Sterilant solid powder mixer
By introducing a stirring, shaking, and boiling mechanism into the powder mixer, the problems of poor mixing effect and filter clogging are solved, achieving more efficient and safer powder mixing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- JIANGSU KANGBAT BIOLOGICAL ENG CO LTD
- Filing Date
- 2023-12-31
- Publication Date
- 2026-07-03
Smart Images

Figure CN117732291B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of powder mixing equipment technology, and more particularly to a disinfectant solid powder mixer. Background Technology
[0002] Disinfectants are reagents used in public health to disinfect the environment or substances. They come in liquid or powder form. The final preparation of powdered disinfectants requires mixing multiple reagents to form a mixed reagent, often using a powder mixer to achieve high reagent quality. However, most disinfectants are highly oxidizing and chemically reactive, such as chlorine dioxide. These chemical powders pose a certain risk during mixing; improper operation or changes in dosage can easily lead to explosions. Therefore, currently, the mixing of these powders is mostly done using carbon dioxide or other inert gases in a controlled pressure and temperature mixing chamber. This not only ensures the actual mixing effect but also prevents the corrosion of the mixing rod by the powder, which is common in traditional mixing equipment.
[0003] Patent CN105457514B discloses a mixer with a positive pressure automatic feeding system. The system uses a PLC to control the opening of the feed pipe regulating valve, allowing powder to enter the filter through the feed pipe. The powder is filtered through the filter cartridge and then enters the powder conveying hopper, before flowing into the mixer through the conveying pipe. Excess gas in the mixer is discharged through the exhaust pipe. When there is too much filter residue in the filter, it affects the gas discharge from the filter cartridge, increasing the gas pressure in the cartridge. When the gas pressure in the cartridge exceeds the pressure gauge's set pressure, the PLC system controls the closing of the feed pipe regulating valve to reduce the cartridge pressure. After a short period of gas delivery through the monitoring pipe, the monitoring pipe regulating valve is closed, the conveying pipe regulating valve is closed, the slag discharge pipe regulating valve is opened, and then the air inlet regulating valve is opened, allowing the filter residue to be discharged from the filter cartridge by high-pressure air.
[0004] However, existing mixers generally provide poor mixing effects for powders, and the gas inside the tank exhibits a stable boiling state. Therefore, when multiple media are mixed together, it is impossible to achieve proper mixing between the various media, resulting in a longer mixing time. In addition, although such equipment can prevent filter cartridge clogging, the powder is prone to dust generation during the actual mixing process, leading to powder blockage at the filter screen and preventing the actual gas pressure from being discharged normally, thus affecting the boiling state. Finally, since pulse aeration is mostly a single-point fixed aeration, the actual air outlet position of the traditional mixer directly affects the boiling state of the powder inside the mixer, further impacting the actual mixing effect. Summary of the Invention
[0005] The purpose of this invention is to solve the shortcomings of existing technologies, such as poor mixing effect and easy clogging of filter screens, and to provide a solid powder mixer for disinfectants.
[0006] To achieve the above objectives, the present invention adopts the following technical solution: a disinfectant solid powder mixer, comprising a support base frame, a top cover, and a tank:
[0007] Base stand;
[0008] The top cover is fixedly connected to the top of the base frame by a connecting rod, wherein a pulse air inlet and an exhaust pipe are fixedly connected to the top of the top cover respectively;
[0009] The tank body is movably connected to the opposite sides of the top cover and the base frame via bearings;
[0010] A toggle mechanism is located on one side of the tank body and is used to drive the tank body to rotate;
[0011] A shaking mechanism is located inside the top cover and is fixedly connected to the top of the actuation mechanism, used to drive subsequent components to shake.
[0012] The filter steel mesh is connected to the bottom end of the top cover via a spring frame;
[0013] A boiling mechanism is located at the bottom of the pulse air inlet and is fixedly connected to the inside of the tank. It is used to achieve boiling in one side of the tank and to cooperate with stirring.
[0014] The aforementioned actuation mechanism includes a drive motor, transmission teeth, meshing tooth grooves, and eight sets of actuation baffles. The top of the drive motor is fixedly connected to the transmission teeth via a connecting rod. The transmission teeth and the meshing tooth grooves mesh with each other, and the tooth diameter of the meshing tooth grooves is larger than the tooth diameter of the transmission teeth.
