Dicing apparatus
By designing a cutting device that utilizes rotation and lifting components to achieve automated cutting, the problem of low efficiency in manual cutting is solved, resulting in efficient and regular cutting.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HARBIN FUERJIA TECH CO LTD
- Filing Date
- 2025-04-23
- Publication Date
- 2026-06-19
Smart Images

Figure CN224374198U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of processing equipment technology, specifically to a cutting device. Background Technology
[0002] In the preparation of pharmaceuticals or cosmetics, various liquid materials are required to be placed in a square tray for cross-linking due to process requirements. After cross-linking, a large, highly elastic, and highly viscous square solid material is formed. The solid material is then processed to obtain the desired finished pharmaceutical or cosmetic product.
[0003] To improve processing efficiency, solid materials in a pallet are often cut into smaller cubes before processing. However, there is currently no mature equipment or device for cutting solid materials in bulk, so manual cutting is the only option, resulting in low efficiency.
[0004] Therefore, how to solve or improve the problem of low efficiency when manually cutting solid materials has become an important technical problem for those skilled in the art. Utility Model Content
[0005] In view of this, this application provides a cutting device to solve or improve the problem of low efficiency when manually cutting whole solid materials.
[0006] In a first aspect, this application provides a slicing device, comprising:
[0007] The platform is equipped with a placement area for placing trays containing materials.
[0008] A rotating component is connected to the placement platform and adapted to drive the placement platform to rotate between a first position and a second position, wherein the placement platform rotates 90° from the first position to the second position;
[0009] A cutting assembly includes a plurality of blades arranged horizontally in sequence, the blades being adapted for downward cutting;
[0010] A lifting assembly, connected to the cutting assembly, is adapted to drive the cutting assembly to move up and down between a third position and a fourth position.
[0011] With the cutter assembly in the third position, each of the blades is positioned above the placement area;
[0012] When the cutting assembly is in the fourth position, each of the blades abuts against the placement area.
[0013] Optionally, it also includes:
[0014] The scraper has multiple through holes for the blades to pass through, each through hole corresponding to one of the blades.
[0015] With the cutter assembly in the third position, the scraper is located between the cutter assembly and the placement area;
[0016] When the cutting assembly is in the fourth position, the blades pass through the perforations one by one and abut against the placement area.
[0017] Optionally, when the cutter assembly is in the fourth position, the sidewall of the blade is in contact with the inner wall of the perforation.
[0018] Optionally, the width of the perforation gradually increases from bottom to top, and when the cutter assembly is in the fourth position, the sidewall of the blade is in contact with the bottom of the inner wall of the perforation.
[0019] Optionally, it also includes:
[0020] A first limiting plate is disposed on the placement platform;
[0021] A first push plate and a first drive assembly are provided. The first drive assembly is connected to the placement platform. The first push plate is connected to the first drive assembly, and the first drive assembly can drive the first push plate to move closer to or away from the first limiting plate.
[0022] When the tray is placed in the placement area and the first push plate moves close to the first limiting plate, the first push plate and the first limiting plate can clamp the tray.
[0023] Optionally, it also includes:
[0024] A second limiting plate is disposed on the placement platform and is perpendicular to the first limiting plate;
[0025] A second push plate and a second drive assembly are connected to the placement platform. The second push plate is connected to the second drive assembly, and the second drive assembly can drive the second push plate to move closer to or away from the second limiting plate.
[0026] When the tray is placed in the placement area and the second push plate moves close to the second limiting plate, the second push plate and the second limiting plate can clamp the tray.
[0027] Optionally, the first drive assembly includes a first cylinder, which is disposed on the placement platform and connected to the first push plate. The first cylinder is used to drive the first push plate to slide closer to or away from the first limiting plate.
[0028] The second drive assembly includes a second cylinder, which is disposed on the placement platform and connected to the second push plate. The second cylinder is used to drive the second push plate to move closer to or away from the second limiting plate.
[0029] Optionally, the lifting assembly includes:
[0030] A linear module is connected to the cutter assembly and is used to drive the cutter assembly to move along the length direction of the linear module;
[0031] The first electric cylinder and the second electric cylinder are respectively connected to the two ends of the linear module. Both the first electric cylinder and the second electric cylinder are used to drive the linear module to lift and lower. The first electric cylinder and the second electric cylinder are respectively located on both sides of the cutter assembly.
