Multi-blade rotary cutter head assembly and vegetable slicing apparatus

Abstract

The utility model belongs to the field of food processing especially a kind of multi-blade rotary cutter disc assembly and vegetable slicing equipment, the outlet of existing cutter is close to vegetable, when cleaning by cloth and other tools, it is difficult to clean the inside of cutter and the corresponding inner wall, the following scheme is presented, it includes multiple blades;Mounting disc, for installing blade, one end of multiple blades is fixedly arranged in the side of mounting disc, and multiple blades are arranged in ring equidistantly, the center of the side of mounting disc is fixedly arranged with limit rod, the center of the other side of mounting disc is fixedly arranged with sliding cylinder, when needing to clean, open the door, the limit state can be removed, so that mounting disc and blade can be moved outward, to facilitate staff to clean its inside.

Description

Technical Field

[0001] This utility model relates to the field of food processing technology, and in particular to a multi-blade rotary cutter assembly and a vegetable slicing device. Background Technology

[0002] With the accelerating pace of life and the increasing demand for food quality and diversity, vegetables, as an indispensable part of daily diet, are increasingly in demand for processing. In the food processing industry, especially in catering services and food processing enterprises, the demand for vegetable slices is characterized by large scale, high efficiency, and high quality.

[0003] Therefore, existing market devices can directly replace manual slicing of vegetables by feeding them into multiple rotating blades. However, existing slicing equipment has certain inconveniences in terms of cleaning: the blades are too close to the vegetable exit point, making it difficult to clean the inside of the blades and their corresponding inner walls when using tools such as cloths. Therefore, a device is designed that allows for direct adjustment of the blade position during cleaning, ensuring sufficient space for the cleaning operation. Utility Model Content

[0004] The purpose of this invention is to address the shortcomings of existing technologies, such as the difficulty in cleaning the inner side of the blade and its corresponding inner wall, by proposing a multi-blade rotating blade assembly and a vegetable slicing device.

[0005] To achieve the above objectives, the present invention adopts the following technical solution:

[0006] A multi-blade rotary blade assembly and vegetable slicing device, comprising multiple blades;

[0007] A mounting plate is used to mount blades. One end of a plurality of blades is fixedly mounted on one side of the mounting plate, and the plurality of blades are arranged in a ring at equal intervals. A limit rod is fixedly mounted at the center of one side of the mounting plate, and a slide cylinder is fixedly mounted at the center of the other side of the mounting plate.

[0008] A rotating rod is used as a drive shaft, and the sliding cylinder is sleeved on the outer wall of the rotating rod.

[0009] A vegetable slicing device includes a machine body, a frame fixedly mounted on one side of the machine body, a door hinged to one side of the frame, a slicing cavity formed between the frame and the door, a conveying channel opened on one side of the machine body and connected to the slicing cavity, and a blade located inside the slicing cavity.

[0010] A conveying mechanism is used to transport vegetables into the slicing chamber, and the conveying mechanism is set on the worktable of the machine body;

[0011] A locking mechanism is used to limit the limit rod and the stop door. The locking mechanism includes a limit cylinder, one end of which is threaded through the stop door and cooperates with one end of the limit rod.

[0012] In one possible design, the machine body has an internal cavity, a No. 1 servo motor is fixedly installed on the bottom inner wall of the cavity, a bracket is fixedly installed on the side inner wall of the cavity, the rotating rod is rotatably installed inside the bracket, a No. 1 synchronous pulley is fixedly sleeved on the outer wall of the output shaft of the No. 1 servo motor and the outer wall of the rotating rod, and the outer walls of the two No. 1 synchronous pulleys are driven by the same No. 1 synchronous belt, and one end of the slide cylinder passes through the machine body and is slidably sleeved on the outer wall of the rotating rod.

[0013] In one possible design, a sliding groove is provided on one side of the gate, and a retaining strip is slidably disposed inside the sliding groove. A retaining groove is provided on one side of the inner wall of the frame, and one end of the retaining strip cooperates with the retaining groove. Both sides of one end of the retaining strip are set as bevels. A limiting shaft is fixedly provided on one side of the inner wall of the sliding groove, and the retaining strip is slidably sleeved on the outer wall of the limiting shaft. A compression spring is sleeved on the outer wall of the limiting shaft, and the two ends of the compression spring are respectively fixedly disposed on one end of the retaining strip and one side of the inner wall of the sliding groove.

