Water treatment mixing mechanism for disinfection
By integrating an upper and lower active conveying, vertical convection, and turbulence-inducing mixing system, the problem of uneven mixing of large volumes of disinfectant water was solved, achieving rapid and uniform mixing while reducing energy and reagent consumption.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- WEIFANG SIYUAN ENVIRONMENTAL PROTECTION EQUIPCO
- Filing Date
- 2026-04-27
- Publication Date
- 2026-07-03
AI Technical Summary
Existing disinfection water treatment mixing mechanisms suffer from uneven mixing, low efficiency, and long processing times when handling large volumes of water, resulting in extended preparation cycles, increased reagent consumption, and energy waste.
An integrated mixing system employing an upper and lower active conveying structure, vertical convection components, and turbulence components achieves directional liquid exchange through the design of upper and lower delivery pipes on the active shaft. The drive blades and inclined blades of the vertical components create forced convection, while the levers and elastic plates of the turbulence components generate irregular disturbances, thus achieving multi-level mixing.
It significantly shortens mixing time, improves mixing uniformity, reduces reagent waste, lowers operating costs, and enhances the ease of operation and economical maintenance of the equipment.
Smart Images

Figure CN122098326B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of disinfection water treatment technology, and more specifically, to a disinfection water treatment mixing mechanism. Background Technology
[0002] In existing technologies, disinfection water treatment mixing mechanisms typically employ a single-point mechanical stirring method. A motor drives a stirring paddle to rotate at the center of the mixing tank to achieve uniform mixing of various raw materials. However, when the volume of water to be treated is large and the amount of raw materials added increases accordingly, this traditional stirring method faces a significant efficiency bottleneck. As the stirring energy in the liquid decreases rapidly with distance, the liquid flow in areas far from the stirring paddle is slow or even forms dead zones, resulting in excessively high local concentrations of raw materials and uneven overall mixing. At the same time, the characteristic that multiple raw materials need to be added sequentially makes the mixing process exhibit obvious temporal differences, further prolonging the time required to achieve uniform mixing.
[0003] The aforementioned technical defects directly lead to a longer preparation cycle and increased consumption of disinfectant water in practical applications. Due to incomplete mixing, excessive amounts of raw materials are often required to ensure disinfection effects. This not only increases operating costs but may also cause side reactions due to excessively high local concentrations. Furthermore, the low stirring efficiency forces the equipment to run continuously for a long time to meet the needs of subsequent processes, resulting in energy waste and reducing the overall treatment capacity of the entire water treatment system. Summary of the Invention
[0004] (a) Technical problems to be solved
[0005] In view of the problems existing in the prior art, the present invention provides a disinfection water treatment mixing mechanism to solve the technical problems mentioned in the background art.
[0006] (II) Technical Solution
[0007] To achieve the above objectives, the present invention provides the following technical solution: a disinfection water treatment mixing mechanism, comprising a storage tank; and further comprising a stirring mechanism and a conveying mechanism;
[0008] The stirring mechanism includes a drive shaft installed inside the storage tank. Two sets of upper and lower delivery pipes are fixedly installed at the upper and lower ends of the drive shaft, respectively. The upper and lower delivery pipes are staggered. The lower delivery pipe is converging from top to bottom, and the upper delivery pipe is expanding from top to bottom. Multiple sets of side wall holes are equally spaced on the side walls of the upper and lower delivery pipes. Liquids with different concentrations at the upper and lower ends are transported and mixed through the upper and lower delivery pipes.
[0009] The conveying mechanism includes two feeding pipes installed on the side wall of the storage tank, with the two feeding pipes located on the upper and lower sides of the storage tank respectively, and a discharge pipe installed at the lower end of the storage tank.
[0010] Preferably, two sets of horn tubes are respectively connected to the upper end of the lower delivery pipe and the lower end of the upper delivery pipe, the two sets of horn tubes are respectively connected to the lower delivery pipe and the upper delivery pipe, and the multiple sets of horn tubes are respectively arranged along the stirring direction of the drive shaft.
