High-pressure bubble cleaning device for pickled mustard
By designing the retrieval and receiving structures of the high-pressure bubble cleaning device for dried vegetables, the problems of manual retrieval and dripping water in traditional cleaning machines have been solved, achieving automated retrieval and improved environmental friendliness.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Filing Date
- 2025-08-25
- Publication Date
- 2026-07-14
Smart Images

Figure CN224482932U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of dried vegetable processing, specifically, it relates to a high-pressure bubble cleaning device for dried vegetables. Background Technology
[0002] Gongcai, scientifically known as Taigan, is a special variety of stem lettuce in the genus Lactuca of the Asteraceae family. It belongs to the same genus as common lettuce but is a different species. After processing, it has a unique taste that is loved by most people and is currently a mainstream ingredient in hot pot.
[0003] Before processing, the outer surface of the dried gongcai (a type of dried vegetable) needs to be cleaned. The traditional cleaning method is to use a bubble cleaning machine. However, when cleaning dried gongcai with a bubble cleaning machine, the workers need to manually retrieve the cleaned dried gongcai from the device. This retrieval process not only increases the workload of the workers, but also causes a large amount of water to drip around the device.
[0004] In view of this, this utility model is proposed. Utility Model Content
[0005] To solve the above-mentioned technical problems, the basic concept of the technical solution adopted by this utility model is as follows:
[0006] A high-pressure bubble cleaning device for dried vegetables, comprising:
[0007] The cleaning shell is a hollow right-angled trapezoidal box with an open top. Multiple rows of aeration pipes are installed at the bottom of the cavity of the cleaning shell. A drain valve is installed at the bottom of the cavity of the cleaning shell. A support frame is fixedly connected inside the cavity of the cleaning shell, and a bottom catch is snapped into the top of the support frame.
[0008] The retrieval structure is located at the top of the cleaning shell and is used to retrieve the dried vegetables inside the cleaning shell cavity. The retrieval structure includes a rotating column, a sliding cylinder, an extension arm, and a retrieval frame. The rotating column is located above the cleaning shell, the sliding cylinder is sleeved on the wall of the rotating column, the extension arm is fixedly connected to the outer wall of the sliding cylinder, and the retrieval frame is fixedly connected to the end of the extension arm. The retrieval frame is capable of retrieving the dried vegetables inside the cleaning shell cavity.
[0009] In a preferred embodiment of this utility model, the rotating column is cylindrical, the sliding cylinder is cylindrical, and three identical extension arms are arranged in a circular array on the outer arc surface of the sliding cylinder. The wall of each extension arm is provided with the same retrieval frame, and the retrieval frame is a rectangular box with a circular hole at the bottom of the cavity.
[0010] In a preferred embodiment of this utility model, the salvage structure further includes a bracket, a servo motor, a limiting sleeve, a trigger, a fastener, and a spring. The brackets are symmetrically fixedly connected to the top two sides of the cleaning shell, the servo motor is fixedly connected to the outer wall of one of the brackets, the limiting sleeve is fixedly connected to the wall of the rotating column, the trigger is fixedly connected to one side wall of the slide cylinder, the fastener is fixedly connected to the bracket wall at the servo motor, and the spring is sleeved on the outer wall of the rotating column.
[0011] In a preferred embodiment of this utility model, the bracket is a rectangular plate, the two ends of the rotating column can be inserted into the wall of the symmetrical bracket, the servo motor can drive the rotating column to rotate through the coupling, the limiting sleeve is a rectangular sleeve, the limiting sleeve is located at the center of the rotating column biased towards the fastener, and the cavity space of the slide cylinder can be adapted to the outer wall of the limiting sleeve.
[0012] In a preferred embodiment of this utility model, the firmware is located on the wall surface of the bracket facing the limiting sleeve direction, one end of the rotating column can abut against the side wall surface of the slide cylinder, the trigger is a triangular block, the firmware is also a triangular block, and the inclined surface of the firmware can contact the inclined surface of the trigger.
[0013] In a preferred embodiment of the present invention, the rear wall of the cleaning shell is provided with a receiving structure, which includes an electric cylinder, a lower plate, a receiving plate and a connecting plate. The electric cylinder is fixedly connected to the rear wall of the cleaning shell, the lower plate is fixedly connected to one side of the rear wall of the cleaning shell, the receiving plate is slidably connected to the top of the rear wall of the cleaning shell, and the connecting plate is fixedly connected to one side of the receiving plate.
