A cutting machine tool for processing ai radiating fins

By using a cutting and collecting auxiliary component and an anti-inertial drop component, the problem of messy heat sink accumulation was solved, enabling centralized collection and precise drop of heat sinks, thus improving processing efficiency.

CN122142408APending Publication Date: 2026-06-05JIANGSU XIAOPENG MACHINE TOOL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
JIANGSU XIAOPENG MACHINE TOOL CO LTD
Filing Date
2026-03-26
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

In existing technologies, AI heat sinks are often cluttered and piled up after cutting, making them inconvenient to use and affecting subsequent processing efficiency.

Method used

By employing a cutting and collection auxiliary component and an anti-inertia drop component, the heat sinks are collected centrally and dropped precisely. Through the cooperation of the tray and positioning block, the heat sinks are ensured to be neatly arranged and their quantity controlled.

Benefits of technology

This improves the efficiency of subsequent processing of heat sinks, ensures that heat sinks are placed neatly, facilitates manual or robotic arm handling, and enables precise control over the number of heat sinks.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application belongs to the technical field of heat dissipation fin processing, in particular to a cutting machine tool for processing AI heat dissipation fins, which comprises a base, the upper end surface of the base is fixedly connected with a placing table on one side, the top of the placing table is provided with a cutting groove on one side, the inner cavity of the placing table is slidably connected with a sliding block on one side, the sliding block is rotatably provided with a blade on one side, and the blade penetrates through the cutting groove; and the cutting machine tool further comprises a feeding assembly. The cutting and collecting auxiliary assembly is used to realize the centralized collection of the cut heat dissipation fins. Since the multiple heat dissipation fins are arranged on the supporting plate in a unified orientation, the placing state is neat, which is convenient for subsequent manual or mechanical hand taking, and is conducive to improving the subsequent processing efficiency.
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Description

Technical Field

[0001] This invention belongs to the field of heat sink processing technology, specifically a cutting machine tool for processing AI heat sinks. Background Technology

[0002] AI heatsinks are heat dissipation materials used to address the high heat flux density and power consumption issues generated by artificial intelligence chips (such as GPUs and NPUs) under high loads. The manufacturing process of AI heatsinks involves first producing a grid-like substrate, which is then cut into multiple individual heatsinks.

[0003] Patent CN211804197U discloses a heat sink cutting machine tool for improving cutting efficiency. It includes a cutting table with a cutting device, which comprises a lifting platform and a cylinder for driving the lifting platform. The bottom surface of the lifting platform is higher than the upper surface of the cutting table, and a cutting blade is mounted on the lifting platform. Two conveyor rollers are rotatably mounted on the cutting table, with their axes parallel to the length direction of the cutting blade. A conveyor belt is wound between the two conveyor rollers. The cutting table includes a lever, a limit block, and a sensor for measuring the rotation angle of the lever. The lever rotatably engages with the cutting table, and a dial wheel is fitted onto the lever. Several counting teeth are arranged evenly along the circumference of the dial wheel on its side away from the lever, and these teeth mesh with the grid of the heat sink plate. This patent simplifies the operation process and improves cutting efficiency.

[0004] However, the above technical solutions still have the following shortcomings in practical applications: When cutting grid-like panels, they are usually fixed in place before being conveyed. The panels stop after moving a certain distance, and the cutting blade performs the cutting.

[0005] Since a single sheet of material can be cut into multiple individual heat sinks, collection boxes are often used to collect these fins. However, when multiple heat sinks fall into the collection box, they tend to pile up haphazardly. Since the cut heat sinks usually require further processing, the disorganized pile makes them difficult to retrieve, whether manually or using a robotic arm, thus affecting subsequent processing efficiency. Summary of the Invention

[0006] In order to overcome the shortcomings of the prior art and solve at least one of the technical problems mentioned in the background art, the present invention proposes a cutting machine tool for processing AI heat sinks.

[0007] The technical solution adopted by the present invention to solve its technical problem is: a cutting machine tool for processing AI heat sinks, including a base, a placement table fixedly connected to one side of the upper end face of the base, a cutting groove provided on one side of the top of the placement table, a slider slidably connected to one side of the inner cavity of the placement table, and a blade rotatably disposed on one side of the slider, the blade penetrating the cutting groove. It also includes a feeding assembly; The feeding assembly includes a positioning plate slidably connected to one side of the upper surface of the placement platform, and a clamping block is slidably connected to one side of the positioning plate; It also includes a cutting and collection auxiliary component; The cutting and collecting auxiliary component includes a slide block slidably connected to one side of the upper surface of the placement platform. A support column is slidably connected to one side of the upper surface of the slide block. A bracket is slidably connected to one side of the support column. Multiple slide rail plates are fixedly connected to one side of the bracket. Two threaded blocks are slidably connected to one side of the slide rail plates. A support plate is fixedly connected to one side of the threaded blocks. Pulleys are rotatably arranged on both sides of the support plate, and belts are meshed on the pulleys.

