A feeding device for potassium fluosilicate synthesis production
By designing a potassium fluorosilicate synthesis production unit with quantitative feeding, the problems of reaction rate and yield caused by unstable feeding were solved, production efficiency was improved, costs were reduced, and maintenance procedures were simplified.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DEXING JIUBANG CHEM CO LTD
- Filing Date
- 2025-06-18
- Publication Date
- 2026-06-30
Smart Images

Figure CN224422794U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of potassium fluorosilicate technology, and in particular to a feeding device for the synthesis and production of potassium fluorosilicate. Background Technology
[0002] Potassium fluorosilicate (chemical formula K2SiF6) is an important inorganic compound. A feeding device for the synthesis and production of potassium fluorosilicate is a piece of equipment specifically designed for the synthesis and production of potassium fluorosilicate. It is mainly used to solve the problems of insufficient mixing and slow mixing speed when the mixed liquid is poured into the feeding device, thereby improving the production efficiency of potassium fluorosilicate.
[0003] During use, this utility model has several drawbacks. Since the solution is directly poured into the device, quantitative feeding is not possible. This means the amount of material fed each time may be inconsistent, leading to unstable material ratios during the reaction process. Consequently, the reaction rate and yield are affected, requiring operators to frequently adjust the feed rate, increasing operating time and workload, and reducing overall production efficiency. Furthermore, the unstable feed rate may result in raw material waste or shortages, increasing production costs. The inability to precisely control the feed rate also makes production cost estimation and budget control difficult. Therefore, an improved feeding device for the synthesis and production of potassium fluorosilicate is needed to solve these problems. Utility Model Content
[0004] To overcome the problem that the feeding device used in the synthesis and production of potassium fluorosilicate cannot feed the material quantitatively, which affects the reaction rate and yield, reduces the overall production efficiency, and increases the production cost.
[0005] The technical solution of this utility model is as follows: a feeding device for the synthesis and production of potassium fluorosilicate, including a stirring tank, a liquid suction shell, and a stirring assembly. A connecting base for fixing the device is provided at the bottom of the stirring tank. A tank cover for sealing the device is provided on the stirring tank. A support mounting plate is provided on the stirring tank, and a liquid inlet box for storing the solution is provided on the support mounting plate. The stirring assembly is located on the tank cover. The liquid suction shell and the extraction box are fixedly connected to the support mounting plate. An electric telescopic rod is provided inside the liquid suction shell, and a push plate for pushing the solution is provided on the electric telescopic rod. An air pump is fixedly connected to the support mounting plate. A rotating connecting rod is rotatably connected inside the extraction box. An adjusting bracket is provided on the rotating connecting rod, and a pushing rod is provided on the adjusting bracket. The pushing rod is located on the air pump. A three-way pipe is provided on the rotating connecting rod, and the three-way pipe is rotatably connected to the inside of the extraction box.
[0006] Preferably, the liquid suction shell and the extraction box are connected to each other by a pipe, and the discharge box and the extraction box are connected by a set pipe.
[0007] Preferably, the liquid suction shell has a groove at the corresponding position of the pusher plate, and the pusher plate slides inside the groove.
[0008] Preferably, a feed pipe is fixedly connected between the discharge box and the mixing tank, and an electric pusher shaft is slidably connected inside the discharge box.
[0009] Preferably, the discharge box has a groove at the corresponding position of the electric pusher shaft, and the electric pusher shaft slides inside the groove.
[0010] Preferably, the stirring assembly includes a drive motor, the output end of which is fixedly connected to a rotating shaft, the bottom of which is fixedly connected to a rotating rod, a sliding connecting sleeve slidably connected to the rotating rod, a stirring rod fixedly connected to the sliding connecting sleeve, a fixing bolt connected to the internal thread of the sliding connecting sleeve, a limit ring provided inside the stirring tank, the rotating rod rotatably connected inside the limit ring, a connecting limit shell fixedly connected to the outside of the stirring tank, a connecting bolt provided inside the connecting limit shell, the connecting bolt fixedly connected to an adjusting support frame, and a rotating fixing knob connected to the internal thread of the adjusting support frame.