[0015] The above technical solution allows the tank to rotate directly inside the support base frame through the meshing effect of the transmission teeth and the meshing grooves, thus achieving a stirring effect.
[0016] As described above, the actuating baffle is fixedly connected to the bottom of the tank body, and the eight actuating baffles are arranged in a ring array about the bottom of the inner surface of the tank body. The actuating baffles are opened on the outer surface of the tank body, and the drive motor is fixedly connected to one side of the support base frame.
[0017] Through the above technical solution, the eight sets of ring-shaped array of agitator baffles can drive the powder inside the tank to move obliquely upward while the tank rotates, thereby driving the powder to move and stir inside the tank.
[0018] As described above, the vibration mechanism is fixedly connected to the top of the connecting rod at the top of the drive motor, and the transmission teeth and meshing tooth grooves form a certain oblique angle with respect to the horizontal plane.
[0019] Through the above technical solution, the shaking mechanism is directly connected to the drive motor, so that the shaking mechanism can operate during the stirring process, and the meshing angle between the transmission teeth and the meshing groove matches the installation angle between the tank and the support base frame.
[0020] The aforementioned vibration mechanism includes a rotating cam, a movable connecting rod, a limiting sleeve, a locking plate, a corrugated engagement plate, and a stress spring. The two ends of the movable connecting rod are movably connected to the rotating cam and the locking plate respectively via pivot pins, and the connection position between the movable connecting rod and the rotating cam is located at the maximum diameter position of the rotating cam. The end of the locking plate away from the movable connecting rod engages with the corrugated engagement plate. The limiting sleeve is located at the top of the movable connecting rod, and the stress spring is fixedly connected to the bottom end of the corrugated engagement plate.
[0021] Through the above technical solution, the connection between the cam and the movable link enables the movable link to drive one end to reciprocate, thereby achieving the purpose of driving the operation of subsequent equipment.
[0022] As described above, the limiting sleeve is fixedly connected to the top cover, the rotating cam is fixedly connected to the connecting rod at the top of the drive motor, and the pin between the locking cam and the movable connecting rod is slidably connected to the inner side of the limiting sleeve.
[0023] Through the above technical solution, the limiting sleeve can effectively restrict one end of the movable connecting rod from making a straight lateral movement, thereby cooperating to drive the subsequent locking plate to slide between the top cover.
[0024] As described above, the corrugated interlocking plate is L-shaped and is fixedly connected to the top of the filter steel mesh. The bottom end of the stress spring is fixedly connected to the top cover through a connecting plate. The corrugated interlocking plate is elastically connected to the top cover through the stress spring. The upper and lower ends of the rotating cam are movably connected to one side of the top cover through a limiting bracket.
[0025] Through the above technical solution, the corrugated interlocking plate engages with the locking plate through a stress spring. The movement of the locking plate can drive the corrugated interlocking plate to squeeze the filter steel mesh downwards, thus causing the filter steel mesh to vibrate and preventing dust blockage.
[0026] The aforementioned boiling mechanism includes an annular sealing baffle, a convex blocking ring plate, an annular air groove, and eight sets of aeration ports. The convex blocking ring plate is fixedly connected to the outer surface of the annular sealing baffle. The convex blocking ring plate and the annular sealing baffle are movably connected to the inner side of the annular air groove. The aeration ports are fixedly connected to the bottom of the annular air groove, and the eight sets of aeration ports are arranged in a ring array about the bottom surface of the annular air groove.
[0027] Through the above technical solution, the fixing between the convex blocking ring plate and the annular sealing baffle allows the annular sealing baffle to leave a certain space inside the annular air groove for the normal passage of air pressure, while other positions are blocked by the convex blocking ring plate. In this way, the air pressure can enter the aeration pipe at the specified position to achieve aeration and mixing.
[0028] As described above, the annular sealing baffle is fixedly connected to the pulse air inlet, the aeration pipe is connected to the annular air groove, and the connection port is located directly below the outwardly convex barrier ring plate. The inner side of the annular sealing baffle is fixedly connected to the top cover through a connecting rod.
