A polishing solution chemical tank capable of avoiding deposition
By installing a stirring motor and an airflow mixing system in the polishing slurry tank, the problem of abrasive deposition in the polishing slurry is solved, and uniform mixing of components and automatic air delivery are achieved, which improves the performance of the polishing slurry and reduces costs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU SEMI PRECISION TECH CO LTD
- Filing Date
- 2025-08-14
- Publication Date
- 2026-06-09
AI Technical Summary
When the polishing slurry is left to stand, the abrasive components settle at the bottom, resulting in uneven mixing of the components and affecting the quality of use.
An anti-deposition assembly was designed, comprising a stirring motor, a stirring shaft, stirring blades, and a one-way jet nozzle. The stirring motor drives the stirring shaft to rotate, and gas is delivered through the air inlet pipe. The airflow is used to fully mix the polishing liquid, thus preventing particle sedimentation.
The polishing fluid components are uniformly mixed, improving the performance. The automatic air delivery via the circulation component reduces the operating cost of the device.
Smart Images

Figure CN224336263U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of polishing fluid treatment technology, specifically to a polishing fluid container that prevents sedimentation. Background Technology
[0002] Polishing fluid is a water-soluble polishing agent that does not contain any sulfur, phosphorus, or chlorine additives. It has excellent degreasing, rust prevention, cleaning, and brightening properties, and can make metal products reveal a true metallic luster. It is stable, non-toxic, and environmentally friendly.
[0003] Currently, because polishing slurries contain abrasive particles, these particles tend to settle at the bottom of the slurry when it is left to stand. This can lead to uneven mixing of the components, affecting the quality of the slurry when it is used. Utility Model Content
[0004] The purpose of this invention is to provide a polishing liquid container that avoids sedimentation, thereby solving the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a polishing liquid tank for preventing deposition, comprising a tank body and an anti-deposition component. A support is mounted on the top of the tank body, and a gearbox is mounted on the top of the support. A stirring motor is mounted on the input end of the gearbox. The anti-deposition component is located inside one end of the gearbox and includes a stirring shaft, an air inlet pipe, a stirring blade, and a one-way jet nozzle. The stirring shaft is mounted inside the output gear of the gearbox. An air inlet pipe is connected to the upper end of the stirring shaft, and a stirring blade is fixed to the outer side of the lower end of the stirring shaft. A one-way jet nozzle is mounted on the outer side of the stirring blade.
[0006] Furthermore, both the stirring shaft and the stirring blade are hollow inside, and the interiors of the stirring shaft and the stirring blade are connected.
[0007] Furthermore, the upper end of the intake pipe is connected to a circulation assembly, which includes a drive sleeve, a drive groove, a sliding column, and a lifting frame. The drive sleeve is fixed to the outside of the intake pipe, and a drive groove is opened on the outside of the drive sleeve. A sliding column is slidably connected inside the drive groove, and a lifting frame is fixed to one end of the sliding column.
[0008] Furthermore, the drive groove has a V-shaped structure with the ends connected, and the width of the drive groove is equal to the diameter of the sliding column.
[0009] Furthermore, the circulation assembly also includes a piston plate, an air cylinder, and a dustproof mesh plate. The piston plate is mounted on the top of the lifting frame, and an air cylinder is slidably connected to the outer side of the piston plate. A dustproof mesh plate is mounted on the top of the air cylinder.
[0010] Furthermore, the air cylinder is rotatably connected to the air inlet pipe, and the air cylinder is slidably connected to the lifting frame.
[0011] Furthermore, the circulation assembly also includes a one-way valve and an air intake pipe. The one-way valve is fixed to the outside of the air cylinder, and one end of the one-way valve is connected to the air intake pipe. The inside of the air intake pipe is connected to the inside of the cylinder.
[0012] Furthermore, a temperature sensor is installed on the lower outer side of the barrel, and a hanger is fixed inside the barrel, with a heat exchange tube installed at the lower part of the hanger.