[0008] Preferably, one end of the slider is threadedly connected to a threaded rod four, both ends of which are rotatably mounted on the placement platform. A motor seven is fixedly connected to one side of the inner cavity of the placement platform, and the output end of the motor seven is fixedly connected to one end of the threaded rod four. A motor eight is fixedly connected to one side of the slider, and the output end of the motor eight is fixedly connected to the blade.

[0009] Preferably, a threaded rod six is ​​threadedly connected to one side of the positioning plate, and both ends of the threaded rod six are rotatably mounted on the placement platform. A motor nine is fixedly connected to one side of the upper surface of the placement platform, and the output end of the motor nine is fixedly connected to one end of the threaded rod six. A cylinder two is fixedly connected to one side of the positioning plate, and the piston end of the cylinder two is fixedly connected to one side of the clamping block.

[0010] Preferably, a threaded rod 7 is threadedly connected to one side of the slide block, and both ends of the threaded rod 7 are rotatably mounted on the base. A motor 10 is fixedly connected to one side of the upper surface of the base, and the output end of the motor 10 is fixedly connected to one end of the threaded rod 7. A threaded rod 5 is threadedly connected to one side of the support column, and both ends of the threaded rod 5 are rotatably mounted on the slide block. A motor 4 is fixedly connected to one side of the upper surface of the slide block, and the output end of the motor 4 is fixedly connected to one end of the threaded rod 5.

[0011] Preferably, a threaded rod is threadedly connected to one side of the bracket, and both ends of the threaded rod are rotatably mounted on the support column. A motor is fixedly connected to one side of the upper end of the support column, and the output end of the motor is fixedly connected to one end of the threaded rod.

[0012] Preferably, a bidirectional threaded rod is rotatably provided at both ends of one side of the slide rail plate, and the two sides of the bidirectional threaded rod are respectively threadedly connected to two threaded blocks. A motor is fixedly connected to one end of the slide rail plate, and the output end of the motor is fixedly connected to one end of the bidirectional threaded rod.

[0013] Preferably, a motor six is ​​fixedly connected to one side of the pallet, and the output end of the motor six is ​​fixedly connected to a pulley.

[0014] Preferably, it also includes an anti-inertial fall component; The anti-inertial fall assembly includes a transverse frame slidably connected to one side of the upper end face of the bracket. Two sliding rods are fixedly connected to both ends of one side of the transverse frame. A transverse block is slidably connected to the sliding rods. A cylinder is fixedly connected to the lower end face of the transverse block. A positioning block is fixedly connected to the piston end of the cylinder.

[0015] Preferably, one end of the transverse frame is threadedly connected to a threaded rod II, both ends of the threaded rod II are rotatably mounted on the bracket, one end of the bracket is fixedly connected to a motor II, and the output end of the motor II is fixedly connected to one end of the threaded rod II.

[0016] Preferably, a threaded rod three is threadedly connected to one side of the transverse block, and both ends of the threaded rod three are rotatably mounted on the transverse frame. A motor three is fixedly connected to one end of the transverse frame, and the output end of the motor three is fixedly connected to one end of the threaded rod three.

[0017] The beneficial effects of this invention are as follows: 1. The cutting machine tool for processing AI heat sinks described in this invention utilizes a cutting and collecting auxiliary component to achieve centralized collection of the cut heat sinks. Since multiple heat sinks are arranged in a uniform orientation on the tray, their placement is neat and tidy, facilitating subsequent manual or robotic handling and improving subsequent processing efficiency.

[0018] 2. The cutting machine tool for processing AI heat sinks described in this invention utilizes an anti-inertia drop component. When the heat sink is dropped from the end of the pallet via a belt, a positioning block presses down the corresponding heat sink. The pressed heat sink and the heat sink to its left will not move. Only the heat sink to the right of the positioning block will fall from the end of the pallet in sequence, thereby achieving precise control over the number of heat sinks falling and thus meeting different usage requirements. Attached Figure Description

[0019] The invention will now be further described with reference to the accompanying drawings.

