Traditional Chinese medicine material water treatment grid structure
By designing alternating grid components and a motor-driven wire rope system, the problem of production efficiency in cleaning the grid structure in the water treatment system of a traditional Chinese medicine processing plant was solved, enabling continuous cleaning of impurities without interrupting water treatment and improving production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BEIJING HUAYANG KUILONG PHARM CO LTD
- Filing Date
- 2025-07-03
- Publication Date
- 2026-06-05
AI Technical Summary
The existing water treatment system in Chinese herbal medicine processing plants requires interrupting water flow when cleaning the bar screen structure, which affects production efficiency.
A traditional Chinese medicine water treatment grid structure was designed, which includes a gantry frame, a grid assembly, a guide assembly, and a traction device. By using two sets of grid assemblies alternately, the vertical movement of the grid assemblies is achieved using a motor and a wire rope system, thus cleaning impurities without interrupting the water treatment system.
It enables continuous cleaning of impurities from Chinese medicinal herbs after washing without interrupting the water treatment system, thereby improving the production efficiency of Chinese medicinal herb processing plants.
Smart Images

Figure CN224321127U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of grid structure technology, specifically to a grid structure for water treatment of traditional Chinese medicine materials. Background Technology
[0002] Traditional Chinese medicinal herbs are unique native medicinal materials in my country, used to treat diseases. They mainly include the roots, stems, flowers, and fruits of various plants. In the modern processing and production of traditional Chinese medicinal herbs, the cleaning of raw materials is a crucial pre-treatment process, especially for roots, stems, minerals, and some fruits. During harvesting, transportation, and storage, they often accumulate a large amount of impurities such as gravel, weeds, and leaf fragments. These impurities not only affect subsequent processes such as cutting, processing, and extraction, but also directly relate to the quality, safety, and efficacy of the final medicine. After cleaning the medicinal herbs, the impurities are discharged along with the wastewater. To reduce the discharge of impurities, a grid structure is needed in the water treatment of traditional Chinese medicinal herb processing plants. Its core function is to intercept and separate larger solid impurities carried by the herbs, preventing them from entering subsequent water treatment units and causing blockages.
[0003] Currently, the bar screens used in water treatment at Chinese herbal medicine processing plants generally require interrupting the water treatment system when it is necessary to remove impurities such as gravel, weeds, and leaf fragments. This means stopping the flow of wastewater and subsequent treatment processes, which makes continuous operation impossible and thus affects the production efficiency of Chinese herbal medicine processing plants. Utility Model Content
[0004] The purpose of this utility model is to overcome the defects of the prior art and provide a grid structure for water treatment of Chinese medicinal materials to solve the problems mentioned in the background art.
[0005] A water treatment grid structure for traditional Chinese medicine materials, comprising:
[0006] Gantry frame;
[0007] The grid assembly consists of two sets of grid assemblies, which are slidably disposed on the front and rear sides inside the gantry frame, with the two sets of grid assemblies arranged one above the other.
[0008] The guide assembly has two sets and is respectively embedded and fixed on the front and rear sides of the inner wall of the gantry frame. The two sets of guide assemblies are used to guide the vertical movement of the two sets of grid assemblies.
[0009] A traction device is fixed to the upper end of the gantry frame. The traction device is connected to two sets of the grid assemblies respectively. The traction device is used to individually traction the two sets of the grid assemblies to move vertically.
[0010] Preferably, external motor buttons are fixedly installed on both the upper and lower sides of the front end of the gantry frame.
[0011] Preferably, the grid assembly includes a grid mesh and a grid base, the grid mesh being slidably connected inside the gantry frame, and the grid base being vertically fixed to the lower end of the grid mesh, the grid mesh and the grid base forming an L-shape.
[0012] Preferably, the guide assembly includes a guide rail, a guide block, a built-in motor button, and a spring rod. The guide rail is embedded and fixed to the gantry frame, the guide block is slidably connected inside the guide rail, and the guide block is fixed to the upper part of the grid.
[0013] Preferably, the built-in motor buttons are a pair and symmetrically fixed at the upper and lower ends of the inner wall of the guide rail. Each built-in motor button has a spring rod on both sides, one end of which is fixed to the inner wall of the guide rail. The guide block is in contact with the built-in motor buttons and the spring rods.
