A cleaning device for processing wild chrysanthemum

By designing the water circulation and stirring blade structure of the cleaning device, the problem of secondary pollution from impurities during chrysanthemum cleaning was solved, achieving efficient chrysanthemum cleaning and water resource recycling.

CN224332898UActive Publication Date: 2026-06-09ANLU FURUILONG TRADITIONAL CHINESE MEDICINE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANLU FURUILONG TRADITIONAL CHINESE MEDICINE CO LTD
Filing Date
2025-07-09
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing chrysanthemum cleaning devices tend to pick up floating impurities along with the chrysanthemums when scooping them from the water, causing secondary pollution of the chrysanthemums.

Method used

Design a device that includes a cleaning chamber, a circulation chamber, a mesh plate, an overflow port, a receiving frame, a filter screen, and a rinsing assembly. Through the combined use of water circulation and stirring blades, it achieves the separation of impurities and the effective cleaning of chrysanthemums.

Benefits of technology

It effectively separates floating impurities, keeps the cleaning water clean, ensures the cleaning effect of chrysanthemums, saves water resources, and improves cleaning efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of wild chrysanthemum processing technology and discloses a cleaning device for wild chrysanthemum processing, including a cleaning chamber and a circulation chamber. A support frame is fixedly installed at the top center of the cleaning chamber, and a drive cylinder is installed at the top center of the support frame. The power output shaft of the drive cylinder extends into the cleaning chamber and is fixedly fitted with a mesh plate. An overflow port is opened on the top side of the cleaning chamber, and a receiving frame is fixed at the bottom side of the overflow port. In this application, the wild chrysanthemums to be cleaned can be immersed in water using the mesh plate. During cleaning, impurities on the wild chrysanthemums pass through the mesh plate and float on the water surface. Through the action of water circulation, the impurities floating on the water surface enter the circulation chamber from the overflow port and are intercepted by the filter screen, thereby keeping the water surface of the cleaning chamber clean. This makes it convenient for the wild chrysanthemums to be taken out of the cleaning chamber later, as the wild chrysanthemums will not be adhered to the floating impurities, ensuring the cleaning effect of the wild chrysanthemums.
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Description

Technical Field

[0001] This utility model relates to the field of wild chrysanthemum processing technology, specifically a cleaning device for processing wild chrysanthemums. Background Technology

[0002] Wild chrysanthemum is a perennial herb with creeping stems at the base and many branches in the upper part. Its leaves are alternate, ovate-triangular or ovate-elliptic. Wild chrysanthemum has the effects of clearing heat and detoxifying, and dispelling wind and calming the liver; therefore, it is often used as a raw material in traditional Chinese medicine.

[0003] After harvesting, wild chrysanthemums may have dust, broken leaves, and other impurities on their surface. Therefore, they need to be cleaned before being processed into traditional Chinese medicine.

[0004] A Chinese patent, CN222491265U, describes a chrysanthemum cleaning device, which includes: "a cleaning pool and side troughs. A side trough is located in the middle of the upper part of the left and right sides of the cleaning pool. A telescopic rod is installed in each of the two side troughs. A lower frame is located on the upper right side of the cleaning pool. A side frame is installed on the right side of the lower frame. Filter screens are installed in the middle of both the side frame and the lower frame. A transverse block is fixed in the middle of the upper part of the side frame. A threaded hole is located in the middle of the transverse block. A transmission screw is installed in the threaded hole. A first bearing is connected to the right end of the transmission screw, and a drive motor is connected to its left end. A central rod is located in the middle of the cleaning pool. Compared with the prior art, this invention has the following advantages: By setting up a drive motor, transmission screw, first bearing, transverse block, and threaded hole, after the chrysanthemums are cleaned, they will float on the water surface. The above structure can drive the lower frame and side frame to move to the left, thus facilitating the collection of the floating chrysanthemums above the lower frame."

[0005] Through a search of the aforementioned patented technologies, we found that when cleaning chrysanthemums, the debris or impurities carried on the chrysanthemums float on the water surface due to buoyancy. When using the side frame and middle frame in conjunction with the filter screen to scoop up the chrysanthemums from the water, the impurities floating on the water surface are also scooped up, causing the impurities to re-adhere to the chrysanthemums, resulting in secondary pollution. Therefore, it is necessary to design a cleaning device for processing wild chrysanthemums with better performance to address this situation. Utility Model Content

[0006] To overcome the shortcomings mentioned above, this utility model aims to provide a technical solution that can solve the above problems.