[0032] Optionally, the rotating component includes:
[0033] A rotating shaft is vertically positioned and connected to the placement platform.
[0034] An electric motor is connected to the rotating shaft and is adapted to drive the rotating shaft to rotate.
[0035] Optionally, the cutter assembly further includes:
[0036] The frame, to which each of the blades is connected, and arranged sequentially along the frame;
[0037] A connecting frame is provided, and each of the aforementioned frames is connected to the connecting frame, which in turn is connected to the lifting assembly.
[0038] This application provides a slicing device, including a body, a placement platform rotating assembly, a cutting assembly, and a lifting assembly. A placement area on the placement platform is used to place a tray containing materials. The rotating assembly, mounted on the body and connected to the placement platform, drives the placement platform to rotate between a first position and a second position. When the placement platform rotates from the first position to the second position, or from the second position to the first position, the placement platform rotates 90°. The cutting assembly includes multiple blades arranged laterally in sequence. Each blade is capable of cutting downwards. The lifting assembly is connected to the cutting assembly, thereby driving the cutting assembly to move up and down between a third position and a fourth position. When the cutting assembly rises to the third position, the blades of the cutting assembly are above the placement area; when the cutting assembly descends to the fourth position, the blades of the cutting assembly lower to abut against the placement area.
[0039] When cutting a whole piece of material in a tray, a rotating assembly rotates the placement platform to the first position, and a lifting assembly raises the cutting assembly to the third position. The tray is then placed on the placement area of the platform, and the lifting assembly lowers the cutting assembly to the fourth position, where the blades perform the first cut, cutting the material into strips. After cutting, the lifting assembly raises the cutting assembly to the third position, and the rotating assembly rotates the placement platform 90° to the second position. The lifting assembly then lowers the cutting assembly to the fourth position, where the blades perform a second cut, with the two cuts perpendicular to each other, thus cutting the material into cubes. This setup requires only one rotation and two cuts to cut a whole piece of material into cubes, making it more efficient than manual cutting. Attached Figure Description
[0040] To more clearly illustrate the technical solutions in the specific embodiments or related technologies of this application, the drawings used in the description of the specific embodiments or related technologies will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.
[0041] Figure 1 This is a schematic diagram of the structure of a slicing device according to an embodiment of this application;
[0042] Figure 2 This is a schematic diagram of the scraper structure of a slicing device according to an embodiment of this application;
[0043] Figure 3 This is a cross-sectional schematic diagram of the scraper of a slicing device according to an embodiment of this application;
[0044] Figure 4 This is a schematic diagram of the cutter assembly structure of a slicing device according to an embodiment of this application.
[0045] Explanation of reference numerals in the attached figures:
[0046] 1. Placement platform; 2. Rotating assembly; 201. Rotating shaft; 202. Motor; 3. Cutting assembly; 301. Blade; 302. Frame; 303. Connecting frame; 4. Lifting assembly; 401. Linear module; 402. First electric cylinder; 403. Second electric cylinder; 5. Scraper; 51. Perforation; 6. First limiting plate; 7. First push plate; 8. First cylinder; 9. Second limiting plate; 10. Second push plate; 11. Second cylinder; 12. Electrical control box; 13. First control switch; 14. Second control switch; 15. Third control switch; 16. Fourth control switch; 17. Fifth control switch; 18. Tray. Detailed Implementation
[0047] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.
[0048] The following is combined Figures 1 to 4 This describes an embodiment of the present application.
[0049] According to embodiments of this application, in one aspect, a slicing device is provided, such as... Figure 1 As shown, it includes a machine body, a placement platform 1, a rotating assembly 2, a cutting assembly 3, and a lifting assembly 4. The placement platform 1 is provided with a placement area for placing a tray 18 containing materials.
[0050] The rotating assembly 2 is mounted on the machine body and connected to the placement platform 1, enabling the rotating assembly 2 to drive the placement platform 1 to rotate between a first position and a second position. After the tray 18 is placed in the placement area on the placement platform 1, rotating the placement platform 1 using the rotating assembly 2 allows the tray 18 to rotate along with the placement platform 1. When the placement platform 1 rotates from the first position to the second position, or from the second position to the first position, the placement platform 1 rotates 90°.