[0014] In one possible design, the locking mechanism further includes a fixing rod, a side groove is provided on one side of the stop, a slide bar is slidably arranged inside the side groove, and the fixing rod is fixedly arranged on one side of the slide bar. A fixing groove is provided on one side of the locking bar, one end of the fixing rod slides through into the interior of the slide groove and cooperates with the fixing groove, and a ring is fixedly arranged on one end of the slide bar, and the ring is rotatably sleeved on the outer wall of the limiting cylinder.

[0015] In one possible design, the conveying mechanism includes a first belt, a groove is provided on the top of the machine body worktable, and a first rotating roller is rotatably mounted at both ends inside the groove. A first pulley is fixedly fitted on the outer wall of each of the two first rotating rollers. The first belt is driven and fitted on the outer wall of the two first pulleys. A support platform is fixedly mounted inside the groove and is located inside the first belt. A second servo motor is fixedly mounted on the bottom inner wall of the machine cavity. One end of one of the first rotating rollers rotates through into the machine cavity. A second synchronous pulley is fixedly fitted on the outer wall of the first rotating roller and the outer wall of the output shaft of the second servo motor. The outer walls of the two second synchronous pulleys are driven and fitted with the same second synchronous belt.

[0016] In one possible design, the conveying mechanism further includes a second belt, a sliding frame is slidably arranged inside the conveying channel, and two second rotating rollers are rotatably arranged inside the sliding frame. The outer walls of the two second rotating rollers are fixedly fitted with second pulleys, and the second belt is driven by being fitted onto the outer walls of the two second pulleys. The second belt is located above the first belt.

[0017] In this application, during actual use, a first servo motor is driven, which in turn drives a rotating rod to rotate via a first synchronous belt and a first synchronous pulley. The rotating rod then drives a limit rod to rotate via a slide cylinder, thereby causing multiple blades to rotate and perform the cutting action. Vegetable conveying is achieved by driving a second servo motor, which drives a first rotating roller to rotate via a second synchronous pulley and a second synchronous belt. The first rotating roller then drives a first belt via a pulley. The worker simply places the vegetables on top of the first belt for conveying, allowing them to pass through the conveyor channel into the slicing chamber for slicing. When cleaning the blades and slicing chamber is required, simply rotating the handwheel at one end of the limit cylinder will displace the limit cylinder, causing it to detach from the outer wall of the limit rod. As the limit cylinder moves, it will also drive a circular ring. When the ring moves, it will drive the fixed rod to move via the slider, causing the fixed rod to disengage from the fixed groove, thus releasing the locking strip. At this time, when the handwheel is pulled to open the stop gate, the inclined surface at one end of the locking strip will touch the groove, causing it to retract into the groove, allowing the stop gate to be opened. Then, the slicing chamber can be cleaned. For cleaning the blade, since the limiting cylinder is no longer limiting the limiting rod, the mounting plate and blade can be moved outward. At this time, the operator can easily clean the back of the blade. After completion, simply close the stop gate again and turn the handwheel to reset the limiting cylinder. The limiting cylinder will fit around and abut against the limiting rod, ensuring the stability of the blade during slicing. The fixed rod will also reset, re-locking the locking strip, thus locking the stop gate to prevent accidental opening.

[0018] In this utility model, the multi-blade rotating blade assembly and vegetable slicing equipment can achieve automatic vegetable conveying through the conveying mechanism, reducing manual operation and improving production efficiency.

[0019] In this utility model, the multi-blade rotating blade assembly and vegetable slicing device, through the locking mechanism, can close and fix the baffle to prevent accidental opening, while also limiting the position of the blade to ensure stable slicing. When cleaning is required, the baffle can be released to open for cleaning, and the blade can be moved outward to facilitate cleaning the inside of the blade.