[0007] To achieve the above objectives, this utility model provides the following technical solution: a cleaning device for processing wild chrysanthemums, comprising a cleaning chamber and a circulation chamber. A support frame is fixedly installed at the center of the top of the cleaning chamber, and a drive cylinder is installed at the center of the top of the support frame. The power output shaft of the drive cylinder extends into the cleaning chamber and is fixedly fitted with a mesh plate. An overflow port is opened on the top of one side of the cleaning chamber, and a receiving frame is fixed at the bottom of the overflow port. A water-leaking grille is provided on one side of the bottom wall of the receiving frame, and the bottom of the water-leaking grille is connected to a guide frame placed inside the circulation chamber. A water pump for supplying water to the cleaning chamber is installed on one side of the bottom wall of the circulation chamber.

[0008] As a further embodiment of this utility model: positioning blocks are fixed on both the left and right sides of the inner wall of the cleaning chamber, and limiting rods are fixed on the front and rear sides of the top of each positioning block. The limiting rods movably penetrate the mesh plate and extend out of the cleaning chamber.

[0009] As a further embodiment of this utility model: the front and rear sides of the right side of the inner cavity of the cleaning chamber and the position near the overflow port are all designed with an inclined structure, the overflow port is designed with an inclined structure, the receiving frame is designed with an inclined structure, and the receiving frame is located above the circulation chamber.

[0010] As a further embodiment of this utility model: the circulation chamber is fixed to the right side of the cleaning chamber, and a filter screen is provided inside the cleaning chamber. The water pump is located to the left of the filter screen, the flow guide frame is located to the right of the filter screen and is fixed to the inner wall of the cleaning chamber by a connecting block, and the mesh diameter of the filter screen is smaller than the mesh diameter of the screen plate.

[0011] As a further embodiment of this utility model: the outlet end of the water pump is connected to a guide pipe, and the end of the guide pipe away from the water pump is fixedly inserted through the cleaning chamber and connected to a rinsing assembly. The rinsing assembly includes a diverter pipe, an outlet pipe, and an outlet nozzle.

[0012] As a further embodiment of this utility model: the diversion pipe is fixed to one side of the inner wall of the cleaning chamber and located below the positioning block. The middle of one side of the diversion pipe is connected to the guide pipe. There are several water outlet pipes that are equidistantly connected to the other side of the guide pipe. Each water outlet pipe has water nozzles equidistantly connected to both sides. The water nozzles between every two water outlet pipes are staggered. The water outlet pipe is located below the mesh plate.

[0013] As a further embodiment of this utility model: a servo motor is also installed on the left side of the cleaning chamber and near the bottom. The power output shaft of the servo motor extends through the interior of the cleaning chamber and is connected to a rotating rod. An agitator is fixed in the middle of the rotating rod and is located below the water outlet pipe.

[0014] As a further embodiment of this utility model: the inner bottom walls of both the cleaning chamber and the circulation chamber are designed as inclined structures, and a drain valve is connected to the bottom of one side of both the cleaning chamber and the circulation chamber.

[0015] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0016] I. In this application, through the designed structure of cleaning chamber, drive cylinder, screen plate, overflow port, receiving frame and circulation chamber, the wild chrysanthemums to be cleaned can be submerged in water using the screen plate. During cleaning, impurities on the wild chrysanthemums pass through the screen plate and float on the water surface. Through the action of water circulation, the impurities floating on the water surface enter the circulation chamber from the overflow port and are intercepted by the filter screen, thereby keeping the water surface of the cleaning chamber clean. This makes it convenient to remove the wild chrysanthemums from the cleaning chamber later, as the wild chrysanthemums will not be adhered to the floating impurities, ensuring the cleaning effect of the wild chrysanthemums.

[0017] Second, in this application, the water circulation effect of the cleaning chamber and the circulation chamber can keep the water flowing continuously, and continuously send the impurities floating on the surface of the water in the cleaning chamber into the circulation chamber. After being filtered and intercepted by the filter screen, the cleaning water can be recycled, saving water resources and ensuring the cleaning effect of wild chrysanthemums.

[0018] Third, in this application, the designed rinsing component allows the water flow from the water nozzle to come into contact with the wild chrysanthemums in the water, washing away impurities on the wild chrysanthemums. The water flow from the water nozzle can also move the wild chrysanthemums in the water, preventing them from remaining still. In addition, the designed stirring blades can agitate the cleaning water inside the cleaning chamber, further moving the wild chrysanthemums in the water and achieving a better cleaning effect. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the overall three-dimensional structure of this utility model;

[0020] Figure 2 This is a front sectional view of the structure of this utility model;

[0021] Figure 3 This is a three-dimensional structural diagram of the mesh plate of this utility model;

[0022] Figure 4 This is a three-dimensional structural diagram of the flushing assembly of this utility model.