[0029] Through the above technical solution, the pulse air inlet, which is also the connecting air pipe, continuously injects air pressure into the inner side of the annular air groove, while the aeration pipe inlet at different positions is affected by the outwardly convex blocking ring plate above it to realize the operation of air supply and air cut-off.
[0030] As described above, the annular air groove is formed on the inner surface of the tank, the arc length of the outwardly convex barrier ring plate is five-eighths of the arc length of the annular sealing baffle, the connection position between the pulse air inlet and the annular sealing baffle is located on the side away from the outwardly convex barrier ring plate, the aeration pipe is located at the top of two adjacent sets of actuating baffles, and the aeration pipe and the actuating baffle are aligned with each other.
[0031] Through the above technical solution, the convex blocking ring plate with an arc length of five-eighths is combined with eight sets of aeration pipes, so that under normal circumstances, three sets of aeration pipes are connected and closed with the aeration pipe, thus realizing the operation of unilateral aeration.
[0032] Compared with the prior art, the advantages and positive effects of the present invention are as follows:
[0033] I. This invention, through its set-up actuation mechanism, allows the drive motor to rotate the tank inside the support base frame after normal operation on one side. The meshing effect of the transmission teeth and meshing grooves causes the tank to rotate. Eight sets of actuation baffles are directly fixed inside the tank, and the tank and the meshing angle of the teeth and grooves form a certain oblique angle. In this lateral rotation state, the tank can move the internal powder to a relatively horizontal height before it falls to the bottom of the tank. Combined with aeration, this improves the actual stirring effect and is suitable for stirring various powder media, greatly improving stirring efficiency.
[0034] II. The present invention utilizes a shaking mechanism. The rotating cam, driven by a drive motor, causes the movable connecting rod to rotate. One end of the movable connecting rod then drives the locking plate and the corrugated interlocking plate to reciprocate and engage. Under pressure, the corrugated interlocking plate presses down on the stress spring at the bottom and the filter mesh. The filter mesh vibrates under the top cover due to the elastic reset action of the stress spring, thereby shaking off the powder on the surface of the filter mesh. This ensures the long-term working effect of the filter mesh and prevents clogging of the filter mesh from causing changes in air pressure that affect the actual aeration effect.
[0035] Third, the present invention, through the boiling mechanism, ensures that during the normal rotation of the tank, the annular sealing baffle is directly connected to the pulse air inlet, and the annular sealing baffle rotates inside the annular air groove. In this way, the gas rushing into the annular air groove from the pulse air inlet can directly provide air pressure to the three sets of aeration pipes below under the obstruction of the convex blocking ring plate. Meanwhile, the other five sets of aeration pipes are blocked by the convex blocking ring plate and do not blow air. Combined with the tilt angle of the tank, the effect of unilateral aeration is achieved. The rotating tank can drive the powder to continuously boil with the aeration pipes, which can further improve the actual mixing and stirring effect. Attached Figure Description
[0036] Figure 1 A schematic diagram of the overall structure of the disinfectant solid powder mixer provided by the present invention.
[0037] Figure 2 This is a half-sectional schematic diagram of the overall structure of the disinfectant solid powder mixer provided by the present invention.
[0038] Figure 3 This is a schematic diagram of the inner structure of the tank of the disinfectant solid powder mixer provided by the present invention.
[0039] Figure 4 A schematic diagram of the connection structure of the support base frame for the disinfectant solid powder mixer provided by the present invention.
[0040] Figure 5 A half-sectional view of the support base frame for the disinfectant solid powder mixer provided by the present invention.
[0041] Figure 6 A schematic diagram of the planar structure of the support base frame for the disinfectant solid powder mixer provided by the present invention.
[0042] Figure 7 The disinfectant solid powder mixer provided by the present invention Figure 2 Enlarged schematic diagram of the structure at point A.
[0043] Figure 8 The disinfectant solid powder mixer provided by the present invention Figure 4 Enlarged schematic diagram of the structure at point B.
[0044] Figure 9 The disinfectant solid powder mixer provided by the present invention Figure 5 Enlarged schematic diagram of the structure at point C.
[0045] Figure 10 The disinfectant solid powder mixer provided by the present invention Figure 6 Enlarged schematic diagram of the structure at point D.