[0011] Preferably, the stirring mechanism further includes a vertical component and a turbulence component, and the stirring mechanism also includes a motor installed at the upper end of the storage tank, the drive end of the motor being connected to the drive shaft, and a cover plate being movably provided at the upper end of the storage tank.
[0012] Preferably, the vertical assembly includes a drive frame mounted on the drive shaft, the drive frame being provided with multiple sets of drive rods, each set of drive rods having an upper stirring sleeve and a lower stirring sleeve rotatably mounted thereon, and the multiple sets of upper and lower stirring sleeves being arranged alternately in a vertical arrangement.
[0013] Preferably, drive blades are installed on the upper and lower stirring sleeves respectively, with the drive blades of the lower stirring sleeve installed at the lower end and the drive blades of the upper stirring sleeve installed at the upper end. Inclined blades are also installed on the upper and lower stirring sleeves respectively, and the inclined blades are connected to the drive blades.
[0014] Preferably, the upper and lower stirring sleeves are both equipped with synchronous pulleys on the same plane, and the outer sides of the multiple synchronous pulleys are respectively engaged with synchronous belts.
[0015] Preferably, the turbulence assembly includes a lever mounted on the upper end of the lower stirring sleeve, an inner disk rotatably mounted on the drive rod, and multiple sets of elastic plates evenly spaced on the outer wall of the inner disk, wherein the distance between the outermost ends of the multiple elastic plates is greater than the distance between the lever and the drive rod.
[0016] Preferably, the upper end of the drive rod is provided with a top plate, and the top plate is provided with limit grooves. A filling block is slidably disposed in the limit groove, and the filling block and the drive rod are coaxially arranged.
[0017] Preferably, a torsion spring is fixedly provided at the lower end of the top plate, the lower end of the torsion spring is connected to the inner plate, the filling block is located inside the torsion spring, and the inside of the torsion spring is attached to the outer wall of the filling block. A limit plate is provided on the drive rod, and the inner plate is attached to the lower end face of the limit plate.
[0018] Preferably, the filling block is provided with a follower bolt for limiting rotation, the follower bolt is threaded to the drive rod, and the upper end of the follower bolt is provided with a hexagonal block.
[0019] (III) Beneficial Effects
[0020] Compared with the prior art, the present invention provides a disinfection water treatment mixing mechanism, which has the following beneficial effects:
[0021] This invention fundamentally solves the problem of mixing dead zones caused by the attenuation of stirring energy in large-capacity mixing through an innovative upper and lower layer active conveying structure. The upper and lower conveying pipes fixed on the active shaft adopt an irregular channel design with contraction and expansion, and together with the trumpet tubes arranged along the rotation direction, they can actively draw in the upper layer liquid and force it downward along the lower conveying pipe during rotation, while simultaneously drawing in the lower layer liquid and force it upward along the upper conveying pipe. During the conveying process, the liquid is sprayed and released into different depth areas through side wall holes distributed along the way, realizing directional, quantitative, and multi-point forced exchange of the upper and lower layers of liquid with the largest concentration gradient. This active conveying mechanism completely breaks through the limitations of traditional stirring that relies on overall turbulent diffusion, enabling the exchange of substances between high-concentration and low-concentration areas to be completed in a very short time, significantly shortening the stirring time required to achieve uniform mixing.
[0022] The vertical assembly constructed in this invention establishes a multi-layered vertical convection field within the storage tank through the combined motion of the drive blades and the inclined blades. While the upper and lower stirring sleeves revolve around the drive shaft, they also rotate around the drive rod due to liquid resistance. The thrust generated by the rotating drive blades corresponds to their installation positions; the lower drive blades push the lower layer of liquid upwards, while the upper drive blades push the upper layer of liquid downwards, thus forming multiple forced convection currents in opposite directions and staggered positions in the vertical direction. Simultaneously, the rotation of the inclined blades further converts the horizontal flow energy into vertical thrust, significantly enhancing the vertical convection intensity. All stirring sleeves maintain strictly synchronized rotation speeds through the meshing transmission of synchronous pulleys and synchronous belts, ensuring uniform convection intensity at all points within the entire storage tank and avoiding uneven mixing caused by localized differences in stirring strength.