[0023] The reference numerals and names in the figure are as follows:

[0024] 1. Cleaning chamber; 2. Circulation chamber; 3. Overflow port; 4. Receiving frame; 5. Leakage grille; 6. Guide frame; 7. Filter screen; 8. Water pump; 801. Guide pipe; 9. Support frame; 10. Drive cylinder; 11. Mesh plate; 12. Limiting rod; 13. Flushing assembly; 1301. Diverter pipe; 1302. Water outlet pipe; 1303. Water outlet nozzle; 14. Positioning block; 15. Servo motor; 16. Rotating rod; 17. Agitator blade; 18. Drain valve. Detailed Implementation

[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0026] Please see Figure 1-4 A cleaning device for processing wild chrysanthemums includes a cleaning chamber 1 and a circulation chamber 2. A support frame 9 is fixedly installed at the center of the top of the cleaning chamber 1. A drive cylinder 10 is installed at the center of the top of the support frame 9. The power output shaft of the drive cylinder 10 extends into the cleaning chamber 1 and is fixedly fitted with a mesh plate 11. The support frame 9 is fixed on the cleaning chamber 1 and can support the drive cylinder 10 to ensure the stability of the drive cylinder 10 during operation. An overflow port 3 is opened on the top of one side of the cleaning chamber 1. A receiving frame 4 is fixed at the bottom of one side of the overflow port 3. A water-leaking grid 5 is provided on one side of the bottom wall of the receiving frame 4. The bottom of the water-leaking grid 5 is connected to a guide frame 6 placed inside the circulation chamber 2. The water-leaking grid 5 does not filter impurities. Impurities can pass through the water-leaking grid 5 and enter the guide frame 6. The water-leaking grid 5 can block relatively large wild chrysanthemums to prevent them from falling into the guide frame 6. A water pump 8 for supplying water to the cleaning chamber 1 is installed on one side of the bottom wall of the circulation chamber 2.

[0027] Please see Figure 1 , Figure 2 and Figure 3 In this embodiment, positioning blocks 14 are fixed on both the left and right sides of the inner wall of the cleaning chamber 1. Each positioning block 14 has a limit rod 12 fixed on the front and rear sides of its top. The limit rod 12 moves through the mesh plate 11 and extends out of the cleaning chamber 1.

[0028] Specifically, the positioning block 14 can position the downward movement of the mesh plate 11 on the one hand, and support and fix the limiting rod 12 on the other hand. The limiting rod 12 can limit the four corners of the mesh plate 11 to ensure the stability of the mesh plate 11 during movement.

[0029] Please see Figure 2In this embodiment, the front and rear sides of the right side of the inner cavity of the cleaning chamber 1 and the position near the overflow port 3 are all designed as inclined structures. The overflow port 3 is designed as an inclined structure, the receiving frame 4 is designed as an inclined structure, and the receiving frame 4 is located above the circulation chamber 2.

[0030] Specifically, the front and rear sides of the right side of the inner cavity of the cleaning chamber 1 are designed with an inclined structure, which can guide the water flow and facilitate the water flow to carry floating impurities into the overflow port 3 and into the receiving frame 4. The receiving frame 4 is designed with an inclined structure to facilitate the flow of water and enable the water flow to carry impurities into the guide frame 6.

[0031] Please see Figure 1 and Figure 2 In this embodiment, the circulation chamber 2 is fixed to the right side of the cleaning chamber 1, and the cleaning chamber 1 is equipped with a filter screen 7. The water pump 8 is located to the left of the filter screen 7, the guide frame 6 is located to the right of the filter screen 7 and is fixed to the inner wall of the cleaning chamber 1 by a connecting block, and the mesh diameter of the filter screen 7 is smaller than the mesh diameter of the screen plate 11.

[0032] Specifically, the filter screen 7 can filter impurities carried by the water flow, preventing impurities from entering the left side of the filter screen 7 and affecting the water pump 8. The aperture of the filter screen 7 is smaller than that of the mesh plate 11. The effect is that the filter screen 7 filters impurities, while the mesh plate 11 only presses down the relatively large wild chrysanthemums, and the impurities will pass through the mesh holes on the mesh plate 11 and float on the water surface.

