6. The workbench device 3 is installed at an angle on top of the main frame device 2. The inlet frame device 4 and the frame device 5 are installed on top of the workbench device 3, with the frame device 5 located directly above the inlet frame device 4. The material 6 is placed inside the inlet frame device 4. The workbench device 3 has a rectangular structure, and a first cutting edge 13 is provided on its surface. The first cutting edge 13 has a rectangular structure, and a movable cover 7 is welded to the bottom of the first cutting edge 13. The movable cover 7 has a rectangular structure, and its top and interior are a through structure. A sliding seat 8 is provided inside the movable cover 7. A set of pneumatic push rods 10 distributed symmetrically are installed at the bottom of the movable cover 7. The top driving end of the pneumatic push rod 10 is fixed to the sliding seat 8 by screws. A cutting blade 9 is installed on the top of the sliding seat 8. The workbench device 3 has a discharge port 11 at the top and a discharge cover 12 at the bottom. The discharge cover 12 is located at the bottom of the discharge port 11 and has a funnel-shaped structure. The discharge port 11 is located in front of the first cutting edge 13.

[0032] Analysis of the above: During the cutting process, material 6 is placed into the inlet frame device 4. Because the inlet frame device 4 is inclined, the front end of material 6 moves forward and downward. Then, the front end of material 6 is limited by the stop bar 18. A set of pneumatic push rods 10 drives the sliding seat 8 to rise. The cutter 9 mounted on the sliding seat 8 can then cut the material 6 above. During the cutting process, material 6 is shredded to achieve the purpose of crushing. During the cutting process, the front end of material 6 is also limited by the upper sealing cover 15 to improve the stability of the material. The upper sealing cover 15 also provides protection to prevent material 6 from splashing and improve the cleanliness of the equipment. During the lifting and lowering process, the highest height of the sliding seat 8 will be flush with the first cutter 13, which can prevent material from falling into the movable cover 7. After the cutting is completed, the material can fall out through the drop outlet 40, and then fall into the large discharge frame 34 below through the discharge outlet 11 and discharge cover 12 and slide out.

[0033] Example 2:

[0034] Please see Figure 1-5 The present invention provides a technical solution based on Embodiment 1: The entry frame device 4 includes a main storage frame 14 and an upper sealing cover 15. The upper sealing cover 15 is welded to the top front end of the main storage frame 14. The top of the upper sealing cover 15 has a cutting knife movable opening 16. The top of the upper sealing cover 15 has a splash guard 17. The splash guard 17 is located in front of the cutting knife movable opening 16. The upper sealing cover 15 and the splash guard 17 form an L-shaped structure.

[0035] Analysis of the above content: The upper sealing cover 15 is for the purpose of facilitating the splashing of material 6 during the cutting process, thereby improving the cleanliness of the equipment. The cutter access port 16 opened at the top of the upper sealing cover 15 is for the installation and movement of the cutter 9. The splash guard 17 is also to prevent the material 6 brought out by the cutter 9 during the cutting process from splashing.

[0036] Example 3:

[0037] Please see Figure 1-5 The present invention provides a technical solution based on Embodiment 1: the main storage frame 14 has a rectangular structure, the bottom front end of the main storage frame 14 has a drop outlet 40, and a set of baffles 18 are installed inside the main storage frame 14.

[0038] Analysis of the above content: The stop bar 18 is used to limit the front end of the material 6, so that the material 6 can be cut by the cutter 9. Then the cut part of the material front end can fall out through the drop outlet 40 opened at the bottom front end of the main storage frame 14.

[0039] Example 4:

[0040] Please see Figure 1-5 The present invention provides a technical solution based on embodiment one: the main storage frame 14 is provided with side mounting blocks 19 on both the left and right sides, the side mounting blocks 19 are rectangular in shape, the surface of the side mounting blocks 19 is provided with locking notches 20, and locking bolts 21 are installed on the surface of the locking notches 20.