[0011] Preferably, several connecting and limiting shells are provided, and the several connecting and limiting shells are evenly arranged on the mixing tank.
[0012] The beneficial effects of this utility model are:
[0013] 1. Compared to feeding devices used in the synthesis of potassium fluorosilicate that cannot quantitatively feed, this system uses an air pump to drive a rotating connecting rod on a manual adjustment bracket. This rotating connecting rod connects the liquid suction shell, extraction box, and inlet box via a three-way pipe. An electric telescopic rod pulls a push plate for quantitative extraction, effectively achieving quantitative feeding. This ensures consistency in each feed, prevents instability in material ratios during the reaction process, guarantees the reaction rate and output of the unit, eliminates the need for frequent feed adjustments, reduces operating time and workload, improves overall production efficiency, prevents waste or shortage of raw materials, and lowers production costs. This effectively prevents the inability of feeding devices used in the synthesis of potassium fluorosilicate to quantitatively feed, which could affect the reaction rate and output, reduce overall production efficiency, and increase production costs.
[0014] 2. By separating the tank cover from the mixing tank body, and by twisting the fixing bolts to make the sliding connecting sleeve, along with the mixing rod, slide off the rotating rod, the mixing rod can be separated and disassembled. During long-term use, components such as the mixing rod and bearings may wear or be damaged. The detachable design makes the replacement of these components simple and quick, without the need for large-scale disassembly of the entire feeding device, thereby shortening maintenance time and improving production efficiency. During the synthesis of potassium fluorosilicate, some solid particles or viscous substances may remain inside the mixing device. The detachable design allows operators to remove the mixing device for thorough cleaning, preventing residues from contaminating or affecting subsequent production. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of one embodiment of a feeding device for the synthesis and production of potassium fluorosilicate.
[0016] Figure 2 for Figure 1 Schematic diagram of the structure of the central support mounting plate;
[0017] Figure 3 for Figure 1 A schematic diagram of the internal structure of the components on the middle support mounting plate;
[0018] Figure 4 for Figure 1 Schematic diagram of the structure of the mixing tank;
[0019] Figure 5 for Figure 1 A partial structural diagram of the mixing tank.
[0020] Explanation of reference numerals in the attached drawings: 1. Mixing tank; 2. Connecting base; 3. Tank cover; 4. Support mounting plate; 5. Liquid inlet box; 801. Drive motor; 802. Rotating shaft; 803. Rotating rod; 804. Sliding connecting sleeve; 805. Mixing rod; 806. Fixing bolt; 807. Limiting ring; 808. Connecting limiting shell; 809. Connecting bolt; 810. Adjusting support frame; 811. Rotating fixing knob; 901. Liquid suction shell; 902. Extraction box; 903. Discharge box; 904. Air pump; 905. Rotating connecting rod; 906. Adjusting bracket; 907. Push rod; 908. Feed pipe; 909. Electric telescopic rod; 910. Push plate; 911. T-connector; 912. Electric pusher shaft. Detailed Implementation
[0021] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0022] Please see Figure 1 - Figure 5This utility model provides an embodiment: a feeding device for the synthesis and production of potassium fluorosilicate, including a stirring tank 1, a liquid suction shell 901, and a stirring assembly. A connecting base 2 for fixing the device is provided at the bottom of the stirring tank 1. A tank cover 3 for sealing the device is provided on the stirring tank 1. A support mounting plate 4 is provided on the stirring tank 1, and a liquid inlet box 5 for storing the solution is provided on the support mounting plate 4. The stirring assembly is located on the tank cover 3. The liquid suction shell 901 and the extraction box 902 are fixedly connected to the support mounting plate 4. An electric telescopic rod 909 is provided inside the liquid suction shell 901, and a pusher plate 910 for pushing the solution is provided on the electric telescopic rod 909. An air pump 904 is fixedly connected to the support mounting plate 4. A rotating connecting rod 905 is rotatably connected inside the extraction box 902, and an adjusting bracket 906 is provided on the rotating connecting rod 905. A pusher plate 906 is provided on the adjusting bracket 906. The moving rod 907 and the pushing rod 907 are mounted on the air pump 904. The rotating connecting rod 905 is equipped with a three-way pipe 911, which is rotatably connected to the inside of the extraction box 902. The air pump 904 drives the pushing rod 907 and the adjusting bracket 906 to drive the rotating connecting rod 905 to rotate inside the extraction box 902. The rotating connecting rod 905 drives the three-way pipe 911 to rotate to a suitable position, so that it connects the liquid suction shell 901 with the hot air three-way pipe 911 of the liquid inlet box 5. The electric telescopic rod 909 pulls the push plate 910 to draw an appropriate amount of solution from inside the liquid inlet box 5 into the liquid suction shell 901.