[0020] In this invention, when the vegetables are transported to the slicing chamber by the conveying mechanism, they are sliced ​​by multiple rotating blades. The mounting plate on which the blades are mounted is limited by the limiting cylinder to ensure stable rotation. When the door is opened for cleaning, the limiting state can be released, allowing the mounting plate and blades to move outward, thus facilitating cleaning of the inside by the staff. Attached Figure Description

[0021] Figure 1 This is an exploded structural diagram of a multi-blade rotary cutter head assembly proposed in this utility model;

[0022] Figure 2 This is a three-dimensional structural diagram of a vegetable slicing device proposed in this utility model;

[0023] Figure 3 This is a schematic diagram of the internal structure of a vegetable slicing device frame proposed in this utility model;

[0024] Figure 4 This is a cross-sectional structural diagram of the gate of a vegetable slicing device proposed in this utility model;

[0025] Figure 5 This is a cross-sectional structural diagram of a vegetable slicing device proposed in this utility model;

[0026] Figure 6 This is a schematic diagram of the internal structure of the cavity of a vegetable slicing device proposed in this utility model.

[0027] In the diagram: 1. Blade; 2. Mounting plate; 3. Slide cylinder; 4. Rotating rod; 5. Limiting rod; 6. Machine body; 7. Frame; 8. Gate; 9. Conveying mechanism; 10. Limiting cylinder; 11. Conveying channel; 12. Ring; 13. Slide bar; 14. Side groove; 15. Compression spring; 16. Slide groove; 17. Limiting shaft; 18. Clamping bar; 19. Fixing rod; 20. Sliding frame; 21. Second rotating roller; 22. Second belt; 23. Support platform; 24. First belt; 25. First rotating roller; 26. Groove; 27. Bracket; 28. First synchronous belt; 29. ​​First servo motor; 30. Second servo motor; 31. Machine cavity; 32. Second synchronous belt. Detailed Implementation

[0028] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0029] Example 1

[0030] Reference Figure 1A multi-blade rotary blade assembly includes: multiple blades 1, a mounting plate 2, a slide cylinder 3, and a rotating rod 4. One end of each of the multiple blades 1 is fixed to one side of the mounting plate 2 by at least two bolts, and the multiple blades 1 are arranged in a ring at equal intervals. A limit rod 5 is fixedly installed at the center of one side of the mounting plate 2 to limit the position of the mounting plate 2, and a slide cylinder 3 is fixedly installed at the center of the other side. The slide cylinder 3 is sleeved on the outer wall of the rotating rod 4, and the rotating rod 4 acts as a drive shaft to drive the blades 1 to rotate. By driving the rotating rod 4, the multiple blades 1 can be rotated to perform slicing operations.

[0031] This application can be used in the field of food processing, or in other fields applicable to this application.

[0032] Example 2

[0033] refer to Figure 1-2 An improvement upon Embodiment 1: A vegetable slicing device, applied in the food processing field, includes a multi-blade rotary cutter assembly, and further includes:

[0034] 6. Body, 7. Frame, 8. Door, 9. Conveying mechanism, and 10. Locking mechanism.

[0035] A frame 7 is fixedly installed on one side of the machine body 6, and a baffle 8 is hinged to one side of the frame 7, forming a slicing cavity between the frame 7 and the baffle 8. A conveying channel 11 is provided on one side of the machine body 6, and the conveying channel 11 is connected to the slicing cavity. When vegetables enter the slicing cavity through the conveying channel 11, they are sliced ​​by the blades 1 inside.

[0036] Reference Figure 6 For driving the blade 1, a servo motor 29 is fixedly installed in the machine cavity 31 inside the worktable 6 by bolts. The rotating rod 4 in the blade assembly is rotatably installed in the bracket 27 inside the machine cavity 31. The outer wall of the rotating rod 4 and the outer wall of the output shaft of the servo motor 29 are both fixedly fitted with a synchronous pulley. The outer walls of the two synchronous pulleys are fitted with the same synchronous belt 28. By driving the motor, the rotating rod 4 can be rotated through the corresponding synchronous belt and synchronous pulley. The sliding cylinder 3, which is slidably fitted on the outer wall of the rotating rod 4, will also rotate accordingly, thereby driving the blade 1 installed on the mounting plate 2 to rotate and slice.