[0041] Analysis of the above content: The side mounting block 19 is to facilitate the fixing of the main storage frame 14 to the workbench device 3. During installation, the side mounting block 19 is attached to the workbench device 3, and the workbench device 3 can be reserved with fixing holes 26. Then, the locking notch 20 of the side mounting block 19 corresponds to the fixing hole 26 of the workbench device 3. The operator uses the locking bolt 21 to fix it, thereby fixing the main storage frame 14 to the workbench device 3.

[0042] Example 5:

[0043] Please see Figure 1-5 The present invention provides a technical solution based on Embodiment 1: The frame device 5 includes an upper frame block 22, support columns 23, and load-bearing bases 24. The upper frame block 22 has a rectangular structure with arc-shaped ends. A set of load-bearing bases 24 are provided, and the set of load-bearing bases 24 are symmetrically installed on the top of the upper frame block 22 by screws. A load-bearing block 25 is welded to the top of the load-bearing base 24. A fixing hole 26 is opened on the top of the load-bearing base 24. A main frame 28 is opened at the bottom of the upper frame block 22. A set of support columns 23 are provided, and the set of support columns 23 are symmetrically installed at the bottom of the upper frame block 22. A column fixing block 27 is provided at the bottom of the support column 23. A fixing hole 26 is also opened on the surface of the column fixing block 27. A second cutting edge 42 is opened at the bottom of the upper frame block 22.

[0044] Analysis of the above content: When installing the frame device 5, the column fixing block 27 is attached to the workbench device 3, and then screws are inserted into the fixing holes 26 of the column fixing block 27 to fix the frame device 5. When the installation cutter 9 rises to the top, the top of the installation cutter 9 will be embedded in the second cutting edge 42 at the bottom of the upper frame block 22 to improve safety and prevent workers from touching the frame device 5.

[0045] Example 6:

[0046] Please see Figure 1-5The present invention provides a technical solution based on Embodiment 1: The main frame device 2 includes a main frame 28, a front sealing plate 29, a bottom plate 30, a maintenance door 31, and a rear sealing plate 41. The top of the main frame 28 has an inclined structure. The front sealing plate 29 is welded and installed at the front end of the main frame 28, and the rear sealing plate 41 is welded and installed at the rear end of the main frame 28. A set of maintenance doors 31 is provided, and a set of maintenance doors 31 are respectively installed on the left and right sides of the main frame 28. The bottom plate 30 is installed at the bottom of the main frame 28.

[0047] Analysis of the above content: The front sealing plate 29, the bottom plate 30, the maintenance door 31 and the rear sealing plate 41 are for the purpose of installing the main frame 28. The maintenance door 31 is installed by hinges, which makes it easy to open and facilitates the maintenance of the components inside the main frame 28 by the staff.

[0048] Example 7:

[0049] Please see Figure 1-5 The present invention provides a technical solution based on Embodiment 1: the front sealing plate 29 has a rectangular structure, and an outlet 32 ​​is provided above the surface of the front sealing plate 29, the outlet 32 ​​having a rectangular structure.

[0050] Analysis of the above content: The outlet 32 ​​is provided above the surface of the front sealing plate 29 to facilitate the installation and discharge of the large discharge frame 34 and the small discharge frame 35, thereby achieving the purpose of convenient installation.

[0051] Example 8:

[0052] Please see Figure 1-5 The present invention provides a technical solution based on Embodiment 1: An installation beam 39 is welded to the front end of the main frame 28, and a discharge plate 33 is welded to the top of the installation beam 39. The discharge plate 33 has an inclined structure, and a large discharge frame 34 passes through the top of the discharge plate 33. The large discharge frame 34 is located directly below the discharge hood 12, and a small discharge frame 35 is provided at the front end of the large discharge frame 34.

[0053] Analysis of the above content: The crossbeam 39 is installed to support the discharge plate 33, and the discharge plate 33 is to facilitate the support of the large discharge frame 34 and the small discharge frame 35, so that the large discharge frame 34 and the small discharge frame 35 can achieve the purpose of sliding discharge. In use, the cut and crushed material 6 falls into the large discharge frame 34 below through the discharge cover 12. The large discharge frame 34 is installed at an inclined angle, so the cut and crushed material 6 can slide into the front end of the large discharge frame 34.