[0051] like Figure 4 As shown, the cutter assembly 3 includes multiple blades 301 arranged horizontally in sequence. Each blade 301 is vertically arranged, thus enabling it to cut downwards.
[0052] The lifting assembly 4 is connected to the cutting assembly 3, thereby enabling the lifting assembly 4 to drive the cutting assembly 3 to move up and down between the third position and the fourth position. When the cutting assembly 3 is raised to the third position, the blade 301 of the cutting assembly 3 is located above the placement area. When the cutting assembly 3 is lowered to the fourth position, the blade 301 of the cutting assembly 3 is lowered to abut against the placement area.
[0053] Thus, when cutting the whole piece of material in the tray 18, the rotating component 2 is used to rotate the placement platform 1 to the first position, and the lifting component 4 is used to raise the cutting component 3 to the third position. Then, the tray 18 is placed in the placement area on the placement platform 1, and the lifting component 4 is used to lower the cutting component 3 to the fourth position, so that each blade 301 performs the first cut on the material in the tray 18, cutting the material into strips.
[0054] After cutting, the lifting assembly 4 is used to raise the cutting assembly 3 to the third position, and the rotating assembly 2 is used to rotate the placement platform 1 by 90° to the second position. Then, the lifting assembly 4 is used to lower the cutting assembly 3 to the fourth position, so that each blade 301 cuts the material a second time. The two cutting lines are perpendicular, thus cutting the material into square shapes.
[0055] With this setup, only one rotation and two cuts are needed to cut the entire material into squares, which is more efficient than manual cutting.
[0056] Moreover, compared to manual cutting, the cut square-shaped materials are more regular and the dimensions are more precise.
[0057] As an optional embodiment, such as Figure 1 As shown, the slicing device also includes a scraper 5, which can be connected to the main body or to the lifting assembly 4. The scraper 5 is horizontally positioned.
[0058] like Figure 2 As shown, multiple perforations 51 are provided on the scraper 5, and the perforations 51 correspond one-to-one with the blades 301 of the blade 301 assembly.
[0059] When the cutter assembly 3 is in the third position, the scraper 5 is located between the cutter assembly 3 and the placement area, and when the cutter assembly 3 is in the fourth position, each blade 301 passes through a corresponding perforation 51 and abuts against the placement area.
[0060] Thus, when the tray 18 containing materials is placed in the placement area and the cutter assembly 3 is in the fourth position, the blade 301 of the cutter assembly 3 cuts the material in the tray 18 once. Afterwards, when the lifting assembly 4 raises the cutter assembly 3 to the third position, the blade 301 leaves the perforation 51. At this time, the scraper 5 prevents material from sticking to the blade 301.
[0061] In a further embodiment, when the cutter assembly 3 is in the fourth position, the two sidewalls of the blade 301 are in contact with the inner wall of the perforation 51.
[0062] Thus, after the material in the tray 18 is cut once using the blade 301 of the cutting assembly 3, when the cutting assembly 3 is raised to the third position using the lifting assembly 4, the blade 301 leaves the perforation 51. Since the two sidewalls of the blade 301 are in contact with the inner wall of the perforation 51, any material fragments adhering to the sidewalls of the blade 301 are blocked by the scraper 5 and will not enter the perforation 51 as the blade 301 rises. This scrapes off the material fragments adhering to the sidewalls of the blade 301, preventing material adhering to the sidewalls of the blade 301 from affecting the next cut.
[0063] In some embodiments, such as Figure 3As shown, the width of the perforation 51 gradually increases from bottom to top. When the cutter assembly 3 descends from the third position to the fourth position, as long as the blade 301 can enter the top of the perforation 51, it can pass through the perforation 51 under the guidance of the side wall of the perforation 51 as it continues to descend. At this time, the side wall of the blade 301 is in contact with the bottom of the inner wall of the perforation 51. When the cutter assembly 3 rises from the fourth position to the third position, the material fragments adhering to the side walls of the blade 301 are blocked by the scraper 5 and will not enter the perforation 51 as the blade 301 rises. This scrapes off the material fragments adhering to the side walls of the blade 301, preventing material adhering to the side walls of the blade 301 from affecting the next cut.
[0064] This setup makes installation easier. It also prevents the blade 301 from shifting due to prolonged use, thus avoiding inaccurate passage through the perforation 51.