[0013] This utility model provides a polishing liquid container that avoids sedimentation, and has the following beneficial effects:
[0014] 1. By setting up the anti-settling component, the stirring motor can drive the stirring shaft to rotate through the gearbox, so that the stirring blades can stir the lower part of the inside of the barrel. Secondly, the air inlet pipe can be used to deliver gas into the stirring shaft and spray it upward from the one-way jet nozzle. This allows the airflow to further mix the polishing liquid in the barrel while stirring, thereby preventing the particles in the polishing liquid from settling and ensuring that the components of the polishing liquid are mixed evenly, thus improving the product's performance.
[0015] 2. Through the setting of the circulation component, when the stirring shaft drives the air inlet pipe to rotate, the drive sleeve will rotate at the same time, and the air cylinder will limit and guide the lifting frame. Therefore, the drive groove will push the sliding column to make the lifting frame drive the piston plate to move up and down reciprocally. When the piston plate moves down, it will pump the air inside the air cylinder into the air inlet pipe to realize automatic air supply. When the piston plate moves up, the air at the upper end of the barrel will circulate to the air cylinder through the air suction pipe and the one-way valve to automatically replenish the gas. Thus, the automatic air supply function can be realized without adding an additional drive source during the stirring process, which helps to reduce the operating cost of the device. Attached Figure Description
[0016] Figure 1 This is a three-dimensional bottom view of the overall structure of the polishing liquid container that avoids sedimentation according to this utility model;
[0017] Figure 2 This is a schematic diagram of the internal structure of a polishing liquid container that avoids sedimentation, according to the present invention.
[0018] Figure 3 This is a three-dimensional structural diagram of an anti-deposition component for a polishing liquid tank that prevents deposition, according to the present invention.
[0019] Figure 4 This is a three-dimensional structural diagram of a lifting frame for a polishing liquid tank that prevents sedimentation, according to the present invention.
[0020] In the diagram: 1. Barrel body; 2. Support; 3. Gearbox; 4. Stirring motor; 5. Anti-settling component; 501. Stirring shaft; 502. Air inlet pipe; 503. Stirring blade; 504. One-way jet nozzle; 6. Circulation component; 601. Drive sleeve; 602. Drive groove; 603. Sliding column; 604. Lifting frame; 605. Piston plate; 606. Air cylinder; 607. Dustproof mesh plate; 608. One-way valve; 609. Suction pipe; 7. Temperature sensor; 8. Hanger; 9. Heat exchanger tube. Detailed Implementation
[0021] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model.
[0022] like Figures 1 to 3 As shown, a polishing liquid container for preventing deposition includes a container body 1 and an anti-deposition component 5. A support 2 is mounted on the top of the container body 1, and a gearbox 3 is mounted on the top of the support 2. A stirring motor 4 is mounted on the input end of the gearbox 3. The anti-deposition component 5 is located inside one end of the gearbox 3 and includes a stirring shaft 501, an air inlet pipe 502, stirring blades 503, and a one-way jet nozzle 504. The stirring shaft 501 is housed inside the output gear of the gearbox 3. The upper end of the stirring shaft 501 is connected to the air inlet pipe 502, and stirring blades 504 are fixed to the outer side of the lower end of the stirring shaft 501. 03. A one-way jet nozzle 504 is provided on the outside of the stirring blade 503. The stirring motor 4 can drive the stirring shaft 501 to rotate through the gearbox 3, so that the stirring blade 503 can stir the lower part of the inside of the barrel 1. The inside of the stirring shaft 501 and the stirring blade 503 are both hollow, and the inside of the stirring shaft 501 and the inside of the stirring blade 503 are connected. Gas is delivered into the stirring shaft 501 through the air inlet pipe 502 and sprayed upward from the one-way jet nozzle 504. At the same time as stirring, the airflow can be used to further mix the polishing liquid in the barrel 1, thereby avoiding the sedimentation of particles in the polishing liquid.