[0037] Reference Figure 5-6For transporting vegetables, the corresponding conveying mechanism 9 is set on the worktable of the machine body 6. The conveying mechanism 9 includes components such as a first belt 24, a support platform 23, and a second servo motor 30. A groove 26 is opened on the top of the worktable of the machine body 6. A first transmission roller 25 is rotatably installed at both ends of the groove 26. The first belt 24 is driven by the first pulleys on the outer walls of the two first transmission rollers 25. At the same time, the support platform 23 is fixedly installed on the inner wall of the groove 26 and is located inside the first belt 24 to provide support. The power of the transmission rollers is provided by the second servo motor 30, which is fixedly installed in the machine cavity 31 inside the machine body 6 by bolts. The motor drives the second synchronous pulley on the outer wall of one of the first rotating rollers 25 to rotate through the second synchronous pulley on the outer wall of the output shaft and the second synchronous belt 32 on the surface, thereby driving the first belt 24 to move. So when the second servo motor 30 is driven, it can drive the first belt 24 to transport the vegetables on the surface to the slicing chamber for slicing.

[0038] Furthermore, the conveying mechanism also includes components such as a sliding frame 20 slidably disposed inside the conveying channel 11. Two secondary rotating rollers 21 are rotatably disposed inside the sliding frame 20, and secondary pulleys are fixedly sleeved on the outer walls of the two rotating rollers. A secondary belt 22 is driven and sleeved on the outer walls of the two secondary belt pulleys. The secondary belt 22 is located above the primary belt 24 and is used to press the vegetables below. At the same time, a sliding rod is provided at the top of the sliding frame 20 and is slidably disposed inside the machine body 6. A tension spring is sleeved on the outer wall of the rod, so that when the vegetables are conveyed and touch the secondary belt 22, the tension spring will apply a downward force, thereby ensuring the pressing effect and ensuring the stability of the vegetables during slicing.

[0039] Reference Figure 4 The locking mechanism is used to limit the position of the limiting rod 5 and the stop gate 8. The locking mechanism includes components such as the limiting cylinder 10, the fixing rod 19, and the slide bar 13. One end of the limiting cylinder 10 is threaded through the stop gate 8 and engages with one end of the limiting rod 5. The fixing rod 19 is fixedly mounted on one side of the slide bar 13, which is slidably mounted inside the side groove 14. The retaining strip 18 is slidably mounted inside the slide groove 16, and one end of the retaining strip 18 engages with a retaining groove on the inner wall of one side of the frame 7.

[0040] Specifically, when cleaning the cutting tool and slicing chamber is required, simply rotate the handwheel at one end of the limiting cylinder 10. The limiting cylinder 10 will shift, disengaging from the outer wall of the limiting rod 5. As the limiting cylinder 10 moves, it will also move the ring 12, which in turn will move the fixing rod 19 via the slide bar 13. This disengages the fixing rod 19 from the fixing groove, thus releasing the locking strip 18. At this point, pulling the handwheel to open the stop gate 8 will cause the inclined surface at one end of the locking strip 18 to touch the locking groove, retracting it into the slide groove 16. The stop gate 8 can then be opened, allowing for cutting. The cavity is cleaned, and for cleaning the blade, since the limiting cylinder 10 is released from the limiting rod 5, the mounting plate 2 and the blade 1 can be moved outward. At this time, the operator can easily clean the back of the blade 1. After completion, simply close the gate 8 again and turn the handwheel to drive the limiting cylinder 10 to reset. The limiting cylinder 10 will fit on and abut against the limiting rod 5, so that the mounting plate 2 cannot move laterally, thus ensuring the stability of the blade 1 when slicing. The fixing rod 19 will also be reset, and the locking strip 18 will be fixed again, thus locking the gate 8 to prevent accidental opening.

[0041] However, as is well known to those skilled in the art, the working principles and wiring methods of servo motor 29 and servo motor 30 are commonplace and are conventional methods or common knowledge. They will not be described in detail here. Those skilled in the art can make any selections according to their needs or convenience.

[0042] The accompanying drawings in this application are for illustrative purposes only. The dimensions and shapes of the components shown are not actual limitations but are merely schematic representations. In actual implementation, the components can be reasonably configured and adjusted according to specific needs and actual conditions.

[0043] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. A multi-blade rotary cutterhead assembly, comprising: include: Multiple blades (1); Mounting disc (2) is used to mount blades (1). One end of a plurality of blades (1) is fixedly mounted on one side of the mounting disc (2), and the plurality of blades (1) are arranged in a ring at equal intervals. A limit rod (5) is fixedly mounted at the center of one side of the mounting disc (2), and a slide cylinder (3) is fixedly mounted at the center of the other side of the mounting disc (2). The rotating rod (4) is used as a drive shaft, and the slide cylinder (3) is sleeved on the outer wall of the rotating rod (4).