[0065] As an optional implementation method, such as Figure 1 As shown, the slicing device also includes a first limiting plate 6, a first push plate 7, and a first driving assembly. The first limiting plate 6 is fixedly mounted on the placement platform 1, and the first driving assembly is connected to the placement platform 1. The first push plate 7 is connected to the first driving assembly, and the first driving assembly can drive the first push plate 7 to move closer to or away from the first limiting plate 6.
[0066] After the pallet 18 containing the materials is placed in the placement area, the pallet 18 abuts against the first limiting plate 6. Then, the first push plate 7 is driven to approach the first limiting plate 6 until the first push plate 7 abuts against the side of the pallet 18 away from the first limiting plate 6. The first push plate 7 and the first limiting plate 6 clamp the pallet 18, thereby fixing the pallet 18 and preventing it from leaving the placement area.
[0067] In an optional embodiment, the first driving assembly includes a first cylinder 8, the cylinder body of which is mounted on the placement platform 1. The piston rod of the first cylinder 8 points towards the first limiting plate 6. A first push plate 7 is connected to the piston rod of the first cylinder 8, so that when the piston rod of the first cylinder 8 moves, it drives the first push plate 7 to move closer to or away from the first limiting plate 6. In this way, the first cylinder 8 can drive the first push plate 7 to move closer to or away from the first limiting plate 6.
[0068] In a further embodiment, such as Figure 1 As shown, the slicing device also includes a second limiting plate 9, a second push plate 10, and a second driving assembly. The second limiting plate 9 is fixedly mounted on the placement platform 1, and the second driving assembly is connected to the placement platform 1. The second push plate 10 is connected to the second driving assembly, which allows the second push plate 10 to move closer to or further away from the second limiting plate 9.
[0069] After the pallet 18 containing the materials is placed in the placement area, the first side of the pallet 18 abuts against the first limiting plate 6, and the second side of the pallet 18 adjacent to the first side abuts against the second limiting plate 9. Then, the first drive assembly drives the first push plate 7 to move closer to the first limiting plate 6 until the first push plate 7 abuts against the side of the pallet 18 opposite to the first limiting plate 6. Simultaneously, the second drive assembly drives the second push plate 10 to move closer to the second limiting plate 9 until the second push plate 10 abuts against the side of the pallet 18 opposite to the second limiting plate 9. Thus, the first push plate 7 and the second push plate 10 simultaneously press the pallet 18 in different directions, resulting in better stability of the pallet 18.
[0070] In optional embodiments, such as Figure 1 As shown, the second drive assembly includes a second cylinder 11, the cylinder body of which is mounted on the placement platform 1. The piston rod of the second cylinder 11 points towards the second limiting plate 9. A second push plate 10 is connected to the piston rod of the second cylinder 11, so that when the piston rod of the second cylinder 11 moves, it drives the second push plate 10 to move closer to or away from the second limiting plate 9. In this way, the second cylinder 11 can drive the second push plate 10 to move closer to or away from the second limiting plate 9.
[0071] In some embodiments, the first limiting plate 6 and the second limiting plate 9 are vertically connected, so that the first limiting plate 6 and the second limiting plate 9 form a 90° angle. For a square tray 18, one of the tray 18 can be placed between the first limiting plate 6 and the second limiting plate 9, so that the two adjacent side walls of the tray 18 abut against the first limiting plate 6 and the second limiting plate 9 respectively.
[0072] As an optional embodiment, such as Figure 1 As shown, the lifting assembly 4 includes a linear module 401, a first electric cylinder 402, and a second electric cylinder 403.
[0073] The linear module 401 is a commonly used mechanical device that converts rotary motion into linear motion. Its slider enables the linear module 401 to slide linearly along its length. The cutter assembly 3 is connected to the slider of the linear module 401, so that the linear module 401 can drive the cutter assembly 3 to move along the length of the linear module 401.
[0074] A first electric cylinder 402 is vertically disposed on the first side of the cutter assembly 3, and a second electric cylinder 403 is vertically disposed on the second side of the cutter assembly 3. The first electric cylinder 402 and the second electric cylinder 403 are disposed opposite each other on both sides of the cutter assembly 3. The movable part of the first electric cylinder 402 is connected to the first end of the linear module 401, and the movable end of the second electric cylinder 403 is connected to the second end of the linear module 401. Thus, when the first electric cylinder 402 and the second electric cylinder 403 work synchronously, they can push the linear module 401 to rise and fall, thereby driving the cutter assembly 3 to rise and fall.