[0020] Figure 1 This is a three-dimensional structural schematic diagram of the present invention; Figure 2 This is a three-dimensional structural diagram of the slide block; Figure 3 yes Figure 2 Enlarged view of a portion of point A in the middle; Figure 4 yes Figure 2 Enlarged view of a section at point B in the middle; Figure 5 This is a schematic diagram of the three-dimensional structure at the support column; Figure 6 This is a schematic diagram of the three-dimensional structure of the slide rail plate; Figure 7 This is a schematic diagram of the three-dimensional structure of the blade. Figure 8 This is a schematic diagram of the three-dimensional structure of the placement platform; Figure 9 yes Figure 8 Enlarged view of a section at point C; Figure 10 This is a schematic diagram of the three-dimensional structure of the belt.

[0021] In the diagram: 1. Placement platform; 2. Support column; 3. Slide block; 4. Motor 1; 5. Threaded rod 1; 6. Bracket; 7. Threaded rod 2; 8. Motor 2; 9. Horizontal movement frame; 10. Support plate; 11. Motor 3; 12. Threaded rod 3; 13. Slide rod; 14. Horizontal movement block; 15. Base; 16. Motor 4; 17. Cylinder 1; 18. Positioning block; 19. Slide rail plate; 20. Motor 5; 21. Bidirectional threaded rod; 22. Threaded block; 23. Belt; 24. Motor 6; 25. Pulley; 26. Motor 7; 27. Threaded rod 4; 28. Slider; 29. ​​Blade; 30. Motor 8; 31. Threaded rod 5; 32. Cutting groove; 33. Positioning plate; 34. Clamping block; 35. Cylinder 2; 36. Motor 9; 37. Threaded rod 6; 38. Motor 10; 39. Threaded rod 7. Detailed Implementation

[0022] The technical solution of the present invention will now be clearly and completely described 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.

[0023] Please refer to Figures 1-10 The present invention provides a technical solution: a cutting machine tool for processing AI heat sinks, including a base 15, a placement table 1 fixedly connected to one side of the upper end face of the base 15, a cutting groove 32 provided on one side of the top of the placement table 1, a slider 28 slidably connected to one side of the inner cavity of the placement table 1, and a blade 29 rotatably disposed on one side of the slider 28, the blade 29 penetrating the cutting groove 32. It also includes a feeding assembly; The feeding assembly includes a positioning plate 33 that is slidably connected to one side of the upper surface of the placement table 1, and a clamping block 34 is slidably connected to one side of the positioning plate 33; It also includes a cutting and collection auxiliary component; The cutting and collecting auxiliary component includes a slide block 3 slidably connected to one side of the upper surface of the placement platform 1. A support column 2 is slidably connected to one side of the upper surface of the slide block 3. A bracket 6 is slidably connected to one side of the support column 2. Multiple slide rail plates 19 are fixedly connected to one side of the bracket 6. Two threaded blocks 22 are slidably connected to one side of the slide rail plate 19. A support plate 10 is fixedly connected to one side of the threaded block 22. Pulleys 25 are rotatably installed on both sides of the support plate 10. A belt 23 is meshed on the pulleys 25.

[0024] In this embodiment, as Figure 2 , Figures 5-10 As shown, one end of the slider 28 is threadedly connected to a threaded rod 27. Both ends of the threaded rod 27 are rotatably mounted on the placement platform 1. A motor 26 is fixedly connected to one side of the inner cavity of the placement platform 1. The output end of the motor 26 is fixedly connected to one end of the threaded rod 27. A motor 30 is fixedly connected to one side of the slider 28. The output end of the motor 30 is fixedly connected to the blade 29.

[0025] A threaded rod 37 is threadedly connected to one side of the positioning plate 33. Both ends of the threaded rod 37 are rotatably mounted on the placement platform 1. A motor 36 is fixedly connected to one side of the upper surface of the placement platform 1. The output end of the motor 36 is fixedly connected to one end of the threaded rod 37. A cylinder 35 is fixedly connected to one side of the positioning plate 33. The piston end of the cylinder 35 is fixedly connected to one side of the clamping block 34.

[0026] A threaded rod 39 is threadedly connected to one side of the slide block 3. Both ends of the threaded rod 39 are rotatably mounted on the base 15. A motor 38 is fixedly connected to one side of the upper surface of the base 15. The output end of the motor 38 is fixedly connected to one end of the threaded rod 39. A threaded rod 31 is threadedly connected to one side of the support column 2. Both ends of the threaded rod 31 are rotatably mounted on the slide block 3. A motor 16 is fixedly connected to one side of the upper surface of the slide block 3. The output end of the motor 16 is fixedly connected to one end of the threaded rod 31.