[0023] The turbulence-disrupting component of this invention effectively disrupts the laminar flow state that easily forms during stirring through periodic pulse disturbances, significantly improving the micro-mixing effect. The rotation of the lower stirring sleeve drives the lever to periodically move the elastic plate on the internal disc. When the lever passes the elastic plate, the energy stored in the torsion spring is released instantaneously, causing the elastic plate to rebound quickly and generate a pulse-like pushing force on the surrounding liquid. This irregular disturbance causes the liquid micro-particles to generate random motion trajectories, effectively promoting uniform mixing at the molecular scale. At the same time, the adjustable design of the insertion depth of the filler block inside the torsion spring allows the operator to steplessly adjust the turbulence intensity according to the liquid viscosity or mixing difficulty. The deeper the filler block is inserted, the shorter the effective working length of the torsion spring, the greater the stiffness, the faster the elastic plate resets, and the stronger the turbulence. This flexible and adjustable turbulence mechanism enables the equipment to adapt to diverse mixing needs, from low-viscosity clean water to high-viscosity disinfectant liquids.
[0024] This invention integrates three mixing mechanisms—active transport, vertical convection, and random turbulence—into a single stirring system, achieving a leap in mixing efficiency. The active transport mechanism is responsible for rapid material exchange between upper and lower layers at the macroscopic scale, the vertical convection mechanism is responsible for vertical fluid circulation at the mesoscopic scale, and the random turbulence mechanism is responsible for uniform mixing at the molecular level at the microscopic scale. The synergistic effect of these three mechanisms enables large-volume disinfection water to reach an ideal mixing state in a short time. Compared with traditional stirring methods, the mixing time can be shortened by more than 40%. At the same time, due to the improved mixing uniformity, the waste and side reaction risks caused by excessive addition of reagents can be reduced, providing a strong guarantee for energy saving, consumption reduction, and operational stability of water treatment processes.
[0025] This invention ensures efficient mixing while fully considering the ease of operation and economical maintenance of the equipment. All stirring sleeves are synchronously driven through a simple structure of synchronous pulleys and synchronous belts, avoiding the installation and debugging difficulties caused by complex gear transmissions. The adjustment of the turbulence intensity can be completed simply by operating the hexagonal block through the cover plate without disassembling any parts. The layered addition design of the upper and lower feeding pipes allows the operator to flexibly select the addition position according to the characteristics of the reagent to optimize the mixing effect. All moving parts adopt a modular design, and any stirring sleeve or turbulence component can be replaced individually without overall disassembly when damaged, which significantly reduces the maintenance cost and downtime of the equipment throughout its entire life cycle. Attached Figure Description
[0026] Figure 1 This is a schematic diagram of the overall structure of a disinfection water treatment mixing mechanism according to the present invention;
[0027] Figure 2 In this invention Figure 1 A schematic diagram of the cross-sectional structure;
[0028] Figure 3 This is a schematic diagram of the drive shaft in this invention;
[0029] Figure 4 This is a schematic diagram of the upper and lower feed pipes in this invention;
[0030] Figure 5 This is a schematic diagram of the upper and lower stirring sleeves in this invention;
[0031] Figure 6 This is a schematic diagram of the synchronous belt and synchronous pulley in this invention;
[0032] Figure 7 This is a cross-sectional view of the drive frame in this invention;
[0033] Figure 8 This is a schematic diagram of the lower stirring sleeve in this invention;
[0034] Figure 9This is an exploded structural diagram of the filling block and elastic plate in this invention.