[0054] Example 9:

[0055] Please see Figure 1-5The present invention provides a technical solution based on Embodiment 1: threaded support bolts 36 and movable wheels 38 are installed at the four corners of the bottom of the base plate 30, and support feet 37 are installed at the bottom of the threaded support bolts 36, and the support feet 37 have a suction cup-like structure.

[0056] Analysis of the above content: The staff can move the device body 1 using the movable wheel 38. When fixing the position of the device body 1, the staff can use pliers to turn the nut on the support foot 37, thereby rotating the threaded support bolt 36. Then the bottom of the threaded support bolt 36 can be lowered, so that the support foot 37 supports the ground, and the bottom of the movable wheel 38 can be lifted off the ground. Finally, the device body 1 is supported by the support foot 37, and the suction cup-shaped support foot 27 has higher stability.

[0057] To further demonstrate the authenticity, inventiveness, and technical effectiveness of this solution, the following data is provided.

[0058] I. Data Support for Improving Work Efficiency

[0059] Cutting efficiency

[0060] Cutting method: The cutter is installed vertically using a pneumatic push rod, and the single cutting stroke time is about 0.5-1 second (the speed of the pneumatic push rod is adjustable, and one cutting cycle is completed per second under normal working conditions).

[0061] Processing capacity: Taking a standard plasma sediment block (approximately 20cm×10cm×5cm) as an example, 1-2 blocks can be cut at a time, and approximately 30-60 blocks can be processed per hour, which is 6-12 times more efficient than manual cutting (5-10 blocks per hour).

[0062] Discharge efficiency

[0063] Discharge path: The cut material slides out through the drop outlet → discharge outlet → discharge cover → large discharge frame → small discharge frame. The inclined structure design makes the material slide at a speed of about 0.3-0.5m / s, and the entire discharge time is ≤5 seconds, avoiding the time loss of manual collection.

[0064] II. Supporting data related to safety and loss control

[0065] Splash protection

[0066] Protective structure: The upper sealing cover and the splash guard form an L-shaped protective area. According to actual measurements, the material splash range during cutting is reduced from 1-2 meters during manual operation to less than 0.2 meters, and the splash loss rate is reduced from 10%-15% during conventional manual operation to less than 3%.

[0067] Sealing performance: The main storage frame is fixed to the workbench device by side mounting blocks and locking bolts, with a sealing gap of ≤0.5mm to prevent material leakage.

[0068] Loss control

[0069] Cutting precision: The installation precision of the cutter and the cutting edge is ≤0.2mm, ensuring uniform cutting of materials, reducing residue, and increasing material utilization rate from 70%-80% for manual operation to over 95%.

[0070] Material loss: The discharge hood adopts a funnel-shaped structure with a large discharge frame tilted at an angle of 15°-20°. When the material slides out, the residual amount is ≤1%, which is significantly reduced compared to manual scraping (residual amount 5%-10%).

[0071] III. Data Support for Operational Compliance and Convenience

[0072] Ergonomics

[0073] Height adjustment: The threaded support bolts at the bottom of the base plate can be adjusted to a height range of 5-10cm to accommodate different operator heights (160-185cm). The arm movement angle during operation is ≤45°, reducing labor intensity.

[0074] Mobility and Fixation: The moving wheels are 10cm in diameter, with a pushing resistance of ≤50N, allowing for easy movement by a single person; the support feet have suction cups with a diameter of 8cm, providing a load-bearing capacity of ≥500kg when fixed, ensuring equipment stability.

[0075] Maintenance and cleaning

[0076] Detachable parts: The inlet frame device, the cutter installation frame, the large outlet frame and other parts can be quickly disassembled (disassembly time ≤ 5 minutes) for easy cleaning and disinfection, in compliance with GMP hygiene standards.

[0077] Convenience of maintenance: The maintenance doors on both sides of the main frame open at an angle of ≥90°, and the internal components (such as pneumatic push rods and discharge plates) are easily accessible for maintenance, with a single maintenance time of ≤30 minutes.

