A flocculating agent mixing and stirring device
By introducing a dust collection mechanism and a spiral discharge shaft into the flocculant mixing and stirring device, the problem of dust flying was solved, and efficient material recycling and discharge were achieved, improving the working environment and production efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 新郑市源衡水务有限公司
- Filing Date
- 2025-07-03
- Publication Date
- 2026-07-14
AI Technical Summary
Existing flocculant mixing and stirring devices are prone to dust flying during discharge, affecting the working environment and making it difficult to fully recycle the materials.
A flocculant mixing and stirring device was designed, equipped with a dust suction mechanism and a discharge mechanism. The device uses a servo motor to drive the stirring shaft and the fan to generate suction, sucking in the flying dust, and uses a spiral discharge shaft to prevent clogging, thus achieving material sealing and efficient discharge.
It effectively prevents dust from flying, ensures complete material recycling, and improves the safety of the working environment and production efficiency.
Smart Images

Figure CN224485601U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of flocculant processing technology, and in particular to a flocculant mixing and stirring device. Background Technology
[0002] The main function of flocculants is to promote the aggregation and sedimentation of solid suspended particles in liquids. Flocculants are polar organic or inorganic polymers that adsorb suspended particles in water, causing them to gradually form larger clumps, thereby reducing the turbidity and suspended solids content of the water. Flocculants have wide applications in environmental remediation, water treatment, chemical production, and food processing, effectively removing suspended particles and pollutants from liquids, making the water quality more stable and reliable. Processing flocculants requires stirring the raw materials, necessitating a flocculant mixing and stirring device.
[0003] To this end, the specification of patent CN215196961U discloses a mixing device for preparing aluminum-iron composite salt flocculant, including a chamber and a saturation chamber. The outer side of the chamber is provided with a heat insulation layer, and the inner side wall of the chamber is provided with a heating pipe. The top of the side wall of the chamber is provided with a first feed port and a second feed port. The top of the chamber is provided with two pH adjustment pipes. A stirring motor is bolted between the two pH adjustment pipes of the chamber. The output end of the stirring motor is threadedly connected to a stirring shaft. A stirring blade is welded to a section of the stirring shaft inside the chamber. The bottom of the chamber is provided with a finished product discharge port. There are two saturation chambers with the same structure. This utility model has the following advantages: it is easy to use by adjusting the pH meter; the pH is controlled quickly by the pH adjustment pipe; the quality and concentration of raw materials are controlled by the saturation chamber and the flow control valve, so that the effective components are retained at a high content; the heat insulation layer reduces energy waste; the flow control valve controls the amount of saturated salt solution entering and regulates the feed rate; the heating pipe on the side wall provides uniform heating and fast reaction efficiency.
[0004] The aforementioned mixing device for preparing aluminum-iron composite salt flocculant proposes to control the amount of saturated salt solution entering through a flow control valve to regulate the feed rate, and to install heating tubes on the side wall for uniform heating and fast reaction efficiency. However, some dust may be generated during discharge, preventing complete material recovery, and the dust may also affect the user's working environment. Utility Model Content
[0005] The purpose of this invention is to provide a flocculant mixing and stirring device to solve the problem that existing flocculant mixing and stirring devices are difficult to handle flying dust.
[0006] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a flocculant mixing and stirring device, including a base;
[0007] The base is equipped with a support leg at its top, a housing is equipped with a housing at its top, a feed inlet is equipped with a cover at the top of the housing, and a cover is equipped with a cover at the top of the feed inlet.
[0008] A servo motor is installed on one side of the outer casing, and a stirring shaft is installed on one side of the servo motor. A stirring blade is installed on the outside of the stirring shaft, and a dust collection mechanism is installed on one side of the outer casing.
[0009] The dust collection mechanism includes a blower box installed on one side of the outer casing, an inlet on one side of the blower box, a baffle installed at the bottom of the inlet, a fan installed on one side of the blower box, and a filter screen installed on one side of the blower box.
[0010] In use, the feed inlet and the cover form a locking structure. The cover can seal the feed inlet. After opening the cover, the material can be loaded into the shell. During processing, the cover can be closed to prevent the material from flying. Then, the servo motor will drive the stirring shaft to rotate. The rotation of the stirring shaft will drive the stirring blade to rotate. The rotation of the stirring blade will stir the inside of the shell, allowing the material to mix.
[0011] Furthermore, a discharge mechanism is installed on one side of the outer casing, and the discharge mechanism includes a discharge pipe installed at the bottom end of one side of the outer casing, a discharge port installed at the bottom end of the discharge pipe, and a rotary motor installed on one side of the discharge pipe. The discharge mechanism can discharge dust.
[0012] Furthermore, a discharge shaft is installed on one side of the rotary motor. The discharge shaft is spiral in shape, and its rotation can move the dust.