[0014] In a preferred embodiment of this utility model, the retractable end of the electric cylinder can be fixedly connected to the side wall of the connecting plate, the receiving plate is located behind the bracket, the connecting plate is located above the lower plate, the receiving plate is shovel-shaped, a circular groove is provided at the bottom of the cavity of the receiving plate, the lower plate is rectangular, a sloping groove is provided at the top of the lower plate, the top sloping surface of the lower plate can communicate with the cavity of the cleaning shell, and the receiving plate is located above the lower plate.
[0015] Compared with the prior art, the present invention has the following advantages:
[0016] 1. By setting up a retrieval structure, the dried vegetables inside the cleaning shell cavity are retrieved using a reciprocating rotating retrieval frame. As the retrieval frame rotates, it automatically shakes, which not only facilitates the faster flow of dripping water but also makes it easier for the dried vegetables to be poured out of the retrieval frame. Therefore, this solution not only eliminates the need for manual retrieval of the dried vegetables but also reduces a large amount of water dripping around the device.
[0017] 2. By setting up a receiving structure, a reciprocating receiving tray is used to catch the dried vegetables retrieved by the retrieval frame. After catching the dried vegetables, most of the water droplets dripping from the vegetable wall can be recycled back into the cleaning chamber, which effectively improves the environmental friendliness of this solution.
[0018] The specific embodiments of this utility model will be described in further detail below with reference to the accompanying drawings. Attached Figure Description
[0019] In the attached diagram:
[0020] Figure 1 This is a perspective view of the present utility model;
[0021] Figure 2 This is a disassembly diagram of the bracket of this utility model;
[0022] Figure 3 This is a disassembly diagram of the receiving plate of this utility model;
[0023] Figure 4 This is a disassembly diagram of the rotating column of this utility model;
[0024] Figure 5 This is a disassembly diagram of the slide and limiting sleeve of this utility model.
[0025] In the diagram: 20. Cleaning shell; 21. Aeration pipe; 22. Support frame; 23. Bottom support; 24. Servo motor; 30. Bracket; 31. Rotating column; 32. Limiting sleeve; 33. Slide cylinder; 34. Extension arm; 35. Retrieval frame; 36. Trigger; 37. Fixture; 38. Spring; 40. Electric cylinder; 41. Lower plate; 42. Connecting plate; 43. Connecting plate. Detailed Implementation
[0026] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions in the embodiments will be clearly and completely described below with reference to the accompanying drawings. The following embodiments are used to illustrate this utility model.
[0027] like Figure 1 , Figure 2 and Figure 3 As shown, a high-pressure bubble cleaning device for dried vegetables includes: a cleaning shell 20, which is a hollow right-angled trapezoidal box with an open top; multiple rows of aeration pipes 21 are installed at the bottom of the cavity of the cleaning shell 20; a drain valve is installed at the bottom of the cavity of the cleaning shell 20; a support frame 22 is fixedly connected to the cavity of the cleaning shell 20; a bottom cover 23 is snapped onto the top of the support frame 22; all the aeration pipes 21 in the cavity of the cleaning shell 20 are connected to a high-pressure air pump; the high-pressure air pump can deliver high-pressure bubbles into the cavity of the cleaning shell 20 through the aeration pipes 21; the drain valve can discharge the water in the cavity of the cleaning shell 20; the bottom cover 23 is a rectangular screen; and the high-pressure air pump is electrically connected to a corresponding power source. This is existing technology and will not be described in detail here.
[0028] like Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5 As shown, the retrieval structure is set on top of the cleaning shell 20 for retrieving the dried vegetables inside the cavity of the cleaning shell 20. The retrieval structure includes: a rotating column 31, a sliding cylinder 33, an extension arm 34, and a retrieval frame 35. The rotating column 31 is set above the cleaning shell 20. The sliding cylinder 33 is sleeved on the wall of the rotating column 31. The extension arm 34 is fixedly connected to the outer wall of the sliding cylinder 33. The retrieval frame 35 is fixedly connected to the end of the extension arm 34. The retrieval frame 35 is capable of retrieving the dried vegetables inside the cavity of the cleaning shell 20.