[0027] A threaded rod 5 is threadedly connected to one side of the bracket 6. Both ends of the threaded rod 5 are rotatably mounted on the support column 2. A motor 4 is fixedly connected to one side of the upper end of the support column 2. The output end of the motor 4 is fixedly connected to one end of the threaded rod 5.

[0028] The slide rail plate 19 has a double-threaded rod 21 rotatably installed at both ends on one side. The two sides of the double-threaded rod 21 are threadedly connected to two threaded blocks 22 respectively. A motor 20 is fixedly connected to one end of the slide rail plate 19. The output end of the motor 20 is fixedly connected to one end of the double-threaded rod 21.

[0029] A motor 24 is fixedly connected to one side of the pallet 10, and the output end of the motor 24 is fixedly connected to the pulley 25.

[0030] Specifically, in existing technologies, when cutting grid-like panels, they are typically fixed first and then conveyed. The panels stop after moving a certain distance, and the cutting blade performs the cutting.

[0031] Since a single sheet of material can be cut into multiple individual heat sinks, collection boxes are often used to collect these fins. However, when multiple heat sinks fall into the collection box, they tend to pile up haphazardly. Since the cut heat sinks usually require further processing, the disorganized pile makes them difficult to retrieve, whether manually or using a robotic arm, thus affecting subsequent processing efficiency.

[0032] Therefore, in order to solve the above problems, the working principle of this embodiment is as follows: First, place the grid-shaped plate to be cut on the placement table 1 with the opening facing down, and make one end of the plate fit against one side of the positioning plate 33. Then, use cylinder 2 35 to drive the clamping block 34 to move laterally, and use the clamping block 34 to press and fix the plate.

[0033] Subsequently, by rotating threaded rod 39 driven by motor 10 38, threaded rod 31 driven by motor 4 16, and threaded rod 5 driven by motor 1 4, the position of bracket 6 in the x, y, and z axes is adjusted. Furthermore, rotating bidirectional threaded rod 21 driven by motor 5 20 adjusts the distance between the two support plates 10 on slide rail 19, aligning the two support plates 10 with the openings on both sides of the material, with the support plates 10 extending into the openings. Then, rotating threaded rod 37 driven by motor 9 36 causes positioning plate 33 to slide on placement table 1, moving the material on the placement table 1 until it stops after moving a certain distance. At this point, rotating threaded rod 27 driven by motor 7 26 causes slider 28 to slide within the cavity of placement table 1, causing blade 29 to move laterally and approach the material. Simultaneously, rotating blade 29 driven by motor 8 30 allows blade 29 to cut the material.

[0034] The cut heat sinks are placed on two trays 10. At this point, motor 6 24 drives pulley 25 to rotate, causing belt 23 to rotate. Belt 23 then moves the heat sink towards slide rail 19 until it is blocked. This process is repeated; each cut heat sink is placed on a tray 10 and, under the action of belt 23, adheres to the previous heat sink, resulting in multiple cut heat sinks arranged on the trays 10. After a sufficient number of heat sinks have been placed on the two trays 10, the position of bracket 6 is adjusted so that the empty tray 10 aligns with the material, and the cut heat sinks are picked up again. This achieves centralized collection of the cut heat sinks. Because multiple heat sinks are arranged in a uniform direction on the trays 10, their placement is neat and tidy, facilitating subsequent manual or robotic retrieval and improving processing efficiency.

[0035] In this embodiment, as Figures 2-4 As shown, it also includes an anti-inertial fall component; The anti-inertial fall assembly includes a transverse frame 9 slidably connected to one side of the upper end face of the bracket 6. Two ends of one side of the transverse frame 9 are fixedly connected to slide rods 13. A transverse block 14 is slidably connected to the slide rods 13. A cylinder 17 is fixedly connected to the lower end face of the transverse block 14. A positioning block 18 is fixedly connected to the piston end of the cylinder 17.

[0036] One end of the transverse frame 9 is threadedly connected to a threaded rod 7. Both ends of the threaded rod 7 are rotatably mounted on the bracket 6. One end of the bracket 6 is fixedly connected to a motor 8. The output end of the motor 8 is fixedly connected to one end of the threaded rod 7.