[0046] Legend:
[0047] 1. Support base frame; 2. Top cover; 3. Tank body; 4. Pulse air inlet; 5. Actuating mechanism; 501. Drive motor; 502. Transmission gear; 503. Engaging tooth groove; 504. Actuating baffle; 6. Vibration mechanism; 601. Rotating cam; 602. Movable connecting rod; 603. Limiting sleeve; 604. Locking cam; 605. Corrugated interlocking plate; 606. Stress spring; 7. Filter steel mesh; 8. Boiling mechanism; 801. Annular sealing baffle; 802. Outwardly protruding barrier ring plate; 803. Annular air groove; 804. Aeration pipe inlet; 9. Exhaust pipe. Detailed Implementation
[0048] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0049] like Figure 1-10 As shown, the present invention provides a technical solution: a disinfectant solid powder mixer, comprising a support base frame 1, a top cover 2, and a tank body 3.
[0050] Base frame 1;
[0051] The top cover 2 is fixedly connected to the top of the base frame 1 by a connecting rod. The top of the top cover 2 is fixedly connected to the pulse air inlet 4 and the exhaust pipe 9.
[0052] The tank body 3 is movably connected to the opposite sides of the top cover 2 and the base frame 1 via bearings;
[0053] A toggle mechanism 5 is disposed on one side of the tank 3 and is used to drive the tank 3 to rotate;
[0054] The shaking mechanism 6 is located inside the top cover 2 and is fixedly connected to the top of the actuation mechanism 5, and is used to drive the subsequent components to shake.
[0055] The filter steel mesh 7 is connected to the bottom end of the top cover 2 via a spring frame;
[0056] The boiling mechanism 8 is located at the bottom of the pulse air inlet 4 and is fixedly connected to the inside of the tank 3. It is used to achieve boiling in one area inside the tank 3, and to cooperate with stirring.
[0057] In this embodiment, different media powders are directly poured into the inside of the tank 3 through the top cover 2. Then, the actuating mechanism 5 on one side of the support base frame 1 drives the tilted tank 3 to rotate inside the support base frame 1. In this way, the tank 3 can be driven by the actuating mechanism 5 to carry the powder to a high place and scatter it down, achieving a better mixing effect in conjunction with aeration. It is suitable for mixing multiple media. At the same time, the actuating mechanism 5 drives the shaking mechanism 6 on one side of the top cover 2 to move. The shaking mechanism 6 can drive the filter steel mesh 7 to shake inside the top cover 2, thereby preventing dust blockage of the filter steel mesh 7. The boiling mechanism 8 inside the tank 3 is directly connected to the pulse air inlet 4. The rotating tank 3 can achieve the air gun inflation effect at different positions. In this way, the aeration phenomenon only occurs on one side of the tank 3, resulting in a better mixing effect. The excess air pressure inside the tank 3 is discharged from the exhaust pipe 9 at the top of the top cover 2.
[0058] like Figure 2 and Figure 3 As shown, the actuating mechanism 5 includes a drive motor 501, transmission gears 502, meshing tooth grooves 503, and eight sets of actuating baffles 504. The top of the drive motor 501 is fixedly connected to the transmission gears 502 via a connecting rod. The transmission gears 502 and the meshing tooth grooves 503 mesh with each other, and the tooth diameter of the meshing tooth grooves 503 is larger than the tooth diameter of the transmission gears 502. The actuating baffles 504 are fixedly connected to the bottom of the can body 3, and the eight sets of actuating baffles 504 are arranged in a circular array about the bottom of the inner surface of the can body 3. The actuating baffles 504 are opened on the outer surface of the can body 3. The drive motor 501 is fixedly connected to one side of the support base frame 1. The shaking mechanism 6 is fixedly connected to the top of the connecting rod at the top of the drive motor 501. The transmission gears 502 and the meshing tooth grooves 503 form a certain angle with respect to the horizontal plane.
[0059] In this embodiment, the drive motor 501 drives the transmission gear 502 to rotate on one side of the tank 3 via the connecting rod. The meshing groove 503 on the surface of the tank 3 meshes with the transmission gear 502, and the tank 3 is movably connected to the support base frame 1 and the top cover 2. In this way, the tank 3 in the tilted state can rotate inside the support base frame 1. The eight sets of actuating baffles 504 on the bottom of the inner surface of the tank 3 rotate with the tank 3. This effect can cause the powder to fall from a high place to a low place, and achieve a better mixing effect in conjunction with aeration.