[0075] Thus, when cutting the whole piece of material in the tray 18, the rotating component 2 is used to rotate the placement platform 1 to the first position, at which time the cutting component 3 is located directly above the placement area. The tray 18 is placed in the placement area on the placement platform 1, and the first electric cylinder 402 and the second electric cylinder 403 work synchronously, causing the cutting component 3 to descend to the fourth position, so that each blade 301 performs the first cut on the material in the tray 18, cutting the material into strips.
[0076] After cutting is completed, the first electric cylinder 402 and the second electric cylinder 403 work synchronously, causing the cutter assembly 3 to rise to the third position. The rotating assembly 2 then rotates the placement platform 1 by 90° to the second position. Then, the first electric cylinder 402 and the second electric cylinder 403 work synchronously, causing the cutter assembly 3 to fall to the fourth position. Thus, each blade 301 performs a second cut on the material. The two cut lines are perpendicular, thereby cutting the material into square shapes.
[0077] The linear module 401 is horizontally positioned, enabling it to drive the cutter assembly 3 to move horizontally between the first electric cylinder 402 and the second electric cylinder 403. This allows the linear module 401 to fine-tune the horizontal position of the cutter assembly 3, ensuring it is positioned directly above the placement area.
[0078] As an optional embodiment, such as Figure 1 As shown, the rotating assembly 2 includes a rotating shaft 201 and a motor 202. The rotating shaft 201 is vertically arranged and connected to the placement platform 1, while the placement platform 1 is horizontally arranged. The rotating shaft 201 is perpendicular to the placement platform 1. Thus, when the rotating shaft 201 rotates, it can drive the placement platform 1 to rotate horizontally.
[0079] The motor 202 is connected to the rotating shaft 201, so that the motor 202 can drive the rotating shaft 201 to rotate, thereby driving the placement platform 1 to rotate horizontally.
[0080] Specifically, when cutting the whole piece of material in the tray 18, the motor 202 drives the rotating shaft 201 to rotate until the placement platform 1 rotates horizontally to the first position and stops. The lifting component 4 is then used to raise the cutting component 3 to the third position. Then, the tray 18 is placed in the placement area on the placement platform 1, and the lifting component 4 is used to lower the cutting component 3 to the fourth position, so that each blade 301 performs the first cut on the material in the tray 18, cutting the material into strips.
[0081] After cutting is completed, the lifting assembly 4 is used to raise the cutting assembly 3 to the third position, and the motor 202 drives the rotating shaft 201 to rotate until the placement platform 1 rotates horizontally by 90° to the second position and stops. Then, the lifting assembly 4 is used to lower the cutting assembly 3 to the fourth position, so that each blade 301 cuts the material a second time. The two cutting lines are perpendicular, thus cutting the material into square shapes.
[0082] As an optional embodiment, such as Figure 4 As shown, the cutter assembly 3 also includes a frame 302 and a connecting bracket 303. The frame 302 includes a horizontal bar, a first vertical bar, and a second vertical bar. The first vertical bar is connected to the first end of the horizontal bar and is perpendicular to the horizontal bar, and the second vertical bar is connected to the second end of the horizontal bar and is perpendicular to the horizontal bar. Thus, the frame 302 as a whole is inverted U-shaped.
[0083] Each blade 301 is vertically connected to the crossbar, so that each blade 301 is arranged sequentially along the length of the crossbar and is parallel to the first vertical bar or the first and second vertical bars.
[0084] The length of the crossbar should be greater than the width of the scraper 5. When the cutter assembly 3 is in the fourth position, each blade 301 passes through a corresponding perforation 51 and abuts against the placement area. At this time, the first and second vertical bars are located on both sides of the scraper 5, respectively.
[0085] Each frame 302 is connected to a connecting frame 303, and they are arranged sequentially along the length of the connecting frame 303. The connecting frame 303 is connected to the slider of the linear module 401. Thus, the connecting frame 303 is connected to the lifting assembly 4 through the linear module 401. The lifting assembly 4 drives the linear module 401 to rise and fall, which in turn drives the connecting frame 303 to rise and fall, and consequently drives the frame 302 and even the blade 301 to rise and fall.