[0013] Furthermore, the stirring blades are arranged at equal intervals on the outside of the stirring shaft, and the stirring blades are distributed in a ring. The rotation of the stirring blades can stir the raw materials.
[0014] Furthermore, the top of the bellows is provided with through holes, and the through holes are arranged at equal intervals at the top of the bellows, allowing the bellows to be ventilated.
[0015] Furthermore, a disassembly and assembly structure is installed at the top of the feed inlet, and the disassembly and assembly structure includes an installation plate installed at the top of the feed inlet, a rotating shaft installed on the inner side of the installation plate, and a buckle installed at the top of the rotating shaft. The disassembly and assembly structure can fix the cover.
[0016] Furthermore, a locking block is provided at the bottom of the cover, and a locking groove is provided at the top of the feed inlet. The cover and the feed inlet form a locking structure, which facilitates disassembly.
[0017] The advantages of the flocculant mixing and stirring device provided by this utility model are as follows: during use, the dust can be sucked in by the dust suction mechanism to prevent dust from flying, and the flying dust can also be sucked into the air box to prevent waste. The feed port can be sealed by the cover to prevent dust from being discharged through the feed port during processing. The material can be discharged by the discharge mechanism to prevent material blockage during discharge.
[0018] A fan is installed inside the bellows, connected to a stirring shaft. When the stirring shaft rotates, it also drives the fan to rotate, generating suction. When the material is discharged, the flying dust is sucked into the bellows through the inlet, preventing dust from flying away. A filter screen prevents dust from being discharged through the through-hole, and a baffle prevents dust from being discharged through the inlet. In this way, the dust can be stored inside the bellows. After processing, the dust inside the bellows can be treated, thus achieving the purpose of the flocculant mixing and stirring device to facilitate the treatment of flying dust.
[0019] A rotary motor is installed on one side of the discharge pipe. The operation of the rotary motor drives the discharge shaft to rotate. The discharge shaft is spiral in shape. The rotation of the discharge shaft causes the material inside the outer shell to move inside the discharge pipe. The material moves and is discharged through the discharge port. The spiral shape of the discharge shaft can prevent the material from getting stuck and can be processed quickly. This achieves the purpose of the flocculant mixing and stirring device to facilitate the discharge of materials. Attached Figure Description
[0020] Figure 1 This is a three-dimensional structural schematic diagram of the present invention;
[0021] Figure 2 This is a three-dimensional cross-sectional structural diagram of the present invention;
[0022] Figure 3 For the present utility model Figure 1 Enlarged cross-sectional view of point A in the middle section;
[0023] Figure 4 This is a partial three-dimensional structural diagram of the dust collection mechanism of this utility model;
[0024] Figure 5 This is a partial three-dimensional structural diagram of the discharge mechanism of this utility model.
[0025] The following are the annotations in the diagram: 1. Outer shell; 2. Servo motor; 3. Stirring shaft; 4. Stirring blade; 5. Support leg; 6. Base; 7. Discharge mechanism; 701. Rotary motor; 702. Discharge pipe; 703. Discharge shaft; 704. Discharge port; 8. Dust collection mechanism; 801. Air box; 802. Inlet; 803. Baffle; 804. Filter screen; 805. Fan; 806. Through hole; 9. Feed port; 10. Cover; 11. Disassembly and assembly structure; 1101. Mounting plate; 1102. Rotating shaft; 1103. Buckle. Detailed Implementation
[0026] 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.
[0027] Please see Figures 1-5 One embodiment of this utility model is a flocculant mixing and stirring device, which includes a base 6.
[0028] The base 6 is equipped with a support leg 5 at its top, and a housing 1 is installed at the top of the support leg 5. A discharge mechanism 7 is installed on one side of the housing 1, and the discharge mechanism 7 includes a discharge pipe 702 installed at the bottom of one side of the housing 1. A discharge port 704 is installed at the bottom of the discharge pipe 702. A rotary motor 701 is installed on one side of the discharge pipe 702, and a discharge shaft 703 is installed on one side of the rotary motor 701. The discharge shaft 703 is spiral in shape.
[0029] See attached document Figures 1-2 and attached Figure 5 As shown, the operation of the rotary motor 701 will drive the discharge shaft 703 to rotate. The discharge shaft 703 is spiral in shape. The rotation of the discharge shaft 703 will cause the material inside the outer casing 1 to move inside the discharge pipe 702. The material will be discharged through the discharge port 704. The rotation of the spiral discharge shaft 703 can prevent the material from getting blocked and can be processed quickly.
[0030] The top of the outer shell 1 is equipped with a feed port 9, and the top of the feed port 9 is equipped with a disassembly structure 11. The disassembly structure 11 includes a mounting plate 1101 mounted on the top of the feed port 9, a rotating shaft 1102 mounted on the inner side of the mounting plate 1101, and a buckle 1103 mounted on the top of the rotating shaft 1102.