[0023] Please see Figure 4 - Figure 5 In this embodiment, the liquid suction shell 901 and the extraction box 902 are connected to each other via a pipe, and the discharge box 903 is connected to the extraction box 902 via a pipe. The pipes connecting the liquid suction shell 901, the extraction box 902, and the discharge box 903 guide the flow of the solution. The liquid suction shell 901 has a groove at a corresponding position on the push plate 910, and the push plate 910 slides within the groove. The groove within the push plate 910 limits its movement as it slides. A feed pipe 908 is fixedly connected between the discharge box 903 and the mixing tank 1. An electric pusher shaft 912 is slidably connected inside the discharge box 903. The solution in the discharge box 903 is pushed by the electric pusher shaft 912 through the feed pipe 908 into the mixing tank 1. A groove is provided in the discharge box 903 at the corresponding position of the electric pusher shaft 912. The electric pusher shaft 912 slides inside the groove. The groove provided inside the discharge box 903 at the corresponding position of the electric pusher shaft 912 limits the movement of the electric pusher shaft 912 inside the groove.
[0024] Please see Figure 2 - Figure 3In this embodiment, the stirring assembly includes a drive motor 801, a rotating shaft 802 fixedly connected to the output end of the drive motor 801, a rotating rod 803 fixedly connected to the bottom of the rotating shaft 802, a sliding connecting sleeve 804 slidably connected to the rotating rod 803, a stirring rod 805 fixedly connected to the sliding connecting sleeve 804, a fixing bolt 806 threadedly connected to the inside of the sliding connecting sleeve 804, a limiting ring 807 provided inside the stirring tank 1, the rotating rod 803 rotatably connected inside the limiting ring 807, and a connecting limiting shell 808 fixedly connected to the outside of the stirring tank 1. The internal part of 808 is provided with connecting bolts 809, which are fixedly connected to the adjusting support frame 810. The internal thread of the adjusting support frame 810 is connected to a rotating fixing knob 811. The driving motor 801 drives the rotating shaft 802 to drive the stirring rod 805 on the rotating rod 803 to stir the solution inside the mixing tank 1 to achieve uniform mixing. Several connecting limiting shells 808 are provided, and the several connecting limiting shells 808 are evenly arranged on the mixing tank 1. The several connecting limiting shells 808 make the mixing tank 1 more stable when the tank cover 3 is fixed.
[0025] During operation, when quantitatively injecting the solution, the air pump 904 drives the push rod 907 and the adjusting bracket 906 to rotate the connecting rod 905 inside the extraction box 902. The rotating connecting rod 905 rotates the three-way pipe 911 to the appropriate position, connecting the liquid suction shell 901 to the hot air three-way pipe 911 of the liquid inlet box 5. The electric telescopic rod 909 pulls the push plate 910 to draw an appropriate amount of solution from inside the liquid inlet box 5 into the liquid suction shell 901. The electric telescopic rod 909 pushes the push plate 910 to push the solution into the discharge box 903. The electric pusher shaft 912 then pushes the discharge box. The solution in box 903 is squeezed into the interior of the mixing tank 1 through the feed pipe 908. The drive motor 801 drives the rotating shaft 802 to drive the stirring rod 805 on the rotating rod 803 to stir the solution inside the mixing tank 1 to achieve uniform mixing. When disassembling, the rotating fixing knob 811 is turned to disengage it from the tank cover 3. The nut on the connecting bolt 809 is turned to rotate the adjusting support frame 810. The tank cover 3 and the stirring assembly are then lifted out through the handle on the tank cover 3. The sliding connecting sleeve 804 is disengaged from the stirring rod 805 by turning the fixing bolt 806, thus completing the disassembly.