[0029] like Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5 As shown, the rotating column 31 is cylindrical, and the sliding cylinder 33 is cylindrical. Three identical extension arms 34 are arranged in a circular array on the outer arc surface of the sliding cylinder 33. Each extension arm 34 has an identical retrieval frame 35 on its wall. The retrieval frame 35 is a rectangular box with a circular hole at the bottom of its cavity. The retrieval structure also includes a bracket 30, a servo motor 24, a limiting sleeve 32, a trigger 36, a fastener 37, and a spring 38. The brackets 30 are symmetrically fixed to the top two sides of the cleaning shell 20. The servo motor 24 is fixedly connected to the outer wall of one of the brackets 30. The limiting sleeve 32 is fixedly connected to the wall of the rotating column 31. The trigger 36 is fixedly connected to one side wall of the sliding cylinder 33. The fastener 37 is fixedly connected to the servo motor 38. On the wall of the bracket 30 at the servo motor 24, the spring 38 is sleeved on the outer wall of the rotating column 31. The bracket 30 is a rectangular plate. Both ends of the rotating column 31 can be inserted into the wall of the symmetrical bracket 30. The servo motor 24 can drive the rotating column 31 to rotate through the coupling. The limiting sleeve 32 is a rectangular sleeve. The limiting sleeve 32 is located at the center of the rotating column 31, biased towards the fastener 37. The cavity space of the slide cylinder 33 can fit the outer wall of the limiting sleeve 32. The fastener 37 is located on the wall of the bracket 30 facing the limiting sleeve 32. One end of the rotating column 31 can abut against the side wall of the slide cylinder 33. The trigger 36 is a triangular block. The fastener 37 is also a triangular block. The inclined surface of the fastener 37 can contact the inclined surface of the trigger 36.
[0030] In practical use, first, add the cleaning solution into the cavity of the cleaning shell 20, then turn on the high-pressure air pump. When the high-pressure air pump is turned on, it will deliver air bubbles to the cleaning solution in the cavity of the cleaning shell 20 through the aeration pipe 21. At this time, pour the dried vegetables to be cleaned directly into the cleaning solution in the cavity of the cleaning shell 20. The dried vegetables will be cleaned as the cleaning solution churns. After cleaning, turn on the power of the servo motor 24. The servo motor 24 can drive the rotating column 31 to rotate between the symmetrical supports 30. As the rotating column 31 rotates, it will drive the limiting sleeve 32 to rotate synchronously. The limiting sleeve 32 will drive the sliding cylinder 33 to rotate synchronously. The sliding cylinder 33 will drive... The extension arm 34 and the retrieval frame 35 rotate synchronously. As the retrieval frame 35 rotates, it scoops up the dried vegetables from the cleaning fluid inside the cleaning shell 20. Then, as the sliding cylinder 33 rotates, the trigger 36 rotates synchronously with it. When the trigger 36 rotates to contact the inclined surface of the fastener 37, the fastener 37 abuts against the trigger 36, causing the sliding cylinder 33 to slide along the limiting sleeve 32. At this time, the limiting sleeve 32 compresses the spring 38 during sliding, causing it to shrink. After the trigger 36 and the fastener 37 become misaligned, the spring 38 releases the compressed force, thus abutting the sliding cylinder 33 to slide laterally against the wall of the limiting sleeve 32. The cylinder 33 drives the extension arm 34 and the retrieval frame 35 to vibrate synchronously. The water from the retrieval frame 35 is shaken off by the vibration, and this water falls back into the cleaning shell 20. As the retrieval frame 35 rotates to above the receiving tray 42, the water from the retrieval frame 35 falls to the top of the receiving tray 42. At this point, the water dripping from the water on the top of the receiving tray 42 leaks from the circular groove on the wall of the receiving tray 42 into the cleaning shell 20. Simultaneously, as the retrieval frame 35 rotates above the receiving tray 42, the electric cylinder 40 extends, driving the connecting plate during this extension. 43 and the receiving tray 42 slide synchronously towards the lower plate 41. At this time, the receiving tray 42 will move the congee on its top to the top of the lower plate 41. The water dripping from the receiving tray 42 will fall onto the top of the lower plate 41 and then re-enter the cleaning shell 20 cavity along the slope of the lower plate 41. At this time, the staff only needs to clean the congee on the top of the receiving tray 42. The electric cylinder 40 and the servo motor 24 are controlled by PLC. The electric cylinder 40 will extend after the retrieval frame 35 rotates to the top of the receiving tray 42 and pours out the congee in the cavity of the retrieval frame 35 to the top of the receiving tray 42. Then it will retract after the retrieval frame 35 passes.
[0031] In summary, by setting up a retrieval structure and using a reciprocating rotating retrieval frame 35, the dried vegetables inside the cleaning shell 20 can be retrieved. As the retrieval frame 35 rotates, it can automatically shake, which not only facilitates the faster flow of dripping water but also makes it easier for the dried vegetables to be poured out of the retrieval frame 35. Therefore, this solution not only eliminates the need for manual retrieval of dried vegetables but also reduces a large amount of water dripping around the device.