[0014] Preferably, the traction device includes a housing, a controller, a motor, a worm gear, a shaft, a worm wheel, a rope pulley, and a wire rope. The housing is fixed to the gantry frame. The controller is fixed to the right end of the inner wall of the housing. There is a pair of motors, which are respectively fixed to the front and rear sides of the right end inside the housing. The external motor button and the internal motor button are both connected to the controller. The controller is connected to the motor. The upper and lower external motor buttons are respectively connected to the two motors through the controller. The internal motor button on the lower side of the front guide rail is respectively connected to the two motors through the controller. The internal motor button on the upper side of the front guide rail is connected to the front motor through the controller. The internal motor button on the lower side of the rear guide rail is respectively connected to the two motors through the controller. The internal motor button on the upper side of the rear guide rail is connected to the rear motor through the controller.
[0015] Preferably, the output shaft of the motor is connected to a worm gear at its end, and a worm wheel is connected to the upper part of the worm gear. A shaft is fixed at the center of the worm wheel. The first end of the shaft is connected to a bearing on the inner wall of the housing. A bearing seat is installed at the end of the shaft. The lower part of the bearing seat is fixed to the bottom of the housing. A rope pulley is fixed to the outside of the shaft and on one side of the worm wheel. A steel wire rope is wound around the outside of the rope pulley. The end of the steel wire rope passes through the housing and the gantry frame. The ends of the front and rear steel wire ropes are fixed to the upper ends of the front and rear grid panels, respectively.
[0016] The beneficial effects of this utility model are as follows: By setting two sets of grid components to be used alternately, when one set of grid components needs to clean the impurities blocked by the medicinal materials being washed, pressing the corresponding external motor button will cause the other set of grid components to move vertically downwards and stop automatically. At the same time, the grid component that needs to be cleaned will automatically move upwards and stop automatically. In this way, without interrupting the water treatment system in the medicinal material processing plant, the grid components can be used to block impurities such as gravel, weeds, and leaf fragments in the washing wastewater, thereby ensuring the efficiency of medicinal material processing in the medicinal material processing plant. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the overall design of this utility model.
[0018] Figure 2 This is a top view sectional diagram of the traction device of this utility model.
[0019] Figure 3 This is a side view of the guide component of this utility model.
[0020] In the diagram: 1. Gantry frame; 11. External motor button; 2. Grid assembly; 21. Grid mesh; 22. Grid base; 3. Guide assembly; 31. Guide rail; 32. Guide block; 33. Internal motor button; 34. Spring rod; 4. Traction device; 41. Chassis; 42. Controller; 43. Motor; 44. Worm gear; 45. Bearing seat; 46. Shaft; 47. Worm wheel; 48. Rope pulley; 49. Wire rope. Detailed Implementation
[0021] like Figures 1-3 As shown, a water treatment grid structure for traditional Chinese medicine includes:
[0022] Gantry frame 1, with external motor buttons 11 fixedly installed on both the upper and lower sides of the front end of the gantry frame 1;
[0023] The grid assembly 2 consists of two sets, which are slidably installed on the front and rear sides inside the gantry frame 1. The two sets of grid assemblies 2 are arranged one above the other. The grid assembly 2 includes a grid mesh 21 and a grid base 22. The grid mesh 21 is slidably connected inside the gantry frame 1, and the grid base 22 is vertically fixed to the lower end of the grid mesh 21. Since the grid mesh 21 and the grid base 22 form an L-shape, after the water flows through the grid mesh 21, impurities such as gravel, weeds, and leaf fragments are blocked by the grid mesh 21 and located on the upper part of the grid base 22. This makes it convenient for the staff of the Chinese herbal medicine processing plant to clean the impurities on the grid base 22.
[0024] Guide components 3, comprising two sets respectively embedded and fixed on the front and rear sides of the inner wall of the gantry frame 1, are used to guide the vertical movement of the two sets of grid components 2. Each guide component 3 includes a guide rail 31, a guide block 32, a built-in motor button 33, and a spring rod 34. The guide rail 31 is embedded and fixed to the gantry frame 1, the guide block 32 is slidably connected inside the guide rail 31 and fixed to the upper part of the grid mesh 21, and the built-in motor button 33 is a pair symmetrically fixed on the inner wall of the guide rail 31. At both ends, spring rods 34 are provided on both sides of the built-in motor button 33. One end of the spring rod 34 is fixed to the inner wall of the guide rail 31. The guide block 32 contacts the built-in motor button 33 and the spring rod 34. When the grid 21 moves vertically up and down, it can drive the guide block 32 to slide along the guide rail 31. This not only plays a guiding role, but also when the grid 21 moves up to the top or down to the bottom, it can drive the guide block 32 to contact the spring rod 34 first to play a buffering role, and then contact the built-in motor button 33.