[0035] In the diagram: 11. Storage tank; 21. Drive shaft; 22. Upper feed pipe; 23. Lower feed pipe; 24. Side wall hole; 25. Horn tube; 26. Motor; 27. Cover plate; 31. Feed pipe; 32. Discharge pipe; 41. Vertical assembly; 42. Drive frame; 43. Drive rod; 44. Upper mixing sleeve; 45. Lower mixing sleeve; 46. Drive blade; 47. Angled blade; 48. Synchronous pulley; 49. Synchronous belt; 51. Turbulence assembly; 52. Lever; 53. Internal disc; 54. Elastic plate; 55. Top disc; 56. Limiting groove; 57. Filler block; 58. Torsion spring; 59. Limiting disc; 510. Follower bolt; 511. Hexagonal block. Detailed Implementation
[0036] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. The present invention will now be described in detail with reference to the accompanying drawings and embodiments.
[0037] It should be noted that, unless otherwise specified, all technical and scientific terms used in this application have the same meaning as commonly understood by one of ordinary skill in the art to which this application pertains.
[0038] In this invention, unless otherwise stated, the directional terms such as "up" and "down" generally refer to the directions shown in the accompanying drawings, or to the vertical, perpendicular, or gravitational direction; similarly, for ease of understanding and description, "left" and "right" generally refer to the left and right shown in the accompanying drawings; "inner" and "outer" refer to the inner and outer contours of each component itself, but the above directional terms are not intended to limit this invention.
[0039] Please see Figures 1 to 9 This embodiment provides a disinfection water treatment mixing mechanism, which aims to solve the technical problems of uneven mixing and long time consumption caused by large water volume and low traditional stirring efficiency in the existing disinfection water preparation process. By integrating a stirring mechanism with active conveying and multi-stage turbulence functions in the upper and lower layers and a conveying mechanism that can add raw materials to the upper and lower sides of the storage tank respectively, the rapid and uniform mixing of a large amount of disinfection water is achieved, which significantly improves the stirring efficiency and mixing effect.
[0040] 1. Overall structure and initial state
[0041] The disinfection water treatment mixing mechanism includes a storage tank 11 as a container, and a stirring mechanism and a conveying mechanism installed on the storage tank 11. The stirring mechanism is used to drive the liquid in the storage tank 11 to perform multi-dimensional mixing. It consists of a drive shaft 21, an upper delivery pipe 22, a lower delivery pipe 23, a vertical component 41, and a turbulence component 51. The conveying mechanism is used to add different raw materials to the upper and lower regions of the storage tank 11 to form an initial concentration gradient.
[0042] 2. Composition of the core system
[0043] 2.1 Active Conveying Unit
[0044] The active conveying unit is the core component for realizing active exchange of liquid between upper and lower layers. It includes an active shaft 21 rotatably installed inside the storage tank 11. An upper delivery pipe 22 and a lower delivery pipe 23 are fixedly installed at the upper and lower ends of the active shaft 21, respectively, and are arranged alternately along the axial direction. The diameter of the lower delivery pipe 23 gradually narrows from top to bottom, while the diameter of the upper delivery pipe 22 gradually expands from top to bottom. Multiple sets of side wall holes 24 for liquid discharge are equally spaced along the axial direction on the side walls of the upper delivery pipe 22 and the lower delivery pipe 23. Multiple sets of horn pipes 25 are respectively connected to the upper end of the lower delivery pipe 23 and the lower end of the upper delivery pipe 22. The multiple sets of horn pipes 25 are arranged along the rotation direction of the active shaft 21 to guide the liquid into the pipes when rotating. A cover plate 27 for easy maintenance is movably installed at the upper end of the storage tank 11. A motor 26 is fixedly installed at the upper end of the storage tank 11, and the drive end of the motor 26 is fixedly connected to the active shaft 21.
[0045] 2.2 Vertical Component 41
[0046] The vertical assembly 41 is the core component for achieving forced vertical convection of the liquid. It includes a drive frame 42 fixedly mounted on the drive shaft 21. Multiple sets of drive rods 43 are vertically arranged on the drive frame 42. Each set of drive rods 43 is rotatably fitted with an upper stirring sleeve 44 and a lower stirring sleeve 45, which are arranged alternately. Drive blades 46 are fixedly mounted on the upper stirring sleeve 44 and the lower stirring sleeve 45, with the drive blades 46 of the lower stirring sleeve 45 mounted at the lower end and the drive blades 46 of the upper stirring sleeve 44 mounted at the upper end. Inclined blades 47 are also fixedly mounted on the upper stirring sleeve 44 and the lower stirring sleeve 45, and the inclined blades 47 are fixedly connected to the drive blades 46. Synchronous pulleys 48 are fixedly mounted on the upper stirring sleeve 44 and the lower stirring sleeve 45 at the same plane. The outer sides of all synchronous pulleys 48 are meshed with a synchronous belt 49 to achieve synchronous rotation of all stirring sleeves.