[0032] like Figure 1 , Figure 2 and Figure 3 As shown, the rear wall of the cleaning shell 20 is provided with a receiving structure, which includes an electric cylinder 40, a lower plate 41, a receiving plate 42, and a connecting plate 43. The electric cylinder 40 is fixedly connected to the rear wall of the cleaning shell 20, the lower plate 41 is fixedly connected to one side of the rear wall of the cleaning shell 20, the receiving plate 42 is slidably connected to the top of the rear wall of the cleaning shell 20, and the connecting plate 43 is fixedly connected to one side wall of the receiving plate 42. The retracting end of the electric cylinder 40 can be fixedly connected to the side wall of the connecting plate 43. The receiving plate 42 is located behind the bracket 30, and the connecting plate 43 is located above the lower plate 41. The receiving plate 42 is a shovel-shaped plate, and a circular groove is opened at the bottom of the cavity of the receiving plate 42. The lower plate 41 is a rectangular plate, and a sloping groove is opened at the top of the lower plate 41. The sloping top of the lower plate 41 can communicate with the cavity of the cleaning shell 20. The receiving plate 42 is located above the lower plate 41.
[0033] In actual use, when the retrieval frame 35 rotates the retrieved vegetables to above the receiving plate 42, the vegetables in the cavity of the retrieval frame 35 will fall to the top of the receiving plate 42. At this time, the dripping water mixed in with the vegetables on the top of the receiving plate 42 will leak from the round groove on the wall of the receiving plate 42 into the cavity of the cleaning shell 20. At the same time, when the retrieval frame 35 rotates to above the receiving plate 42, the electric cylinder 40 will extend. When the electric cylinder 40 extends, it will drive the connecting plate 43 and the receiving plate 42 to slide synchronously towards the lower plate 41. At this time, the receiving plate 42 will move the vegetables on its top to directly above the lower plate 41.
[0034] In summary, by setting up a receiving structure to catch the dried vegetables scooped up by the scooping frame 35 using a reciprocating receiving tray 42, and by recycling most of the water droplets dripping from the vegetable wall back into the cleaning shell 20 after catching the vegetables, the environmental friendliness of this solution is effectively improved.
[0035] Working principle: The dried vegetables to be cleaned are poured directly into the cleaning liquid in the cleaning chamber 20. The vegetables are then cleaned by the churning of the cleaning liquid. After cleaning, the servo motor 24 is powered on, driving the rotating column 31 to rotate between the symmetrical supports 30. As the rotating column 31 rotates, it drives the limiting sleeve 32 to rotate synchronously, which in turn drives the sliding cylinder 33 to rotate synchronously. The sliding cylinder 33 then drives the extension arm 34 and the retrieval frame 35 to rotate synchronously. As the retrieval frame 35 rotates, it retrievals the dried vegetables from the cleaning liquid in the cleaning chamber 20. Then, as the sliding cylinder 33 rotates, the trigger 36 rotates synchronously with it. When the trigger 36 rotates to the point where its inclined surface contacts the inclined surface of the fastener 37, the fastener 37 will abut against the trigger 36, causing the sliding cylinder 36 to rotate. The cylinder 33 slides along the limiting sleeve 32. When the limiting sleeve 32 slides, it will compress the spring 38, causing it to shrink. After the trigger 36 and the fastener 37 are misaligned, the spring 38 will release the compressed force, thus resisting the cylinder 33 to slide laterally on the wall of the limiting sleeve 32. At this time, the cylinder 33 will drive the extension arm 34 and the retrieval frame 35 to vibrate synchronously. The vegetables picked up by the retrieval frame 35 will shake off some water as the retrieval frame 35 vibrates. The shaken water will fall back into the cleaning shell 20 cavity. As the retrieval frame 35 drives the vegetables picked up to continue rotating above the receiving plate 42, the vegetables in the cavity of the retrieval frame 35 will fall to the top of the receiving plate 42. At this time, the dripping water mixed in with the vegetables on the top of the receiving plate 42 will leak from the circular groove on the wall of the receiving plate 42 into the cleaning shell 20 cavity.
[0036] It is understood that this utility model has been described through some embodiments, and those skilled in the art will recognize that various changes or equivalent substitutions can be made to these features and embodiments without departing from the spirit and scope of this utility model. Furthermore, under the teachings of this utility model, these features and embodiments can be modified to adapt to specific situations and materials without departing from the spirit and scope of this utility model. Therefore, this utility model is not limited to the specific embodiments disclosed herein, and all embodiments falling within the scope of the claims of this application are within the protection scope of this utility model.