[0078] IV. Supporting data on structural stability

[0079] load-bearing capacity

[0080] Frame assembly: The upper frame block is made of Q235 steel with a thickness of 10mm. The arc-shaped structure at both ends makes its load-bearing capacity ≥200kg. The support column has a diameter of 50mm and a compressive strength ≥1000N.

[0081] Main frame assembly: The main frame is made of 40mm×40mm square tube welded together. The top inclined structure has a load-bearing capacity of ≥500kg. The front sealing plate and rear sealing plate are 3mm thick to ensure the overall structure is stable.

[0082] pneumatic system parameters

[0083] Pneumatic push rod: Model SC-50×100, working pressure 0.4-0.6MPa, thrust ≥1000N, repeatability ±0.5mm, ensuring the stability and reliability of the cutting action.

[0084] Technical Effect Comparison Table

[0085]

[0086] VI. Data Source Explanation

[0087] Performance test data: Based on standard plasma precipitate blocks (density approximately 1.05 g / cm³, hardness approximately 20 Shore A) tested at 0.5 MPa pressure and 25°C.

[0088] Structural parameters: determined based on the actual design drawings of the device and material mechanics calculations, and the structural strength was verified by 3D modeling and finite element analysis.

[0089] Loss rate calculation: It is obtained by weighing the difference in material weight before and after cutting, and the average value is taken after 10 repeated tests.

[0090] The above data directly supports the technical effects of this invention, namely, "improving work efficiency, protecting product safety, reducing losses, and enhancing operational compliance," and all parameters can be verified through experiments and reproduced through engineering calculations.

[0091] The present invention comprises: 1. Device body; 2. Main frame device; 3. Workbench device; 4. Inlet frame device; 5. Frame device; 6. Material; 7. Movable cover; 8. Sliding seat; 9. Cutter mounting; 10. Pneumatic push rod; 11. Outlet; 12. Outlet cover; 13. First cutter opening; 14. Main storage frame; 15. Upper sealing cover; 16. Cutter movable opening; 17. Splash guard; 18. Stop bar; 19. Side mounting block; 20. Locking notch; 21. Locking bolt; 22. Upper frame block; 23. Support column; 24. Load-bearing base; 25. Load-bearing block; 26. Fixing hole; 27. Column fixing block; 28. Main frame; 29. ​​Front sealing plate; 30. Base plate; 31. Maintenance door; 32. Outlet; 33. Discharge plate; 34. Large discharge frame. 35. Small discharge frame; 36. Threaded support bolt; 37. Support foot; 38. Moving wheel; 39. Mounting beam; 40. Drop outlet; 41. Rear sealing plate; 42. Second cutting edge. All components are general standard parts or components known to those skilled in the art. Their structure and principle can be learned by those skilled in the art through technical manuals or conventional experimental methods. The problem solved by this invention is that existing methods for crushing raw materials for low-temperature precipitation of human blood protein in blood products result in splashing losses, extremely low efficiency, and high labor intensity. In this dissolution process, most of the operator's energy and time are consumed. This invention, through the combination of the above components, can improve work efficiency, protect product safety, minimize losses, and ensure compliance of product operation.

[0092] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0093] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A slicing-type plasma sedimentation and crushing machine, characterized in that: The device includes a main body (1), which includes a main frame device (2), a workbench device (3), an entry frame device (4), a frame device (5), and a material (6). The workbench device (3) is installed at an angle on top of the main frame device (2). The entry frame device (4) and the frame device (5) are installed on top of the workbench device (3). The frame device (5) is located directly above the entry frame device (4). The material (6) is placed inside the entry frame device (4). The workbench device (3) has a rectangular structure. The workbench device (3) has a first cutting edge (13) on its surface. The first cutting edge (13) has a rectangular structure. A movable cover (7) is welded to the bottom of the first cutting edge (13). The movable cover (7) has a rectangular structure and the top and the interior are a through structure. A sliding seat (8) is provided inside the movable cover (7). A set of pneumatic push rods (10) distributed symmetrically are installed at the bottom of the movable cover (7). The top driving end of the pneumatic push rod (10) is fixed to the sliding seat (8) by screws. A cutting tool (9) is installed on the top of the sliding seat (8).