[0033] Please see Figure 2 and Figure 4 In this embodiment, the outlet end of the water pump 8 is connected to a guide pipe 801. The end of the guide pipe 801 away from the water pump 8 is fixedly inserted through the cleaning chamber 1 and connected to the rinsing assembly 13. The rinsing assembly 13 includes a diversion pipe 1301, an outlet pipe 1302, and an outlet nozzle 1303. The diversion pipe 1301 is fixed on one side of the inner wall of the cleaning chamber 1 and located below the positioning block 14. The middle of one side of the diversion pipe 1301 is connected to the guide pipe 801. There are several outlet pipes 1302 connected at equal intervals to the other side of the guide pipe 801. Each outlet pipe 1302 has an outlet nozzle 1303 connected at equal intervals on both sides. The outlet nozzles 1303 between every two outlet pipes 1302 are staggered. The outlet pipes 1302 are located below the mesh plate 11.

[0034] Specifically, after the wild chrysanthemum is pressed down by the mesh plate 11, it can be pressed between multiple water outlet pipes 1302. After the water pump 8 is started, the clean water inside the circulation chamber 2 can be transported to the rinsing component 13 through the guide pipe 801 and discharged through multiple water outlet nozzles 1303. Since the multiple water outlet nozzles 1303 are staggered, the water flow can continuously contact the wild chrysanthemum in the water, which can better wash away the impurities carried on the wild chrysanthemum.

[0035] Please see Figure 2 In this embodiment, a servo motor 15 is installed on the left side of the cleaning chamber 1 near the bottom. The power output shaft of the servo motor 15 extends through the interior of the cleaning chamber 1 and is connected to a rotating rod 16. An agitator 17 is fixed in the middle of the rotating rod 16 and is located below the water outlet pipe 1302.

[0036] Specifically, depending on the actual cleaning situation, when cleaning a large number of wild chrysanthemums at once, the servo motor 15 can be started. The power output shaft of the servo motor 15 drives the rotating rod 16 to rotate, thereby driving the stirring blade 17 to stir the cleaning water inside the cleaning chamber 1. The movement of the cleaning water can then move the wild chrysanthemums in the water, making it easier for impurities on the wild chrysanthemums to fall off, resulting in a better cleaning effect.

[0037] Please see Figure 1 and Figure 2 In this embodiment, the inner bottom walls of both the cleaning chamber 1 and the circulation chamber 2 are designed as inclined structures, and a drain valve 18 is connected to the bottom of one side of both the cleaning chamber 1 and the circulation chamber 2.

[0038] Specifically, the inner bottom walls of both the cleaning chamber 1 and the circulation chamber 2 are designed with an inclined structure, which facilitates the subsequent drainage of water from the cleaning chamber 1 and the circulation chamber 2 by opening the drain valve 18 respectively, thus facilitating the cleaning of the interior of the cleaning chamber 1 and the circulation chamber 2 and making subsequent use more convenient.

[0039] When in use: Place the wild chrysanthemums that need to be cleaned into the cleaning chamber 1, and then start the drive cylinder 10. The power output shaft of the drive cylinder 10 extends and presses down the screen plate 11. The screen plate 11 moves into the cleaning chamber 1 and presses down the wild chrysanthemums floating on the water surface, so that the wild chrysanthemums are submerged in the water.

[0040] Water pump 8 inputs water from inside the circulation chamber 2 into the diversion pipe 1301 through the guide pipe 801. After entering the diversion pipe 1301, the cleaning water enters multiple outlet pipes 1302 and is sprayed out through the outlet nozzle 1303. After the water is sprayed out from the outlet nozzle 1303, it comes into contact with the wild chrysanthemums in the water, thereby washing away the impurities on the wild chrysanthemums. The impurities float to the surface of the water after passing through the mesh plate 11. As water pump 8 continuously supplies water into the cleaning chamber 1, the impurities floating on the surface of the water will be discharged through the overflow port 3 along with the excess water, and will enter the guide frame 6 through the receiving frame 4 and return to the circulation chamber 2. In the circulation chamber 2, the water is filtered by the filter screen 7, so that water pump 8 can always send clean water into the cleaning chamber 1.

[0041] During the cleaning process, when cleaning a large number of wild chrysanthemums at once, the servo motor 15 can be started. The power output shaft of the servo motor 15 drives the rotating rod 16 to rotate. The rotating rod 16 drives the stirring blade 17 to stir in the water, thereby moving the wild chrysanthemums in the water and making it easier to remove impurities from the wild chrysanthemums.