[0037] A threaded rod 12 is threadedly connected to one side of the transverse block 14. Both ends of the threaded rod 12 are rotatably mounted on the transverse frame 9. A motor 11 is fixedly connected to one end of the transverse frame 9. The output end of the motor 11 is fixedly connected to one end of the threaded rod 12.

[0038] Specifically, in the above embodiments, although the tray 10 can be used to neatly place the cut heat sinks, when it is necessary to remove the heat sinks from the tray 10, the belt 23 is still needed to transport the heat sinks to the end of the tray 10, and then let the heat sinks fall from the end of the tray 10. However, in some cases, in order to meet the actual use requirements, only a fixed number of heat sinks need to fall from the tray 10. When the heat sinks move on the tray 10, if the number of falling is controlled by controlling the start and stop of the belt 23, when the belt 23 stops, the subsequent heat sinks are likely to fall together due to inertia, making it difficult to accurately control the number of heat sinks falling.

[0039] Therefore, in order to solve the above problems, the working principle of this embodiment is as follows: First, motor 8 drives threaded rod 7 to rotate, causing transverse frame 9 to move laterally on bracket 6, aligning it with different trays 10. Then, motor 11 drives threaded rod 12 to rotate, causing transverse block 14 to move laterally on slide rod 13, aligning positioning block 18 with a designated heat sink. Cylinder 17 then lowers positioning block 18, pressing down on the heat sink. At this point, driving belt 23 will prevent the pressed heat sink and the heat sink to its left from moving; only the heat sink to the right of positioning block 18 will fall sequentially from the end of tray 10, allowing precise control over the number of falling heat sinks and meeting different usage requirements.

[0040] Working principle: First, the grid-shaped plate to be cut is placed on the placement table 1 with the opening facing down, and one end of the plate is attached to one side of the positioning plate 33. Then, the cylinder 35 drives the clamping block 34 to move laterally, and the plate is pressed and fixed by the clamping block 34.

[0041] Subsequently, by rotating threaded rod 39 driven by motor 10 38, threaded rod 31 driven by motor 4 16, and threaded rod 5 driven by motor 1 4, the position of bracket 6 in the x, y, and z axes is adjusted. Furthermore, rotating bidirectional threaded rod 21 driven by motor 5 20 adjusts the distance between the two support plates 10 on slide rail 19, aligning the two support plates 10 with the openings on both sides of the material, with the support plates 10 extending into the openings. Then, rotating threaded rod 37 driven by motor 9 36 causes positioning plate 33 to slide on placement table 1, moving the material on the placement table 1 until it stops after moving a certain distance. At this point, rotating threaded rod 27 driven by motor 7 26 causes slider 28 to slide within the cavity of placement table 1, causing blade 29 to move laterally and approach the material. Simultaneously, rotating blade 29 driven by motor 8 30 allows blade 29 to cut the material.

[0042] The cut heat sinks are placed on two trays 10. At this point, motor 6 24 drives pulley 25 to rotate, causing belt 23 to rotate. Belt 23 then moves the heat sink towards slide rail 19 until it is blocked. This process is repeated; each cut heat sink is placed on a tray 10 and, under the action of belt 23, adheres to the previous heat sink, resulting in multiple cut heat sinks arranged on the trays 10. After a sufficient number of heat sinks have been placed on the two trays 10, the position of bracket 6 is adjusted so that the empty tray 10 aligns with the material, and the cut heat sinks are picked up again. This achieves centralized collection of the cut heat sinks. Because multiple heat sinks are arranged in a uniform direction on the trays 10, their placement is neat and tidy, facilitating subsequent manual or robotic retrieval and improving processing efficiency.

[0043] Motor 28 drives threaded rod 27 to rotate, causing transverse frame 9 to move laterally on bracket 6, aligning it with different trays 10. Then, motor 31 drives threaded rod 312 to rotate, causing transverse block 14 to move laterally on slide rod 13, aligning positioning block 18 with a designated heat sink. Cylinder 17 then lowers positioning block 18, pressing down on the heat sink. At this point, driving belt 23 will prevent the pressed heat sink and the heat sink to its left from moving; only the heat sink to the right of positioning block 18 will fall sequentially from the end of tray 10, allowing precise control over the number of heat sinks falling and meeting different usage requirements.