[0023] like Figures 1 to 4As shown, the upper end of the air intake pipe 502 is connected to a circulation assembly 6, which includes a drive sleeve 601, a drive groove 602, a sliding column 603, and a lifting frame 604. The drive sleeve 601 is fixed to the outside of the air intake pipe 502, and a drive groove 602 is formed on the outside of the drive sleeve 601. When the stirring shaft 501 drives the air intake pipe 502 to rotate, the drive sleeve 601 will rotate simultaneously. A sliding column 603 is slidably connected inside the drive groove 602, and a lifting frame 604 is fixed to one end of the sliding column 603. The drive groove 602 has a V-shaped structure with its ends connected. The width of the moving groove 602 is equal to the diameter of the sliding column 603. When the moving groove 602 rotates, it pushes the sliding column 603 to make the lifting frame 604 reciprocate up and down. The circulation assembly 6 also includes a piston plate 605, an air cylinder 606, and a dustproof mesh plate 607. The piston plate 605 is installed on the top of the lifting frame 604, and the air cylinder 606 is slidably connected to the outside of the piston plate 605. The top of the air cylinder 606 is equipped with a dustproof mesh plate 607 to prevent dust from falling into the upper part of the air cylinder 606. The air cylinder 606 is rotatably connected to the air inlet pipe 502, and the air cylinder 606 is connected to the lifting frame. The 604 sliding connection, due to the fixed connection between the air cylinder 606 and the support 2, limits and guides the lifting frame 604. The circulation assembly 6 also includes a one-way valve 608 and an air intake pipe 609. The one-way valve 608 is fixed to the outside of the air cylinder 606, and one end of the one-way valve 608 is connected to the air intake pipe 609. The inside of the air intake pipe 609 is connected to the inside of the barrel 1. When the piston plate 605 moves down, it pumps the air inside the air cylinder 606 into the air intake pipe 502 to achieve automatic air delivery. When the piston plate 605 moves up, the one-way jet head 504 closes, and the barrel... The air at the upper part of the body 1 is circulated to the air cylinder 606 through the air intake pipe 609 and the one-way valve 608 to automatically replenish the gas. The lower end of the air intake pipe 609 is also equipped with a commonly used filter cover to extend the service life of the equipment. A temperature sensor 7 is installed on the lower outer side of the body 1, and a hanger 8 is fixed inside the body 1. A heat exchange pipe 9 is installed at the lower part of the hanger 8. Since the heat exchange pipe 9 is equipped with inlet and outlet water pipes, external cold water or hot water can be pumped into the heat exchange pipe 9 through the pump body to exchange heat with the polishing liquid. The temperature of the polishing liquid is detected by the temperature sensor 7.
[0024] In summary, when using this polishing solution container to prevent sedimentation, first, according to... Figures 1 to 4The structure shown first activates the stirring motor 4 via the controller, causing it to drive the stirring shaft 501 to rotate via the gearbox 3. This causes the stirring blades 503 to stir the lower part of the interior of the barrel 1. Secondly, when the stirring shaft 501 drives the air inlet pipe 502 to rotate, the drive sleeve 601 rotates simultaneously. The air cylinder 606, fixedly connected to the support 2, limits and guides the lifting frame 604. Therefore, the drive groove 602 pushes the sliding column 603, causing the lifting frame 604 to drive the piston plate 605 in a reciprocating up-and-down motion. When the piston plate 605 moves downward, it pumps air from inside the air cylinder 606 into the air inlet pipe 502, which is then ejected upwards from the one-way jet nozzle 504 through the stirring shaft 501. This allows for simultaneous stirring and air circulation. The flow further mixes the polishing liquid in the barrel 1 thoroughly, thereby preventing the sedimentation of particles in the polishing liquid and ensuring uniform mixing of the polishing liquid components, thus improving the product's performance. Then, when the piston plate 605 moves upward, the air at the upper end of the barrel 1 will circulate to the air cylinder 606 through the suction pipe 609 and the one-way valve 608 due to the closure of the one-way jet head 504, automatically replenishing the gas. This allows for automatic gas delivery without the need for an additional drive source during the stirring process, which helps reduce the operating cost of the device. Finally, the heat exchange tube 9 is equipped with inlet and outlet water pipes. Cold or hot water can be supplied to the heat exchange tube 9 through the water supply equipment to exchange heat with the polishing liquid, and the temperature of the polishing liquid is detected by the temperature sensor 7.