[0026] Through the above steps, the air pump 904 drives the rotating connecting rod 905 on the labor adjustment bracket 906 to rotate. The rotating connecting rod 905 drives the three-way pipe 911 to connect the liquid suction shell 901 with the extraction box 902 and the liquid inlet box 5. The electric telescopic rod 909 pulls the push plate 910 to extract the liquid quantitatively. This solves the problem that the feeding device used for potassium fluorosilicate synthesis production cannot feed the liquid quantitatively, which affects the reaction rate and output, reduces the overall production efficiency, and increases the production cost.
Claims
1. A feeding device for the synthesis of potassium fluosilicate, comprising a stirred tank (1), characterized by the fact that it comprises: It also includes a liquid suction shell (901) and a stirring assembly. The bottom of the stirring tank (1) is provided with a connecting base (2) for fixing the device. The stirring tank (1) is provided with a tank cover (3) for sealing the device. The stirring tank (1) is provided with a support mounting plate (4). The support mounting plate (4) is provided with a liquid inlet box (5) for storing the solution. The stirring assembly is provided on the tank cover (3). The liquid suction shell (901) and the extraction box (902) are fixedly connected to the support mounting plate (4). The inside of the liquid suction shell (901) is provided with an electric telescopic rod (909). The electric telescopic rod (909) is provided with a pusher plate (910) for pushing the solution. An air pump (904) is fixedly connected to the support mounting plate (4). A rotating connecting rod (905) is rotatably connected inside the extraction box (902). An adjusting bracket (906) is provided on the rotating connecting rod (905). A push rod (907) is provided on the adjusting bracket (906). The push rod (907) is provided on the air pump (904). A three-way pipe (911) is provided on the rotating connecting rod (905). The three-way pipe (911) is rotatably connected inside the extraction box (902).
2. The feeding device for the synthesis of potassium fluosilicate according to claim 1, characterized in that: The liquid suction shell (901) and the extraction box (902) are connected to each other by a pipe, and the discharge box (903) and the extraction box (902) are connected by a set pipe.
3. The feeding device for the synthesis of potassium fluosilicate according to claim 1, characterized in that: The liquid suction shell (901) has a groove at the corresponding position of the push plate (910), and the push plate (910) slides inside the groove.
4. The feeding device for the synthesis of potassium fluosilicate according to claim 1, characterized in that: A feed pipe (908) is fixedly connected between the discharge box (903) and the mixing tank (1), and an electric pusher shaft (912) is slidably connected inside the discharge box (903).
5. The feeding device for the synthesis of potassium fluosilicate according to claim 4, characterized in that: The discharge box (903) has a groove at the corresponding position of the electric pusher shaft (912), and the electric pusher shaft (912) slides inside the groove.
6. The feeding device for the synthesis of potassium fluosilicate according to claim 1, characterized in that: The stirring assembly includes a drive motor (801), the output end of the drive motor (801) is fixedly connected to a rotating shaft (802), the bottom of the rotating shaft (802) is fixedly connected to a rotating rod (803), a sliding connecting sleeve (804) is slidably connected to the rotating rod (803), a stirring rod (805) is fixedly connected to the sliding connecting sleeve (804), a fixing bolt (806) is threaded inside the sliding connecting sleeve (804), a limiting ring (807) is provided inside the stirring tank (1), the rotating rod (803) is rotatably connected inside the limiting ring (807), a connecting limiting shell (808) is fixedly connected to the outside of the stirring tank (1), a connecting bolt (809) is provided inside the connecting limiting shell (808), the connecting bolt (809) is fixedly connected to the adjusting support frame (810), and a rotating fixing knob (811) is threaded inside the adjusting support frame (810).
7. The feeding device for the synthesis of potassium fluosilicate according to claim 6, characterized in that: A number of connecting limiting shells (808) are provided, and the number of connecting limiting shells (808) are evenly arranged on the mixing tank (1).