[0086] In some combined embodiments, such as Figure 1 As shown, the placement platform 1 is provided with a placement area, and the placement platform 1 is connected to the motor 202 via a rotating shaft 201.
[0087] The placement platform 1 is equipped with a first limiting plate 6, a first push plate 7, a first cylinder 8, a second limiting plate 9, a second push plate 10, and a second cylinder 11. The first limiting plate 6 is fixedly mounted on the placement platform 1, and a first driving assembly can drive the first push plate 7 to move closer to or away from the first limiting plate 6. The second limiting plate 9 is fixedly mounted on the placement platform 1, and a second driving assembly can drive the second push plate 10 to move closer to or away from the second limiting plate 9.
[0088] A first electric cylinder 402 and a second electric cylinder 403 are vertically mounted on both sides of the placement platform 1. The movable part of the first electric cylinder 402 is connected to the first end of the linear module 401, and the movable part of the second electric cylinder 403 is connected to the second end of the linear module 401. The cutter assembly 3 is connected to the linear module 401 and is located above the placement area.
[0089] One end of the scraper 5 is connected to the cylinder body of the first electric cylinder 402, and the other end is connected to the cylinder body of the second electric cylinder 403. The scraper 5 is provided with a through hole 51 for the blade 301 of the cutting assembly 3 to pass through. The scraper 5 is located between the straight module 401 and the placement area.
[0090] When cutting the whole piece of material in the tray 18, the motor 202 drives the rotating shaft 201 to rotate, thereby driving the placement platform 1 to rotate to the first position, at which time the blade 301 of the cutting assembly 3 is located directly above the placement area. The tray 18 containing the material is placed in the placement area, at which time the tray 18 abuts against the first limiting plate 6 and the second limiting plate 9 respectively. The first cylinder 8 drives the first push plate 7 to move closer to the first limiting plate 6 to press the tray 18 firmly, and the second cylinder 11 drives the second push plate 10 to move closer to the second limiting plate 9 to further press the tray 18 firmly.
[0091] The first electric cylinder 402 and the second electric cylinder 403 work synchronously to lower the cutter assembly 3 to the fourth position, so that each blade 301 performs the first cut on the material in the tray 18, cutting the material into strips. Then, the first electric cylinder 402 and the second electric cylinder 403 work synchronously to raise the cutter assembly 3 to the third position.
[0092] After cutting is completed, the first electric cylinder 402 and the second electric cylinder 403 work synchronously, causing the cutter assembly 3 to rise to the third position. The rotating assembly 2 then rotates the placement platform 1 by 90° to the second position. Then, the first electric cylinder 402 and the second electric cylinder 403 work synchronously, causing the cutter assembly 3 to fall to the fourth position. Thus, each blade 301 performs a second cut on the material. The two cut lines are perpendicular, thereby cutting the material into square shapes.
[0093] The linear module 401 is used to drive the cutter assembly 3 to move, so as to make horizontal fine adjustments to the position of the cutter assembly 3 and ensure that the cutter assembly 3 is located directly above the placement area.
[0094] In optional embodiments, such as Figure 1 As shown, the cutting device also includes an electrical control box 12, which contains a control module. The control module is communicatively connected to the motor 202, the first cylinder 8, the second cylinder 11, the first electric cylinder 402, the second electric cylinder 403, and the linear module 401.
[0095] The cutting device also includes a first control switch 13, a second control switch 14, a third control switch 15, a fourth control switch 16, and a fifth control switch 17.
[0096] The first control switch 13 is connected to the control module, and thus the first control switch 13 is used to control the first cylinder 8 to drive the first push plate 7 to move.
[0097] The second control switch 14 is connected to the control module, and thus the second control switch 14 is used to control the second cylinder 11 to drive the second push plate 10 to move.
[0098] The third control switch 15 is connected to the control module for communication, and thus the third control switch 15 is used to control the linear module 401.
[0099] The fourth control switch 16 is communicatively connected to the control module, so that the fourth control switch 16 is used to simultaneously control the first electric cylinder 402 and the second electric cylinder 403.
[0100] The fifth control switch 17 is connected to the control module, and thus the fifth control switch 17 is used to control the motor 202 to drive the rotating shaft 201 to rotate.