[0047] 2.3 Aerodynamic components 51
[0048] The turbulence assembly 51 is the core component used to generate irregular disturbances to disrupt laminar flow. It includes a lever 52 fixedly installed on the upper end of the lower stirring sleeve 45, an inner disk 53 rotatably sleeved on the drive rod 43, and multiple sets of elastic plates 54 fixedly arranged at equal intervals along the circumference on the outer wall of the inner disk 53. The gyration radius of the outer ends of the multiple sets of elastic plates 54 is greater than the distance from the lever 52 to the axis of the drive rod 43. A top disk 55 is fixedly installed on the upper end of the drive rod 43. A limiting groove 56 is formed on the top disk 55, and a device coaxial with the drive rod 43 is slidably arranged in the limiting groove 56. The filling block 57 has a torsion spring 58 between the lower end of the top plate 55 and the inner plate 53, and the lower end of the torsion spring 58 is fixedly connected to the inner plate 53. The filling block 57 is located inside the torsion spring 58, and the inner ring of the torsion spring 58 is attached to the outer wall of the filling block 57. A limit plate 59 is also fixedly installed on the drive rod 43. The upper end surface of the inner plate 53 is attached to the lower end surface of the limit plate 59. A follower bolt 510 is rotatably connected to the filling block 57, and the follower bolt 510 is threadedly connected to the drive rod 43. A hexagonal block 511 for operation is provided at the upper end of the follower bolt 510.
[0049] 2.4 Conveying Mechanism
[0050] The conveying mechanism is used to realize the layered addition of raw materials. It includes a feeding pipe 31 located at the upper end of the side wall of the storage tank 11 and a feeding pipe 31 located at the lower end of the side wall of the storage tank 11. A discharge pipe 32 is provided at the bottom of the storage tank 11 for discharging the mixed disinfection water.
[0051] 3. Working process and principle of the device
[0052] The working process and mixing principle of the disinfection water treatment mixing mechanism are as follows: When preparing disinfection water, different raw materials are first injected into the upper and lower parts of the storage tank 11 through the upper and lower feeding pipes 31, so that an initial concentration gradient of light at the top and heavy at the bottom or concentrated at the top and diluted at the bottom is formed in the storage tank 11. Then, the motor 26 is started to drive the drive shaft 21 to rotate.
[0053] The rotation of the drive shaft 21 drives the upper delivery pipe 22 and the lower delivery pipe 23 to rotate synchronously. Since both the upper delivery pipe 22 and the lower delivery pipe 23 are equipped with trumpet tubes 25 arranged along the rotation direction, when the trumpet tubes 25 rotate and cut the liquid, a local negative pressure is generated at their openings, drawing the surrounding liquid into the pipes. The liquid in the upper part enters the lower delivery pipe 23 through the upper trumpet tube 25. Since the lower delivery pipe 23 has a structure that gradually narrows from top to bottom, the liquid gradually increases in velocity during the downward transport process and is sprayed outward from multiple side wall holes 24 along the way, achieving the effect of forcibly transporting the upper liquid to different depth areas in the lower layer. At the same time, the liquid in the lower part enters the upper delivery pipe 22 through the lower trumpet tube 25. Since the upper delivery pipe 22 has a structure that gradually expands from top to bottom, the liquid is also sprayed outward from the side wall holes 24 during the upward transport process, achieving the effect of forcibly transporting the lower liquid to different depth areas in the upper layer. This bidirectional active transport allows the liquids with the greatest concentration difference between the upper and lower layers to exchange and mix quickly, significantly shortening the time required for overall concentration homogenization.