[0025] The embodiments of this utility model are given for illustrative and descriptive purposes only, and are not intended to be exhaustive or to limit the utility model to the forms disclosed. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described in order to better illustrate the principles and practical applications of this utility model, and to enable those skilled in the art to understand this utility model and design various embodiments with various modifications suitable for a particular purpose.
Claims
1. A polishing slurry container for preventing deposition, comprising a container body (1) and an anti-deposition component (5), characterized in that, The top of the barrel (1) is provided with a support (2), and the top of the support (2) is provided with a gearbox (3). The input end of the gearbox (3) is provided with a stirring motor (4). The anti-deposition component (5) is provided inside one end of the gearbox (3). The anti-deposition component (5) includes a stirring shaft (501), an air inlet pipe (502), a stirring blade (503), and a one-way jet head (504). The output gear of the gearbox (3) is provided with a stirring shaft (501). The upper end of the stirring shaft (501) is connected to the air inlet pipe (502), and the lower end of the stirring shaft (501) is fixed with a stirring blade (503). The outer side of the stirring blade (503) is provided with a one-way jet head (504).
2. The polishing slurry tank for preventing deposition according to claim 1, characterized in that, The interiors of the stirring shaft (501) and the stirring blade (503) are both hollow, and the interiors of the stirring shaft (501) and the stirring blade (503) are connected.
3. The polishing slurry tank for preventing deposition according to claim 1, characterized in that, The upper end of the air intake pipe (502) is connected to a circulation assembly (6), and the circulation assembly (6) includes a drive sleeve (601), a drive groove (602), a slide column (603), and a lifting frame (604). The drive sleeve (601) is fixed to the outside of the air intake pipe (502), and a drive groove (602) is opened on the outside of the drive sleeve (601). The slide column (603) is slidably connected inside the drive groove (602), and a lifting frame (604) is fixed to one end of the slide column (603).
4. A polishing slurry container for preventing deposition according to claim 3, characterized in that, The drive groove (602) has a V-shaped structure with the ends connected, and the width of the drive groove (602) is equal to the diameter of the slide column (603).
5. A polishing slurry container for preventing deposition according to claim 3, characterized in that, The circulation assembly (6) further includes a piston plate (605), an air cylinder (606), and a dustproof mesh plate (607). The piston plate (605) is mounted on the top of the lifting frame (604), and the air cylinder (606) is slidably connected to the outside of the piston plate (605). The dustproof mesh plate (607) is mounted on the top of the air cylinder (606).
6. A polishing slurry tank for preventing deposition according to claim 5, characterized in that, The air cylinder (606) is rotatably connected to the air inlet pipe (502), and the air cylinder (606) is slidably connected to the lifting frame (604).
7. A polishing slurry container for preventing deposition according to claim 5, characterized in that, The circulation assembly (6) also includes a one-way valve (608) and an air intake pipe (609). The one-way valve (608) is fixed on the outside of the air cylinder (606), and one end of the one-way valve (608) is connected to the air intake pipe (609). The inside of the air intake pipe (609) is connected to the inside of the barrel (1).
8. A polishing slurry tank for preventing deposition according to claim 1, characterized in that, A temperature sensor (7) is installed on the lower outer side of the barrel (1), and a hanger (8) is fixed inside the barrel (1), and a heat exchange tube (9) is installed on the lower part of the hanger (8).