[0025] A traction device 4 is fixed to the upper end of the gantry frame 1. The traction device 4 is connected to two sets of the grid assembly 2 respectively. The traction device 4 is used to individually traction the two sets of grid assembly 2 for vertical movement. The traction device 4 includes a housing 41, a controller 42, a motor 43, a worm gear 44, a shaft 46, a worm wheel 47, a rope pulley 48, and a wire rope 49. The housing 41 is fixed to the gantry frame 1. The controller 42 is fixed to the right end of the inner wall of the housing 41. There is a pair of motors 43, which are respectively fixed to the front and rear sides of the right end inside the housing 41. Both the external motor button 11 and the internal motor button 33 are connected to the controller 42. The controller 42 is connected to the motor 43. The two external motor buttons 11 are connected via a control mechanism. The controller 42 is connected to two motors 43 respectively. The built-in motor button 33 on the lower side of the front guide rail 31 is connected to both motors 43 via the controller 42. The built-in motor button 33 on the upper side of the front guide rail 31 is connected to the front motor 43 via the controller 42. The built-in motor button 33 on the lower side of the rear guide rail 31 is connected to both motors 43 via the controller 42. The built-in motor button 33 on the upper side of the rear guide rail 31 is connected to the rear motor 43 via the controller 42. The output shaft of each motor 43 is connected to a worm gear 44. The upper part of each worm gear 44 is connected to a worm wheel 47. A shaft 46 is fixed at the center of each worm wheel 47. The first end of the rod 46 is connected to the bearing on the inner wall of the housing 41. Each end of the rod 46 is equipped with a bearing seat 45, the lower part of which is fixed to the bottom of the housing 41. A rope pulley 48 is fixed to the outside of each rod 46 and to one side of the worm gear 47. A steel wire rope 49 is wound around the outside of each rope pulley 48. The end of the steel wire rope 49 passes through the housing 41 and the gantry frame 1. The ends of the front and rear steel wire ropes 49 are respectively fixed to the upper ends of the front and rear grid meshes 21. When the front grid mesh 21 needs cleaning, the external motor button 11 on the upper side is pressed. The external motor button 11 causes the rear motor 43 to rotate forward. This causes the rear motor 43 to drive the worm gear 44 to rotate, and the worm gear 44, through transmission with the worm wheel 47, drives the rear... When shaft 46 rotates, the rear shaft 46 drives the rear pulley 48 to rotate, unwinding the wire rope 49. At this time, the rear wire rope 49 lowers onto the rear grid mesh 21. As the rear grid mesh 21 moves down, it contacts the built-in motor button 33 below. This built-in motor button 33 stops the rear motor 43 and simultaneously reverses the front motor 43. The front motor 43 then drives the worm gear 44 to rotate. The worm gear 44 and worm wheel 47 drive the front shaft 46 to rotate, which in turn drives the front pulley 48 to rotate, winding the wire rope 49. Simultaneously, the front wire rope 49 pulls up the front grid mesh 21. As the front grid mesh 21 moves up, it contacts the built-in motor button 33 above.The built-in motor button 33 stops the front motor 43, allowing the front grille 21 to be cleaned. Simultaneously, the rear grille 21 filters out impurities from the wastewater after washing the medicinal herbs.
[0026] When the rear grid mesh 21 needs cleaning, press the external motor button 11 on the lower side. The external motor button 11 on the lower side will cause the front motor 43 to rotate forward. This will drive the worm gear 44 to rotate. The worm gear 44 and worm wheel 47 will drive the front shaft 46 to rotate. The front shaft 46 will then drive the front rope pulley 48 to rotate and unwind the wire rope 49. At this time, the front wire rope 49 will lower the front grid mesh 21. As the front grid mesh 21 moves down, it will contact the internal motor button 33 below. The internal motor button 33 will stop the front motor 43 and simultaneously control... The rear motor 43 reverses, driving the worm gear 44 to rotate. The worm gear 44 and worm wheel 47 drive the rear shaft 46 to rotate, which in turn drives the rear rope wheel 48 to rotate and wind up the wire rope 49. At this time, the rear wire rope 49 pulls up the rear grid 21. As the rear grid 21 moves up to the guide block 32 and contacts the built-in motor button 33 above, the built-in motor button 33 controls the rear motor 43 to stop. At this time, the rear grid 21 can be cleaned, and the front grid 21 is used to block impurities in the wastewater after washing the Chinese medicinal materials.