[0060] like Figure 9 and Figure 10 As shown, the vibration mechanism 6 includes a rotating cam 601, a movable connecting rod 602, a limiting sleeve 603, a locking plate 604, a corrugated engagement plate 605, and a stress spring 606. The two ends of the movable connecting rod 602 are movably connected to the rotating cam 601 and the locking plate 604 respectively via pivot pins. The connection position between the movable connecting rod 602 and the rotating cam 601 is located at the maximum diameter of the rotating cam 601. The end of the locking plate 604 away from the movable connecting rod 602 engages with the corrugated engagement plate 605. The limiting sleeve 603 is located at the top of the movable connecting rod 602, and the stress spring 606 is fixedly connected to the bottom end of the corrugated engagement plate 605. The limiting sleeve 603 is fixedly connected to the top cover 2, and the rotating cam 601 is fixedly connected to the connecting shaft at the top of the drive motor 501. The pin between the locking plate 604 and the movable connecting rod 602 is slidably connected to the inner side of the limiting sleeve 603. The corrugated interlocking plate 605 is L-shaped and is fixedly connected to the top of the filter steel mesh 7. The bottom end of the stress spring 606 is fixedly connected to the top cover 2 through the connecting plate. The corrugated interlocking plate 605 is elastically connected to the top cover 2 through the stress spring 606. The upper and lower ends of the rotating cam 601 are movably connected to one side of the top cover 2 through the limiting bracket.
[0061] In this embodiment, the rotating cam 601 is first fixed to the top of the connecting rod at the top of the drive motor 501. The connection between the movable connecting rod 602 and the rotating cam 601 allows one end of the movable connecting rod 602 to swing. The swinging effect is limited by the limiting sleeve 603, causing the movable connecting rod 602 to drive the locking plate 604 to reciprocate laterally on one side of the top cover 2. The locking plate 604 engages with the corrugated engagement plate 605. Thus, the lateral movement of the locking plate 604 enables the corrugated engagement plate to engage with the corrugated engagement plate 605. The plywood 605 is subjected to downward force, pressing the stress spring 606 and the filter steel mesh 7. The stress spring 606 is fixed to the top cover 2 by a connecting plate, while the filter steel mesh 7 is fixed to the top cover 2 at only one end. In this way, the filter steel mesh 7 is driven to achieve elastic vibration under the action of elasticity, so that the filter steel mesh 7 can shake at the top of the tank 3, shaking off the powder on the surface of the filter steel mesh 7, preventing the filter steel mesh 7 from clogging, and reducing the occurrence of dust in the tank 3 to a certain extent under the obstruction of the filter steel mesh 7.
[0062] like Figure 3 , Figure 7 and Figure 8As shown, the boiling mechanism 8 includes an annular sealing baffle 801, a convex blocking ring plate 802, an annular air groove 803, and eight sets of aeration ports 804. The convex blocking ring plate 802 is fixedly connected to the outer surface of the annular sealing baffle 801. The convex blocking ring plate 802 and the annular sealing baffle 801 are movably connected to the inner side of the annular air groove 803. The aeration ports 804 are fixedly connected to the bottom of the annular air groove 803, and the eight sets of aeration ports 804 are arranged in a ring array about the bottom surface of the annular air groove 803. The annular sealing baffle 801 is fixedly connected to the pulse air inlet 4. The aeration ports 804 communicate with the annular air groove 803, and the communication port is located directly below the convex blocking ring plate 802. The inner side of the annular sealing baffle 801 is fixedly connected to the top cover 2 via a connecting rod. An annular air groove 803 is formed on the inner surface of the tank body 3. The circumference of the outwardly convex barrier ring plate 802 is five-eighths of the circumference of the annular sealing baffle 801. The connection position between the pulse air inlet 4 and the annular sealing baffle 801 is located on the side away from the outwardly convex barrier ring plate 802. The aeration pipe port 804 is located on the top of two adjacent sets of actuating baffles 504, and the aeration pipe port 804 and the actuating baffles 504 are aligned with each other.