[0101] Although embodiments of this application have been described in conjunction with the accompanying drawings, those skilled in the art can make various modifications and variations without departing from the spirit and scope of this application, and all such modifications and variations fall within the scope defined by this application.
Claims
1. A cutting device, characterized in that, include: The placement platform (1) is provided with a placement area for placing a tray (18) containing materials. A rotating component (2) is connected to the placement platform (1) and is adapted to drive the placement platform (1) to rotate between a first position and a second position, wherein the placement platform (1) rotates 90° from the first position to the second position; The cutting assembly (3) includes a plurality of blades (301) arranged laterally in sequence, the blades (301) being adapted for downward cutting; A lifting assembly (4) is connected to the cutter assembly (3) and is adapted to drive the cutter assembly (3) to move up and down between a third position and a fourth position; The scraper (5) is provided with a plurality of through holes (51) through which the blade (301) passes, and the through holes (51) correspond one-to-one with the blade (301); With the cutter assembly (3) in the third position, each of the blades (301) is located above the placement area, and the scraper (5) is located between the cutter assembly (3) and the placement area; When the cutter assembly (3) is in the fourth position, each of the blades (301) passes through the perforation (51) and abuts against the placement area.
2. The dicing device according to claim 1, characterized in that, When the cutter assembly (3) is in the fourth position, the sidewall of the blade (301) is in contact with the inner wall of the perforation (51).
3. The dicing device according to claim 2, characterized in that, The width of the perforation (51) gradually increases from bottom to top. When the cutter assembly (3) is in the fourth position, the sidewall of the blade (301) is in contact with the bottom of the inner wall of the perforation (51).
4. The dicing device according to claim 1, characterized in that, Also includes: The first limiting plate (6) is disposed on the placement platform (1); A first push plate (7) and a first drive assembly, wherein the first drive assembly is connected to the placement platform (1), the first push plate (7) is connected to the first drive assembly, and the first drive assembly can drive the first push plate (7) to move closer to or away from the first limiting plate (6), wherein, When the tray (18) is placed in the placement area and the first push plate (7) moves close to the first limiting plate (6), the first push plate (7) and the first limiting plate (6) can clamp the tray (18).
5. The dicing device according to claim 4, characterized in that, Also includes: The second limiting plate (9) is disposed on the placement platform (1) and is perpendicular to the first limiting plate (6); A second push plate (10) and a second drive assembly, the second drive assembly being connected to the placement platform (1), the second push plate (10) being connected to the second drive assembly, the second drive assembly being able to drive the second push plate (10) to move closer to or away from the second limiting plate (9), wherein, When the tray (18) is placed in the placement area and the second push plate (10) moves close to the second limiting plate (9), the second push plate (10) and the second limiting plate (9) can clamp the tray (18).
6. The dicing device according to claim 5, characterized in that, The first driving component includes a first cylinder (8), which is disposed on the placement platform (1) and connected to the first push plate (7). The first cylinder (8) is used to drive the first push plate (7) to slide closer to or away from the first limiting plate (6). The second drive assembly includes a second cylinder (11), which is disposed on the placement platform (1) and connected to the second push plate (10). The second cylinder (11) is used to drive the second push plate (10) to move closer to or away from the second limiting plate (9).
7. The dicing device according to claim 1, characterized in that, The lifting assembly (4) includes: A linear module (401) is connected to the cutter assembly (3) and is used to drive the cutter assembly (3) to move along the length direction of the linear module (401); The first electric cylinder (402) and the second electric cylinder (403) are respectively connected to the two ends of the linear module (401). The first electric cylinder (402) and the second electric cylinder (403) are both used to drive the linear module (401) to rise and fall. The first electric cylinder (402) and the second electric cylinder (403) are respectively located on both sides of the cutter assembly (3).
8. The dicing device according to claim 1, characterized in that, The rotating component (2) includes: A rotating shaft (201) is vertically positioned and connected to the placement platform (1); The motor (202) is connected to the rotating shaft (201) and is adapted to drive the rotating shaft (201) to rotate.
9. The dicing device according to claim 1, characterized in that, The cutting blade assembly (3) also includes: The frame (302) is connected to each of the blades (301) and arranged sequentially along the frame (302); The connecting frame (303) is connected to each of the frames (302), and the connecting frame (303) is connected to the lifting assembly (4).