2. The slicing-type plasma sedimentation and crushing machine according to claim 1, characterized in that: The workbench device (3) has an outlet (11) at the top and a discharge cover (12) at the bottom. The discharge cover (12) is located at the bottom of the outlet (11) and has a funnel-shaped structure. The outlet (11) is located in front of the first cutting edge (13).

3. The slicing-type plasma sedimentation and crushing machine according to claim 1, characterized in that: The entry frame device (4) includes a main storage frame (14) and an upper sealing cover (15). The upper sealing cover (15) is welded to the top front end of the main storage frame (14). The upper sealing cover (15) has a cutter access port (16) on its top and a splash guard (17) on its top. The splash guard (17) is located in front of the cutter access port (16). The upper sealing cover (15) and the splash guard (17) form an L-shaped structure.

4. A slicing-type plasma sedimentation and crushing machine according to claim 3, characterized in that: The main storage frame (14) has a rectangular structure. The bottom front end of the main storage frame (14) has a drop outlet (40). A set of baffles (18) is installed inside the main storage frame (14).

5. A slicing-type plasma sedimentation and crushing machine according to claim 3, characterized in that: The main storage frame (14) is provided with side mounting blocks (19) on both the left and right sides. The side mounting blocks (19) are rectangular in shape. The surface of the side mounting blocks (19) is provided with locking notches (20). Locking bolts (21) are installed on the surface of the locking notches (20).

6. A slicing-type plasma sedimentation and crushing machine according to claim 1, characterized in that: The frame device (5) includes an upper frame block (22), a support column (23), and a load-bearing base (24). The upper frame block (22) has a rectangular structure and arc-shaped structures at both ends. The load-bearing base (24) is provided in a set. The set of load-bearing bases (24) is symmetrically installed on the top of the upper frame block (22) by screws. The top of the load-bearing base (24) is welded with a load-bearing block (25). The top of the load-bearing base (24) is provided with a fixing hole (26). The bottom of the upper frame block (22) is provided with a main frame (28). The support column (23) is provided in a set. The set of support columns (23) is symmetrically installed on the bottom of the upper frame block (22). The bottom of the support column (23) is provided with a column fixing block (27). The surface of the column fixing block (27) is also provided with a fixing hole (26). The bottom of the upper frame block (22) is provided with a second cutting edge (42).

7. A slicing-type plasma sedimentation and crushing machine according to claim 1, characterized in that: The main frame device (2) includes a main frame (28), a front sealing plate (29), a bottom plate (30), a maintenance door (31), and a rear sealing plate (41). The top of the main frame (28) is inclined. The front sealing plate (29) is welded to the front end of the main frame (28), and the rear sealing plate (41) is welded to the rear end of the main frame (28). A set of maintenance doors (31) is provided. A set of maintenance doors (31) is installed on the left and right sides of the main frame (28) respectively by hinges. The bottom plate (30) is installed at the bottom of the main frame (28).

8. A slicing-type plasma sedimentation and crushing machine according to claim 7, characterized in that: The front sealing plate (29) has a rectangular structure, and an outlet (32) is provided above the surface of the front sealing plate (29). The outlet (32) has a rectangular structure.

9. A slicing-type plasma sedimentation and crushing machine according to claim 7, characterized in that: The main frame (28) has an installation beam (39) welded to its front end. The installation beam (39) has a discharge plate (33) welded to its top. The discharge plate (33) has an inclined structure. The top of the discharge plate (33) has a large discharge frame (34). The large discharge frame (34) is located directly below the discharge hood (12). The front end of the large discharge frame (34) has a small discharge frame (35).

10. A slicing-type plasma sedimentation and crushing machine according to claim 7, characterized in that: The bottom of the base plate (30) is equipped with threaded support bolts (36) and moving wheels (38) at the four corners. The bottom of the threaded support bolts (36) is equipped with support feet (37), which are suction cup-shaped structures.