[0063] In this embodiment, the pulse air inlet 4 is directly connected to the annular sealing baffle 801, which pushes the air pressure into the annular air groove 803 inside the tank 3. The bottom end of the annular air groove 803 is connected to the eight sets of aeration pipe ports 804. However, the actual position where the air pressure can enter the aeration pipe ports 804 is located where the convex blocking ring plate 802 is not blocked. Thus, with the convex blocking ring plate 802 and the annular sealing baffle 801 blocking the annular air groove 803, the air pressure is pushed into the tank 3 from the three sets of aeration pipe ports 804, and aeration is performed on one side of the tank 3. The rotating tank 3 can realize that the aeration pipe ports 804 at different positions are filled with air within the specified position area, thereby further improving the mixing effect and making it suitable for mixing operations between various reagents.
[0064] Working principle: First, disinfectant powder of different media is poured directly into the inside of the tank 3 through the top cover 2. Then, the drive motor 501 in the actuation mechanism 5 on one side of the support base frame 1 rotates, which drives the transmission gear 502 at the top to rotate through the connecting rod. The transmission gear 502 meshes with the meshing groove 503 on the surface of the tank 3, and there is an angle between the tank 3 and the support base frame 1. Under the meshing action, the tank 3 can rotate between the support base frame 1 and the top cover 2. With the help of the eight sets of actuation baffles 504 on the inner surface of the tank 3, the powder is agitated inside the tank 3, thereby achieving a better stirring effect.
[0065] Meanwhile, the top connecting rod of the drive motor 501 can also drive the rotating cam 601 in the vibration mechanism 6 to rotate. Under the movable connection with the movable connecting rod 602, the rotating cam 601 can realize the reciprocating swing effect of one end of the movable connecting rod 602. This effect is transformed into lateral reciprocating motion under the limit of the limiting sleeve 603. In this way, the movable connecting rod 602 can drive the locking plate 604 and the corrugated biting plate 605 to engage frequently. The bottom end of the corrugated biting plate 605 is elastically connected to the top cover 2 through the stress spring 606, and the corrugated biting plate 605 is directly fixed to one end of the surface of the filter steel mesh 7. In this way, the filter steel mesh 7 can be subjected to a vibration effect, which shakes off the dust on the surface of the filter steel mesh 7, thereby preventing the filter steel mesh 7 from clogging.
[0066] While the tank 3 rotates to stir the powder, the pulse air inlet 4 can normally fill the annular air groove 803 in the boiling mechanism 8 with inert gases such as carbon dioxide. The gas flows in the annular air groove 803 and is blocked by the annular sealing baffle 801 and the outwardly protruding blocking ring plate 802, so that the gas directly enters the aeration pipe 804 below to blow gas and boil the powder. The annular sealing baffle 801 and the outwardly protruding blocking ring plate 802 are fixed to the top cover 2. In this way, the rotating tank 3 can drive the aeration pipe 804 at different positions to blow gas at the specified positions, thereby further realizing the stirring and mixing. Finally, carbon dioxide or other inert gases are discharged from the exhaust pipe 9 at the top of the top cover 2 and the tank 3 is discharged, completing the entire stirring and mixing operation.
[0067] The above description is merely a preferred embodiment of the present invention and is not intended to limit the present invention in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present invention without departing from the scope of the present invention shall still fall within the protection scope of the present invention.