[0044] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. A cutting machine tool for processing AI heat sinks, comprising a base (15), characterized in that: A placement platform (1) is fixedly connected to one side of the upper end face of the base (15). A cutting groove (32) is provided on one side of the top of the placement platform (1). A slider (28) is slidably connected to one side of the inner cavity of the placement platform (1). A blade (29) is rotatably provided on one side of the slider (28). The blade (29) penetrates the cutting groove (32). It also includes a feeding assembly; The feeding assembly includes a positioning plate (33) slidably connected to one side of the upper surface of the placement table (1), and a clamping block (34) is slidably connected to one side of the positioning plate (33). It also includes a cutting and collection auxiliary component; The cutting and collecting auxiliary component includes a slide (3) slidably connected to one side of the upper surface of the placement platform (1), a support column (2) slidably connected to one side of the upper surface of the slide (3), a bracket (6) slidably connected to one side of the support column (2), a plurality of slide rail plates (19) fixedly connected to one side of the bracket (6), two threaded blocks (22) slidably connected to one side of the slide rail plate (19), a support plate (10) fixedly connected to one side of the threaded block (22), and pulleys (25) rotatably arranged on both sides of the support plate (10), with belts (23) meshing on the pulleys (25).

2. The cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: One end of the slider (28) is threadedly connected to a threaded rod four (27), both ends of the threaded rod four (27) are rotatably mounted on the placement platform (1), a motor seven (26) is fixedly connected to one side of the inner cavity of the placement platform (1), the output end of the motor seven (26) is fixedly connected to one end of the threaded rod four (27), a motor eight (30) is fixedly connected to one side of the slider (28), and the output end of the motor eight (30) is fixedly connected to the blade (29).

3. The cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: The positioning plate (33) is threaded to one side with a threaded rod six (37). Both ends of the threaded rod six (37) are rotatably mounted on the placement platform (1). The upper surface of the placement platform (1) is fixedly connected to a motor nine (36). The output end of the motor nine (36) is fixedly connected to one end of the threaded rod six (37). The positioning plate (33) is fixedly connected to a cylinder two (35). The piston end of the cylinder two (35) is fixedly connected to one side of the pressing block (34).

4. The cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: The slide (3) is threaded with a threaded rod seven (39) on one side. Both ends of the threaded rod seven (39) are rotatably mounted on the base (15). The upper surface of the base (15) is fixedly connected with a motor ten (38). The output end of the motor ten (38) is fixedly connected to one end of the threaded rod seven (39). The support column (2) is threaded with a threaded rod five (31) on one side. Both ends of the threaded rod five (31) are rotatably mounted on the slide (3). The upper surface of the slide (3) is fixedly connected with a motor four (16). The output end of the motor four (16) is fixedly connected to one end of the threaded rod five (31).

5. The cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: The support (6) is threaded to one side with a threaded rod (5), both ends of which are rotatably mounted on the support column (2). The upper end of the support column (2) is fixedly connected to a motor (4), and the output end of the motor (4) is fixedly connected to one end of the threaded rod (5).

6. The cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: The slide rail plate (19) has a two-way threaded rod (21) rotatably installed at both ends on one side. The two-way threaded rod (21) is threadedly connected to two threaded blocks (22) on both sides respectively. A motor five (20) is fixedly connected to one end of the slide rail plate (19). The output end of the motor five (20) is fixedly connected to one end of the two-way threaded rod (21).

7. A cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: A motor six (24) is fixedly connected to one side of the pallet (10), and the output end of the motor six (24) is fixedly connected to the pulley (25).

8. The cutting machine tool for processing AI heat sinks according to claim 1, characterized in that: It also includes anti-inertial fall components; The anti-inertial fall assembly includes a transverse frame (9) slidably connected to one side of the upper end face of the bracket (6). A slide rod (13) is fixedly connected to both ends of one side of the transverse frame (9). A transverse block (14) is slidably connected to the slide rod (13). A cylinder (17) is fixedly connected to the lower end face of the transverse block (14). A positioning block (18) is fixedly connected to the piston end of the cylinder (17).

9. A cutting machine tool for processing AI heat sinks according to claim 8, characterized in that: One end of the transverse frame (9) is threadedly connected to a threaded rod (7), both ends of which are rotatably mounted on the bracket (6). One end of the bracket (6) is fixedly connected to a motor (8), and the output end of the motor (8) is fixedly connected to one end of the threaded rod (7).

10. A cutting machine tool for processing AI heat sinks according to claim 8, characterized in that: The transverse block (14) is threadedly connected to a threaded rod three (12) on one side. Both ends of the threaded rod three (12) are rotatably mounted on the transverse frame (9). One end of the transverse frame (9) is fixedly connected to a motor three (11). The output end of the motor three (11) is fixedly connected to one end of the threaded rod three (12).