[0054] While the active conveying is underway, the vertical assembly 41 begins to operate. The drive blades 46 on the upper and lower stirring sleeves 44 and 45 generate a rotational torque around the drive rod 43 due to the resistance of the liquid as they revolve with the drive shaft 21. The rotation of the drive blades 46 drives the inclined blades 47 to rotate synchronously. Since the drive blades 46 of the lower stirring sleeve 45 are installed at the lower end, the thrust they generate transports the lower liquid upwards, while the drive blades 46 of the upper stirring sleeve 44 are installed at the upper end, and the thrust they generate transports the upper liquid downwards, thus forming forced convection in the vertical direction, further enhancing the exchange efficiency of the upper and lower liquids. Through the meshing transmission of the synchronous pulley 48 and the synchronous belt 49, all the upper stirring sleeves 44 and lower stirring sleeves 45 maintain the same rotational speed, ensuring that the convection intensity generated at each point is uniform.
[0055] During the rotation of the mixing sleeve, the lever 52 fixed to the upper end of the lower mixing sleeve 45 rotates accordingly. When the lever 52 rotates to contact a set of elastic plates 54, the lever 52 pushes the elastic plates 54 to deflect along with the internal disk 53, overcoming the resistance of the torsion spring 58. As the lever 52 continues to rotate until it passes the end point of the elastic plate 54, the elastic plate 54 quickly rebounds and resets under the energy stored in the torsion spring 58. This instantaneous elastic recovery action generates a pulse-like driving force on the surrounding liquid, forming irregular local turbulence, effectively disrupting the laminar flow state that may be generated by continuous stirring, causing the liquid micro-particles to move randomly, and significantly improving the micro-mixing effect.
[0056] The operator can adjust the turbulence intensity according to the liquid viscosity or mixing difficulty. During adjustment, the cover plate 27 is opened, and the hexagonal block 511 is turned with a wrench to drive the follower bolt 510 to rotate. Since the follower bolt 510 is threadedly connected to the drive rod 43 and limited to the filler block 57, the rotation of the follower bolt 510 will drive the filler block 57 to move up and down along the limiting groove 56, changing the depth of the filler block 57 inserted into the torsion spring 58, thereby changing the effective length of the torsion spring 58 participating in torsional deformation, and thus adjusting the torsional stiffness of the torsion spring 58. The deeper the filler block 57 is inserted, the shorter the effective length of the torsion spring 58 and the greater the stiffness, the faster the elastic plate 54 resets and the stronger the turbulence. Conversely, the shallower the filler block 57 is inserted, the gentler the turbulence, thus achieving stepless adjustment of the turbulence intensity.
[0057] After thorough mixing, the disinfectant water is discharged through the drain pipe 32 at the bottom of the storage tank 11 and enters the subsequent use stage.
[0058] Working principle summary: This invention achieves forced extraction and jet delivery of liquids from the upper and lower layers through the contraction and expansion structure of the upper delivery pipe 22 and the lower delivery pipe 23, and the setting of the trumpet pipe 25. Vertical convection is formed by the rotation of the upper and lower stirring sleeves 45 in the vertical component 41 and the opposing delivery of the inclined blades 47. Irregular disturbance is generated by the periodic movement of the spring plate by the lever 52 in the turbulence component 51. The synergistic effect of these three factors enables a large volume of disinfectant water to achieve uniform mixing in a short time, significantly improving stirring efficiency and mixing quality.
[0059] Of all the solutions mentioned above, those involving the connection between two components can be selected according to the actual situation, such as welding, bolt and nut connection, bolt or screw connection, or other known connection methods, which will not be elaborated here. For all the fixed connections mentioned above, welding is preferred. Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of the present invention. The scope of the present invention is defined by the appended claims and their equivalents.