Claims
1. A high-pressure bubble cleaning device for dried vegetables, characterized in that, include: The cleaning shell (20) is a hollow right-angled trapezoidal box with an open top. Multiple rows of aeration pipes (21) are installed at the bottom of the cavity of the cleaning shell (20). A drain valve is installed at the bottom of the cavity of the cleaning shell (20). A support frame (22) is fixedly connected inside the cavity of the cleaning shell (20). A bottom catch (23) is snapped into the top of the support frame (22). The retrieval structure is set on the top of the cleaning shell (20) for retrieving the dried vegetables inside the cavity of the cleaning shell (20). The retrieval structure includes: a rotating column (31), a sliding cylinder (33), an extension arm (34), and a retrieval frame (35). The rotating column (31) is set above the cleaning shell (20). The sliding cylinder (33) is sleeved on the wall of the rotating column (31). The extension arm (34) is fixedly connected to the outer wall of the sliding cylinder (33). The retrieval frame (35) is fixedly connected to the end of the extension arm (34). The retrieval frame (35) is capable of retrieving the dried vegetables inside the cavity of the cleaning shell (20).
2. The high-pressure bubble cleaning device for dried radish according to claim 1, characterized in that, The rotating column (31) is cylindrical, the sliding cylinder (33) is cylindrical, and the outer arc surface of the sliding cylinder (33) is arranged with three identical extension arms (34). The wall of each extension arm (34) is provided with the same retrieval frame (35). The retrieval frame (35) is a rectangular box with a round hole at the bottom of the cavity.
3. The high-pressure bubble cleaning device for dried vegetables according to claim 1, characterized in that, The salvage structure also includes a bracket (30), a servo motor (24), a limiting sleeve (32), a trigger (36), a fastener (37), and a spring (38). The brackets (30) are symmetrically fixedly connected to the top two sides of the cleaning shell (20). The servo motor (24) is fixedly connected to the outer wall of one of the brackets (30). The limiting sleeve (32) is fixedly connected to the wall of the rotating column (31). The trigger (36) is fixedly connected to one side wall of the slide cylinder (33). The fastener (37) is fixedly connected to the wall of the bracket (30) at the servo motor (24). The spring (38) is sleeved on the outer wall of the rotating column (31).
4. The high-pressure bubble cleaning device for dried mustard greens according to claim 3, characterized in that, The bracket (30) is a rectangular plate. The two ends of the rotating column (31) can be inserted into the wall of the symmetrical bracket (30). The servo motor (24) can drive the rotating column (31) to rotate through the coupling. The limiting sleeve (32) is a rectangular sleeve. The limiting sleeve (32) is located at the center of the rotating column (31) biased towards the fastener (37). The cavity space of the slide cylinder (33) can be adapted to the outer wall of the limiting sleeve (32).
5. The high-pressure bubble cleaning device for dried vegetables according to claim 3, characterized in that, The firmware (37) is located on the wall of the bracket (30) facing the limiting sleeve (32). One end of the rotating column (31) can abut against the side wall of the slide cylinder (33). The trigger (36) is a triangular block, and the firmware (37) is also a triangular block. The inclined surface of the firmware (37) can contact the inclined surface of the trigger (36).
6. The high-pressure bubble cleaning device for dried mustard greens according to claim 1, characterized in that, The rear wall of the cleaning shell (20) is provided with a receiving structure, which includes an electric cylinder (40), a lower plate (41), a receiving plate (42), and a connecting plate (43). The electric cylinder (40) is fixedly connected to the rear wall of the cleaning shell (20), the lower plate (41) is fixedly connected to one side of the rear wall of the cleaning shell (20), the receiving plate (42) is slidably connected to the top of the rear wall of the cleaning shell (20), and the connecting plate (43) is fixedly connected to one side of the receiving plate (42).
7. The high-pressure bubble cleaning device for dried vegetables according to claim 6, characterized in that, The retractable end of the electric cylinder (40) can be fixedly connected to the side wall of the connecting plate (43). The receiving plate (42) is located behind the bracket (30). The connecting plate (43) is located above the lower plate (41). The receiving plate (42) is a shovel-shaped plate. A circular groove is provided at the bottom of the cavity of the receiving plate (42). The lower plate (41) is a rectangular plate. A sloping groove is provided at the top of the lower plate (41). The sloping top of the lower plate (41) can communicate with the cavity of the cleaning shell (20). The receiving plate (42) is located above the lower plate (41).