2. A vegetable slicing apparatus comprising a multi-blade rotary knife disc assembly as claimed in claim 1, characterised in that, Also includes: The machine body (6) has a frame (7) fixedly installed on one side, and a door (8) is hinged on one side of the frame (7). A slicing cavity is formed between the frame (7) and the door (8). A conveying channel (11) is opened on one side of the machine body (6), and the conveying channel (11) is connected to the slicing cavity. The blade (1) is located inside the slicing cavity. A conveying mechanism (9) is used to convey vegetables into the slicing cavity. The conveying mechanism (9) is set on the worktable of the machine body (6). A locking mechanism is used to limit the limit rod (5) and the stop (8). The locking mechanism includes a limit cylinder (10), one end of which is threaded through the stop (8) and cooperates with one end of the limit rod (5).

3. A vegetable slicing apparatus according to claim 2, wherein The machine body (6) has an internal cavity (31). A servo motor (29) is fixedly installed on the bottom inner wall of the machine cavity (31). A bracket (27) is fixedly installed on the side inner wall of the machine cavity (31). The rotating rod (4) is rotatably installed inside the bracket (27). A synchronous pulley is fixedly sleeved on the outer wall of the output shaft of the servo motor (29) and the outer wall of the rotating rod (4). The outer walls of the two synchronous pulleys are driven by the same synchronous belt (28). One end of the slide cylinder (3) passes through the machine body (6) and is slidably sleeved on the outer wall of the rotating rod (4).

4. A vegetable slicing apparatus according to claim 3, wherein A sliding groove (16) is provided on one side of the gate (8), and a retaining strip (18) is slidably arranged inside the sliding groove (16). A retaining groove is provided on one side of the inner wall of the frame (7). One end of the retaining strip (18) is engaged with the retaining groove. Both sides of one end of the retaining strip (18) are set as inclined surfaces. A limiting shaft (17) is fixedly provided on one side of the inner wall of the sliding groove (16), and the retaining strip (18) is slidably sleeved on the outer wall of the limiting shaft (17). A compression spring (15) is sleeved on the outer wall of the limiting shaft (17), and the two ends of the compression spring (15) are respectively fixedly arranged on one end of the retaining strip (18) and one side of the inner wall of the sliding groove (16).

5. A vegetable slicing apparatus according to claim 4, wherein The locking mechanism also includes a fixing rod (19), a side groove (14) is provided on one side of the blocking gate (8), a slide bar (13) is slidably provided inside the side groove (14), and the fixing rod (19) is fixedly provided on one side of the slide bar (13). A fixing groove is provided on one side of the locking bar (18), one end of the fixing rod (19) slides through into the interior of the slide groove (16) and cooperates with the fixing groove. One end of the slide bar (13) is fixedly provided with a ring (12), and the ring (12) is rotatably sleeved on the outer wall of the limiting cylinder (10).

6. A vegetable slicing apparatus according to claim 5, wherein The conveying mechanism (9) includes a first belt (24). A groove (26) is provided on the top of the worktable of the machine body (6). A first rotating roller (25) is rotatably provided at both ends inside the groove (26). A first pulley is fixedly sleeved on the outer wall of the two first rotating rollers (25). The first belt (24) is driven and sleeved on the outer wall of the two first belt (24) pulleys. A support platform (23) is fixedly provided inside the groove (26), and the support platform (23) is located inside the first belt (24). A second servo motor (30) is fixedly provided on the bottom inner wall of the machine cavity (31). One end of one of the first rotating rollers (25) rotates through into the inside of the machine cavity (31). A second synchronous pulley is fixedly sleeved on the outer wall of the first rotating roller (25) and the outer wall of the output shaft of the second servo motor (30). The same second synchronous belt (32) is driven and sleeved on the outer wall of the two second synchronous pulleys.

7. A vegetable slicing apparatus according to claim 6, wherein The conveying mechanism (9) also includes a second belt (22). A sliding frame (20) is slidably arranged inside the conveying channel (11). Two second rotating rollers (21) are rotatably arranged inside the sliding frame (20). The outer walls of the two second rotating rollers (21) are fixedly fitted with second pulleys. The second belt (22) is driven and fitted on the outer walls of the two second belt pulleys. The second belt (22) is located above the first belt (24).

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