[0031] See attached document Figures 1-3As shown, the inlet 9 and the cover 10 form a locking structure. The cover 10 can seal the inlet 9. After opening the cover 10, the material can be loaded into the shell 1. During processing, the cover 10 can be closed. The rotating shaft 1102 on the inner side of the mounting plate 1101 can rotate. The rotation of the rotating shaft 1102 will drive the buckle 1103 to rotate. The rotation of the buckle 1103 will lock the cover 10. The buckle 1103 can fix the cover 10. During processing, the cover 10 can prevent the material from flying. Then, the servo motor 2 will drive the stirring shaft 3 to rotate. The rotation of the stirring shaft 3 will drive the stirring blade 4 to rotate. The rotation of the stirring blade 4 will stir the inside of the shell 1, so that the material is mixed.
[0032] A cover 10 is installed at the top of the feed inlet 9, a locking block is provided at the bottom of the cover 10, and a locking groove is provided at the top of the feed inlet 9. The cover 10 and the feed inlet 9 form a locking structure.
[0033] A servo motor 2 is installed on one side of the outer casing 1, and a stirring shaft 3 is installed on one side of the servo motor 2. A stirring blade 4 is installed on the outside of the stirring shaft 3. The stirring blade 4 is arranged at equal intervals on the outside of the stirring shaft 3 and is distributed in a ring. A dust collection mechanism 8 is installed on one side of the outer casing 1.
[0034] The vacuuming mechanism 8 includes a blower box 801 installed on one side of the outer casing 1. The top of the blower box 801 is provided with a through hole 806, and the through holes 806 are arranged at equal intervals on the top of the blower box 801.
[0035] An inlet 802 is provided on one side of the bellows 801, a baffle 803 is installed at the bottom of the inlet 802, a fan 805 is installed on one side of the bellows 801, and a filter screen 804 is installed on one side of the bellows 801.
[0036] See attached document Figures 1-2 and attached Figure 4 As shown, the blower 805 is connected to the stirring shaft 3. When the stirring shaft 3 rotates, it will also drive the blower 805 to rotate. The rotation of the blower 805 will generate suction. When the material is discharged, the flying dust will be sucked into the air box 801 through the inlet 802 to prevent the dust from flying. The filter screen 804 can prevent the dust from being discharged through the through hole 806, and the baffle 803 can prevent the dust from being discharged through the inlet 802. In this way, the dust can be stored inside the air box 801. After the processing is completed, the dust inside the air box 801 can be treated.
[0037] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A flocculant mixing and stirring device, comprising a base (6); Its features are: The base (6) is equipped with a support leg (5) at the top, the support leg (5) is equipped with a shell (1) at the top, the shell (1) is equipped with a feed inlet (9) at the top, and the feed inlet (9) is equipped with a cover (10) at the top. A servo motor (2) is installed on one side of the outer shell (1), and a stirring shaft (3) is installed on one side of the servo motor (2). A stirring blade (4) is installed on the outside of the stirring shaft (3), and a dust collection mechanism (8) is installed on one side of the outer shell (1). The dust collection mechanism (8) includes a blower (801) installed on one side of the outer shell (1), an inlet (802) provided on one side of the blower (801), a baffle (803) installed at the bottom of the inlet (802), a fan (805) installed on one side of the blower (801), and a filter (804) installed on one side of the blower (801).
2. The flocculant mixing and stirring device according to claim 1, characterized in that: A discharge mechanism (7) is installed on one side of the outer shell (1), and the discharge mechanism (7) includes a discharge pipe (702) installed at the bottom end of one side of the outer shell (1), a discharge port (704) installed at the bottom end of the discharge pipe (702), and a rotary motor (701) installed on one side of the discharge pipe (702).
3. The flocculant mixing and stirring device according to claim 2, characterized in that: A discharge shaft (703) is installed on one side of the rotary motor (701), and the discharge shaft (703) is spiral in shape.
4. The flocculant mixing and stirring device according to claim 1, characterized in that: The stirring blades (4) are arranged at equal intervals on the outside of the stirring shaft (3), and the stirring blades (4) are distributed in a ring.
5. The flocculant mixing and stirring device according to claim 1, characterized in that: The top of the bellows (801) is provided with a through hole (806), and the through holes (806) are arranged at equal intervals at the top of the bellows (801).
6. The flocculant mixing and stirring device according to claim 1, characterized in that: The top of the feed inlet (9) is equipped with a disassembly structure (11), and the disassembly structure (11) includes an installation plate (1101) installed on the top of the feed inlet (9), a rotating shaft (1102) installed on the inner side of the installation plate (1101), and a buckle (1103) installed on the top of the rotating shaft (1102).
7. The flocculant mixing and stirring device according to claim 1, characterized in that: The bottom of the cover (10) is provided with a locking block, and the top of the feed inlet (9) is provided with a locking groove. The cover (10) and the feed inlet (9) form a locking structure.