[0027] In summary, by setting up two sets of grid components 2 to be used alternately, when one set of grid components 2 needs to clean the impurities blocked by the medicinal materials being washed, pressing the corresponding external motor button 11 will cause the other set of grid components 2 to move vertically downwards and stop automatically. At the same time, the grid component 2 that needs to be cleaned will automatically move upwards and stop automatically. In this way, without interrupting the water treatment system in the medicinal material processing plant, the grid components 2 can be used to block impurities such as gravel, weeds, and leaf fragments in the washing wastewater, thereby ensuring the efficiency of medicinal material processing in the medicinal material processing plant.
Claims
1. A bar screen structure for water treatment of traditional Chinese medicinal materials, characterized in that, include: Gantry frame (1); The grid assembly (2) has two sets and is slidably disposed on the front and rear sides inside the gantry frame (1), with the two sets of grid assemblies (2) arranged one above the other; The guide assembly (3) has two sets and is embedded and fixed on the front and rear sides of the inner wall of the gantry frame (1). The two sets of guide assemblies (3) are used to guide the vertical movement of the two sets of grid assemblies (2). The traction device (4) is fixed on the upper end of the gantry frame (1). The traction device (4) is connected to the two sets of grid assemblies (2) respectively. The traction device (4) is used to pull the two sets of grid assemblies (2) vertically.
2. The water treatment grid structure for traditional Chinese medicinal materials according to claim 1, characterized in that: External motor buttons (11) are fixedly installed on both the upper and lower sides of the front end of the gantry frame (1).
3. The water treatment grid structure for traditional Chinese medicinal materials according to claim 2, characterized in that: The grid assembly (2) includes a grid mesh (21) and a grid base (22). The grid mesh (21) is slidably connected inside the gantry frame (1), and the grid base (22) is vertically fixed at the lower end of the grid mesh (21). The grid mesh (21) and the grid base (22) form an L-shape.
4. The water treatment grid structure for traditional Chinese medicinal materials according to claim 3, characterized in that: The guide assembly (3) includes a guide rail (31), a guide block (32), a built-in motor button (33) and a spring rod (34). The guide rail (31) is embedded and fixed to the gantry frame (1). The guide block (32) is slidably connected inside the guide rail (31). The guide block (32) is fixed to the upper part of the grid mesh (21).
5. The water treatment grid structure for traditional Chinese medicinal materials according to claim 4, characterized in that: The built-in motor button (33) has a pair and is symmetrically fixed at the upper and lower ends of the inner wall of the guide rail (31). The built-in motor button (33) is provided with spring rods (34) on both sides. One end of the spring rod (34) is fixed to the inner wall of the guide rail (31). The guide block (32) is in contact with the built-in motor button (33) and the spring rod (34).
6. The water treatment grid structure for traditional Chinese medicinal materials according to claim 5, characterized in that: The traction device (4) includes a housing (41), a controller (42), a motor (43), a worm gear (44), a shaft (46), a worm wheel (47), a rope pulley (48), and a wire rope (49). The housing (41) is fixed to the gantry frame (1). The controller (42) is fixed to the right end of the inner wall of the housing (41). There is a pair of motors (43) and they are respectively fixed to the front and rear sides of the right end inside the housing (41). The external motor button (11) and the internal motor button (33) are both connected to the controller (42). The controller (42) is connected to the motor (43). The upper and lower external motor buttons (11) are connected to the controller. (42) Connected to the two motors (43) respectively. The built-in motor button (33) on the lower side of the front guide rail (31) is connected to the two motors (43) respectively through the controller (42). The built-in motor button (33) on the upper side of the front guide rail (31) is connected to the front motor (43) through the controller (42). The built-in motor button (33) on the lower side of the rear guide rail (31) is connected to the two motors (43) respectively through the controller (42). The built-in motor button (33) on the upper side of the rear guide rail (31) is connected to the rear motor (43) through the controller (42).
7. The water treatment grid structure for traditional Chinese medicinal materials according to claim 6, characterized in that: The output shaft of each motor (43) is connected to a worm gear (44). The upper part of each worm gear (44) is connected to a worm wheel (47). A shaft (46) is fixed at the center of each worm wheel (47). The first end of the shaft (46) is connected to a bearing on the inner wall of the housing (41). A bearing seat (45) is installed at the end of each shaft (46). The lower part of the bearing seat (45) is fixed to the bottom of the housing (41). A rope wheel (48) is fixed outside the shaft (46) and on one side of the worm wheel (47). A wire rope (49) is wound around the outside of the rope wheel (48). The end of the wire rope (49) moves through the housing (41) and the gantry (1). The ends of the front and rear wire ropes (49) are fixed to the upper ends of the front and rear grid meshes (21), respectively.