Claims
1. A disinfection water treatment mixing mechanism, comprising a storage tank (11); characterized in that: It also includes a mixing mechanism and a conveying mechanism; The stirring mechanism includes a drive shaft (21) installed inside the storage tank (11). Two sets of upper delivery pipes (22) and lower delivery pipes (23) are fixedly installed at the upper and lower ends of the drive shaft (21), respectively. The upper delivery pipes (22) and lower delivery pipes (23) are staggered. The lower delivery pipes (23) contract from top to bottom, while the upper delivery pipes (22) expand from top to bottom. Multiple sets of sidewall holes (24) are equally spaced on the sidewalls of the upper delivery pipes (22) and the lower delivery pipes (23). Liquids of different concentrations at the upper and lower ends are transported and mixed through the upper delivery pipes (22) and the lower delivery pipes (23). Two sets of horn tubes (25) are respectively connected to the upper end of the feed pipe (23) and the lower end of the upper feed pipe (22). The two sets of horn tubes (25) are respectively connected to the lower feed pipe (23) and the upper feed pipe (22), and multiple sets of horn tubes (25) are respectively arranged along the stirring direction of the drive shaft (21). The stirring mechanism also includes a vertical component (41) and a turbulence component (51). The stirring mechanism also includes a motor (26) installed on the upper end of the storage tank (11). The drive end of the motor (26) is connected to the drive shaft (21). The vertical component (41) includes a drive frame (51) installed on the drive shaft (21). 42), the drive frame (42) is provided with multiple sets of drive rods (43), and upper stirring sleeves (44) and lower stirring sleeves (45) are rotatably mounted on the multiple sets of drive rods (43), and the multiple sets of upper stirring sleeves (44) and lower stirring sleeves (45) are arranged alternately up and down, and drive blades (46) are respectively installed on the upper stirring sleeves (44) and lower stirring sleeves (45). The drive blades (46) of the lower stirring sleeves (45) are installed at the lower end, and the drive blades (46) of the upper stirring sleeves are installed at the upper end. Inclined blades (47) are respectively installed on the upper stirring sleeves (44) and lower stirring sleeves (45), and the inclined blades (47) are respectively installed on the upper stirring sleeves (44) and lower stirring sleeves (45). The upper stirring sleeve (44) and the lower stirring sleeve (45) are both equipped with synchronous pulleys (48) on the same plane, and the outer sides of the multiple synchronous pulleys (48) are respectively meshed with synchronous belts (49). The turbulence assembly (51) includes a lever (52) installed on the upper end of the lower stirring sleeve (45). An inner disk (53) is rotatably installed on the drive rod (43). Multiple sets of elastic plates (54) are equally spaced on the outer wall of the inner disk (53). The distance between the outermost ends of the multiple elastic plates (54) is greater than the distance between the lever (52) and the drive rod (43). The conveying mechanism includes two feeding pipes (31) disposed on the side wall of the storage tank (11), and the two feeding pipes (31) are respectively located on the upper and lower sides of the storage tank (11), and a discharge pipe (32) is provided at the lower end of the storage tank (11).
2. The disinfection water treatment mixing mechanism according to claim 1, characterized in that: The upper end of the storage tank (11) is movably provided with a cover plate (27).
3. The disinfection water treatment mixing mechanism according to claim 1, characterized in that: The upper end of the drive rod (43) is provided with a top plate (55), and a limiting groove (56) is provided on the top plate (55). A filling block (57) is slidably arranged in the limiting groove (56), and the filling block (57) and the drive rod (43) are coaxially arranged.
4. The disinfection water treatment mixing mechanism according to claim 3, characterized in that: A torsion spring (58) is fixedly provided at the lower end of the top plate (55). The lower end of the torsion spring (58) is connected to the inner plate (53). The filling block (57) is located inside the torsion spring (58), and the inside of the torsion spring (58) is attached to the outer wall of the filling block (57). A limiting plate (59) is provided on the drive rod (43), and the inner plate (53) is attached to the lower end face of the limiting plate (59).
5. The disinfection water treatment mixing mechanism according to claim 4, characterized in that: The filling block (57) is provided with a follower bolt (510) for limiting rotation. The follower bolt (510) is threaded onto the drive rod (43), and a hexagonal block (511) is provided at the upper end of the follower bolt (510).