Claims
1. A solid powder mixer for disinfectants, characterized in that: include: Base frame (1); The top cover (2) is fixedly connected to the top of the base frame (1) by a connecting rod. The top of the top cover (2) is fixedly connected to a pulse air inlet (4) and an exhaust pipe (9). The tank body (3) is movably connected to the opposite sides of the top cover (2) and the base frame (1) via bearings; A toggle mechanism (5) is provided on one side of the tank (3) to drive the tank (3) to rotate; The shaking mechanism (6) is located inside the top cover (2) and is fixedly connected to the top of the actuation mechanism (5) to drive the subsequent components to shake. The filter steel mesh (7) is connected to the bottom end of the top cover (2) by a spring frame; A boiling mechanism (8) is located at the bottom end of the pulse air inlet (4); The actuating mechanism (5) includes: The drive motor (501) has a connecting rod fixedly connected to its output shaft; The transmission gear (502) is fixedly connected to the connecting rod at the top of the drive motor (501), and the meshing groove (503) is opened on the surface of the tank (3), and the meshing groove (503) and the transmission gear (502) mesh with each other; The tooth diameter of the meshing tooth groove (503) is larger than the tooth diameter of the transmission tooth (502), and the eight sets of actuating baffles (504) are arranged in a ring array about the bottom of the inner surface of the tank (3), and there is an angle between the tank (3) and the ground. The vibration mechanism (6) includes: a rotating cam (601), a movable connecting rod (602), a limiting sleeve (603), a locking plate (604), a wave-shaped engagement plate (605), and a stress spring (606). The rotating cam (601) is fixedly connected to the top end of the connecting rod at the top of the drive motor (501). The two ends of the movable connecting rod (602) are movably connected to the rotating cam (601) and the locking plate (604) respectively through pins. The connection position between the movable connecting rod (602) and the rotating cam (601) is located at the maximum diameter of the rotating cam (601). The limiting sleeve (603) is fixedly connected to the top cover (2), and the limiting sleeve (603) is set on the top of the movable connecting rod (602). The end of the locking plate (604) away from the movable connecting rod (602) is engaged with the wave bite plate (605). The wave bite plate (605) is L-shaped and is fixedly connected to the top of the filter steel mesh (7). The stress spring (606) is fixedly connected to the bottom end of the wave bite plate (605). The bottom end of the stress spring (606) is fixedly connected to the top cover (2) through the connecting plate. The boiling mechanism (8) includes: an annular sealing baffle (801), an outwardly convex barrier ring plate (802), an annular gas groove (803), and eight sets of aeration pipe ports (804). The annular sealing baffle (801) is fixedly connected to the pulse air inlet (4). The inner side of the annular sealing baffle (801) is fixedly connected to the top cover (2) through a connecting rod. The outwardly convex barrier ring plate (802) is fixedly connected to the outer surface of the annular sealing baffle (801). The annular gas groove (803) is opened on the inner surface of the tank (3). The aeration pipe ports (804) are connected to the annular gas groove (803), and the connection port is located directly below the outwardly convex barrier ring plate (802). The aeration pipe ports (804) are fixedly connected to the bottom of the annular gas groove (803). The circumference of the convex barrier ring plate (802) is five-eighths of the circumference of the annular sealing baffle (801). The pulse air inlet (4) is directly connected to the annular sealing baffle (801) to push the air pressure into the annular air groove (803) inside the tank (3). The bottom end of the annular air groove (803) is connected to the eight sets of aeration pipes (804). The actual air pressure can enter the aeration pipes (804) at the position where the convex barrier ring plate (802) is not blocked. Under the blockage of the annular air groove (803) by the convex barrier ring plate (802) and the annular sealing baffle (801), the air pressure is pushed into the tank (3) from the three sets of aeration pipes (804) to perform aeration operation on one side of the tank (3). The tank (3) in the rotating state can realize that the aeration pipes (804) at different positions can be filled and aerated in the specified position area.
2. The disinfectant solid powder mixer according to claim 1, characterized in that: The pin between the cam plate (604) and the movable connecting rod (602) is slidably connected to the inner side of the limiting sleeve (603).
3. The disinfectant solid powder mixer according to claim 2, characterized in that: The wave-shaped interlocking plate (605) is elastically connected to the top cover (2) via a stress spring (606), and the upper and lower ends of the rotating cam (601) are movably connected to one side of the top cover (2) via a limiting bracket.
4. The disinfectant solid powder mixer according to claim 1, characterized in that: The convex barrier ring plate (802) and the annular sealing baffle (801) are movably connected to the inner side of the annular air groove (803), and the aeration pipes (804) are arranged in an annular array about the bottom surface of the annular air groove (803).
5. The disinfectant solid powder mixer according to claim 4, characterized in that: The connection between the pulse air inlet (4) and the annular sealing baffle (801) is located on the side away from the outwardly protruding barrier ring (802). The aeration port (804) is located at the top of two adjacent sets of actuating baffles (504), and the aeration port (804) and the actuating baffles (504) are aligned with each other.