[0042] After the wild chrysanthemums have been cleaned, the drive cylinder 10 can be activated to lift the mesh plate 11 away from the top of the cleaning chamber 1, so that the cleaned wild chrysanthemums float on the water surface again. At this time, through the action of water flow, the wild chrysanthemums can enter the receiving frame 4 through the overflow port 3. The staff can also use tools to pull the wild chrysanthemums out of the overflow port 3 and into the receiving frame 4. At this time, the wild chrysanthemums are received in the receiving frame 4, and the staff can easily take the cleaned wild chrysanthemums from the receiving frame 4.

[0043] It should be noted that during cleaning, some impurities floating on the water surface may be discharged slowly because they are far from the overflow outlet 3. In this case, staff can use tools to move the impurities far from the overflow outlet 3, so that the impurities floating on the water surface can be discharged more quickly. They can also manually pick up the larger impurities floating on the water surface. After cleaning, the impurities that fail to float on the water surface will settle on the inner bottom wall of the cleaning chamber 1, so as to facilitate subsequent discharge.

[0044] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A cleaning device for processing wild chrysanthemums, characterized in that, It includes a cleaning chamber (1) and a circulation chamber (2). A support frame (9) is fixed at the top center of the cleaning chamber (1). A drive cylinder (10) is installed at the top center of the support frame (9). The power output shaft of the drive cylinder (10) extends into the cleaning chamber (1) and is fixed with a mesh plate (11). An overflow port (3) is provided on the top of one side of the cleaning chamber (1). A receiving frame (4) is fixed at the bottom of one side of the overflow port (3). A water-leaking grid (5) is provided on one side of the bottom wall of the receiving frame (4). A guide frame (6) placed inside the circulation chamber (2) is connected to the bottom of the water-leaking grid (5). A water pump (8) for supplying water to the cleaning chamber (1) is installed on one side of the bottom wall of the circulation chamber (2).

2. The cleaning device for processing wild chrysanthemums according to claim 1, characterized in that, Positioning blocks (14) are fixed on both the left and right sides of the inner wall of the cleaning chamber (1). Each positioning block (14) has a limit rod (12) fixed on the front and back sides of its top. The limit rod (12) moves through the mesh plate (11) and extends out of the cleaning chamber (1).

3. The cleaning device for processing wild chrysanthemums according to claim 1, characterized in that, The front and rear sides of the right side of the inner cavity of the cleaning chamber (1) and the position near the overflow port (3) are all designed with an inclined structure. The overflow port (3) is designed with an inclined structure. The receiving frame (4) is designed with an inclined structure. The receiving frame (4) is located above the circulation chamber (2).

4. The cleaning device for processing wild chrysanthemums according to claim 1, characterized in that, The circulation chamber (2) is fixed to the right side of the cleaning chamber (1), and a filter screen (7) is provided inside the cleaning chamber (1). The water pump (8) is located to the left of the filter screen (7), and the flow guide frame (6) is located to the right of the filter screen (7) and is fixed to the inner wall of the cleaning chamber (1) by a connecting block. The mesh diameter of the filter screen (7) is smaller than the mesh diameter of the screen plate (11).

5. The cleaning device for processing wild chrysanthemums according to claim 1, characterized in that, The outlet end of the water pump (8) is connected to a guide pipe (801). The end of the guide pipe (801) away from the water pump (8) is fixedly inserted through the cleaning chamber (1) and connected to a flushing assembly (13). The flushing assembly (13) includes a diversion pipe (1301), an outlet pipe (1302), and an outlet nozzle (1303).

6. The cleaning device for processing wild chrysanthemums according to claim 5, characterized in that, The diversion pipe (1301) is fixed on one side of the inner wall of the cleaning chamber (1) and located below the positioning block (14). The middle of one side of the diversion pipe (1301) is connected to the guide pipe (801). There are several water outlet pipes (1302) that are equidistantly connected to the other side of the guide pipe (801). Each water outlet pipe (1302) has water outlet nozzles (1303) equidistantly connected to both sides. The water outlet nozzles (1303) between every two water outlet pipes (1302) are staggered. The water outlet pipe (1302) is located below the mesh plate (11).

7. The cleaning device for processing wild chrysanthemums according to claim 1, characterized in that, A servo motor (15) is installed on the left side of the cleaning chamber (1) near the bottom. The power output shaft of the servo motor (15) extends through the interior of the cleaning chamber (1) and is connected to a rotating rod (16). An agitator (17) is fixed in the middle of the rotating rod (16) and is located below the water outlet pipe (1302).

8. A cleaning device for processing wild chrysanthemums according to claim 1, characterized in that, The inner bottom walls of the cleaning chamber (1) and the circulation chamber (2) are both designed as inclined structures, and the bottom of one side of the cleaning chamber (1) and the circulation chamber (2) are connected to a drain valve (18).